VirtualBox

source: vbox/trunk/src/VBox/Devices/USB/DevXHCI.cpp@ 99844

Last change on this file since 99844 was 99739, checked in by vboxsync, 19 months ago

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1/* $Id: DevXHCI.cpp 99739 2023-05-11 01:01:08Z vboxsync $ */
2/** @file
3 * DevXHCI - eXtensible Host Controller Interface for USB.
4 */
5
6/*
7 * Copyright (C) 2012-2023 Oracle and/or its affiliates.
8 *
9 * This file is part of VirtualBox base platform packages, as
10 * available from https://www.virtualbox.org.
11 *
12 * This program is free software; you can redistribute it and/or
13 * modify it under the terms of the GNU General Public License
14 * as published by the Free Software Foundation, in version 3 of the
15 * License.
16 *
17 * This program is distributed in the hope that it will be useful, but
18 * WITHOUT ANY WARRANTY; without even the implied warranty of
19 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
20 * General Public License for more details.
21 *
22 * You should have received a copy of the GNU General Public License
23 * along with this program; if not, see <https://www.gnu.org/licenses>.
24 *
25 * SPDX-License-Identifier: GPL-3.0-only
26 */
27
28/** @page pg_dev_xhci xHCI - eXtensible Host Controller Interface Emulation.
29 *
30 * This component implements an xHCI USB controller.
31 *
32 * The xHCI device is significantly different from the EHCI and OHCI
33 * controllers in that it is not timer driven. A worker thread is responsible
34 * for transferring data between xHCI and VUSB.
35 *
36 * Since there can be dozens or even hundreds of USB devices, and because USB
37 * transfers must share the same bus, only one worker thread is created (per
38 * host controller).
39 *
40 *
41 * The xHCI operational model is heavily based around a producer/consumer
42 * model utilizing rings -- Command, Event, and Transfer rings. The Event ring
43 * is only written by the xHC and is read-only for the HCD (Host Controller
44 * Driver). The Command/Transfer rings are only written by the HCD and are
45 * read-only for the xHC.
46 *
47 * The rings contain TRBs (Transfer Request Blocks). The TRBs represent not
48 * only data transfers but also commands and status information. Each type of
49 * ring only produces/consumes specific TRB types.
50 *
51 * When processing a ring, the xHC simply keeps advancing an internal pointer.
52 * For the Command/Transfer rings, the HCD uses Link TRBs to manage the ring
53 * storage in a fairly arbitrary manner. Since the HCD cannot write to the
54 * Event ring, the Event Ring Segment Table (ERST) is used to manage the ring
55 * storage instead.
56 *
57 * The Cycle bit is used to manage the ring buffer full/empty condition. The
58 * Producer and Consumer both have their own Cycle State (PCS/CCS). The Cycle
59 * bit of each TRB determines who owns it. The consumer only processes TRBs
60 * whose Cycle bit matches the CCS. HCD software typically toggles the Cycle
61 * bit on each pass through the ring. The Link TRB can be used to toggle the
62 * CCS accordingly.
63 *
64 * Multiple Transfer TRBs can be chained together (via the Chain bit) into a
65 * single Transfer Descriptor (TD). This provides a convenient capability for
66 * the HCD to turn a URB into a single TD regardless of how the URB is laid
67 * out in physical memory. If a transfer encounters an error or is terminated
68 * by a short packet, the entire TD (i.e. chain of TRBs) is retired.
69 *
70 * Note that the xHC detects and handles short packets on its own. Backends
71 * are always asked not to consider a short packet to be an error condition.
72 *
73 * Command and Event TRBs cannot be chained, thus an ED (Event Descriptor)
74 * or a Command Descriptor (CD) always consists of a single TRB.
75 *
76 * There is one Command ring per xHC, one Event ring per interrupter (one or
77 * more), and a potentially very large number of Transfer rings. There is a
78 * 1:1 mapping between Transfer Rings and USB pipes, hence each USB device
79 * uses 1-31 Transfer rings (at least one for the default control endpoint,
80 * up to 31 if all IN/OUT endpoints are used). USB 3.0 devices may also use
81 * up to 64K streams per endpoint, each with its Transfer ring, massively
82 * increasing the potential number of Transfer rings in use.
83 *
84 * When building a Transfer ring, it's possible to queue up a large number
85 * of TDs and as soon as the oldest ones are retired, queue up new TDs. The
86 * Transfer ring might thus never be empty.
87 *
88 * For tracking ring buffer position, the TRDP and TREP fields in an endpoint
89 * context are used. The TRDP is the 'TR Dequeue Pointer', i.e. the position
90 * of the next TRB to be completed. This field is visible by the HCD when the
91 * endpoint isn't running. It reflects TRBs completely processed by the xHC
92 * and hence no longer owned by the xHC.
93 *
94 * The TREP field is the 'TR Enqueue Pointer' and tracks the position of the
95 * next TRB to start processing (submit). This is purely internal to the
96 * xHC. The TREP can potentially get far ahead of the TRDP, but only in the
97 * part of the ring owned by the xHC (i.e. with matching DCS bit).
98 *
99 * Unlike most other xHCI data structures, transfer TRBs may describe memory
100 * buffers with no alignment restrictions (both starting position and size).
101 * In addition, there is no relationship between TRB boundaries and USB
102 * packet boundaries.
103 *
104 *
105 * Typically an event would be generated via the IOC bit (Interrupt On
106 * Completion) when the last TRB of a TD is completed. However, multiple IOC
107 * bits may be set per TD. This may be required when a TD equal or larger
108 * than 16MB is used, since transfer events utilize a 24-bit length field.
109 *
110 * There is also the option of using Transfer Event TRBs to report TRB
111 * completion. Transfer Event TRBs may be freely intermixed with transfer
112 * TRBs. Note that an event TRB will produce an event reporting the size of
113 * data transferred since the last event TRB or since the beginning of a TD.
114 * The xHC submits URBs such that they either comprise the entire TD or end
115 * at a Transfer Event TRB, thus there is no need to track the EDTLA
116 * separately.
117 *
118 * Transfer errors always generate events, irrespective of IOC settings. The
119 * xHC has always the option to generate events at implementation-specific
120 * points so that the HCD does not fall too far behind.
121 *
122 * Control transfers use special TDs. A Setup Stage TD consists of only a
123 * single Setup Stage TRB (there's no Chain bit). The optional Data Stage
124 * TD consists of a Data Stage TRB chained to zero or more Normal TRBs
125 * and/or Event Data TRBs. The Status Stage TD then consists of a Status
126 * Stage TRB optionally chained to an Event Data TRB. The HCD is responsible
127 * for building the TDs correctly.
128 *
129 * For isochronous transfers, only the first TRB of a TD is actually an
130 * isochronous TRB. If the TD is chained, it will contain Normal TRBs (and
131 * possibly Event Data TRBs).
132 *
133 *
134 * Isochronous transfers require multiple TDs/URBs to be in flight at a
135 * time. This complicates dealing with non-data TRBs (such as link or event
136 * data TRBs). These TRBs cannot be completed while a previous TRB is still
137 * in flight. They are completed either: a) when submitting URBs and there
138 * are no in-flight URBs, or b) just prior to completing an URB.
139 *
140 * This approach works because URBs must be completed strictly in-order. The
141 * TRDP and TREP determine whether there are in-flight TRBs (TREP equals
142 * TRDP if and only if there are no in-flight TRBs).
143 *
144 * When submitting TRBs and there is in-flight traffic, non-data TRBs must
145 * be examined and skipped over. Link TRBs need to be taken into account.
146 *
147 * Unfortunately, certain HCDs (looking at you, Microsoft!) violate the xHCI
148 * specification and make assumptions about how far ahead of the TRDP the
149 * xHC can get. We have to artificially limit the number of in-flight TDs
150 * for this reason.
151 *
152 * Non-isochronous TRBs do not require this treatment for correct function
153 * but are likely to benefit performance-wise from the pipelining.
154 *
155 * With high-speed and faster transfers, there is an added complication for
156 * endpoints with more than one transfer per frame, i.e. short intervals. At
157 * least some host USB stacks require URBs to cover an entire frame, which
158 * means we may have to glue together several TDs into a single URB.
159 *
160 *
161 * A buggy or malicious guest can create a transfer or command ring that
162 * loops in on itself (in the simplest case using a sequence of one or more
163 * link TRBs where the last TRB points to the beginning of the sequence).
164 * Such a loop would effectively hang the processing thread. Since we cannot
165 * easily detect a generic loop, and because even non-looped TRB/command
166 * rings might contain extremely large number of items, we limit the number
167 * of entries that we are willing to process at once. If the limit is
168 * crossed, the xHC reports a host controller error and shuts itself down
169 * until it's reset.
170 *
171 * Note that for TRB lists, both URB submission and completion must protect
172 * against loops because the lists in guest memory are not guaranteed to stay
173 * unchanged between submitting and completing URBs.
174 *
175 * The event ring is not susceptible to loops because the xHC is the producer,
176 * not consumer. The event ring can run out of space but that is not a fatal
177 * problem.
178 *
179 *
180 * The interrupt logic uses an internal IPE (Interrupt Pending Enable) bit
181 * which controls whether the register-visible IP (Interrupt Pending) bit
182 * can be set. The IPE bit is set when a non-blocking event (BEI bit clear)
183 * is enqueued. The IPE bit is cleared when the event ring is initialized or
184 * transitions to empty (i.e. ERDP == EREP). When IPE transtitions to set,
185 * it will set IP unless the EHB (Event Handler Busy) bit is set or IMODC
186 * (Interrupt Moderation Counter) is non-zero. When IMODC counts down to
187 * zero, it sets the IP bit if IPE is set and EHB is not. Setting the IP bit
188 * triggers interrupt delivery. Note that clearing the IPE bit does not
189 * change the IP bit state.
190 *
191 * Interrupt delivery depends on whether MSI/MSI-X is in use or not. With MSI,
192 * an interrupter's IP (Interrupt Pending) bit is cleared as soon as the MSI
193 * message is written; with classic PCI interrupt delivery, the HCD must clear
194 * the IP bit. However, the EHB (Event Handler Busy) bit is always set, which
195 * causes further interrupts to be blocked on the interrupter until the HCD
196 * processes pending events and clears the EHB bit.
197 *
198 * Note that clearing the EHB bit may immediately trigger an interrupt if
199 * additional event TRBs were queued up while the HCD was processing previous
200 * ones.
201 *
202 *
203 * Each enabled USB device has a corresponding slot ID, a doorbell, as well as
204 * a device context which can be accessed through the DCBAA (Device Context
205 * Base Address Array). Valid slot IDs are in the 1-255 range; the first entry
206 * (i.e. index 0) in the DCBAA may optionally point to the Scratchpad Buffer
207 * Array, while doorbell 0 is associated with the Command Ring.
208 *
209 * While 255 valid slot IDs is an xHCI architectural limit, existing xHC
210 * implementations usually set a considerably lower limit, such as 32. See
211 * the XHCI_NDS constant.
212 *
213 * It would be tempting to use the DCBAA to determine which slots are free.
214 * Unfortunately the xHC is not allowed to access DCBAA entries which map to
215 * disabled slots (see section 6.1). A parallel aSlotState array is hence used
216 * to internally track the slot state and find available slots. Once a slot
217 * is enabled, the slot context entry in the DCBAA is used to track the
218 * slot state.
219 *
220 *
221 * Unlike OHCI/UHCI/EHCI, the xHC much more closely tracks USB device state.
222 * HCDs are not allowed to issue SET_ADDRESS requests at all and must use
223 * the Address Device xHCI command instead.
224 *
225 * HCDs can use SET_CONFIGURATION and SET_INTERFACE requests normally, but
226 * must inform the xHC of the changes via Configure Endpoint and Evaluate
227 * Context commands. Similarly there are Reset Endpoint and Stop Endpoint
228 * commands to manage endpoint state.
229 *
230 * A corollary of the above is that unlike OHCI/UHCI/EHCI, with xHCI there
231 * are very clear rules and a straightforward protocol for managing
232 * ownership of structures in physical memory. During normal operation, the
233 * xHC owns all device context memory and the HCD must explicitly ask the xHC
234 * to relinquish the ownership.
235 *
236 * The xHCI architecture offers an interesting feature in that it reserves
237 * opaque fields for xHCI use in certain data structures (slot and endpoint
238 * contexts) and gives the xHC an option to request scratchpad buffers that
239 * a HCD must provide. The xHC may use the opaque storage and/or scratchpad
240 * buffers for saving internal state.
241 *
242 * For implementation reasons, the xHCI device creates two root hubs on the
243 * VUSB level; one for USB2 devices (USB 1.x and 2.0), one for USB3. The
244 * behavior of USB2 vs. USB3 ports is different, and a device can only be
245 * attached to either one or the other hub. However, there is a single array
246 * of ports to avoid overly complicating the code, given that port numbering
247 * is linear and encompasses both USB2 and USB3 ports.
248 *
249 *
250 * The default emulated device is an Intel 7-Series xHC aka Panther Point.
251 * This was Intel's first xHC and is widely supported. It is also possible
252 * to select an Intel 8-Series xHC aka Lynx Point; this is only useful for
253 * debugging and requires the 'other' set of Windows 7 drivers.
254 *
255 * For Windows XP guest support, it is possible to emulate a Renesas
256 * (formerly NEC) uPD720201 xHC. It would be possible to emulate the earlier
257 * NEC chips but those a) only support xHCI 0.96, and b) their drivers
258 * require a reboot during installation. Renesas' drivers also support
259 * Windows Vista and 7.
260 *
261 *
262 * NB: Endpoints are addressed differently in xHCI and USB. In USB,
263 * endpoint addresses are 8-bit values with the low four bits identifying
264 * the endpoint number and the high bit indicating the direction (0=OUT,
265 * 1=IN); see e.g. 9.3.4 in USB 2.0 spec. In xHCI, endpoint addresses are
266 * used as DCIs (Device Context Index) and for that reason, they're
267 * compressed into 5 bits where the lowest bit(!) indicates direction (again
268 * 1=IN) and bits 1-4 designate the endpoint number. Endpoint 0 is somewhat
269 * special and uses DCI 1. See 4.8.1 in xHCI spec.
270 *
271 *
272 * NB: A variable named iPort is a zero-based index into the port array.
273 * On the other hand, a variable named uPort is a one-based port number!
274 * The implementation (obviously) uses zero-based indexing, but USB ports
275 * are numbered starting with 1. The same is true of xHCI slot numbering.
276 * The macros IDX_TO_ID() and ID_TO_IDX(a) should be used to convert between
277 * the two numbering conventions to make the intent clear.
278 *
279 */
280
281
282/*********************************************************************************************************************************
283* Header Files *
284*********************************************************************************************************************************/
285#define LOG_GROUP LOG_GROUP_DEV_XHCI
286#include <VBox/pci.h>
287#include <VBox/msi.h>
288#include <VBox/vmm/pdm.h>
289#include <VBox/err.h>
290#include <VBox/log.h>
291#include <iprt/assert.h>
292#ifdef IN_RING3
293# include <iprt/uuid.h>
294# include <iprt/critsect.h>
295#endif
296#include <VBox/vusb.h>
297#ifdef VBOX_IN_EXTPACK_R3
298# include <VBox/version.h>
299#endif
300#ifndef VBOX_IN_EXTPACK
301# include "VBoxDD.h"
302#endif
303
304
305/*********************************************************************************************************************************
306* (Most of the) Defined Constants, Macros and Structures *
307*********************************************************************************************************************************/
308
309/* Optional error injection support via DBGF. */
310//#define XHCI_ERROR_INJECTION
311
312/** The saved state version. */
313#define XHCI_SAVED_STATE_VERSION 1
314
315
316/** Convert a zero-based index to a 1-based ID. */
317#define IDX_TO_ID(a) (a + 1)
318/** Convert a 1-based ID to a zero-based index. */
319#define ID_TO_IDX(a) (a - 1)
320
321/** PCI device related constants. */
322#define XHCI_PCI_MSI_CAP_OFS 0x80
323
324/** Number of LUNs/root hubs. One each for USB2/USB3. */
325#define XHCI_NUM_LUNS 2
326
327/** @name The following two constants were determined experimentally.
328 * They determine the maximum number of TDs allowed to be in flight.
329 * NB: For isochronous TDs, the number *must* be limited because
330 * Windows 8+ violates the xHCI specification and does not keep
331 * the transfer rings consistent.
332 * @{
333 */
334//#define XHCI_MAX_ISOC_IN_FLIGHT 3 /* Scarlett needs 3; was 12 */
335#define XHCI_MAX_ISOC_IN_FLIGHT 12
336#define XHCI_MAX_BULK_IN_FLIGHT 8
337/** @} */
338
339/** @name Implementation limit on the number of TRBs and commands
340 * the xHC is willing to process at once. A larger number is taken
341 * to indicate a broken or malicious guest, and causes a HC error.
342 * @{
343 */
344#define XHCI_MAX_NUM_CMDS 128
345#define XHCI_MAX_NUM_TRBS 1024
346/** @} */
347
348/** Implementation TD size limit. Prevents EDTLA wrap-around. */
349#define XHCI_MAX_TD_SIZE (16 * _1M - 1)
350
351/** Special value to prevent further queuing. */
352#define XHCI_NO_QUEUING_IN_FLIGHT (XHCI_MAX_BULK_IN_FLIGHT * 2)
353
354/* Structural Parameters #1 (HCSPARAMS1) values. */
355
356/** Maximum allowed Number of Downstream Ports on the root hub. Careful
357 * when changing -- other structures may need adjusting!
358 */
359#define XHCI_NDP_MAX 32
360
361/** Default number of USB 2.0 ports.
362 *
363 * @note AppleUSBXHCI does not handle more than 15 ports. At least OS X
364 * 10.8.2 crashes if we report more than 15 ports! Hence the default
365 * is 8 USB2 + 6 USB3 ports for a total of 14 so that OS X is happy.
366 */
367#define XHCI_NDP_20_DEFAULT 8
368
369/** Default number of USB 3.0 ports. */
370#define XHCI_NDP_30_DEFAULT 6
371
372/** Number of interrupters. */
373#define XHCI_NINTR 8
374
375/** Mask for interrupter indexing. */
376#define XHCI_INTR_MASK (XHCI_NINTR - 1)
377
378/* The following is only true if XHCI_NINTR is a (non-zero) power of two. */
379AssertCompile((XHCI_NINTR & XHCI_INTR_MASK) == 0);
380
381/** Number of Device Slots. Determines the number of doorbell
382 * registers and device slots, among other things. */
383#define XHCI_NDS 32
384
385/* Enforce xHCI architectural limits on HCSPARAMS1. */
386AssertCompile(XHCI_NDP_MAX < 255 && XHCI_NINTR < 1024 && XHCI_NDS < 255);
387AssertCompile(XHCI_NDP_20_DEFAULT + XHCI_NDP_30_DEFAULT <= XHCI_NDP_MAX);
388AssertCompile(XHCI_NDP_MAX <= XHCI_NDS);
389
390/* Structural Parameters #2 (HCSPARAMS2) values. */
391
392/** Isochronous Scheduling Threshold. */
393#define XHCI_IST (RT_BIT(3) | 1) /* One frame. */
394
395/** Max number of Event Ring Segment Table entries as a power of two. */
396#define XHCI_ERSTMAX_LOG2 5
397/** Max number of Event Ring Segment Table entries. */
398#define XHCI_ERSTMAX RT_BIT(XHCI_ERSTMAX_LOG2)
399
400/* Enforce xHCI architectural limits on HCSPARAMS2. */
401AssertCompile(XHCI_ERSTMAX_LOG2 < 16);
402
403
404/** Size of the xHCI memory-mapped I/O region. */
405#define XHCI_MMIO_SIZE _64K
406
407/** Size of the capability part of the MMIO region. */
408#define XHCI_CAPS_REG_SIZE 0x80
409
410/** Offset of the port registers in operational register space. */
411#define XHCI_PORT_REG_OFFSET 0x400
412
413/** Offset of xHCI extended capabilities in MMIO region. */
414#define XHCI_XECP_OFFSET 0x1000
415
416/** Offset of the run-time registers in MMIO region. */
417#define XHCI_RTREG_OFFSET 0x2000
418
419/** Offset of the doorbell registers in MMIO region. */
420#define XHCI_DOORBELL_OFFSET 0x3000
421
422/** Size of the extended capability area. */
423#define XHCI_EXT_CAP_SIZE 1024
424
425/* Make sure we can identify MMIO register accesses properly. */
426AssertCompile(XHCI_DOORBELL_OFFSET > XHCI_RTREG_OFFSET);
427AssertCompile(XHCI_XECP_OFFSET > XHCI_PORT_REG_OFFSET + XHCI_CAPS_REG_SIZE);
428AssertCompile(XHCI_RTREG_OFFSET > XHCI_XECP_OFFSET + XHCI_EXT_CAP_SIZE);
429
430
431/** Maximum size of a single extended capability. */
432#define MAX_XCAP_SIZE 256
433
434/** @name xHCI Extended capability types.
435 * @{ */
436#define XHCI_XCP_USB_LEGACY 1 /**< USB legacy support. */
437#define XHCI_XCP_PROTOCOL 2 /**< Protocols supported by ports. */
438#define XHCI_XCP_EXT_PM 3 /**< Extended power management (non-PCI). */
439#define XHCI_XCP_IOVIRT 4 /**< Hardware xHCI virtualization support. */
440#define XHCI_XCP_MSI 5 /**< Message interrupts (non-PCI). */
441#define XHCI_XCP_LOCAL_MEM 6 /**< Local memory (for debug support). */
442#define XHCI_XCP_USB_DEBUG 10 /**< USB debug capability. */
443#define XHCI_XCP_EXT_MSI 17 /**< MSI-X (non-PCI). */
444/** @} */
445
446
447/* xHCI Register Bits. */
448
449
450/** @name Capability Parameters (HCCPARAMS) bits
451 * @{ */
452#define XHCI_HCC_AC64 RT_BIT(0) /**< RO */
453#define XHCI_HCC_BNC RT_BIT(1) /**< RO */
454#define XHCI_HCC_CSZ RT_BIT(2) /**< RO */
455#define XHCI_HCC_PPC RT_BIT(3) /**< RO */
456#define XHCI_HCC_PIND RT_BIT(4) /**< RO */
457#define XHCI_HCC_LHRC RT_BIT(5) /**< RO */
458#define XHCI_HCC_LTC RT_BIT(6) /**< RO */
459#define XHCI_HCC_NSS RT_BIT(7) /**< RO */
460#define XHCI_HCC_MAXPSA_MASK (RT_BIT(12)|RT_BIT(13)|RT_BIT(14)| RT_BIT(15)) /**< RO */
461#define XHCI_HCC_MAXPSA_SHIFT 12
462#define XHCI_HCC_XECP_MASK 0xFFFF0000 /**< RO */
463#define XHCI_HCC_XECP_SHIFT 16
464/** @} */
465
466
467/** @name Command Register (USBCMD) bits
468 * @{ */
469#define XHCI_CMD_RS RT_BIT(0) /**< RW - Run/Stop */
470#define XHCI_CMD_HCRST RT_BIT(1) /**< RW - Host Controller Reset */
471#define XHCI_CMD_INTE RT_BIT(2) /**< RW - Interrupter Enable */
472#define XHCI_CMD_HSEE RT_BIT(3) /**< RW - Host System Error Enable */
473#define XHCI_CMD_LCRST RT_BIT(7) /**< RW - Light HC Reset */
474#define XHCI_CMD_CSS RT_BIT(8) /**< RW - Controller Save State */
475#define XHCI_CMD_CRS RT_BIT(9) /**< RW - Controller Restore State */
476#define XHCI_CMD_EWE RT_BIT(10) /**< RW - Enable Wrap Event */
477#define XHCI_CMD_EU3S RT_BIT(11) /**< RW - Enable U3 MFINDEX Stop */
478
479#define XHCI_CMD_MASK ( XHCI_CMD_RS | XHCI_CMD_HCRST | XHCI_CMD_INTE | XHCI_CMD_HSEE | XHCI_CMD_LCRST \
480 | XHCI_CMD_CSS | XHCI_CMD_CRS | XHCI_CMD_EWE | XHCI_CMD_EU3S)
481/** @} */
482
483
484/** @name Status Register (USBSTS) bits
485 * @{ */
486#define XHCI_STATUS_HCH RT_BIT(0) /**< RO - HC Halted */
487#define XHCI_STATUS_HSE RT_BIT(2) /**< RW1C - Host System Error */
488#define XHCI_STATUS_EINT RT_BIT(3) /**< RW1C - Event Interrupt */
489#define XHCI_STATUS_PCD RT_BIT(4) /**< RW1C - Port Change Detect */
490#define XHCI_STATUS_SSS RT_BIT(8) /**< RO - Save State Status */
491#define XHCI_STATUS_RSS RT_BIT(9) /**< RO - Resture State Status */
492#define XHCI_STATUS_SRE RT_BIT(10) /**< RW1C - Save/Restore Error */
493#define XHCI_STATUS_CNR RT_BIT(11) /**< RO - Controller Not Ready */
494#define XHCI_STATUS_HCE RT_BIT(12) /**< RO - Host Controller Error */
495
496#define XHCI_STATUS_WRMASK (XHCI_STATUS_HSE | XHCI_STATUS_EINT | XHCI_STATUS_PCD | XHCI_STATUS_SRE)
497/** @} */
498
499
500/** @name Default xHCI speed definitions (7.2.2.1.1)
501 * @{ */
502#define XHCI_SPD_FULL 1
503#define XHCI_SPD_LOW 2
504#define XHCI_SPD_HIGH 3
505#define XHCI_SPD_SUPER 4
506/** @} */
507
508/** @name Port Status and Control Register bits (PORTSCUSB2/PORTSCUSB3)
509 * @{ */
510#define XHCI_PORT_CCS RT_BIT(0) /**< ROS - Current Connection Status */
511#define XHCI_PORT_PED RT_BIT(1) /**< RW1S - Port Enabled/Disabled */
512#define XHCI_PORT_OCA RT_BIT(3) /**< RO - Over-current Active */
513#define XHCI_PORT_PR RT_BIT(4) /**< RW1S - Port Reset */
514#define XHCI_PORT_PLS_MASK (RT_BIT(5) | RT_BIT(6) | RT_BIT(7) | RT_BIT(8)) /**< RWS */
515#define XHCI_PORT_PLS_SHIFT 5
516#define XHCI_PORT_PP RT_BIT(9) /**< RWS - Port Power */
517#define XHCI_PORT_SPD_MASK (RT_BIT(10) | RT_BIT(11) | RT_BIT(12) | RT_BIT(13)) /**< ROS */
518#define XHCI_PORT_SPD_SHIFT 10
519#define XHCI_PORT_LWS RT_BIT(16) /**< RW - Link State Write Strobe */
520#define XHCI_PORT_CSC RT_BIT(17) /**< RW1CS - Connect Status Change */
521#define XHCI_PORT_PEC RT_BIT(18) /**< RW1CS - Port Enabled/Disabled Change */
522#define XHCI_PORT_WRC RT_BIT(19) /**< RW1CS - Warm Port Reset Change */
523#define XHCI_PORT_OCC RT_BIT(20) /**< RW1CS - Over-current Change */
524#define XHCI_PORT_PRC RT_BIT(21) /**< RW1CS - Port Reset Change */
525#define XHCI_PORT_PLC RT_BIT(22) /**< RW1CS - Port Link State Change */
526#define XHCI_PORT_CEC RT_BIT(23) /**< RW1CS - Port Config Error Change */
527#define XHCI_PORT_CAS RT_BIT(24) /**< RO - Cold Attach Status */
528#define XHCI_PORT_WCE RT_BIT(25) /**< RWS - Wake on Connect Enable */
529#define XHCI_PORT_WDE RT_BIT(26) /**< RWS - Wake on Disconnect Enable */
530#define XHCI_PORT_WOE RT_BIT(27) /**< RWS - Wake on Over-current Enable */
531#define XHCI_PORT_DR RT_BIT(30) /**< RO - Device (Not) Removable */
532#define XHCI_PORT_WPR RT_BIT(31) /**< RW1S - Warm Port Reset */
533
534#define XHCI_PORT_RESERVED (RT_BIT(2) | RT_BIT(14) | RT_BIT(15) | RT_BIT(28) | RT_BIT(29))
535
536#define XHCI_PORT_WAKE_MASK (XHCI_PORT_WCE|XHCI_PORT_WDE|XHCI_PORT_WOE)
537#define XHCI_PORT_CHANGE_MASK (XHCI_PORT_CSC|XHCI_PORT_PEC|XHCI_PORT_WRC|XHCI_PORT_OCC|XHCI_PORT_PRC|XHCI_PORT_PLC|XHCI_PORT_CEC)
538#define XHCI_PORT_CTL_RW_MASK (XHCI_PORT_PP|XHCI_PORT_LWS)
539#define XHCI_PORT_CTL_W1_MASK (XHCI_PORT_PED|XHCI_PORT_PR|XHCI_PORT_WPR)
540#define XHCI_PORT_RO_MASK (XHCI_PORT_CCS|XHCI_PORT_OCA|XHCI_PORT_SPD_MASK|XHCI_PORT_CAS|XHCI_PORT_DR)
541/** @} */
542
543/** @name Port Link State values
544 * @{ */
545#define XHCI_PLS_U0 0 /**< U0 State. */
546#define XHCI_PLS_U1 1 /**< U1 State. */
547#define XHCI_PLS_U2 2 /**< U2 State. */
548#define XHCI_PLS_U3 3 /**< U3 State (Suspended). */
549#define XHCI_PLS_DISABLED 4 /**< Disabled. */
550#define XHCI_PLS_RXDETECT 5 /**< RxDetect. */
551#define XHCI_PLS_INACTIVE 6 /**< Inactive. */
552#define XHCI_PLS_POLLING 7 /**< Polling. */
553#define XHCI_PLS_RECOVERY 8 /**< Recovery. */
554#define XHCI_PLS_HOTRST 9 /**< Hot Reset. */
555#define XHCI_PLS_CMPLMODE 10 /**< Compliance Mode. */
556#define XHCI_PLS_TSTMODE 11 /**< Test Mode. */
557/* Values 12-14 are reserved. */
558#define XHCI_PLS_RESUME 15 /**< Resume. */
559/** @} */
560
561
562/** @name Command Ring Control Register (CRCR) bits
563 * @{ */
564#define XHCI_CRCR_RCS RT_BIT(0) /**< RW - Ring Cycle State */
565#define XHCI_CRCR_CS RT_BIT(1) /**< RW1S - Command Stop */
566#define XHCI_CRCR_CA RT_BIT(2) /**< RW1S - Command Abort */
567#define XHCI_CRCR_CRR RT_BIT(3) /**< RO - Command Ring Running */
568
569#define XHCI_CRCR_RD_MASK UINT64_C(0xFFFFFFFFFFFFFFF8) /* Mask off bits always read as zero. */
570#define XHCI_CRCR_ADDR_MASK UINT64_C(0xFFFFFFFFFFFFFFC0)
571#define XHCI_CRCR_UPD_MASK (XHCI_CRCR_ADDR_MASK | XHCI_CRCR_RCS)
572/** @} */
573
574
575/** @name Interrupter Management Register (IMAN) bits
576 * @{ */
577#define XHCI_IMAN_IP RT_BIT(0) /**< RW1C - Interrupt Pending */
578#define XHCI_IMAN_IE RT_BIT(1) /**< RW - Interrupt Enable */
579
580#define XHCI_IMAN_VALID_MASK (XHCI_IMAN_IP | XHCI_IMAN_IE)
581/** @} */
582
583
584/** @name Interrupter Moderation Register (IMOD) bits
585 * @{ */
586#define XHCI_IMOD_IMODC_MASK 0xFFFF0000 /**< RW */
587#define XHCI_IMOD_IMODC_SHIFT 16
588#define XHCI_IMOD_IMODI_MASK 0x0000FFFF /**< RW */
589/** @} */
590
591
592/** @name Event Ring Segment Table Size Register (ERSTSZ) bits
593 * @{ */
594#define XHCI_ERSTSZ_MASK 0x0000FFFF /**< RW */
595/** @} */
596
597/** @name Event Ring Segment Table Base Address Register (ERSTBA) bits
598 * @{ */
599#define XHCI_ERST_ADDR_MASK UINT64_C(0xFFFFFFFFFFFFFFC0)
600/** @} */
601
602/** For reasons that are not obvious, NEC/Renesas xHCs only require 16-bit
603 * alignment for the ERST base. This is not in line with the xHCI spec
604 * (which requires 64-bit alignment) but is clearly documented by NEC.
605 */
606#define NEC_ERST_ADDR_MASK UINT64_C(0xFFFFFFFFFFFFFFF0)
607
608/** Firmware revision reported in NEC/Renesas mode. Value chosen based on
609 * OS X driver check (OS X supports these chips since they're commonly
610 * found in ExpressCards).
611 */
612#define NEC_FW_REV 0x3028
613
614/** @name Event Ring Deqeue Pointer Register (ERDP) bits
615 * @{ */
616#define XHCI_ERDP_DESI_MASK 0x00000007 /**< RW - Dequeue ERST Segment Index */
617#define XHCI_ERDP_EHB RT_BIT(3) /**< RW1C - Event Handler Busy */
618#define XHCI_ERDP_ADDR_MASK UINT64_C(0xFFFFFFFFFFFFFFF0) /**< RW - ERDP address mask */
619/** @} */
620
621/** @name Device Context Base Address Array (DCBAA) definitions
622 * @{ */
623#define XHCI_DCBAA_ADDR_MASK UINT64_C(0xFFFFFFFFFFFFFFC0) /**< Applies to DCBAAP and its entries. */
624/** @} */
625
626/** @name Doorbell Register bits
627 * @{ */
628#define XHCI_DB_TGT_MASK 0x000000FF /**< DB Target mask. */
629#define XHCI_DB_STRMID_SHIFT 16 /**< DB Stream ID shift. */
630#define XHCI_DB_STRMID_MASK 0xFFFF0000 /**< DB Stream ID mask. */
631/** @} */
632
633/** Address mask for device/endpoint/input contexts. */
634#define XHCI_CTX_ADDR_MASK UINT64_C(0xFFFFFFFFFFFFFFF0)
635
636/** @name TRB Completion Codes
637 * @{ */
638#define XHCI_TCC_INVALID 0 /**< CC field not updated. */
639#define XHCI_TCC_SUCCESS 1 /**< Successful TRB completion. */
640#define XHCI_TCC_DATA_BUF_ERR 2 /**< Overrun/underrun. */
641#define XHCI_TCC_BABBLE 3 /**< Babble detected. */
642#define XHCI_TCC_USB_XACT_ERR 4 /**< USB transaction error. */
643#define XHCI_TCC_TRB_ERR 5 /**< TRB error detected. */
644#define XHCI_TCC_STALL 6 /**< USB Stall detected. */
645#define XHCI_TCC_RSRC_ERR 7 /**< Inadequate xHC resources. */
646#define XHCI_TCC_BWIDTH_ERR 8 /**< Unable to allocate bandwidth. */
647#define XHCI_TCC_NO_SLOTS 9 /**< MaxSlots (NDS) exceeded. */
648#define XHCI_TCC_INV_STRM_TYP 10 /**< Invalid stream context type. */
649#define XHCI_TCC_SLOT_NOT_ENB 11 /**< Slot not enabled. */
650#define XHCI_TCC_EP_NOT_ENB 12 /**< Endpoint not enabled. */
651#define XHCI_TCC_SHORT_PKT 13 /**< Short packet detected. */
652#define XHCI_TCC_RING_UNDERRUN 14 /**< Transfer ring underrun. */
653#define XHCI_TCC_RING_OVERRUN 15 /**< Transfer ring overrun. */
654#define XHCI_TCC_VF_RING_FULL 16 /**< VF event ring full. */
655#define XHCI_TCC_PARM_ERR 17 /**< Invalid context parameter. */
656#define XHCI_TCC_BWIDTH_OVER 18 /**< Isoc bandwidth overrun. */
657#define XHCI_TCC_CTX_STATE_ERR 19 /**< Transition from illegal context state. */
658#define XHCI_TCC_NO_PING 20 /**< No ping response in time. */
659#define XHCI_TCC_EVT_RING_FULL 21 /**< Event Ring full. */
660#define XHCI_TCC_DEVICE_COMPAT 22 /**< Incompatible device detected. */
661#define XHCI_TCC_MISS_SVC 23 /**< Missed isoc service. */
662#define XHCI_TCC_CMDR_STOPPED 24 /**< Command ring stopped. */
663#define XHCI_TCC_CMD_ABORTED 25 /**< Command aborted. */
664#define XHCI_TCC_STOPPED 26 /**< Endpoint stopped. */
665#define XHCI_TCC_STP_INV_LEN 27 /**< EP stopped, invalid transfer length. */
666 /* 28 Reserved. */
667#define XHCI_TCC_MAX_EXIT_LAT 29 /**< Max exit latency too large. */
668 /* 30 Reserved. */
669#define XHCI_TCC_ISOC_OVERRUN 31 /**< Isochronous buffer overrun. */
670#define XHCI_TCC_EVT_LOST 32 /**< Event lost due to overrun. */
671#define XHCI_TCC_ERR_OTHER 33 /**< Implementation specific error. */
672#define XHCI_TCC_INV_STRM_ID 34 /**< Invalid stream ID. */
673#define XHCI_TCC_SEC_BWIDTH_ERR 35 /**< Secondary bandwidth error. */
674#define XHCI_TCC_SPLIT_ERR 36 /**< Split transaction error. */
675/** @} */
676
677#if defined(IN_RING3) && defined(LOG_ENABLED)
678/** Human-readable completion code descriptions for debugging. */
679static const char * const g_apszCmplCodes[] = {
680 "CC field not updated", "Successful TRB completion", "Overrun/underrun", "Babble detected", /* 0-3 */
681 "USB transaction error", "TRB error detected", "USB Stall detected", "Inadequate xHC resources", /* 4-7 */
682 "Unable to allocate bandwidth", "MaxSlots (NDS) exceeded", "Invalid stream context type", "Slot not enabled", /* 8-11 */
683 "Endpoint not enabled", "Short packet detected", "Transfer ring underrun", "Transfer ring overrun", /* 12-15 */
684 "VF event ring full", "Invalid context param", "Isoc bandwidth overrun", "Transition from illegal ctx state", /* 16-19 */
685 "No ping response in time", "Event Ring full", "Incompatible device detected", "Missed isoc service", /* 20-23 */
686 "Command ring stopped", "Command aborted", "Endpoint stopped", "EP stopped, invalid transfer length", /* 24-27 */
687 "Reserved", "Max exit latency too large", "Reserved", "Isochronous buffer overrun", /* 28-31 */
688 "Event lost due to overrun", "Implementation specific error", "Invalid stream ID", "Secondary bandwidth error", /* 32-35 */
689 "Split transaction error" /* 36 */
690};
691#endif
692
693
694/* TRBs marked as 'TRB' are only valid in the transfer ring. TRBs marked
695 * as 'Command' are only valid in the command ring. TRBs marked as 'Event'
696 * are the only ones generated in the event ring. The Link TRB is valid
697 * in both the transfer and command rings.
698 */
699
700/** @name TRB Types
701 * @{ */
702#define XHCI_TRB_INVALID 0 /**< Reserved/unused TRB type. */
703#define XHCI_TRB_NORMAL 1 /**< Normal TRB. */
704#define XHCI_TRB_SETUP_STG 2 /**< Setup Stage TRB. */
705#define XHCI_TRB_DATA_STG 3 /**< Data Stage TRB. */
706#define XHCI_TRB_STATUS_STG 4 /**< Status Stage TRB. */
707#define XHCI_TRB_ISOCH 5 /**< Isochronous TRB. */
708#define XHCI_TRB_LINK 6 /**< Link. */
709#define XHCI_TRB_EVT_DATA 7 /**< Event Data TRB. */
710#define XHCI_TRB_NOOP_XFER 8 /**< No-op transfer TRB. */
711#define XHCI_TRB_ENB_SLOT 9 /**< Enable Slot Command. */
712#define XHCI_TRB_DIS_SLOT 10 /**< Disable Slot Command. */
713#define XHCI_TRB_ADDR_DEV 11 /**< Address Device Command. */
714#define XHCI_TRB_CFG_EP 12 /**< Configure Endpoint Command. */
715#define XHCI_TRB_EVAL_CTX 13 /**< Evaluate Context Command. */
716#define XHCI_TRB_RESET_EP 14 /**< Reset Endpoint Command. */
717#define XHCI_TRB_STOP_EP 15 /**< Stop Endpoint Command. */
718#define XHCI_TRB_SET_DEQ_PTR 16 /**< Set TR Dequeue Pointer Command. */
719#define XHCI_TRB_RESET_DEV 17 /**< Reset Device Command. */
720#define XHCI_TRB_FORCE_EVT 18 /**< Force Event Command. */
721#define XHCI_TRB_NEG_BWIDTH 19 /**< Negotiate Bandwidth Command. */
722#define XHCI_TRB_SET_LTV 20 /**< Set Latency Tolerate Value Command. */
723#define XHCI_TRB_GET_PORT_BW 21 /**< Get Port Bandwidth Command. */
724#define XHCI_TRB_FORCE_HDR 22 /**< Force Header Command. */
725#define XHCI_TRB_NOOP_CMD 23 /**< No-op Command. */
726 /* 24-31 Reserved. */
727#define XHCI_TRB_XFER 32 /**< Transfer Event. */
728#define XHCI_TRB_CMD_CMPL 33 /**< Command Completion Event. */
729#define XHCI_TRB_PORT_SC 34 /**< Port Status Change Event. */
730#define XHCI_TRB_BW_REQ 35 /**< Bandwidth Request Event. */
731#define XHCI_TRB_DBELL 36 /**< Doorbell Event. */
732#define XHCI_TRB_HC_EVT 37 /**< Host Controller Event. */
733#define XHCI_TRB_DEV_NOTIFY 38 /**< Device Notification Event. */
734#define XHCI_TRB_MFIDX_WRAP 39 /**< MFINDEX Wrap Event. */
735 /* 40-47 Reserved. */
736#define NEC_TRB_CMD_CMPL 48 /**< Command Completion Event, NEC specific. */
737#define NEC_TRB_GET_FW_VER 49 /**< Get Firmware Version Command, NEC specific. */
738#define NEC_TRB_AUTHENTICATE 50 /**< Authenticate Command, NEC specific. */
739/** @} */
740
741#if defined(IN_RING3) && defined(LOG_ENABLED)
742/** Human-readable TRB names for debugging. */
743static const char * const g_apszTrbNames[] = {
744 "Reserved/unused TRB!!", "Normal TRB", "Setup Stage TRB", "Data Stage TRB", /* 0-3 */
745 "Status Stage TRB", "Isochronous TRB", "Link", "Event Data TRB", /* 4-7 */
746 "No-op transfer TRB", "Enable Slot", "Disable Slot", "Address Device", /* 8-11 */
747 "Configure Endpoint", "Evaluate Context", "Reset Endpoint", "Stop Endpoint", /* 12-15 */
748 "Set TR Dequeue Pointer", "Reset Device", "Force Event", "Negotiate Bandwidth", /* 16-19 */
749 "Set Latency Tolerate Value", "Get Port Bandwidth", "Force Header", "No-op", /* 20-23 */
750 "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", /* 24-31 */
751 "Transfer", "Command Completion", "Port Status Change", "BW Request", /* 32-35 */
752 "Doorbell", "Host Controller", "Device Notification", "MFINDEX Wrap", /* 36-39 */
753 "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", "UNDEF", /* 40-47 */
754 "NEC FW Version Completion", "NEC Get FW Version", "NEC Authenticate" /* 48-50 */
755};
756#endif
757
758/** Generic TRB template. */
759typedef struct sXHCI_TRB_G {
760 uint32_t resvd0;
761 uint32_t resvd1;
762 uint32_t resvd2 : 24;
763 uint32_t cc : 8; /**< Completion Code. */
764 uint32_t cycle : 1; /**< Cycle bit. */
765 uint32_t resvd3 : 9;
766 uint32_t type : 6; /**< TRB Type. */
767 uint32_t resvd4 : 16;
768} XHCI_TRB_G;
769AssertCompile(sizeof(XHCI_TRB_G) == 0x10);
770
771/** Generic transfer TRB template. */
772typedef struct sXHCI_TRB_GX {
773 uint32_t resvd0;
774 uint32_t resvd1;
775 uint32_t xfr_len : 17; /**< Transfer length. */
776 uint32_t resvd2 : 5;
777 uint32_t int_tgt : 10; /**< Interrupter target. */
778 uint32_t cycle : 1; /**< Cycle bit. */
779 uint32_t ent : 1; /**< Evaluate Next TRB. */
780 uint32_t isp : 1; /**< Interrupt on Short Packet. */
781 uint32_t ns : 1; /**< No Snoop. */
782 uint32_t ch : 1; /**< Chain bit. */
783 uint32_t ioc : 1; /**< Interrupt On Completion. */
784 uint32_t idt : 1; /**< Immediate Data. */
785 uint32_t resvd3 : 3;
786 uint32_t type : 6; /**< TRB Type. */
787 uint32_t resvd4 : 16;
788} XHCI_TRB_GX;
789AssertCompile(sizeof(XHCI_TRB_GX) == 0x10);
790
791
792/* -= Transfer TRB types =- */
793
794
795/** Normal Transfer TRB. */
796typedef struct sXHCI_TRB_NORM {
797 uint64_t data_ptr; /**< Pointer or data. */
798 uint32_t xfr_len : 17; /**< Transfer length. */
799 uint32_t td_size : 5; /**< Remaining packets. */
800 uint32_t int_tgt : 10; /**< Interrupter target. */
801 uint32_t cycle : 1; /**< Cycle bit. */
802 uint32_t ent : 1; /**< Evaluate Next TRB. */
803 uint32_t isp : 1; /**< Interrupt on Short Packet. */
804 uint32_t ns : 1; /**< No Snoop. */
805 uint32_t ch : 1; /**< Chain bit. */
806 uint32_t ioc : 1; /**< Interrupt On Completion. */
807 uint32_t idt : 1; /**< Immediate Data. */
808 uint32_t resvd0 : 2;
809 uint32_t bei : 1; /**< Block Event Interrupt. */
810 uint32_t type : 6; /**< TRB Type. */
811 uint32_t resvd1 : 16;
812} XHCI_TRB_NORM;
813AssertCompile(sizeof(XHCI_TRB_NORM) == 0x10);
814
815/** Control Transfer - Setup Stage TRB. */
816typedef struct sXHCI_TRB_CTSP {
817 uint8_t bmRequestType; /**< See the USB spec. */
818 uint8_t bRequest;
819 uint16_t wValue;
820 uint16_t wIndex;
821 uint16_t wLength;
822 uint32_t xfr_len : 17; /**< Transfer length (8). */
823 uint32_t resvd0 : 5;
824 uint32_t int_tgt : 10; /**< Interrupter target. */
825 uint32_t cycle : 1; /**< Cycle bit. */
826 uint32_t resvd1 : 4;
827 uint32_t ioc : 1; /**< Interrupt On Completion. */
828 uint32_t idt : 1; /**< Immediate Data. */
829 uint32_t resvd2 : 2;
830 uint32_t bei : 1; /**< Block Event Interrupt. */
831 uint32_t type : 6; /**< TRB Type. */
832 uint32_t trt : 2; /**< Transfer Type. */
833 uint32_t resvd3 : 14;
834} XHCI_TRB_CTSP;
835AssertCompile(sizeof(XHCI_TRB_CTSP) == 0x10);
836
837/** Control Transfer - Data Stage TRB. */
838typedef struct sXHCI_TRB_CTDT {
839 uint64_t data_ptr; /**< Pointer or data. */
840 uint32_t xfr_len : 17; /**< Transfer length. */
841 uint32_t td_size : 5; /**< Remaining packets. */
842 uint32_t int_tgt : 10; /**< Interrupter target. */
843 uint32_t cycle : 1; /**< Cycle bit. */
844 uint32_t ent : 1; /**< Evaluate Next TRB. */
845 uint32_t isp : 1; /**< Interrupt on Short Packet. */
846 uint32_t ns : 1; /**< No Snoop. */
847 uint32_t ch : 1; /**< Chain bit. */
848 uint32_t ioc : 1; /**< Interrupt On Completion. */
849 uint32_t idt : 1; /**< Immediate Data. */
850 uint32_t resvd0 : 3;
851 uint32_t type : 6; /**< TRB Type. */
852 uint32_t dir : 1; /**< Direction (1=IN). */
853 uint32_t resvd1 : 15;
854} XHCI_TRB_CTDT;
855AssertCompile(sizeof(XHCI_TRB_CTDT) == 0x10);
856
857/** Control Transfer - Status Stage TRB. */
858typedef struct sXHCI_TRB_CTSS {
859 uint64_t resvd0;
860 uint32_t resvd1 : 22;
861 uint32_t int_tgt : 10; /**< Interrupter target. */
862 uint32_t cycle : 1; /**< Cycle bit. */
863 uint32_t ent : 1; /**< Evaluate Next TRB. */
864 uint32_t resvd2 : 2;
865 uint32_t ch : 1; /**< Chain bit. */
866 uint32_t ioc : 1; /**< Interrupt On Completion. */
867 uint32_t resvd3 : 4;
868 uint32_t type : 6; /**< TRB Type. */
869 uint32_t dir : 1; /**< Direction (1=IN). */
870 uint32_t resvd4 : 15;
871} XHCI_TRB_CTSS;
872AssertCompile(sizeof(XHCI_TRB_CTSS) == 0x10);
873
874/** Isochronous Transfer TRB. */
875typedef struct sXHCI_TRB_ISOC {
876 uint64_t data_ptr; /**< Pointer or data. */
877 uint32_t xfr_len : 17; /**< Transfer length. */
878 uint32_t td_size : 5; /**< Remaining packets. */
879 uint32_t int_tgt : 10; /**< Interrupter target. */
880 uint32_t cycle : 1; /**< Cycle bit. */
881 uint32_t ent : 1; /**< Evaluate Next TRB. */
882 uint32_t isp : 1; /**< Interrupt on Short Packet. */
883 uint32_t ns : 1; /**< No Snoop. */
884 uint32_t ch : 1; /**< Chain bit. */
885 uint32_t ioc : 1; /**< Interrupt On Completion. */
886 uint32_t idt : 1; /**< Immediate Data. */
887 uint32_t tbc : 2; /**< Transfer Burst Count. */
888 uint32_t bei : 1; /**< Block Event Interrupt. */
889 uint32_t type : 6; /**< TRB Type. */
890 uint32_t tlbpc : 4; /**< Transfer Last Burst Packet Count. */
891 uint32_t frm_id : 11; /**< Frame ID. */
892 uint32_t sia : 1; /**< Start Isoch ASAP. */
893} XHCI_TRB_ISOC;
894AssertCompile(sizeof(XHCI_TRB_ISOC) == 0x10);
895
896/* Number of bits in the frame ID. */
897#define XHCI_FRAME_ID_BITS 11
898
899/** No Op Transfer TRB. */
900typedef struct sXHCI_TRB_NOPT {
901 uint64_t resvd0;
902 uint32_t resvd1 : 22;
903 uint32_t int_tgt : 10; /**< Interrupter target. */
904 uint32_t cycle : 1; /**< Cycle bit. */
905 uint32_t ent : 1; /**< Evaluate Next TRB. */
906 uint32_t resvd2 : 2;
907 uint32_t ch : 1; /**< Chain bit. */
908 uint32_t ioc : 1; /**< Interrupt On Completion. */
909 uint32_t resvd3 : 4;
910 uint32_t type : 6; /**< TRB Type. */
911 uint32_t resvd4 : 16;
912} XHCI_TRB_NOPT;
913AssertCompile(sizeof(XHCI_TRB_NOPT) == 0x10);
914
915
916/* -= Event TRB types =- */
917
918
919/** Transfer Event TRB. */
920typedef struct sXHCI_TRB_TE {
921 uint64_t trb_ptr; /**< TRB pointer. */
922 uint32_t xfr_len : 24; /**< Transfer length. */
923 uint32_t cc : 8; /**< Completion Code. */
924 uint32_t cycle : 1; /**< Cycle bit. */
925 uint32_t resvd0 : 1;
926 uint32_t ed : 1; /**< Event Data flag. */
927 uint32_t resvd1 : 7;
928 uint32_t type : 6; /**< TRB Type. */
929 uint32_t ep_id : 5; /**< Endpoint ID. */
930 uint32_t resvd2 : 3;
931 uint32_t slot_id : 8; /**< Slot ID. */
932} XHCI_TRB_TE;
933AssertCompile(sizeof(XHCI_TRB_TE) == 0x10);
934
935/** Command Completion Event TRB. */
936typedef struct sXHCI_TRB_CCE {
937 uint64_t trb_ptr; /**< Command TRB pointer. */
938 uint32_t resvd0 : 24;
939 uint32_t cc : 8; /**< Completion Code. */
940 uint32_t cycle : 1; /**< Cycle bit. */
941 uint32_t resvd1 : 9;
942 uint32_t type : 6; /**< TRB Type. */
943 uint32_t vf_id : 8; /**< Virtual Function ID. */
944 uint32_t slot_id : 8; /**< Slot ID. */
945} XHCI_TRB_CCE;
946AssertCompile(sizeof(XHCI_TRB_CCE) == 0x10);
947
948/** Port Staus Change Event TRB. */
949typedef struct sXHCI_TRB_PSCE {
950 uint32_t resvd0 : 24;
951 uint32_t port_id : 8; /**< Port ID. */
952 uint32_t resvd1;
953 uint32_t resvd2 : 24;
954 uint32_t cc : 8; /**< Completion Code. */
955 uint32_t cycle : 1; /**< Cycle bit. */
956 uint32_t resvd3 : 9;
957 uint32_t type : 6; /**< TRB Type. */
958 uint32_t resvd4 : 16;
959} XHCI_TRB_PSCE;
960AssertCompile(sizeof(XHCI_TRB_PSCE) == 0x10);
961
962/** Bandwidth Request Event TRB. */
963typedef struct sXHCI_TRB_BRE {
964 uint32_t resvd0;
965 uint32_t resvd1;
966 uint32_t resvd2 : 24;
967 uint32_t cc : 8; /**< Completion Code. */
968 uint32_t cycle : 1; /**< Cycle bit. */
969 uint32_t resvd3 : 9;
970 uint32_t type : 6; /**< TRB Type. */
971 uint32_t resvd4 : 8;
972 uint32_t slot_id : 8; /**< Slot ID. */
973} XHCI_TRB_BRE;
974AssertCompile(sizeof(XHCI_TRB_BRE) == 0x10);
975
976/** Doorbell Event TRB. */
977typedef struct sXHCI_TRB_DBE {
978 uint32_t reason : 5; /**< DB Reason/target. */
979 uint32_t resvd0 : 27;
980 uint32_t resvd1;
981 uint32_t resvd2 : 24;
982 uint32_t cc : 8; /**< Completion Code. */
983 uint32_t cycle : 1; /**< Cycle bit. */
984 uint32_t resvd3 : 9;
985 uint32_t type : 6; /**< TRB Type. */
986 uint32_t vf_id : 8; /**< Virtual Function ID. */
987 uint32_t slot_id : 8; /**< Slot ID. */
988} XHCI_TRB_DBE;
989AssertCompile(sizeof(XHCI_TRB_DBE) == 0x10);
990
991/** Host Controller Event TRB. */
992typedef struct sXHCI_TRB_HCE {
993 uint32_t resvd0;
994 uint32_t resvd1;
995 uint32_t resvd2 : 24;
996 uint32_t cc : 8; /**< Completion Code. */
997 uint32_t cycle : 1; /**< Cycle bit. */
998 uint32_t resvd3 : 9;
999 uint32_t type : 6; /**< TRB Type. */
1000 uint32_t resvd4 : 16;
1001} XHCI_TRB_HCE;
1002AssertCompile(sizeof(XHCI_TRB_HCE) == 0x10);
1003
1004/** Device Notification Event TRB. */
1005typedef struct sXHCI_TRB_DNE {
1006 uint32_t resvd0 : 4;
1007 uint32_t dn_type : 4; /**< Device Notification Type. */
1008 uint32_t dnd_lo : 5; /**< Device Notification Data Lo. */
1009 uint32_t dnd_hi; /**< Device Notification Data Hi. */
1010 uint32_t resvd1 : 24;
1011 uint32_t cc : 8; /**< Completion Code. */
1012 uint32_t cycle : 1; /**< Cycle bit. */
1013 uint32_t resvd2 : 9;
1014 uint32_t type : 6; /**< TRB Type. */
1015 uint32_t resvd3 : 8;
1016 uint32_t slot_id : 8; /**< Slot ID. */
1017} XHCI_TRB_DNE;
1018AssertCompile(sizeof(XHCI_TRB_DNE) == 0x10);
1019
1020/** MFINDEX Wrap Event TRB. */
1021typedef struct sXHCI_TRB_MWE {
1022 uint32_t resvd0;
1023 uint32_t resvd1;
1024 uint32_t resvd2 : 24;
1025 uint32_t cc : 8; /**< Completion Code. */
1026 uint32_t cycle : 1; /**< Cycle bit. */
1027 uint32_t resvd3 : 9;
1028 uint32_t type : 6; /**< TRB Type. */
1029 uint32_t resvd4 : 16;
1030} XHCI_TRB_MWE;
1031AssertCompile(sizeof(XHCI_TRB_MWE) == 0x10);
1032
1033/** NEC Specific Command Completion Event TRB. */
1034typedef struct sXHCI_TRB_NCE {
1035 uint64_t trb_ptr; /**< Command TRB pointer. */
1036 uint32_t word1 : 16; /**< First result word. */
1037 uint32_t resvd0 : 8;
1038 uint32_t cc : 8; /**< Completion Code. */
1039 uint32_t cycle : 1; /**< Cycle bit. */
1040 uint32_t resvd1 : 9;
1041 uint32_t type : 6; /**< TRB Type. */
1042 uint32_t word2 : 16; /**< Second result word. */
1043} XHCI_TRB_NCE;
1044AssertCompile(sizeof(XHCI_TRB_NCE) == 0x10);
1045
1046
1047
1048/* -= Command TRB types =- */
1049
1050
1051/** No Op Command TRB. */
1052typedef struct sXHCI_TRB_NOPC {
1053 uint32_t resvd0;
1054 uint32_t resvd1;
1055 uint32_t resvd2;
1056 uint32_t cycle : 1; /**< Cycle bit. */
1057 uint32_t resvd3 : 9;
1058 uint32_t type : 6; /**< TRB Type. */
1059 uint32_t resvd4 : 16;
1060} XHCI_TRB_NOPC;
1061AssertCompile(sizeof(XHCI_TRB_NOPC) == 0x10);
1062
1063/** Enable Slot Command TRB. */
1064typedef struct sXHCI_TRB_ESL {
1065 uint32_t resvd0;
1066 uint32_t resvd1;
1067 uint32_t resvd2;
1068 uint32_t cycle : 1; /**< Cycle bit. */
1069 uint32_t resvd3 : 9;
1070 uint32_t type : 6; /**< TRB Type. */
1071 uint32_t resvd4 : 16;
1072} XHCI_TRB_ESL;
1073AssertCompile(sizeof(XHCI_TRB_ESL) == 0x10);
1074
1075/** Disable Slot Command TRB. */
1076typedef struct sXHCI_TRB_DSL {
1077 uint32_t resvd0;
1078 uint32_t resvd1;
1079 uint32_t resvd2;
1080 uint32_t cycle : 1; /**< Cycle bit. */
1081 uint32_t resvd3 : 9;
1082 uint32_t type : 6; /**< TRB Type. */
1083 uint32_t resvd4 : 8;
1084 uint32_t slot_id : 8; /**< Slot ID. */
1085} XHCI_TRB_DSL;
1086AssertCompile(sizeof(XHCI_TRB_DSL) == 0x10);
1087
1088/** Address Device Command TRB. */
1089typedef struct sXHCI_TRB_ADR {
1090 uint64_t ctx_ptr; /**< Input Context pointer. */
1091 uint32_t resvd0;
1092 uint32_t cycle : 1; /**< Cycle bit. */
1093 uint32_t resvd1 : 8;
1094 uint32_t bsr : 1; /**< Block Set Address Request. */
1095 uint32_t type : 6; /**< TRB Type. */
1096 uint32_t resvd2 : 8;
1097 uint32_t slot_id : 8; /**< Slot ID. */
1098} XHCI_TRB_ADR;
1099AssertCompile(sizeof(XHCI_TRB_ADR) == 0x10);
1100
1101/** Configure Endpoint Command TRB. */
1102typedef struct sXHCI_TRB_CFG {
1103 uint64_t ctx_ptr; /**< Input Context pointer. */
1104 uint32_t resvd0;
1105 uint32_t cycle : 1; /**< Cycle bit. */
1106 uint32_t resvd1 : 8;
1107 uint32_t dc : 1; /**< Deconfigure. */
1108 uint32_t type : 6; /**< TRB Type. */
1109 uint32_t resvd2 : 8;
1110 uint32_t slot_id : 8; /**< Slot ID. */
1111} XHCI_TRB_CFG;
1112AssertCompile(sizeof(XHCI_TRB_CFG) == 0x10);
1113
1114/** Evaluate Context Command TRB. */
1115typedef struct sXHCI_TRB_EVC {
1116 uint64_t ctx_ptr; /**< Input Context pointer. */
1117 uint32_t resvd0;
1118 uint32_t cycle : 1; /**< Cycle bit. */
1119 uint32_t resvd1 : 9;
1120 uint32_t type : 6; /**< TRB Type. */
1121 uint32_t resvd2 : 8;
1122 uint32_t slot_id : 8; /**< Slot ID. */
1123} XHCI_TRB_EVC;
1124AssertCompile(sizeof(XHCI_TRB_EVC) == 0x10);
1125
1126/** Reset Endpoint Command TRB. */
1127typedef struct sXHCI_TRB_RSE {
1128 uint32_t resvd0;
1129 uint32_t resvd1;
1130 uint32_t resvd2;
1131 uint32_t cycle : 1; /**< Cycle bit. */
1132 uint32_t resvd3 : 8;
1133 uint32_t tsp : 1; /**< Transfer State Preserve. */
1134 uint32_t type : 6; /**< TRB Type. */
1135 uint32_t ep_id : 5; /**< Endpoint ID. */
1136 uint32_t resvd4 : 3;
1137 uint32_t slot_id : 8; /**< Slot ID. */
1138} XHCI_TRB_RSE;
1139AssertCompile(sizeof(XHCI_TRB_RSE) == 0x10);
1140
1141/** Stop Endpoint Command TRB. */
1142typedef struct sXHCI_TRB_STP {
1143 uint32_t resvd0;
1144 uint32_t resvd1;
1145 uint32_t resvd2;
1146 uint32_t cycle : 1; /**< Cycle bit. */
1147 uint32_t resvd3 : 9;
1148 uint32_t type : 6; /**< TRB Type. */
1149 uint32_t ep_id : 5; /**< Endpoint ID. */
1150 uint32_t resvd4 : 2;
1151 uint32_t sp : 1; /**< Suspend. */
1152 uint32_t slot_id : 8; /**< Slot ID. */
1153} XHCI_TRB_STP;
1154AssertCompile(sizeof(XHCI_TRB_STP) == 0x10);
1155
1156/** Set TR Dequeue Pointer Command TRB. */
1157typedef struct sXHCI_TRB_STDP {
1158#if 0
1159 uint64_t dcs : 1; /**< Dequeue Cycle State. */
1160 uint64_t sct : 3; /**< Stream Context Type. */
1161 uint64_t tr_dqp : 60; /**< New TR Dequeue Pointer (63:4). */
1162#else
1163 uint64_t tr_dqp;
1164#endif
1165 uint16_t resvd0;
1166 uint16_t strm_id; /**< Stream ID. */
1167 uint32_t cycle : 1; /**< Cycle bit. */
1168 uint32_t resvd1 : 9;
1169 uint32_t type : 6; /**< TRB Type. */
1170 uint32_t ep_id : 5; /**< Endpoint ID. */
1171 uint32_t resvd2 : 3;
1172 uint32_t slot_id : 8; /**< Slot ID. */
1173} XHCI_TRB_STDP;
1174AssertCompile(sizeof(XHCI_TRB_STDP) == 0x10);
1175
1176/** Reset Device Command TRB. */
1177typedef struct sXHCI_TRB_RSD {
1178 uint32_t resvd0;
1179 uint32_t resvd1;
1180 uint32_t resvd2;
1181 uint32_t cycle : 1; /**< Cycle bit. */
1182 uint32_t resvd3 : 9;
1183 uint32_t type : 6; /**< TRB Type. */
1184 uint32_t resvd4 : 8;
1185 uint32_t slot_id : 8; /**< Slot ID. */
1186} XHCI_TRB_RSD;
1187AssertCompile(sizeof(XHCI_TRB_RSD) == 0x10);
1188
1189/** Get Port Bandwidth Command TRB. */
1190typedef struct sXHCI_TRB_GPBW {
1191 uint64_t pbctx_ptr; /**< Port Bandwidth Context pointer. */
1192 uint32_t resvd0;
1193 uint32_t cycle : 1; /**< Cycle bit. */
1194 uint32_t resvd1 : 9;
1195 uint32_t type : 6; /**< TRB Type. */
1196 uint32_t spd : 4; /**< Dev Speed. */
1197 uint32_t resvd2 : 4;
1198 uint32_t slot_id : 8; /**< Slot ID. */
1199} XHCI_TRB_GPBW;
1200AssertCompile(sizeof(XHCI_TRB_GPBW) == 0x10);
1201
1202/** Force Header Command TRB. */
1203typedef struct sXHCI_TRB_FHD {
1204 uint32_t pkt_typ : 5; /**< Packet Type. */
1205 uint32_t hdr_lo : 27; /**< Header Info Lo. */
1206 uint32_t hdr_mid; /**< Header Info Mid. */
1207 uint32_t hdr_hi; /**< Header Info Hi. */
1208 uint32_t cycle : 1; /**< Cycle bit. */
1209 uint32_t resvd0 : 9;
1210 uint32_t type : 6; /**< TRB Type. */
1211 uint32_t resvd1 : 8;
1212 uint32_t slot_id : 8; /**< Slot ID. */
1213} XHCI_TRB_FHD;
1214AssertCompile(sizeof(XHCI_TRB_FHD) == 0x10);
1215
1216/** NEC Specific Authenticate Command TRB. */
1217typedef struct sXHCI_TRB_NAC {
1218 uint64_t cookie; /**< Cookie to munge. */
1219 uint32_t resvd0;
1220 uint32_t cycle : 1; /**< Cycle bit. */
1221 uint32_t resvd1 : 9;
1222 uint32_t type : 6; /**< TRB Type. */
1223 uint32_t resvd2 : 8;
1224 uint32_t slot_id : 8; /**< Slot ID. */
1225} XHCI_TRB_NAC;
1226AssertCompile(sizeof(XHCI_TRB_NAC) == 0x10);
1227
1228
1229/* -= Other TRB types =- */
1230
1231
1232/** Link TRB. */
1233typedef struct sXHCI_TRB_LNK {
1234 uint64_t rseg_ptr; /**< Ring Segment Pointer. */
1235 uint32_t resvd0 : 22;
1236 uint32_t int_tgt : 10; /**< Interrupter target. */
1237 uint32_t cycle : 1; /**< Cycle bit. */
1238 uint32_t toggle : 1; /**< Toggle Cycle flag. */
1239 uint32_t resvd1 : 2;
1240 uint32_t chain : 1; /**< Chain flag. */
1241 uint32_t ioc : 1; /**< Interrupt On Completion flag. */
1242 uint32_t resvd2 : 4;
1243 uint32_t type : 6; /**< TRB Type. */
1244 uint32_t resvd3 : 16;
1245} XHCI_TRB_LNK;
1246AssertCompile(sizeof(XHCI_TRB_LNK) == 0x10);
1247
1248/** Event Data TRB. */
1249typedef struct sXHCI_TRB_EVTD {
1250 uint64_t evt_data; /**< Event Data. */
1251 uint32_t resvd0 : 22;
1252 uint32_t int_tgt : 10; /**< Interrupter target. */
1253 uint32_t cycle : 1; /**< Cycle bit. */
1254 uint32_t ent : 1; /**< Evaluate Next Target flag. */
1255 uint32_t resvd1 : 2;
1256 uint32_t chain : 1; /**< Chain flag. */
1257 uint32_t ioc : 1; /**< Interrupt On Completion flag. */
1258 uint32_t resvd2 : 3;
1259 uint32_t bei : 1; /**< Block Event Interrupt flag. */
1260 uint32_t type : 6; /**< TRB Type. */
1261 uint32_t resvd3 : 16;
1262} XHCI_TRB_EVTD;
1263AssertCompile(sizeof(XHCI_TRB_EVTD) == 0x10);
1264
1265
1266/* -= Union TRB types for the three rings =- */
1267
1268
1269typedef union sXHCI_XFER_TRB {
1270 XHCI_TRB_NORM norm;
1271 XHCI_TRB_CTSP setup;
1272 XHCI_TRB_CTDT data;
1273 XHCI_TRB_CTSS status;
1274 XHCI_TRB_ISOC isoc;
1275 XHCI_TRB_EVTD evtd;
1276 XHCI_TRB_NOPT nop;
1277 XHCI_TRB_LNK link;
1278 XHCI_TRB_GX gen;
1279} XHCI_XFER_TRB;
1280AssertCompile(sizeof(XHCI_XFER_TRB) == 0x10);
1281
1282typedef union sXHCI_COMMAND_TRB {
1283 XHCI_TRB_ESL esl;
1284 XHCI_TRB_DSL dsl;
1285 XHCI_TRB_ADR adr;
1286 XHCI_TRB_CFG cfg;
1287 XHCI_TRB_EVC evc;
1288 XHCI_TRB_RSE rse;
1289 XHCI_TRB_STP stp;
1290 XHCI_TRB_STDP stdp;
1291 XHCI_TRB_RSD rsd;
1292 XHCI_TRB_GPBW gpbw;
1293 XHCI_TRB_FHD fhd;
1294 XHCI_TRB_NAC nac;
1295 XHCI_TRB_NOPC nopc;
1296 XHCI_TRB_LNK link;
1297 XHCI_TRB_G gen;
1298} XHCI_COMMAND_TRB;
1299AssertCompile(sizeof(XHCI_COMMAND_TRB) == 0x10);
1300
1301typedef union sXHCI_EVENT_TRB {
1302 XHCI_TRB_TE te;
1303 XHCI_TRB_CCE cce;
1304 XHCI_TRB_PSCE psce;
1305 XHCI_TRB_BRE bre;
1306 XHCI_TRB_DBE dbe;
1307 XHCI_TRB_HCE hce;
1308 XHCI_TRB_DNE dne;
1309 XHCI_TRB_MWE mwe;
1310 XHCI_TRB_NCE nce;
1311 XHCI_TRB_G gen;
1312} XHCI_EVENT_TRB;
1313AssertCompile(sizeof(XHCI_EVENT_TRB) == 0x10);
1314
1315
1316
1317/* -=-=-= Contexts =-=-=- */
1318
1319/** Slot Context. */
1320typedef struct sXHCI_SLOT_CTX {
1321 uint32_t route_str : 20; /**< Route String. */
1322 uint32_t speed : 4; /**< Device speed. */
1323 uint32_t resvd0 : 1;
1324 uint32_t mtt : 1; /**< Multi-TT flag. */
1325 uint32_t hub : 1; /**< Hub flag. */
1326 uint32_t ctx_ent : 5; /**< Context entries. */
1327 uint32_t max_lat : 16; /**< Max exit latency in usec. */
1328 uint32_t rh_port : 8; /**< Root hub port number (1-based). */
1329 uint32_t n_ports : 8; /**< No. of ports for hubs. */
1330 uint32_t tt_slot : 8; /**< TT hub slot ID. */
1331 uint32_t tt_port : 8; /**< TT port number. */
1332 uint32_t ttt : 2; /**< TT Think Time. */
1333 uint32_t resvd1 : 4;
1334 uint32_t intr_tgt : 10; /**< Interrupter Target. */
1335 uint32_t dev_addr : 8; /**< Device Address. */
1336 uint32_t resvd2 : 19;
1337 uint32_t slot_state : 5; /**< Slot State. */
1338 uint32_t opaque[4]; /**< For xHC (i.e. our own) use. */
1339} XHCI_SLOT_CTX;
1340AssertCompile(sizeof(XHCI_SLOT_CTX) == 0x20);
1341
1342/** @name Slot Context states
1343 * @{ */
1344#define XHCI_SLTST_ENDIS 0 /**< Enabled/Disabled. */
1345#define XHCI_SLTST_DEFAULT 1 /**< Default. */
1346#define XHCI_SLTST_ADDRESSED 2 /**< Addressed. */
1347#define XHCI_SLTST_CONFIGURED 3 /**< Configured. */
1348/** @} */
1349
1350#ifdef IN_RING3
1351/** Human-readable slot state descriptions for debugging. */
1352static const char * const g_apszSltStates[] = {
1353 "Enabled/Disabled", "Default", "Addressed", "Configured" /* 0-3 */
1354};
1355#endif
1356
1357/** Endpoint Context. */
1358typedef struct sXHCI_EP_CTX {
1359 uint32_t ep_state : 3; /**< Endpoint state. */
1360 uint32_t resvd0 : 5;
1361 uint32_t mult : 2; /**< SS isoc burst count. */
1362 uint32_t maxps : 5; /**< Max Primary Streams. */
1363 uint32_t lsa : 1; /**< Linear Stream Array. */
1364 uint32_t interval : 8; /**< USB request interval. */
1365 uint32_t resvd1 : 8;
1366 uint32_t resvd2 : 1;
1367 uint32_t c_err : 2; /**< Error count. */
1368 uint32_t ep_type : 3; /**< Endpoint type. */
1369 uint32_t resvd3 : 1;
1370 uint32_t hid : 1; /**< Host Initiate Disable. */
1371 uint32_t max_brs_sz : 8; /**< Max Burst Size. */
1372 uint32_t max_pkt_sz : 16; /**< Max Packet Size. */
1373 uint64_t trdp; /**< TR Dequeue Pointer. */
1374 uint32_t avg_trb_len : 16; /**< Average TRB Length. */
1375 uint32_t max_esit : 16; /**< Max EP Service Interval Time Payload. */
1376 /**< The rest for xHC (i.e. our own) use. */
1377 uint32_t last_frm : 16; /**< Last isochronous frame used (opaque). */
1378 uint32_t ifc : 8; /**< isoch in-flight TD count (opaque). */
1379 uint32_t last_cc : 8; /**< Last TRB completion code (opaque). */
1380 uint64_t trep; /**< TR Enqueue Pointer (opaque). */
1381} XHCI_EP_CTX;
1382AssertCompile(sizeof(XHCI_EP_CTX) == 0x20);
1383
1384/** @name Endpoint Context states
1385 * @{ */
1386#define XHCI_EPST_DISABLED 0 /**< Disabled. */
1387#define XHCI_EPST_RUNNING 1 /**< Running. */
1388#define XHCI_EPST_HALTED 2 /**< Halted. */
1389#define XHCI_EPST_STOPPED 3 /**< Not running/stopped. */
1390#define XHCI_EPST_ERROR 4 /**< Not running/error. */
1391/** @} */
1392
1393/** @name Endpoint Type values
1394 * @{ */
1395#define XHCI_EPTYPE_INVALID 0 /**< Not valid. */
1396#define XHCI_EPTYPE_ISOCH_OUT 1 /**< Isochronous Out. */
1397#define XHCI_EPTYPE_BULK_OUT 2 /**< Bulk Out. */
1398#define XHCI_EPTYPE_INTR_OUT 3 /**< Interrupt Out. */
1399#define XHCI_EPTYPE_CONTROL 4 /**< Control Bidi. */
1400#define XHCI_EPTYPE_ISOCH_IN 5 /**< Isochronous In. */
1401#define XHCI_EPTYPE_BULK_IN 6 /**< Bulk In. */
1402#define XHCI_EPTYPE_INTR_IN 7 /**< Interrupt In. */
1403/** @} */
1404
1405/* Pick out transfer type from endpoint. */
1406#define XHCI_EP_XTYPE(a) (a & 3)
1407
1408/* Endpoint transfer types. */
1409#define XHCI_XFTYPE_CONTROL 0
1410#define XHCI_XFTYPE_ISOCH XHCI_EPTYPE_ISOCH_OUT
1411#define XHCI_XFTYPE_BULK XHCI_EPTYPE_BULK_OUT
1412#define XHCI_XFTYPE_INTR XHCI_EPTYPE_INTR_OUT
1413
1414/* Transfer Ring Dequeue Pointer address mask. */
1415#define XHCI_TRDP_ADDR_MASK UINT64_C(0xFFFFFFFFFFFFFFF0)
1416#define XHCI_TRDP_DCS_MASK RT_BIT(0) /* Dequeue Cycle State bit. */
1417
1418
1419#ifdef IN_RING3
1420
1421/* Human-readable endpoint state descriptions for debugging. */
1422static const char * const g_apszEpStates[] = {
1423 "Disabled", "Running", "Halted", "Stopped", "Error" /* 0-4 */
1424};
1425
1426/* Human-readable endpoint type descriptions for debugging. */
1427static const char * const g_apszEpTypes[] = {
1428 "Not Valid", "Isoch Out", "Bulk Out", "Interrupt Out", /* 0-3 */
1429 "Control", "Isoch In", "Bulk In", "Interrupt In" /* 4-7 */
1430};
1431
1432#endif /* IN_RING3 */
1433
1434/* Input Control Context. */
1435typedef struct sXHCI_INPC_CTX {
1436 uint32_t drop_flags; /* Drop Context flags (2-31). */
1437 uint32_t add_flags; /* Add Context flags (0-31). */
1438 uint32_t resvd[6];
1439} XHCI_INPC_CTX;
1440AssertCompile(sizeof(XHCI_INPC_CTX) == 0x20);
1441
1442/* Make sure all contexts are the same size. */
1443AssertCompile(sizeof(XHCI_EP_CTX) == sizeof(XHCI_SLOT_CTX));
1444AssertCompile(sizeof(XHCI_EP_CTX) == sizeof(XHCI_INPC_CTX));
1445
1446/* -= Event Ring Segment Table =- */
1447
1448/** Event Ring Segment Table Entry. */
1449typedef struct sXHCI_ERSTE {
1450 uint64_t addr;
1451 uint16_t size;
1452 uint16_t resvd0;
1453 uint32_t resvd1;
1454} XHCI_ERSTE;
1455AssertCompile(sizeof(XHCI_ERSTE) == 0x10);
1456
1457
1458/* -=-= Internal data structures not defined by xHCI =-=- */
1459
1460
1461/** Device slot entry -- either slot context or endpoint context. */
1462typedef union sXHCI_DS_ENTRY {
1463 XHCI_SLOT_CTX sc; /**< Slot context. */
1464 XHCI_EP_CTX ep; /**< Endpoint context. */
1465} XHCI_DS_ENTRY;
1466
1467/** Full device context (slot context + 31 endpoint contexts). */
1468typedef struct sXHCI_DEV_CTX {
1469 XHCI_DS_ENTRY entry[32];
1470} XHCI_DEV_CTX;
1471AssertCompile(sizeof(XHCI_DEV_CTX) == 32 * sizeof(XHCI_EP_CTX));
1472AssertCompile(sizeof(XHCI_DEV_CTX) == 32 * sizeof(XHCI_SLOT_CTX));
1473
1474/** Pointer to the xHCI device state. */
1475typedef struct XHCI *PXHCI;
1476
1477#ifndef VBOX_DEVICE_STRUCT_TESTCASE
1478/**
1479 * The xHCI controller data associated with each URB.
1480 */
1481typedef struct VUSBURBHCIINT
1482{
1483 /** The slot index. */
1484 uint8_t uSlotID;
1485 /** Number of Tds in the array. */
1486 uint32_t cTRB;
1487} VUSBURBHCIINT;
1488#endif
1489
1490/**
1491 * An xHCI root hub port, shared.
1492 */
1493typedef struct XHCIHUBPORT
1494{
1495 /** PORTSC: Port status/control register (R/W). */
1496 uint32_t portsc;
1497 /** PORTPM: Power management status/control register (R/W). */
1498 uint32_t portpm;
1499 /** PORTLI: USB3 port link information (R/O). */
1500 uint32_t portli;
1501} XHCIHUBPORT;
1502/** Pointer to a shared xHCI root hub port. */
1503typedef XHCIHUBPORT *PXHCIHUBPORT;
1504
1505/**
1506 * An xHCI root hub port, ring-3.
1507 */
1508typedef struct XHCIHUBPORTR3
1509{
1510 /** Flag whether there is a device attached to the port. */
1511 bool fAttached;
1512} XHCIHUBPORTR3;
1513/** Pointer to a ring-3 xHCI root hub port. */
1514typedef XHCIHUBPORTR3 *PXHCIHUBPORTR3;
1515
1516/**
1517 * The xHCI root hub, ring-3 only.
1518 *
1519 * @implements PDMIBASE
1520 * @implements VUSBIROOTHUBPORT
1521 */
1522typedef struct XHCIROOTHUBR3
1523{
1524 /** Pointer to the parent xHC. */
1525 R3PTRTYPE(struct XHCIR3 *) pXhciR3;
1526 /** Pointer to the base interface of the VUSB RootHub. */
1527 R3PTRTYPE(PPDMIBASE) pIBase;
1528 /** Pointer to the connector interface of the VUSB RootHub. */
1529 R3PTRTYPE(PVUSBIROOTHUBCONNECTOR) pIRhConn;
1530 /** The base interface exposed to the roothub driver. */
1531 PDMIBASE IBase;
1532 /** The roothub port interface exposed to the roothub driver. */
1533 VUSBIROOTHUBPORT IRhPort;
1534
1535 /** The LED for this hub. */
1536 PDMLED Led;
1537
1538 /** Number of actually implemented ports. */
1539 uint8_t cPortsImpl;
1540 /** Index of first port for this hub. */
1541 uint8_t uPortBase;
1542
1543 uint16_t Alignment0; /**< Force alignment. */
1544#if HC_ARCH_BITS == 64
1545 uint32_t Alignment1;
1546#endif
1547} XHCIROOTHUBR3;
1548/** Pointer to a xHCI root hub (ring-3 only). */
1549typedef XHCIROOTHUBR3 *PXHCIROOTHUBR3;
1550
1551/**
1552 * An xHCI interrupter.
1553 */
1554typedef struct sXHCIINTRPTR
1555{
1556 /* Registers defined by xHCI. */
1557 /** IMAN: Interrupt Management Register (R/W). */
1558 uint32_t iman;
1559 /** IMOD: Interrupt Moderation Register (R/W). */
1560 uint32_t imod;
1561 /** ERSTSZ: Event Ring Segment Table Size (R/W). */
1562 uint32_t erstsz;
1563 /* Reserved/padding. */
1564 uint32_t reserved;
1565 /** ERSTBA: Event Ring Segment Table Base Address (R/W). */
1566 uint64_t erstba;
1567 /** ERDP: Event Ring Dequeue Pointer (R/W). */
1568 uint64_t erdp;
1569 /* Interrupter lock. */
1570 PDMCRITSECT lock;
1571 /* Internal xHCI non-register state. */
1572 /** Internal Event Ring enqueue pointer. */
1573 uint64_t erep;
1574 /** Internal ERDP re-write counter. */
1575 uint32_t erdp_rewrites;
1576 /** This interrupter's index (for logging). */
1577 uint32_t index;
1578 /** Internal index into Event Ring Segment Table. */
1579 uint16_t erst_idx;
1580 /** Internal index into Event Ring Segment. */
1581 uint16_t trb_count;
1582 /** Internal Event Ring Producer Cycle State. */
1583 bool evtr_pcs;
1584 /** Internal Interrupt Pending Enable flag. */
1585 bool ipe;
1586} XHCIINTRPTR, *PXHCIINTRPTR;
1587
1588/**
1589 * xHCI device state.
1590 * @implements PDMILEDPORTS
1591 */
1592typedef struct XHCI
1593{
1594 /** MFINDEX wraparound timer. */
1595 TMTIMERHANDLE hWrapTimer;
1596
1597#ifdef XHCI_ERROR_INJECTION
1598 bool fDropIntrHw;
1599 bool fDropIntrIpe;
1600 bool fDropUrb;
1601 uint8_t Alignment00[1];
1602#else
1603 uint32_t Alignment00; /**< Force alignment. */
1604#endif
1605
1606 /** Flag indicating a sleeping worker thread. */
1607 volatile bool fWrkThreadSleeping;
1608 volatile bool afPadding[3];
1609
1610 /** The event semaphore the worker thread waits on. */
1611 SUPSEMEVENT hEvtProcess;
1612
1613 /** Bitmap for finished tasks (R3 -> Guest). */
1614 volatile uint32_t u32TasksFinished;
1615 /** Bitmap for finished queued tasks (R3 -> Guest). */
1616 volatile uint32_t u32QueuedTasksFinished;
1617 /** Bitmap for new queued tasks (Guest -> R3). */
1618 volatile uint32_t u32TasksNew;
1619
1620 /** Copy of XHCIR3::RootHub2::cPortsImpl. */
1621 uint8_t cUsb2Ports;
1622 /** Copy of XHCIR3::RootHub3::cPortsImpl. */
1623 uint8_t cUsb3Ports;
1624 /** Sum of cUsb2Ports and cUsb3Ports. */
1625 uint8_t cTotalPorts;
1626 /** Explicit padding. */
1627 uint8_t bPadding;
1628
1629 /** Start of current frame. */
1630 uint64_t SofTime;
1631 /** State of the individual ports. */
1632 XHCIHUBPORT aPorts[XHCI_NDP_MAX];
1633 /** Interrupters array. */
1634 XHCIINTRPTR aInterrupters[XHCI_NINTR];
1635
1636 /** @name Host Controller Capability Registers
1637 * @{ */
1638 /** CAPLENGTH: base + CAPLENGTH = operational register start (R/O). */
1639 uint32_t cap_length;
1640 /** HCIVERSION: host controller interface version (R/O). */
1641 uint32_t hci_version;
1642 /** HCSPARAMS: Structural parameters 1 (R/O). */
1643 uint32_t hcs_params1;
1644 /** HCSPARAMS: Structural parameters 2 (R/O). */
1645 uint32_t hcs_params2;
1646 /** HCSPARAMS: Structural parameters 3 (R/O). */
1647 uint32_t hcs_params3;
1648 /** HCCPARAMS: Capability parameters (R/O). */
1649 uint32_t hcc_params;
1650 /** DBOFF: Doorbell offset (R/O). */
1651 uint32_t dbell_off;
1652 /** RTSOFF: Run-time register space offset (R/O). */
1653 uint32_t rts_off;
1654 /** @} */
1655
1656 /** @name Host Controller Operational Registers
1657 * @{ */
1658 /** USB command register - USBCMD (R/W). */
1659 uint32_t cmd;
1660 /** USB status register - USBSTS (R/W).*/
1661 uint32_t status;
1662 /** Device Control Notification register - DNCTRL (R/W). */
1663 uint32_t dnctrl;
1664 /** Configure Register (R/W). */
1665 uint32_t config;
1666 /** Command Ring Control Register - CRCR (R/W). */
1667 uint64_t crcr;
1668 /** Device Context Base Address Array Pointer (R/W). */
1669 uint64_t dcbaap;
1670 /** @} */
1671
1672 /** Extended Capabilities storage. */
1673 uint8_t abExtCap[XHCI_EXT_CAP_SIZE];
1674 /** Size of valid extended capabilities. */
1675 uint32_t cbExtCap;
1676
1677 uint32_t Alignment1; /**< Align cmdr_dqp. */
1678
1679 /** @name Internal xHCI non-register state
1680 * @{ */
1681 /** Internal Command Ring dequeue pointer. */
1682 uint64_t cmdr_dqp;
1683 /** Internal Command Ring Consumer Cycle State. */
1684 bool cmdr_ccs;
1685 uint8_t aAlignment2[7]; /**< Force alignment. */
1686 /** Internal Device Slot states. */
1687 uint8_t aSlotState[XHCI_NDS];
1688 /** Internal doorbell states. Each bit corresponds to an endpoint. */
1689 uint32_t aBellsRung[XHCI_NDS];
1690 /** @} */
1691
1692 /** @name Model specific configuration
1693 * @{ */
1694 /** ERST address mask. */
1695 uint64_t erst_addr_mask;
1696 /** @} */
1697
1698 /** The MMIO region. */
1699 IOMMMIOHANDLE hMmio;
1700
1701 /** Detected isochronous URBs completed with error. */
1702 STAMCOUNTER StatErrorIsocUrbs;
1703 /** Detected isochronous packets (not URBs!) with error. */
1704 STAMCOUNTER StatErrorIsocPkts;
1705
1706 /** Event TRBs written to event ring(s). */
1707 STAMCOUNTER StatEventsWritten;
1708 /** Event TRBs not written to event ring(s) due to HC being stopped. */
1709 STAMCOUNTER StatEventsDropped;
1710 /** Requests to set the IP bit. */
1711 STAMCOUNTER StatIntrsPending;
1712 /** Actual interrupt deliveries. */
1713 STAMCOUNTER StatIntrsSet;
1714 /** Interrupts not raised because they were disabled. */
1715 STAMCOUNTER StatIntrsNotSet;
1716 /** A pending interrupt was cleared. */
1717 STAMCOUNTER StatIntrsCleared;
1718 /** Number of TRBs that formed a single control URB. */
1719 STAMCOUNTER StatTRBsPerCtlUrb;
1720 /** Number of TRBs that formed a single data (bulk/interrupt) URB. */
1721 STAMCOUNTER StatTRBsPerDtaUrb;
1722 /** Number of TRBs that formed a single isochronous URB. */
1723 STAMCOUNTER StatTRBsPerIsoUrb;
1724 /** Size of a control URB in bytes. */
1725 STAMCOUNTER StatUrbSizeCtrl;
1726 /** Size of a data URB in bytes. */
1727 STAMCOUNTER StatUrbSizeData;
1728 /** Size of an isochronous URB in bytes. */
1729 STAMCOUNTER StatUrbSizeIsoc;
1730
1731#ifdef VBOX_WITH_STATISTICS
1732 /** @name Register access counters.
1733 * @{ */
1734 STAMCOUNTER StatRdCaps;
1735 STAMCOUNTER StatRdCmdRingCtlHi;
1736 STAMCOUNTER StatRdCmdRingCtlLo;
1737 STAMCOUNTER StatRdConfig;
1738 STAMCOUNTER StatRdDevCtxBaapHi;
1739 STAMCOUNTER StatRdDevCtxBaapLo;
1740 STAMCOUNTER StatRdDevNotifyCtrl;
1741 STAMCOUNTER StatRdDoorBell;
1742 STAMCOUNTER StatRdEvtRingDeqPtrHi;
1743 STAMCOUNTER StatRdEvtRingDeqPtrLo;
1744 STAMCOUNTER StatRdEvtRsTblBaseHi;
1745 STAMCOUNTER StatRdEvtRsTblBaseLo;
1746 STAMCOUNTER StatRdEvtRstblSize;
1747 STAMCOUNTER StatRdEvtRsvd;
1748 STAMCOUNTER StatRdIntrMgmt;
1749 STAMCOUNTER StatRdIntrMod;
1750 STAMCOUNTER StatRdMfIndex;
1751 STAMCOUNTER StatRdPageSize;
1752 STAMCOUNTER StatRdPortLinkInfo;
1753 STAMCOUNTER StatRdPortPowerMgmt;
1754 STAMCOUNTER StatRdPortRsvd;
1755 STAMCOUNTER StatRdPortStatusCtrl;
1756 STAMCOUNTER StatRdUsbCmd;
1757 STAMCOUNTER StatRdUsbSts;
1758 STAMCOUNTER StatRdUnknown;
1759
1760 STAMCOUNTER StatWrCmdRingCtlHi;
1761 STAMCOUNTER StatWrCmdRingCtlLo;
1762 STAMCOUNTER StatWrConfig;
1763 STAMCOUNTER StatWrDevCtxBaapHi;
1764 STAMCOUNTER StatWrDevCtxBaapLo;
1765 STAMCOUNTER StatWrDevNotifyCtrl;
1766 STAMCOUNTER StatWrDoorBell0;
1767 STAMCOUNTER StatWrDoorBellN;
1768 STAMCOUNTER StatWrEvtRingDeqPtrHi;
1769 STAMCOUNTER StatWrEvtRingDeqPtrLo;
1770 STAMCOUNTER StatWrEvtRsTblBaseHi;
1771 STAMCOUNTER StatWrEvtRsTblBaseLo;
1772 STAMCOUNTER StatWrEvtRstblSize;
1773 STAMCOUNTER StatWrIntrMgmt;
1774 STAMCOUNTER StatWrIntrMod;
1775 STAMCOUNTER StatWrPortPowerMgmt;
1776 STAMCOUNTER StatWrPortStatusCtrl;
1777 STAMCOUNTER StatWrUsbCmd;
1778 STAMCOUNTER StatWrUsbSts;
1779 STAMCOUNTER StatWrUnknown;
1780 /** @} */
1781#endif
1782} XHCI;
1783
1784/**
1785 * xHCI device state, ring-3 edition.
1786 * @implements PDMILEDPORTS
1787 */
1788typedef struct XHCIR3
1789{
1790 /** The async worker thread. */
1791 R3PTRTYPE(PPDMTHREAD) pWorkerThread;
1792 /** The device instance.
1793 * @note This is only so interface functions can get their bearings. */
1794 PPDMDEVINSR3 pDevIns;
1795
1796 /** Status LUN: The base interface. */
1797 PDMIBASE IBase;
1798 /** Status LUN: Leds interface. */
1799 PDMILEDPORTS ILeds;
1800 /** Status LUN: Partner of ILeds. */
1801 R3PTRTYPE(PPDMILEDCONNECTORS) pLedsConnector;
1802
1803 /** USB 2.0 Root hub device. */
1804 XHCIROOTHUBR3 RootHub2;
1805 /** USB 3.0 Root hub device. */
1806 XHCIROOTHUBR3 RootHub3;
1807
1808 /** State of the individual ports. */
1809 XHCIHUBPORTR3 aPorts[XHCI_NDP_MAX];
1810
1811 /** Critsect to synchronize worker and I/O completion threads. */
1812 RTCRITSECT CritSectThrd;
1813} XHCIR3;
1814/** Pointer to ring-3 xHCI device state. */
1815typedef XHCIR3 *PXHCIR3;
1816
1817/**
1818 * xHCI device data, ring-0 edition.
1819 */
1820typedef struct XHCIR0
1821{
1822 uint32_t uUnused;
1823} XHCIR0;
1824/** Pointer to ring-0 xHCI device data. */
1825typedef struct XHCIR0 *PXHCIR0;
1826
1827
1828/**
1829 * xHCI device data, raw-mode edition.
1830 */
1831typedef struct XHCIRC
1832{
1833 uint32_t uUnused;
1834} XHCIRC;
1835/** Pointer to raw-mode xHCI device data. */
1836typedef struct XHCIRC *PXHCIRC;
1837
1838
1839/** @typedef XHCICC
1840 * The xHCI device data for the current context. */
1841typedef CTX_SUFF(XHCI) XHCICC;
1842/** @typedef PXHCICC
1843 * Pointer to the xHCI device for the current context. */
1844typedef CTX_SUFF(PXHCI) PXHCICC;
1845
1846
1847/* -=-= Local implementation details =-=- */
1848
1849typedef enum sXHCI_JOB {
1850 XHCI_JOB_PROCESS_CMDRING, /**< Process the command ring. */
1851 XHCI_JOB_DOORBELL, /**< A doorbell (other than DB0) was rung. */
1852 XHCI_JOB_XFER_DONE, /**< Transfer completed, look for more work. */
1853 XHCI_JOB_MAX
1854} XHCI_JOB;
1855
1856/* -=-=- Local xHCI definitions -=-=- */
1857
1858/** @name USB states.
1859 * @{ */
1860#define XHCI_USB_RESET 0x00
1861#define XHCI_USB_RESUME 0x40
1862#define XHCI_USB_OPERATIONAL 0x80
1863#define XHCI_USB_SUSPEND 0xc0
1864/** @} */
1865
1866/* Primary interrupter (for readability). */
1867#define XHCI_PRIMARY_INTERRUPTER 0
1868
1869/** @name Device Slot states.
1870 * @{ */
1871#define XHCI_DEVSLOT_EMPTY 0
1872#define XHCI_DEVSLOT_ENABLED 1
1873#define XHCI_DEVSLOT_DEFAULT 2
1874#define XHCI_DEVSLOT_ADDRESSED 3
1875#define XHCI_DEVSLOT_CONFIGURED 4
1876/** @} */
1877
1878/** Get the pointer to a root hub corresponding to given port index. */
1879#define GET_PORT_PRH(a_pThisCC, a_uPort) \
1880 ((a_uPort) >= (a_pThisCC)->RootHub2.cPortsImpl ? &(a_pThisCC)->RootHub3 : &(a_pThisCC)->RootHub2)
1881#define GET_VUSB_PORT_FROM_XHCI_PORT(a_pRh, a_iPort) \
1882 (((a_iPort) - (a_pRh)->uPortBase) + 1)
1883#define GET_XHCI_PORT_FROM_VUSB_PORT(a_pRh, a_uPort) \
1884 ((a_pRh)->uPortBase + (a_uPort) - 1)
1885
1886/** Check if port corresponding to index is USB3, using shared data. */
1887#define IS_USB3_PORT_IDX_SHR(a_pThis, a_uPort) ((a_uPort) >= (a_pThis)->cUsb2Ports)
1888
1889/** Check if port corresponding to index is USB3, using ring-3 data. */
1890#define IS_USB3_PORT_IDX_R3(a_pThisCC, a_uPort) ((a_uPort) >= (a_pThisCC)->RootHub2.cPortsImpl)
1891
1892/** Query the number of configured USB2 ports. */
1893#define XHCI_NDP_USB2(a_pThisCC) ((unsigned)(a_pThisCC)->RootHub2.cPortsImpl)
1894
1895/** Query the number of configured USB3 ports. */
1896#define XHCI_NDP_USB3(a_pThisCC) ((unsigned)(a_pThisCC)->RootHub3.cPortsImpl)
1897
1898/** Query the total number of configured ports. */
1899#define XHCI_NDP_CFG(a_pThis) ((unsigned)RT_MIN((a_pThis)->cTotalPorts, XHCI_NDP_MAX))
1900
1901
1902#ifndef VBOX_DEVICE_STRUCT_TESTCASE
1903
1904
1905/*********************************************************************************************************************************
1906* Internal Functions *
1907*********************************************************************************************************************************/
1908
1909#ifdef IN_RING3
1910
1911/** Build a Protocol extended capability. */
1912static uint32_t xhciR3BuildProtocolCaps(uint8_t *pbCap, uint32_t cbMax, int cPorts, int nPortOfs, int ver)
1913{
1914 uint32_t *pu32Cap = (uint32_t *)pbCap;
1915 unsigned cPsi;
1916
1917 Assert(nPortOfs + cPorts < 255);
1918 Assert(ver == 2 || ver == 3);
1919
1920 cPsi = 0; /* Currently only implied port speed IDs. */
1921
1922 /* Make sure there's enough room. */
1923 if (cPsi * 4 + 16 > cbMax)
1924 return 0;
1925
1926 /* Header - includes (USB) specification version. */
1927 *pu32Cap++ = (ver << 24) | (0 << 16) | XHCI_XCP_PROTOCOL;
1928 /* Specification - 'USB ' */
1929 *pu32Cap++ = 0x20425355;
1930 /* Port offsets and counts. 1-based! */
1931 *pu32Cap++ = (cPsi << 28) | (cPorts << 8) | (nPortOfs + 1);
1932 /* Reserved dword. */
1933 *pu32Cap++ = 0;
1934
1935 return (uint8_t *)pu32Cap - pbCap;
1936}
1937
1938
1939/** Add an extended capability and link it into the chain. */
1940static int xhciR3AddExtCap(PXHCI pThis, const uint8_t *pCap, uint32_t cbCap, uint32_t *puPrevOfs)
1941{
1942 Assert(*puPrevOfs <= pThis->cbExtCap);
1943 Assert(!(cbCap & 3));
1944
1945 /* Check that the extended capability is sane. */
1946 if (cbCap == 0)
1947 return VERR_BUFFER_UNDERFLOW;
1948 if (pThis->cbExtCap + cbCap > XHCI_EXT_CAP_SIZE)
1949 return VERR_BUFFER_OVERFLOW;
1950 if (cbCap > 255 * 4) /* Size must fit into 8-bit dword count. */
1951 return VERR_BUFFER_OVERFLOW;
1952
1953 /* Copy over the capability data and update offsets. */
1954 memcpy(pThis->abExtCap + pThis->cbExtCap, pCap, cbCap);
1955 pThis->abExtCap[*puPrevOfs + 1] = cbCap >> 2;
1956 pThis->abExtCap[pThis->cbExtCap + 1] = 0;
1957 *puPrevOfs = pThis->cbExtCap;
1958 pThis->cbExtCap += cbCap;
1959 return VINF_SUCCESS;
1960}
1961
1962/** Build the xHCI Extended Capabilities region. */
1963static int xhciR3BuildExtCaps(PXHCI pThis, PXHCICC pThisCC)
1964{
1965 int rc;
1966 uint8_t abXcp[MAX_XCAP_SIZE];
1967 uint32_t cbXcp;
1968 uint32_t uPrevOfs = 0;
1969
1970 Assert(XHCI_NDP_USB2(pThisCC));
1971 Assert(XHCI_NDP_USB3(pThisCC));
1972
1973 /* Most of the extended capabilities are optional or not relevant for PCI
1974 * implementations. However, the Supported Protocol caps are required.
1975 */
1976 cbXcp = xhciR3BuildProtocolCaps(abXcp, sizeof(abXcp), XHCI_NDP_USB2(pThisCC), 0, 2);
1977 rc = xhciR3AddExtCap(pThis, abXcp, cbXcp, &uPrevOfs);
1978 AssertReturn(RT_SUCCESS(rc), rc);
1979
1980 cbXcp = xhciR3BuildProtocolCaps(abXcp, sizeof(abXcp), XHCI_NDP_USB3(pThisCC), XHCI_NDP_USB2(pThisCC), 3);
1981 rc = xhciR3AddExtCap(pThis, abXcp, cbXcp, &uPrevOfs);
1982 AssertReturn(RT_SUCCESS(rc), rc);
1983
1984 return VINF_SUCCESS;
1985}
1986
1987
1988/**
1989 * Select an unused device address. Note that this may fail in the unlikely
1990 * case where all possible addresses are exhausted.
1991 */
1992static uint8_t xhciR3SelectNewAddress(PXHCI pThis, uint8_t uSlotID)
1993{
1994 RT_NOREF(pThis, uSlotID);
1995
1996 /*
1997 * Since there is a 1:1 mapping between USB devices and device slots, we
1998 * should be able to assign a USB address which equals slot ID to any USB
1999 * device. However, the address selection algorithm could be completely
2000 * different (it is not defined by the xHCI spec).
2001 */
2002 return uSlotID;
2003}
2004
2005
2006/**
2007 * Read the address of a device context for a slot from the DCBAA.
2008 *
2009 * @returns Given slot's device context base address.
2010 * @param pDevIns The device instance.
2011 * @param pThis Pointer to the xHCI state.
2012 * @param uSlotID Slot ID to get the context address of.
2013 */
2014static uint64_t xhciR3FetchDevCtxAddr(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID)
2015{
2016 uint64_t uCtxAddr;
2017 RTGCPHYS GCPhysDCBAAE;
2018
2019 Assert(uSlotID > 0);
2020 Assert(uSlotID < XHCI_NDS);
2021
2022 /* Fetch the address of the output slot context from the DCBAA. */
2023 GCPhysDCBAAE = pThis->dcbaap + uSlotID * sizeof(uint64_t);
2024 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysDCBAAE, &uCtxAddr, sizeof(uCtxAddr));
2025 LogFlowFunc(("Slot ID %u, device context @ %RGp\n", uSlotID, uCtxAddr));
2026 Assert(uCtxAddr);
2027
2028 return uCtxAddr & XHCI_CTX_ADDR_MASK;
2029}
2030
2031
2032/**
2033 * Fetch a device's slot or endpoint context from memory.
2034 *
2035 * @param pDevIns The device instance.
2036 * @param pThis The xHCI device state.
2037 * @param uSlotID Slot ID to access.
2038 * @param uDCI Device Context Index.
2039 * @param pCtx Pointer to storage for the context.
2040 */
2041static int xhciR3FetchDevCtx(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID, uint8_t uDCI, void *pCtx)
2042{
2043 RTGCPHYS GCPhysCtx;
2044
2045 GCPhysCtx = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
2046 LogFlowFunc(("Reading device context @ %RGp, DCI %u\n", GCPhysCtx, uDCI));
2047 GCPhysCtx += uDCI * sizeof(XHCI_SLOT_CTX);
2048 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysCtx, pCtx, sizeof(XHCI_SLOT_CTX));
2049 return VINF_SUCCESS;
2050}
2051
2052
2053/**
2054 * Fetch a device's slot and endpoint contexts from guest memory.
2055 *
2056 * @param pDevIns The device instance.
2057 * @param pThis The xHCI device state.
2058 * @param uSlotID Slot ID to access.
2059 * @param uDCI Endpoint Device Context Index.
2060 * @param pSlot Pointer to storage for the slot context.
2061 * @param pEp Pointer to storage for the endpoint context.
2062 */
2063static int xhciR3FetchCtxAndEp(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID, uint8_t uDCI, XHCI_SLOT_CTX *pSlot, XHCI_EP_CTX *pEp)
2064{
2065 AssertPtr(pSlot);
2066 AssertPtr(pEp);
2067 Assert(uDCI); /* Can't be 0 -- that's the device context. */
2068
2069 /* Load the slot context. */
2070 xhciR3FetchDevCtx(pDevIns, pThis, uSlotID, 0, pSlot);
2071 /// @todo sanity check the slot context here?
2072 Assert(pSlot->ctx_ent >= uDCI);
2073
2074 /* Load the endpoint context. */
2075 xhciR3FetchDevCtx(pDevIns, pThis, uSlotID, uDCI, pEp);
2076 /// @todo sanity check the endpoint context here?
2077
2078 return VINF_SUCCESS;
2079}
2080
2081
2082/**
2083 * Update an endpoint context in guest memory.
2084 *
2085 * @param pDevIns The device instance.
2086 * @param pThis The xHCI device state.
2087 * @param uSlotID Slot ID to access.
2088 * @param uDCI Endpoint Device Context Index.
2089 * @param pEp Pointer to storage of the endpoint context.
2090 */
2091static int xhciR3WriteBackEp(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID, uint8_t uDCI, XHCI_EP_CTX *pEp)
2092{
2093 RTGCPHYS GCPhysCtx;
2094
2095 AssertPtr(pEp);
2096 Assert(uDCI); /* Can't be 0 -- that's the device context. */
2097
2098 /// @todo sanity check the endpoint context here?
2099 /* Find the physical address. */
2100 GCPhysCtx = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
2101 LogFlowFunc(("Writing device context @ %RGp, DCI %u\n", GCPhysCtx, uDCI));
2102 GCPhysCtx += uDCI * sizeof(XHCI_SLOT_CTX);
2103 /* Write the updated context. */
2104 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysCtx, pEp, sizeof(XHCI_EP_CTX));
2105
2106 return VINF_SUCCESS;
2107}
2108
2109
2110/**
2111 * Modify an endpoint context such that it enters the running state.
2112 *
2113 * @param pEpCtx Pointer to the endpoint context.
2114 */
2115static void xhciR3EnableEP(XHCI_EP_CTX *pEpCtx)
2116{
2117 LogFlow(("Enabling EP, TRDP @ %RGp, DCS=%u\n", pEpCtx->trdp & XHCI_TRDP_ADDR_MASK, pEpCtx->trdp & XHCI_TRDP_DCS_MASK));
2118 pEpCtx->ep_state = XHCI_EPST_RUNNING;
2119 pEpCtx->trep = pEpCtx->trdp;
2120}
2121
2122#endif /* IN_RING3 */
2123
2124#define MFIND_PERIOD_NS (UINT64_C(2048) * 1000000)
2125
2126/**
2127 * Set up the MFINDEX wrap timer.
2128 */
2129static void xhciSetWrapTimer(PPDMDEVINS pDevIns, PXHCI pThis)
2130{
2131 uint64_t u64Now;
2132 uint64_t u64LastWrap;
2133 uint64_t u64Expire;
2134 int rc;
2135
2136 /* Try to avoid drift. */
2137 u64Now = PDMDevHlpTimerGet(pDevIns, pThis->hWrapTimer);
2138// u64LastWrap = u64Now - (u64Now % (0x3FFF * 125000));
2139 u64LastWrap = u64Now / MFIND_PERIOD_NS * MFIND_PERIOD_NS;
2140 /* The MFINDEX counter wraps around every 2048 milliseconds. */
2141 u64Expire = u64LastWrap + (uint64_t)2048 * 1000000;
2142 rc = PDMDevHlpTimerSet(pDevIns, pThis->hWrapTimer, u64Expire);
2143 AssertRC(rc);
2144}
2145
2146/**
2147 * Determine whether MSI/MSI-X is enabled for this PCI device.
2148 *
2149 * This influences interrupt handling in xHCI. NB: There should be a PCIDevXxx
2150 * function for this.
2151 */
2152static bool xhciIsMSIEnabled(PPDMPCIDEV pDevIns)
2153{
2154 uint16_t uMsgCtl;
2155
2156 uMsgCtl = PDMPciDevGetWord(pDevIns, XHCI_PCI_MSI_CAP_OFS + VBOX_MSI_CAP_MESSAGE_CONTROL);
2157 return !!(uMsgCtl & VBOX_PCI_MSI_FLAGS_ENABLE);
2158}
2159
2160/**
2161 * Get the worker thread going -- there's something to do.
2162 */
2163static void xhciKickWorker(PPDMDEVINS pDevIns, PXHCI pThis, XHCI_JOB enmJob, uint32_t uWorkDesc)
2164{
2165 RT_NOREF(enmJob, uWorkDesc);
2166
2167 /* Tell the worker thread there's something to do. */
2168 if (ASMAtomicReadBool(&pThis->fWrkThreadSleeping))
2169 {
2170 LogFlowFunc(("Signal event semaphore\n"));
2171 int rc = PDMDevHlpSUPSemEventSignal(pDevIns, pThis->hEvtProcess);
2172 AssertRC(rc);
2173 }
2174}
2175
2176/**
2177 * Fetch the current ERST entry from guest memory.
2178 */
2179static void xhciFetchErstEntry(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip)
2180{
2181 RTGCPHYS GCPhysErste;
2182 XHCI_ERSTE entry;
2183
2184 Assert(ip->erst_idx < ip->erstsz);
2185 GCPhysErste = ip->erstba + ip->erst_idx * sizeof(XHCI_ERSTE);
2186 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysErste, &entry, sizeof(entry));
2187
2188 /*
2189 * 6.5 claims values in 16-4096 range are valid, but does not say what
2190 * happens for values outside of that range...
2191 */
2192 Assert((pThis->status & XHCI_STATUS_HCH) || (entry.size >= 16 && entry.size <= 4096));
2193
2194 /* Cache the entry data internally. */
2195 ip->erep = entry.addr & pThis->erst_addr_mask;
2196 ip->trb_count = entry.size;
2197 Log(("Fetched ERST Entry at %RGp: %u entries at %RGp\n", GCPhysErste, ip->trb_count, ip->erep));
2198}
2199
2200/**
2201 * Set the interrupter's IP and EHB bits and trigger an interrupt if required.
2202 *
2203 * @param pDevIns The PDM device instance.
2204 * @param pThis Pointer to the xHCI state.
2205 * @param ip Pointer to the interrupter structure.
2206 *
2207 */
2208static void xhciSetIntr(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip)
2209{
2210 Assert(pThis && ip);
2211 LogFlowFunc(("old IP: %u\n", !!(ip->iman & XHCI_IMAN_IP)));
2212
2213 if (!(ip->iman & XHCI_IMAN_IP))
2214 {
2215 /// @todo assert that we own the interrupter lock
2216 ASMAtomicOrU32(&pThis->status, XHCI_STATUS_EINT);
2217 ASMAtomicOrU64(&ip->erdp, XHCI_ERDP_EHB);
2218 ASMAtomicOrU32(&ip->iman, XHCI_IMAN_IP);
2219 if ((ip->iman & XHCI_IMAN_IE) && (pThis->cmd & XHCI_CMD_INTE))
2220 {
2221#ifdef XHCI_ERROR_INJECTION
2222 if (pThis->fDropIntrHw)
2223 {
2224 pThis->fDropIntrHw = false;
2225 ASMAtomicAndU32(&ip->iman, ~XHCI_IMAN_IP);
2226 }
2227 else
2228#endif
2229 {
2230 Log2(("Triggering interrupt on interrupter %u\n", ip->index));
2231 PDMDevHlpPCISetIrq(pDevIns, 0, PDM_IRQ_LEVEL_HIGH);
2232 STAM_COUNTER_INC(&pThis->StatIntrsSet);
2233 }
2234 }
2235 else
2236 {
2237 Log2(("Not triggering interrupt on interrupter %u (interrupts disabled)\n", ip->index));
2238 STAM_COUNTER_INC(&pThis->StatIntrsNotSet);
2239 }
2240
2241 /* If MSI/MSI-X is in use, the IP bit is immediately cleared again. */
2242 if (xhciIsMSIEnabled(pDevIns->apPciDevs[0]))
2243 ASMAtomicAndU32(&ip->iman, ~XHCI_IMAN_IP);
2244 }
2245}
2246
2247#ifdef IN_RING3
2248
2249/**
2250 * Set the interrupter's IPE bit. If this causes a 0->1 transition, an
2251 * interrupt may be triggered.
2252 *
2253 * @param pDevIns The PDM device instance.
2254 * @param pThis Pointer to the xHCI state.
2255 * @param ip Pointer to the interrupter structure.
2256 */
2257static void xhciR3SetIntrPending(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip)
2258{
2259 uint16_t imodc = (ip->imod >> XHCI_IMOD_IMODC_SHIFT) & XHCI_IMOD_IMODC_MASK;
2260
2261 Assert(pThis && ip);
2262 LogFlowFunc(("old IPE: %u, IMODC: %u, EREP: %RGp, EHB: %u\n", ip->ipe, imodc, (RTGCPHYS)ip->erep, !!(ip->erdp & XHCI_ERDP_EHB)));
2263 STAM_COUNTER_INC(&pThis->StatIntrsPending);
2264
2265 if (!ip->ipe)
2266 {
2267#ifdef XHCI_ERROR_INJECTION
2268 if (pThis->fDropIntrIpe)
2269 {
2270 pThis->fDropIntrIpe = false;
2271 }
2272 else
2273#endif
2274 {
2275 ip->ipe = true;
2276 if (!(ip->erdp & XHCI_ERDP_EHB) && (imodc == 0))
2277 xhciSetIntr(pDevIns, pThis, ip);
2278 }
2279 }
2280}
2281
2282
2283/**
2284 * Check if there is space available for writing at least two events on the
2285 * event ring. See 4.9.4 for the state machine (right hand side of diagram).
2286 * If there's only room for one event, the Event Ring Full TRB will need to
2287 * be written out, hence the ring is considered full.
2288 *
2289 * @returns True if space is available, false otherwise.
2290 * @param pDevIns The PDM device instance.
2291 * @param pThis Pointer to the xHCI state.
2292 * @param pIntr Pointer to the interrupter structure.
2293 */
2294static bool xhciR3IsEvtRingFull(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR pIntr)
2295{
2296 uint64_t next_ptr;
2297 uint64_t erdp = pIntr->erdp & XHCI_ERDP_ADDR_MASK;
2298
2299 if (pIntr->trb_count > 1)
2300 {
2301 /* Check the current segment. */
2302 next_ptr = pIntr->erep + sizeof(XHCI_EVENT_TRB);
2303 }
2304 else
2305 {
2306 uint16_t erst_idx;
2307 XHCI_ERSTE entry;
2308 RTGCPHYS GCPhysErste;
2309
2310 /* Need to check the next segment. */
2311 erst_idx = pIntr->erst_idx + 1;
2312 if (erst_idx == pIntr->erstsz)
2313 erst_idx = 0;
2314 GCPhysErste = pIntr->erstba + erst_idx * sizeof(XHCI_ERSTE);
2315 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysErste, &entry, sizeof(entry));
2316 next_ptr = entry.addr & pThis->erst_addr_mask;
2317 }
2318
2319 /// @todo We'll have to remember somewhere that the ring is full
2320 return erdp == next_ptr;
2321}
2322
2323/**
2324 * Write an event to the given Event Ring. This implements a good chunk of
2325 * the event ring state machine in section 4.9.4 of the xHCI spec.
2326 *
2327 * @returns VBox status code. Error if event could not be enqueued.
2328 * @param pDevIns The PDM device instance.
2329 * @param pThis Pointer to the xHCI state.
2330 * @param pEvent Pointer to the Event TRB to be enqueued.
2331 * @param iIntr Index of the interrupter to write to.
2332 * @param fBlockInt Set if interrupt should be blocked (BEI bit).
2333 */
2334static int xhciR3WriteEvent(PPDMDEVINS pDevIns, PXHCI pThis, XHCI_EVENT_TRB *pEvent, unsigned iIntr, bool fBlockInt)
2335{
2336 PXHCIINTRPTR pIntr;
2337 int rc = VINF_SUCCESS;
2338
2339 LogFlowFunc(("Interrupter: %u\n", iIntr));
2340
2341 /* If the HC isn't running, events can not be generated. However,
2342 * especially port change events can be triggered at any time. We just
2343 * drop them here -- it's often not an error condition.
2344 */
2345 if (pThis->cmd & XHCI_CMD_RS)
2346 {
2347 STAM_COUNTER_INC(&pThis->StatEventsWritten);
2348 Assert(iIntr < XHCI_NINTR); /* Supplied by guest, potentially invalid. */
2349 pIntr = &pThis->aInterrupters[iIntr & XHCI_INTR_MASK];
2350
2351 /*
2352 * If the interrupter/event ring isn't in a sane state, just
2353 * give up and report Host Controller Error (HCE).
2354 */
2355 // pIntr->erst_idx
2356
2357 int const rcLock = PDMDevHlpCritSectEnter(pDevIns, &pIntr->lock, VERR_IGNORED); /* R3 only, no rcBusy. */
2358 PDM_CRITSECT_RELEASE_ASSERT_RC_DEV(pDevIns, &pIntr->lock, rcLock); /* eventually, most call chains ignore the status. */
2359
2360 if (xhciR3IsEvtRingFull(pDevIns, pThis, pIntr))
2361 {
2362 LogRel(("xHCI: Event ring full!\n"));
2363 }
2364
2365 /* Set the TRB's Cycle bit as appropriate. */
2366 pEvent->gen.cycle = pIntr->evtr_pcs;
2367
2368 /* Write out the TRB and advance the EREP. */
2369 /// @todo This either has to be atomic from the guest's POV or the cycle bit needs to be toggled last!!
2370 PDMDevHlpPCIPhysWriteMeta(pDevIns, pIntr->erep, pEvent, sizeof(*pEvent));
2371 pIntr->erep += sizeof(*pEvent);
2372 --pIntr->trb_count;
2373
2374 /* Advance to the next ERST entry if necessary. */
2375 if (pIntr->trb_count == 0)
2376 {
2377 ++pIntr->erst_idx;
2378 /* If necessary, roll over back to the beginning. */
2379 if (pIntr->erst_idx == pIntr->erstsz)
2380 {
2381 pIntr->erst_idx = 0;
2382 pIntr->evtr_pcs = !pIntr->evtr_pcs;
2383 }
2384 xhciFetchErstEntry(pDevIns, pThis, pIntr);
2385 }
2386
2387 /* Set the IPE bit unless interrupts are blocked. */
2388 if (!fBlockInt)
2389 xhciR3SetIntrPending(pDevIns, pThis, pIntr);
2390
2391 PDMDevHlpCritSectLeave(pDevIns, &pIntr->lock);
2392 }
2393 else
2394 {
2395 STAM_COUNTER_INC(&pThis->StatEventsDropped);
2396 Log(("Event dropped because HC is not running.\n"));
2397 }
2398
2399 return rc;
2400}
2401
2402
2403/**
2404 * Post a port change TRB to an Event Ring.
2405 */
2406static int xhciR3GenPortChgEvent(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uPort)
2407{
2408 XHCI_EVENT_TRB ed; /* Event Descriptor */
2409 LogFlowFunc(("Port ID: %u\n", uPort));
2410
2411 /*
2412 * Devices can be "physically" attached/detached regardless of whether
2413 * the HC is running or not, but the port status change events can only
2414 * be generated when R/S is set; xhciR3WriteEvent() takes care of that.
2415 */
2416 RT_ZERO(ed);
2417 ed.psce.cc = XHCI_TCC_SUCCESS;
2418 ed.psce.port_id = uPort;
2419 ed.psce.type = XHCI_TRB_PORT_SC;
2420 return xhciR3WriteEvent(pDevIns, pThis, &ed, XHCI_PRIMARY_INTERRUPTER, false);
2421}
2422
2423
2424/**
2425 * Post a command completion TRB to an Event Ring.
2426 */
2427static int xhciR3PostCmdCompletion(PPDMDEVINS pDevIns, PXHCI pThis, unsigned cc, unsigned uSlotID)
2428{
2429 XHCI_EVENT_TRB ed; /* Event Descriptor */
2430 LogFlowFunc(("Cmd @ %RGp, Completion Code: %u (%s), Slot ID: %u\n", (RTGCPHYS)pThis->cmdr_dqp, cc,
2431 cc < RT_ELEMENTS(g_apszCmplCodes) ? g_apszCmplCodes[cc] : "WHAT?!!", uSlotID));
2432
2433 /* The Command Ring dequeue pointer still holds the address of the current
2434 * command TRB. It is written to the completion event TRB as the command
2435 * TRB pointer.
2436 */
2437 RT_ZERO(ed);
2438 ed.cce.trb_ptr = pThis->cmdr_dqp;
2439 ed.cce.cc = cc;
2440 ed.cce.type = XHCI_TRB_CMD_CMPL;
2441 ed.cce.slot_id = uSlotID;
2442 return xhciR3WriteEvent(pDevIns, pThis, &ed, XHCI_PRIMARY_INTERRUPTER, false);
2443}
2444
2445
2446/**
2447 * Post a transfer event TRB to an Event Ring.
2448 */
2449static int xhciR3PostXferEvent(PPDMDEVINS pDevIns, PXHCI pThis, unsigned uIntTgt, unsigned uXferLen, unsigned cc,
2450 unsigned uSlotID, unsigned uEpDCI, uint64_t uEvtData, bool fBlockInt, bool fEvent)
2451{
2452 XHCI_EVENT_TRB ed; /* Event Descriptor */
2453 LogFlowFunc(("Xfer @ %RGp, Completion Code: %u (%s), Slot ID=%u DCI=%u Target=%u EvtData=%RX64 XfrLen=%u BEI=%u ED=%u\n",
2454 (RTGCPHYS)pThis->cmdr_dqp, cc, cc < RT_ELEMENTS(g_apszCmplCodes) ? g_apszCmplCodes[cc] : "WHAT?!!",
2455 uSlotID, uEpDCI, uIntTgt, uEvtData, uXferLen, fBlockInt, fEvent));
2456
2457 /* A transfer event may be either generated by TRB completion (in case
2458 * fEvent=false) or by a special transfer event TRB (fEvent=true). In
2459 * either case, interrupts may be suppressed.
2460 */
2461 RT_ZERO(ed);
2462 ed.te.trb_ptr = uEvtData;
2463 ed.te.xfr_len = uXferLen;
2464 ed.te.cc = cc;
2465 ed.te.ed = fEvent;
2466 ed.te.type = XHCI_TRB_XFER;
2467 ed.te.ep_id = uEpDCI;
2468 ed.te.slot_id = uSlotID;
2469 return xhciR3WriteEvent(pDevIns, pThis, &ed, uIntTgt, fBlockInt); /* Sets the cycle bit, too. */
2470}
2471
2472
2473static int xhciR3FindRhDevBySlot(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, uint8_t uSlotID, PXHCIROOTHUBR3 *ppRh, uint32_t *puPort)
2474{
2475 XHCI_SLOT_CTX slot_ctx;
2476 PXHCIROOTHUBR3 pRh;
2477 unsigned iPort;
2478 int rc;
2479
2480 /// @todo Do any of these need to be release assertions?
2481 Assert(uSlotID <= RT_ELEMENTS(pThis->aSlotState));
2482 Assert(pThis->aSlotState[ID_TO_IDX(uSlotID)] > XHCI_DEVSLOT_EMPTY);
2483
2484 /* Load the slot context. */
2485 xhciR3FetchDevCtx(pDevIns, pThis, uSlotID, 0, &slot_ctx);
2486
2487 /* The port ID is stored in the slot context. */
2488 iPort = ID_TO_IDX(slot_ctx.rh_port);
2489 if (iPort < XHCI_NDP_CFG(pThis))
2490 {
2491 /* Find the corresponding root hub. */
2492 pRh = GET_PORT_PRH(pThisCC, iPort);
2493 Assert(pRh);
2494
2495 /* And the device; if the device was ripped out fAttached will be false. */
2496 if (pThisCC->aPorts[iPort].fAttached)
2497 {
2498 /* Provide the information the caller asked for. */
2499 if (ppRh)
2500 *ppRh = pRh;
2501 if (puPort)
2502 *puPort = GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort);
2503 rc = VINF_SUCCESS;
2504 }
2505 else
2506 {
2507 LogFunc(("No device attached (port index %u)!\n", iPort));
2508 rc = VERR_VUSB_DEVICE_NOT_ATTACHED;
2509 }
2510 }
2511 else
2512 {
2513 LogFunc(("Port out of range (index %u)!\n", iPort));
2514 rc = VERR_INVALID_PARAMETER;
2515 }
2516 return rc;
2517}
2518
2519
2520static void xhciR3EndlessTrbError(PPDMDEVINS pDevIns, PXHCI pThis)
2521{
2522 /* Clear the R/S bit and indicate controller error. */
2523 ASMAtomicAndU32(&pThis->cmd, ~XHCI_CMD_RS);
2524 ASMAtomicOrU32(&pThis->status, XHCI_STATUS_HCE);
2525
2526 /* Ensure that XHCI_STATUS_HCH gets set by the worker thread. */
2527 xhciKickWorker(pDevIns, pThis, XHCI_JOB_XFER_DONE, 0);
2528
2529 LogRelMax(10, ("xHCI: Attempted to process too many TRBs, stopping xHC!\n"));
2530}
2531
2532/**
2533 * TRB walker callback prototype.
2534 *
2535 * @returns true if walking should continue.
2536 * @returns false if walking should be terminated.
2537 * @param pDevIns The device instance.
2538 * @param pThis The xHCI device state.
2539 * @param pXferTRB Pointer to the transfer TRB to handle.
2540 * @param GCPhysXfrTRB Physical address of the TRB.
2541 * @param pvContext User-defined walk context.
2542 * @remarks We don't need to use DECLCALLBACKPTR here, since all users are in
2543 * the same source file, but having the functions marked with
2544 * DECLCALLBACK helps readability.
2545 */
2546typedef DECLCALLBACKPTR(bool, PFNTRBWALKCB,(PPDMDEVINS pDevIns, PXHCI pThis, const XHCI_XFER_TRB *pXferTRB,
2547 RTGCPHYS GCPhysXfrTRB, void *pvContext));
2548
2549
2550/**
2551 * Walk a chain of TRBs which comprise a single TD.
2552 *
2553 * This is something we need to do potentially more than once when submitting a
2554 * URB and then often again when completing the URB. Note that the walker does
2555 * not update the endpoint state (TRDP/TREP/DCS) so that it can be re-run
2556 * multiple times.
2557 *
2558 * @param pDevIns The device instance.
2559 * @param pThis The xHCI device state.
2560 * @param uTRP Initial TR pointer and DCS.
2561 * @param pfnCbk Callback routine.
2562 * @param pvContext User-defined walk context.
2563 * @param pTREP Pointer to storage for final TR Enqueue Pointer/DCS.
2564 */
2565static int xhciR3WalkXferTrbChain(PPDMDEVINS pDevIns, PXHCI pThis, uint64_t uTRP,
2566 PFNTRBWALKCB pfnCbk, void *pvContext, uint64_t *pTREP)
2567{
2568 RTGCPHYS GCPhysXfrTRB;
2569 uint64_t uTREP;
2570 XHCI_XFER_TRB XferTRB;
2571 bool fContinue = true;
2572 bool dcs;
2573 int rc = VINF_SUCCESS;
2574 unsigned cTrbs = 0;
2575
2576 AssertPtr(pvContext);
2577 AssertPtr(pTREP);
2578 Assert(uTRP);
2579
2580 /* Find the transfer TRB address and the DCS. */
2581 GCPhysXfrTRB = uTRP & XHCI_TRDP_ADDR_MASK;
2582 dcs = !!(uTRP & XHCI_TRDP_DCS_MASK); /* MSC upgrades bool to signed something when comparing with a uint8_t:1. */
2583 LogFlowFunc(("Walking Transfer Ring, TREP:%RGp DCS=%u\n", GCPhysXfrTRB, dcs));
2584
2585 do {
2586 /* Fetch the transfer TRB. */
2587 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysXfrTRB, &XferTRB, sizeof(XferTRB));
2588
2589 if ((bool)XferTRB.gen.cycle == dcs)
2590 {
2591 Log2(("Walking TRB@%RGp, type %u (%s) %u bytes ENT=%u ISP=%u NS=%u CH=%u IOC=%u IDT=%u\n", GCPhysXfrTRB, XferTRB.gen.type,
2592 XferTRB.gen.type < RT_ELEMENTS(g_apszTrbNames) ? g_apszTrbNames[XferTRB.gen.type] : "WHAT?!!",
2593 XferTRB.gen.xfr_len, XferTRB.gen.ent, XferTRB.gen.isp, XferTRB.gen.ns, XferTRB.gen.ch, XferTRB.gen.ioc, XferTRB.gen.idt));
2594
2595 /* DCS matches, the TRB is ours to process. */
2596 switch (XferTRB.gen.type) {
2597 case XHCI_TRB_LINK:
2598 Log2(("Link intra-TD: Ptr=%RGp IOC=%u TC=%u CH=%u\n", XferTRB.link.rseg_ptr, XferTRB.link.ioc, XferTRB.link.toggle, XferTRB.link.chain));
2599 Assert(XferTRB.link.chain);
2600 /* Do not update the actual TRDP/TREP and DCS yet, just the temporary images. */
2601 GCPhysXfrTRB = XferTRB.link.rseg_ptr & XHCI_TRDP_ADDR_MASK;
2602 if (XferTRB.link.toggle)
2603 dcs = !dcs;
2604 Assert(!XferTRB.link.ioc); /// @todo Needs to be reported.
2605 break;
2606 case XHCI_TRB_NORMAL:
2607 case XHCI_TRB_ISOCH:
2608 case XHCI_TRB_SETUP_STG:
2609 case XHCI_TRB_DATA_STG:
2610 case XHCI_TRB_STATUS_STG:
2611 case XHCI_TRB_EVT_DATA:
2612 fContinue = pfnCbk(pDevIns, pThis, &XferTRB, GCPhysXfrTRB, pvContext);
2613 GCPhysXfrTRB += sizeof(XferTRB);
2614 break;
2615 default:
2616 /* NB: No-op TRBs are not allowed within TDs (4.11.7). */
2617 Log(("Bad TRB type %u found within TD!!\n", XferTRB.gen.type));
2618 fContinue = false;
2619 /// @todo Stop EP etc.?
2620 }
2621 }
2622 else
2623 {
2624 /* We don't have a complete TD. Interesting times. */
2625 Log2(("DCS mismatch, no more TRBs available.\n"));
2626 fContinue = false;
2627 rc = VERR_TRY_AGAIN;
2628 }
2629
2630 /* Kill the xHC if the TRB list has no end in sight. */
2631 if (++cTrbs > XHCI_MAX_NUM_TRBS)
2632 {
2633 /* Stop the xHC with an error. */
2634 xhciR3EndlessTrbError(pDevIns, pThis);
2635
2636 /* Get out of the loop. */
2637 fContinue = false;
2638 rc = VERR_NOT_SUPPORTED; /* No good error code really... */
2639 }
2640 } while (fContinue);
2641
2642 /* Inform caller of the new TR Enqueue Pointer/DCS (not necessarily changed). */
2643 Assert(!(GCPhysXfrTRB & ~XHCI_TRDP_ADDR_MASK));
2644 uTREP = GCPhysXfrTRB | (unsigned)dcs;
2645 Log2(("Final TRP after walk: %RGp\n", uTREP));
2646 *pTREP = uTREP;
2647
2648 return rc;
2649}
2650
2651
2652/** Context for probing TD size. */
2653typedef struct {
2654 uint32_t uXferLen;
2655 uint32_t cTRB;
2656 uint32_t uXfrLenLastED;
2657 uint32_t cTRBLastED;
2658} XHCI_CTX_XFER_PROBE;
2659
2660
2661/** Context for submitting 'out' TDs. */
2662typedef struct {
2663 PVUSBURB pUrb;
2664 uint32_t uXferPos;
2665 unsigned cTRB;
2666} XHCI_CTX_XFER_SUBMIT;
2667
2668
2669/** Context for completing TDs. */
2670typedef struct {
2671 PVUSBURB pUrb;
2672 uint32_t uXferPos;
2673 uint32_t uXferLeft;
2674 unsigned cTRB;
2675 uint32_t uEDTLA : 24;
2676 uint32_t uLastCC : 8;
2677 uint8_t uSlotID;
2678 uint8_t uEpDCI;
2679 bool fMaxCount;
2680} XHCI_CTX_XFER_COMPLETE;
2681
2682
2683/** Context for building isochronous URBs. */
2684typedef struct {
2685 PVUSBURB pUrb;
2686 unsigned iPkt;
2687 uint32_t offCur;
2688 uint64_t uInitTREP;
2689 bool fSubmitFailed;
2690} XHCI_CTX_ISOCH;
2691
2692
2693/**
2694 * @callback_method_impl{PFNTRBWALKCB,
2695 * Probe a TD and figure out how big it is so that a URB can be allocated to back it.}
2696 */
2697static DECLCALLBACK(bool)
2698xhciR3WalkDataTRBsProbe(PPDMDEVINS pDevIns, PXHCI pThis, const XHCI_XFER_TRB *pXferTRB, RTGCPHYS GCPhysXfrTRB, void *pvContext)
2699{
2700 RT_NOREF(pDevIns, pThis, GCPhysXfrTRB);
2701 XHCI_CTX_XFER_PROBE *pCtx = (XHCI_CTX_XFER_PROBE *)pvContext;
2702
2703 pCtx->cTRB++;
2704
2705 /* Only consider TRBs which transfer data. */
2706 switch (pXferTRB->gen.type)
2707 {
2708 case XHCI_TRB_NORMAL:
2709 case XHCI_TRB_ISOCH:
2710 case XHCI_TRB_SETUP_STG:
2711 case XHCI_TRB_DATA_STG:
2712 case XHCI_TRB_STATUS_STG:
2713 pCtx->uXferLen += pXferTRB->norm.xfr_len;
2714 if (RT_UNLIKELY(pCtx->uXferLen > XHCI_MAX_TD_SIZE))
2715 {
2716 /* NB: We let the TD size get a bit past the max so that we don't lose anything,
2717 * but the EDTLA will wrap around.
2718 */
2719 LogRelMax(10, ("xHCI: TD size (%u) too big, not continuing!\n", pCtx->uXferLen));
2720 return false;
2721 }
2722 break;
2723 case XHCI_TRB_EVT_DATA:
2724 /* Remember where the last seen Event Data TRB was. */
2725 pCtx->cTRBLastED = pCtx->cTRB;
2726 pCtx->uXfrLenLastED = pCtx->uXferLen;
2727 break;
2728 default: /* Could be a link TRB, too. */
2729 break;
2730 }
2731
2732 return pXferTRB->gen.ch;
2733}
2734
2735
2736/**
2737 * @callback_method_impl{PFNTRBWALKCB,
2738 * Copy data from a TD (TRB chain) into the corresponding TD. OUT direction only.}
2739 */
2740static DECLCALLBACK(bool)
2741xhciR3WalkDataTRBsSubmit(PPDMDEVINS pDevIns, PXHCI pThis, const XHCI_XFER_TRB *pXferTRB, RTGCPHYS GCPhysXfrTRB, void *pvContext)
2742{
2743 RT_NOREF(pThis, GCPhysXfrTRB);
2744 XHCI_CTX_XFER_SUBMIT *pCtx = (XHCI_CTX_XFER_SUBMIT *)pvContext;
2745 uint32_t uXferLen = pXferTRB->norm.xfr_len;
2746
2747
2748 /* Only consider TRBs which transfer data. */
2749 switch (pXferTRB->gen.type)
2750 {
2751 case XHCI_TRB_NORMAL:
2752 case XHCI_TRB_ISOCH:
2753 case XHCI_TRB_SETUP_STG:
2754 case XHCI_TRB_DATA_STG:
2755 case XHCI_TRB_STATUS_STG:
2756 /* NB: Transfer length may be zero! */
2757 /// @todo explain/verify abuse of various TRB types here (data stage mapped to normal etc.).
2758 if (uXferLen)
2759 {
2760 /* Sanity check for broken guests (TRBs may have changed since probing). */
2761 if (pCtx->uXferPos + uXferLen <= pCtx->pUrb->cbData)
2762 {
2763 /* Data might be immediate or elsewhere in memory. */
2764 if (pXferTRB->norm.idt)
2765 {
2766 /* If an immediate data TRB claims there's more than 8 bytes, we have a problem. */
2767 if (uXferLen > 8)
2768 {
2769 LogRelMax(10, ("xHCI: Immediate data TRB length %u bytes, ignoring!\n", uXferLen));
2770 return false; /* Stop walking the chain immediately. */
2771 }
2772
2773 Assert(uXferLen >= 1 && uXferLen <= 8);
2774 Log2(("Copying %u bytes to URB offset %u (immediate data)\n", uXferLen, pCtx->uXferPos));
2775 memcpy(pCtx->pUrb->abData + pCtx->uXferPos, pXferTRB, uXferLen);
2776 }
2777 else
2778 {
2779 PDMDevHlpPCIPhysReadUser(pDevIns, pXferTRB->norm.data_ptr, pCtx->pUrb->abData + pCtx->uXferPos, uXferLen);
2780 Log2(("Copying %u bytes to URB offset %u (from %RGp)\n", uXferLen, pCtx->uXferPos, pXferTRB->norm.data_ptr));
2781 }
2782 pCtx->uXferPos += uXferLen;
2783 }
2784 else
2785 {
2786 LogRelMax(10, ("xHCI: Attempted to submit too much data, ignoring!\n"));
2787 return false; /* Stop walking the chain immediately. */
2788 }
2789
2790 }
2791 break;
2792 default: /* Could be an event or status stage TRB, too. */
2793 break;
2794 }
2795 pCtx->cTRB++;
2796
2797 /// @todo Maybe have to make certain that the number of probed TRBs matches? Potentially
2798 /// by the time TRBs get submitted, there might be more of them available if the TD was
2799 /// initially not fully written by HCD.
2800
2801 return pXferTRB->gen.ch;
2802}
2803
2804
2805/**
2806 * Perform URB completion processing.
2807 *
2808 * Figure out how much data was really transferred, post events if required, and
2809 * for IN transfers, copy data from the URB.
2810 *
2811 * @callback_method_impl{PFNTRBWALKCB}
2812 */
2813static DECLCALLBACK(bool)
2814xhciR3WalkDataTRBsComplete(PPDMDEVINS pDevIns, PXHCI pThis, const XHCI_XFER_TRB *pXferTRB, RTGCPHYS GCPhysXfrTRB, void *pvContext)
2815{
2816 XHCI_CTX_XFER_COMPLETE *pCtx = (XHCI_CTX_XFER_COMPLETE *)pvContext;
2817 int rc;
2818 unsigned uXferLen;
2819 unsigned uResidue;
2820 uint8_t cc;
2821 bool fKeepGoing = true;
2822
2823 switch (pXferTRB->gen.type)
2824 {
2825 case XHCI_TRB_NORMAL:
2826 case XHCI_TRB_ISOCH:
2827 case XHCI_TRB_SETUP_STG:
2828 case XHCI_TRB_DATA_STG: /// @todo document abuse; esp. check BEI bit
2829 case XHCI_TRB_STATUS_STG:
2830 /* Assume successful transfer. */
2831 uXferLen = pXferTRB->norm.xfr_len;
2832 cc = XHCI_TCC_SUCCESS;
2833
2834 /* If there was a short packet, handle it accordingly. */
2835 if (pCtx->uXferLeft < uXferLen)
2836 {
2837 /* The completion code is set regardless of IOC/ISP. It may be
2838 * reported later via an Event Data TRB (4.10.1.1)
2839 */
2840 uXferLen = pCtx->uXferLeft;
2841 cc = XHCI_TCC_SHORT_PKT;
2842 }
2843
2844 if (pCtx->pUrb->enmDir == VUSBDIRECTION_IN)
2845 {
2846 Assert(!pXferTRB->norm.idt);
2847
2848 /* NB: Transfer length may be zero! */
2849 if (uXferLen)
2850 {
2851 if (uXferLen <= pCtx->uXferLeft)
2852 {
2853 Log2(("Writing %u bytes to %RGp from URB offset %u (TRB@%RGp)\n", uXferLen, pXferTRB->norm.data_ptr, pCtx->uXferPos, GCPhysXfrTRB));
2854 PDMDevHlpPCIPhysWriteUser(pDevIns, pXferTRB->norm.data_ptr, pCtx->pUrb->abData + pCtx->uXferPos, uXferLen);
2855 }
2856 else
2857 {
2858 LogRelMax(10, ("xHCI: Attempted to read too much data, ignoring!\n"));
2859 }
2860 }
2861 }
2862
2863 /* Update position within TD. */
2864 pCtx->uXferLeft -= uXferLen;
2865 pCtx->uXferPos += uXferLen;
2866 Log2(("Current uXferLeft=%u, uXferPos=%u (length was %u)\n", pCtx->uXferLeft, pCtx->uXferPos, uXferLen));
2867
2868 /* Keep track of the EDTLA and last completion status. */
2869 pCtx->uEDTLA += uXferLen; /* May wrap around! */
2870 pCtx->uLastCC = cc;
2871
2872 /* Report events as required. */
2873 uResidue = pXferTRB->norm.xfr_len - uXferLen;
2874 if (pXferTRB->norm.ioc || (pXferTRB->norm.isp && uResidue))
2875 {
2876 rc = xhciR3PostXferEvent(pDevIns, pThis, pXferTRB->norm.int_tgt, uResidue, cc,
2877 pCtx->uSlotID, pCtx->uEpDCI, GCPhysXfrTRB, pXferTRB->norm.bei, false);
2878 }
2879 break;
2880 case XHCI_TRB_EVT_DATA:
2881 if (pXferTRB->evtd.ioc)
2882 {
2883 rc = xhciR3PostXferEvent(pDevIns, pThis, pXferTRB->evtd.int_tgt, pCtx->uEDTLA, pCtx->uLastCC,
2884 pCtx->uSlotID, pCtx->uEpDCI, pXferTRB->evtd.evt_data, pXferTRB->evtd.bei, true);
2885 }
2886 /* Clear the EDTLA. */
2887 pCtx->uEDTLA = 0;
2888 break;
2889 default:
2890 AssertMsgFailed(("%#x\n", pXferTRB->gen.type));
2891 break;
2892 }
2893
2894 pCtx->cTRB--;
2895 /* For TD fragments, enforce the maximum count, but only as long as the transfer
2896 * is successful. In case of error we have to complete the entire TD! */
2897 if (!pCtx->cTRB && pCtx->fMaxCount && pCtx->uLastCC == XHCI_TCC_SUCCESS)
2898 {
2899 Log2(("Stopping at the end of TD Fragment.\n"));
2900 fKeepGoing = false;
2901 }
2902
2903 /* NB: We currently do not enforce that the number of TRBs can't change between
2904 * submission and completion. If we do, we'll have to store it somewhere for
2905 * isochronous URBs.
2906 */
2907 return pXferTRB->gen.ch && fKeepGoing;
2908}
2909
2910/**
2911 * Process (consume) non-data TRBs on a transfer ring. This function
2912 * completes TRBs which do not have any URB associated with them. Only
2913 * used with running endpoints. Usable regardless of whether there are
2914 * in-flight TRBs or not. Returns the next TRB and its address to the
2915 * caller. May modify the endpoint context!
2916 *
2917 * @param pDevIns The device instance.
2918 * @param pThis The xHCI device state.
2919 * @param uSlotID The slot corresponding to this USB device.
2920 * @param uEpDCI The DCI of this endpoint.
2921 * @param pEpCtx Endpoint context. May be modified.
2922 * @param pXfer Storage for returning the next TRB to caller.
2923 * @param pGCPhys Storage for returning the physical address of TRB.
2924 */
2925static int xhciR3ConsumeNonXferTRBs(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID, uint8_t uEpDCI,
2926 XHCI_EP_CTX *pEpCtx, XHCI_XFER_TRB *pXfer, RTGCPHYS *pGCPhys)
2927{
2928 XHCI_XFER_TRB xfer;
2929 RTGCPHYS GCPhysXfrTRB = 0;
2930 bool dcs;
2931 bool fInFlight;
2932 bool fContinue = true;
2933 int rc;
2934 unsigned cTrbs = 0;
2935
2936 LogFlowFunc(("Slot ID: %u, EP DCI %u\n", uSlotID, uEpDCI));
2937 Assert(uSlotID > 0);
2938 Assert(uSlotID <= XHCI_NDS);
2939
2940 Assert(pEpCtx->ep_state == XHCI_EPST_RUNNING);
2941 do
2942 {
2943 /* Find the transfer TRB address. */
2944 GCPhysXfrTRB = pEpCtx->trdp & XHCI_TRDP_ADDR_MASK;
2945 dcs = !!(pEpCtx->trdp & XHCI_TRDP_DCS_MASK);
2946
2947 /* Determine whether there are any in-flight TRBs or not. This affects TREP
2948 * processing -- when nothing is in flight, we have to move both TREP and TRDP;
2949 * otherwise only the TRDP must be updated.
2950 */
2951 fInFlight = pEpCtx->trep != pEpCtx->trdp;
2952 LogFlowFunc(("Skipping non-data TRBs, TREP:%RGp, TRDP:%RGp, in-flight: %RTbool\n", pEpCtx->trep, pEpCtx->trdp, fInFlight));
2953
2954 /* Fetch the transfer TRB. */
2955 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysXfrTRB, &xfer, sizeof(xfer));
2956
2957 /* Make sure the Cycle State matches. */
2958 if ((bool)xfer.gen.cycle == dcs)
2959 {
2960 Log2(("TRB @ %RGp, type %u (%s) %u bytes ENT=%u ISP=%u NS=%u CH=%u IOC=%u IDT=%u\n", GCPhysXfrTRB, xfer.gen.type,
2961 xfer.gen.type < RT_ELEMENTS(g_apszTrbNames) ? g_apszTrbNames[xfer.gen.type] : "WHAT?!!",
2962 xfer.gen.xfr_len, xfer.gen.ent, xfer.gen.isp, xfer.gen.ns, xfer.gen.ch, xfer.gen.ioc, xfer.gen.idt));
2963
2964 switch (xfer.gen.type) {
2965 case XHCI_TRB_LINK:
2966 Log2(("Link extra-TD: Ptr=%RGp IOC=%u TC=%u CH=%u\n", xfer.link.rseg_ptr, xfer.link.ioc, xfer.link.toggle, xfer.link.chain));
2967 Assert(!xfer.link.chain);
2968 /* Set new TRDP but leave DCS bit alone... */
2969 pEpCtx->trdp = (xfer.link.rseg_ptr & XHCI_TRDP_ADDR_MASK) | (pEpCtx->trdp & XHCI_TRDP_DCS_MASK);
2970 /* ...and flip the DCS bit if required. Then update the TREP. */
2971 if (xfer.link.toggle)
2972 pEpCtx->trdp = (pEpCtx->trdp & ~XHCI_TRDP_DCS_MASK) | (pEpCtx->trdp ^ XHCI_TRDP_DCS_MASK);
2973 if (!fInFlight)
2974 pEpCtx->trep = pEpCtx->trdp;
2975 if (xfer.link.ioc)
2976 rc = xhciR3PostXferEvent(pDevIns, pThis, xfer.link.int_tgt, 0, XHCI_TCC_SUCCESS, uSlotID, uEpDCI,
2977 GCPhysXfrTRB, false, false);
2978 break;
2979 case XHCI_TRB_NOOP_XFER:
2980 Log2(("No op xfer: IOC=%u CH=%u ENT=%u\n", xfer.nop.ioc, xfer.nop.ch, xfer.nop.ent));
2981 /* A no-op transfer TRB must not be part of a chain. See 4.11.7. */
2982 Assert(!xfer.link.chain);
2983 /* Update enqueue/dequeue pointers. */
2984 pEpCtx->trdp += sizeof(XHCI_XFER_TRB);
2985 if (!fInFlight)
2986 pEpCtx->trep += sizeof(XHCI_XFER_TRB);
2987 if (xfer.nop.ioc)
2988 rc = xhciR3PostXferEvent(pDevIns, pThis, xfer.nop.int_tgt, 0, XHCI_TCC_SUCCESS, uSlotID, uEpDCI,
2989 GCPhysXfrTRB, false, false);
2990 break;
2991 default:
2992 fContinue = false;
2993 break;
2994 }
2995 }
2996 else
2997 {
2998 LogFunc(("Transfer Ring empty\n"));
2999 fContinue = false;
3000 }
3001
3002 /* Kill the xHC if the TRB list has no end in sight. */
3003 /* NB: The limit here could perhaps be much lower because a sequence of Link
3004 * and No-op TRBs with no real work to be done would be highly suspect.
3005 */
3006 if (++cTrbs > XHCI_MAX_NUM_TRBS)
3007 {
3008 /* Stop the xHC with an error. */
3009 xhciR3EndlessTrbError(pDevIns, pThis);
3010
3011 /* Get out of the loop. */
3012 fContinue = false;
3013 rc = VERR_NOT_SUPPORTED; /* No good error code really... */
3014 }
3015 } while (fContinue);
3016
3017 /* The caller will need the next TRB. Hand it over. */
3018 Assert(GCPhysXfrTRB);
3019 *pGCPhys = GCPhysXfrTRB;
3020 *pXfer = xfer;
3021 LogFlowFunc(("Final TREP:%RGp, TRDP:%RGp GCPhysXfrTRB:%RGp\n", pEpCtx->trep, pEpCtx->trdp, GCPhysXfrTRB));
3022
3023 return VINF_SUCCESS;
3024}
3025
3026/**
3027 * Transfer completion callback routine.
3028 *
3029 * VUSB will call this when a transfer have been completed
3030 * in a one or another way.
3031 *
3032 * @param pInterface Pointer to XHCI::ROOTHUB::IRhPort.
3033 * @param pUrb Pointer to the URB in question.
3034 */
3035static DECLCALLBACK(void) xhciR3RhXferCompletion(PVUSBIROOTHUBPORT pInterface, PVUSBURB pUrb)
3036{
3037 PXHCIROOTHUBR3 pRh = RT_FROM_MEMBER(pInterface, XHCIROOTHUBR3, IRhPort);
3038 PXHCICC pThisCC = pRh->pXhciR3;
3039 PPDMDEVINS pDevIns = pThisCC->pDevIns;
3040 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
3041 XHCI_SLOT_CTX slot_ctx;
3042 XHCI_EP_CTX ep_ctx;
3043 XHCI_XFER_TRB xfer;
3044 RTGCPHYS GCPhysXfrTRB;
3045 int rc;
3046 unsigned uResidue = 0;
3047 uint8_t uSlotID = pUrb->pHci->uSlotID;
3048 uint8_t cc = XHCI_TCC_SUCCESS;
3049 uint8_t uEpDCI;
3050
3051 /* Check for URBs completed synchronously as part of xHCI command execution.
3052 * The URB will have zero cTRB as it's not associated with a TD.
3053 */
3054 if (!pUrb->pHci->cTRB)
3055 {
3056 LogFlow(("%s: xhciR3RhXferCompletion: uSlotID=%u EP=%u cTRB=%d cbData=%u status=%u\n",
3057 pUrb->pszDesc, uSlotID, pUrb->EndPt, pUrb->pHci->cTRB, pUrb->cbData, pUrb->enmStatus));
3058 LogFlow(("%s: xhciR3RhXferCompletion: Completing xHCI-generated request\n", pUrb->pszDesc));
3059 return;
3060 }
3061
3062 /* If the xHC isn't running, just drop the URB right here. */
3063 if (pThis->status & XHCI_STATUS_HCH)
3064 {
3065 LogFlow(("%s: xhciR3RhXferCompletion: uSlotID=%u EP=%u cTRB=%d cbData=%u status=%u\n",
3066 pUrb->pszDesc, uSlotID, pUrb->EndPt, pUrb->pHci->cTRB, pUrb->cbData, pUrb->enmStatus));
3067 LogFlow(("%s: xhciR3RhXferCompletion: xHC halted, skipping URB completion\n", pUrb->pszDesc));
3068 return;
3069 }
3070
3071#ifdef XHCI_ERROR_INJECTION
3072 if (pThis->fDropUrb)
3073 {
3074 LogFlow(("%s: xhciR3RhXferCompletion: Error injection, dropping URB!\n", pUrb->pszDesc));
3075 pThis->fDropUrb = false;
3076 return;
3077 }
3078#endif
3079
3080 RTCritSectEnter(&pThisCC->CritSectThrd);
3081
3082 /* Convert USB endpoint address to xHCI format. */
3083 if (pUrb->EndPt)
3084 uEpDCI = pUrb->EndPt * 2 + (pUrb->enmDir == VUSBDIRECTION_IN ? 1 : 0);
3085 else
3086 uEpDCI = 1; /* EP 0 */
3087
3088 LogFlow(("%s: xhciR3RhXferCompletion: uSlotID=%u EP=%u cTRB=%d\n",
3089 pUrb->pszDesc, uSlotID, pUrb->EndPt, pUrb->pHci->cTRB));
3090 LogFlow(("%s: xhciR3RhXferCompletion: EP DCI=%u, cbData=%u status=%u\n", pUrb->pszDesc, uEpDCI, pUrb->cbData, pUrb->enmStatus));
3091
3092 /* Load the slot/endpoint contexts from guest memory. */
3093 xhciR3FetchCtxAndEp(pDevIns, pThis, uSlotID, uEpDCI, &slot_ctx, &ep_ctx);
3094
3095 /* If the EP is disabled, we don't own it so we can't complete the URB.
3096 * Leave this EP alone and drop the URB.
3097 */
3098 if (ep_ctx.ep_state != XHCI_EPST_RUNNING)
3099 {
3100 Log(("EP DCI %u not running (state %u), skipping URB completion\n", uEpDCI, ep_ctx.ep_state));
3101 RTCritSectLeave(&pThisCC->CritSectThrd);
3102 return;
3103 }
3104
3105 /* Now complete any non-transfer TRBs that might be on the transfer ring before
3106 * the TRB(s) corresponding to this URB. Preloads the TRB as a side effect.
3107 * Endpoint state now must be written back in case it was modified!
3108 */
3109 xhciR3ConsumeNonXferTRBs(pDevIns, pThis, uSlotID, uEpDCI, &ep_ctx, &xfer, &GCPhysXfrTRB);
3110
3111 /* Deal with failures which halt the EP first. */
3112 if (RT_UNLIKELY(pUrb->enmStatus != VUSBSTATUS_OK))
3113 {
3114 switch(pUrb->enmStatus)
3115 {
3116 case VUSBSTATUS_STALL:
3117 /* Halt the endpoint and inform the HCD.
3118 * NB: The TRDP is NOT advanced in case of error.
3119 */
3120 ep_ctx.ep_state = XHCI_EPST_HALTED;
3121 cc = XHCI_TCC_STALL;
3122 rc = xhciR3PostXferEvent(pDevIns, pThis, xfer.gen.int_tgt, uResidue, cc,
3123 uSlotID, uEpDCI, GCPhysXfrTRB, false, false);
3124 break;
3125 case VUSBSTATUS_DNR:
3126 /* Halt the endpoint and inform the HCD.
3127 * NB: The TRDP is NOT advanced in case of error.
3128 */
3129 ep_ctx.ep_state = XHCI_EPST_HALTED;
3130 cc = XHCI_TCC_USB_XACT_ERR;
3131 rc = xhciR3PostXferEvent(pDevIns, pThis, xfer.gen.int_tgt, uResidue, cc,
3132 uSlotID, uEpDCI, GCPhysXfrTRB, false, false);
3133 break;
3134 case VUSBSTATUS_CRC: /// @todo Separate status for canceling?!
3135 ep_ctx.ep_state = XHCI_EPST_HALTED;
3136 cc = XHCI_TCC_USB_XACT_ERR;
3137 rc = xhciR3PostXferEvent(pDevIns, pThis, xfer.gen.int_tgt, uResidue, cc,
3138 uSlotID, uEpDCI, GCPhysXfrTRB, false, false);
3139
3140 /* NB: The TRDP is *not* advanced and TREP is reset. */
3141 ep_ctx.trep = ep_ctx.trdp;
3142 break;
3143 case VUSBSTATUS_DATA_OVERRUN:
3144 case VUSBSTATUS_DATA_UNDERRUN:
3145 /* Halt the endpoint and inform the HCD.
3146 * NB: The TRDP is NOT advanced in case of error.
3147 */
3148 ep_ctx.ep_state = XHCI_EPST_HALTED;
3149 cc = XHCI_TCC_DATA_BUF_ERR;
3150 rc = xhciR3PostXferEvent(pDevIns, pThis, xfer.gen.int_tgt, uResidue, cc,
3151 uSlotID, uEpDCI, GCPhysXfrTRB, false, false);
3152 break;
3153 default:
3154 AssertMsgFailed(("Unexpected URB status %u\n", pUrb->enmStatus));
3155 }
3156
3157 if (pUrb->enmType == VUSBXFERTYPE_ISOC)
3158 STAM_COUNTER_INC(&pThis->StatErrorIsocUrbs);
3159 }
3160 else if (xfer.gen.type == XHCI_TRB_NORMAL)
3161 {
3162 XHCI_CTX_XFER_COMPLETE ctxComplete;
3163 uint64_t uTRDP;
3164
3165 ctxComplete.pUrb = pUrb;
3166 ctxComplete.uXferPos = 0;
3167 ctxComplete.uXferLeft = pUrb->cbData;
3168 ctxComplete.cTRB = pUrb->pHci->cTRB;
3169 ctxComplete.uSlotID = uSlotID;
3170 ctxComplete.uEpDCI = uEpDCI;
3171 ctxComplete.uEDTLA = 0; // Always zero at the beginning of a new TD.
3172 ctxComplete.uLastCC = cc;
3173 ctxComplete.fMaxCount = ep_ctx.ifc >= XHCI_NO_QUEUING_IN_FLIGHT;
3174 xhciR3WalkXferTrbChain(pDevIns, pThis, ep_ctx.trdp, xhciR3WalkDataTRBsComplete, &ctxComplete, &uTRDP);
3175 ep_ctx.last_cc = ctxComplete.uLastCC;
3176 ep_ctx.trdp = uTRDP;
3177
3178 if (ep_ctx.ifc >= XHCI_NO_QUEUING_IN_FLIGHT)
3179 ep_ctx.ifc -= XHCI_NO_QUEUING_IN_FLIGHT; /* TD fragment done, allow further queuing. */
3180 else
3181 ep_ctx.ifc--; /* TD done, decrement in-flight counter. */
3182 }
3183 else if (xfer.gen.type == XHCI_TRB_ISOCH)
3184 {
3185 XHCI_CTX_XFER_COMPLETE ctxComplete;
3186 uint64_t uTRDP;
3187 unsigned iPkt;
3188
3189 ctxComplete.pUrb = pUrb;
3190 ctxComplete.uSlotID = uSlotID;
3191 ctxComplete.uEpDCI = uEpDCI;
3192
3193 for (iPkt = 0; iPkt < pUrb->cIsocPkts; ++iPkt) {
3194 ctxComplete.uXferPos = pUrb->aIsocPkts[iPkt].off;
3195 ctxComplete.uXferLeft = pUrb->aIsocPkts[iPkt].cb;
3196 ctxComplete.cTRB = pUrb->pHci->cTRB;
3197 ctxComplete.uEDTLA = 0; // Zero at TD start.
3198 ctxComplete.uLastCC = cc;
3199 ctxComplete.fMaxCount = false;
3200 if (pUrb->aIsocPkts[iPkt].enmStatus != VUSBSTATUS_OK)
3201 STAM_COUNTER_INC(&pThis->StatErrorIsocPkts);
3202 xhciR3WalkXferTrbChain(pDevIns, pThis, ep_ctx.trdp, xhciR3WalkDataTRBsComplete, &ctxComplete, &uTRDP);
3203 ep_ctx.last_cc = ctxComplete.uLastCC;
3204 ep_ctx.trdp = uTRDP;
3205 xhciR3ConsumeNonXferTRBs(pDevIns, pThis, uSlotID, uEpDCI, &ep_ctx, &xfer, &GCPhysXfrTRB);
3206 }
3207 ep_ctx.ifc--; /* TD done, decrement in-flight counter. */
3208 }
3209 else if (xfer.gen.type == XHCI_TRB_SETUP_STG || xfer.gen.type == XHCI_TRB_DATA_STG || xfer.gen.type == XHCI_TRB_STATUS_STG)
3210 {
3211 XHCI_CTX_XFER_COMPLETE ctxComplete;
3212 uint64_t uTRDP;
3213
3214 ctxComplete.pUrb = pUrb;
3215 ctxComplete.uXferPos = 0;
3216 ctxComplete.uXferLeft = pUrb->cbData;
3217 ctxComplete.cTRB = pUrb->pHci->cTRB;
3218 ctxComplete.uSlotID = uSlotID;
3219 ctxComplete.uEpDCI = uEpDCI;
3220 ctxComplete.uEDTLA = 0; // Always zero at the beginning of a new TD.
3221 ctxComplete.uLastCC = cc;
3222 ctxComplete.fMaxCount = ep_ctx.ifc >= XHCI_NO_QUEUING_IN_FLIGHT;
3223 xhciR3WalkXferTrbChain(pDevIns, pThis, ep_ctx.trdp, xhciR3WalkDataTRBsComplete, &ctxComplete, &uTRDP);
3224 ep_ctx.last_cc = ctxComplete.uLastCC;
3225 ep_ctx.trdp = uTRDP;
3226 }
3227 else
3228 {
3229 AssertMsgFailed(("Unexpected TRB type %u\n", xfer.gen.type));
3230 Log2(("TRB @ %RGp, type %u unexpected!\n", GCPhysXfrTRB, xfer.gen.type));
3231 /* Advance the TRDP anyway so that the endpoint isn't completely stuck. */
3232 ep_ctx.trdp += sizeof(XHCI_XFER_TRB);
3233 }
3234
3235 /* Update the endpoint state. */
3236 xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uEpDCI, &ep_ctx);
3237
3238 RTCritSectLeave(&pThisCC->CritSectThrd);
3239
3240 if (pUrb->enmStatus == VUSBSTATUS_OK)
3241 {
3242 /* Completion callback usually runs on a separate thread. Let the worker do more. */
3243 Log2(("Ring bell for slot %u, DCI %u\n", uSlotID, uEpDCI));
3244 ASMAtomicOrU32(&pThis->aBellsRung[ID_TO_IDX(uSlotID)], 1 << uEpDCI);
3245 xhciKickWorker(pDevIns, pThis, XHCI_JOB_XFER_DONE, 0);
3246 }
3247}
3248
3249
3250/**
3251 * Handle transfer errors.
3252 *
3253 * VUSB calls this when a transfer attempt failed. This function will respond
3254 * indicating whether to retry or complete the URB with failure.
3255 *
3256 * @returns true if the URB should be retired.
3257 * @returns false if the URB should be re-tried.
3258 * @param pInterface Pointer to XHCI::ROOTHUB::IRhPort.
3259 * @param pUrb Pointer to the URB in question.
3260 */
3261static DECLCALLBACK(bool) xhciR3RhXferError(PVUSBIROOTHUBPORT pInterface, PVUSBURB pUrb)
3262{
3263 PXHCIROOTHUBR3 pRh = RT_FROM_MEMBER(pInterface, XHCIROOTHUBR3, IRhPort);
3264 PXHCICC pThisCC = pRh->pXhciR3;
3265 PXHCI pThis = PDMDEVINS_2_DATA(pThisCC->pDevIns, PXHCI);
3266 bool fRetire = true;
3267
3268 /* If the xHC isn't running, get out of here immediately. */
3269 if (pThis->status & XHCI_STATUS_HCH)
3270 {
3271 Log(("xHC halted, skipping URB error handling\n"));
3272 return fRetire;
3273 }
3274
3275 RTCritSectEnter(&pThisCC->CritSectThrd);
3276
3277 Assert(pUrb->pHci->cTRB); /* xHCI-generated URBs should not fail! */
3278 if (!pUrb->pHci->cTRB)
3279 {
3280 Log(("%s: Failing xHCI-generated request!\n", pUrb->pszDesc));
3281 }
3282 else if (pUrb->enmStatus == VUSBSTATUS_STALL)
3283 {
3284 /* Don't retry on stall. */
3285 Log2(("%s: xhciR3RhXferError: STALL, giving up.\n", pUrb->pszDesc));
3286 } else if (pUrb->enmStatus == VUSBSTATUS_CRC) {
3287 /* Don't retry on CRC errors either. These indicate canceled URBs, among others. */
3288 Log2(("%s: xhciR3RhXferError: CRC, giving up.\n", pUrb->pszDesc));
3289 } else if (pUrb->enmStatus == VUSBSTATUS_DNR) {
3290 /* Don't retry on DNR errors. These indicate the device vanished. */
3291 Log2(("%s: xhciR3RhXferError: DNR, giving up.\n", pUrb->pszDesc));
3292 } else if (pUrb->enmStatus == VUSBSTATUS_DATA_OVERRUN) {
3293 /* Don't retry on OVERRUN errors. These indicate a fatal error. */
3294 Log2(("%s: xhciR3RhXferError: OVERRUN, giving up.\n", pUrb->pszDesc));
3295 } else if (pUrb->enmStatus == VUSBSTATUS_DATA_UNDERRUN) {
3296 /* Don't retry on UNDERRUN errors. These indicate a fatal error. */
3297 Log2(("%s: xhciR3RhXferError: UNDERRUN, giving up.\n", pUrb->pszDesc));
3298 } else {
3299 /// @todo
3300 AssertMsgFailed(("%#x\n", pUrb->enmStatus));
3301 }
3302
3303 RTCritSectLeave(&pThisCC->CritSectThrd);
3304 return fRetire;
3305}
3306
3307
3308/**
3309 * Queue a TD composed of normal TRBs, event data TRBs, and suchlike.
3310 *
3311 * @returns VBox status code.
3312 * @param pDevIns The device instance.
3313 * @param pThis The xHCI device state, shared edition.
3314 * @param pThisCC The xHCI device state, ring-3 edition.
3315 * @param pRh Root hub for the device.
3316 * @param GCPhysTRB Physical gues address of the TRB.
3317 * @param pTrb Pointer to the contents of the first TRB.
3318 * @param pEpCtx Pointer to the cached EP context.
3319 * @param uSlotID ID of the associated slot context.
3320 * @param uAddr The device address.
3321 * @param uEpDCI The DCI(!) of the endpoint.
3322 */
3323static int xhciR3QueueDataTD(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, PXHCIROOTHUBR3 pRh, RTGCPHYS GCPhysTRB,
3324 XHCI_XFER_TRB *pTrb, XHCI_EP_CTX *pEpCtx, uint8_t uSlotID, uint8_t uAddr, uint8_t uEpDCI)
3325{
3326 RT_NOREF(GCPhysTRB);
3327 XHCI_CTX_XFER_PROBE ctxProbe;
3328 XHCI_CTX_XFER_SUBMIT ctxSubmit;
3329 uint64_t uTREP;
3330 bool fFragOnly = false;
3331 int rc;
3332 VUSBXFERTYPE enmType;
3333 VUSBDIRECTION enmDir;
3334
3335 /* Discover how big this TD is. */
3336 RT_ZERO(ctxProbe);
3337 rc = xhciR3WalkXferTrbChain(pDevIns, pThis, pEpCtx->trep, xhciR3WalkDataTRBsProbe, &ctxProbe, &uTREP);
3338 if (RT_SUCCESS(rc))
3339 LogFlowFunc(("Probed %u TRBs, %u bytes total, TREP@%RX64\n", ctxProbe.cTRB, ctxProbe.uXferLen, uTREP));
3340 else
3341 {
3342 LogFlowFunc(("Probing failed after %u TRBs, %u bytes total (last ED after %u TRBs and %u bytes), TREP@%RX64\n", ctxProbe.cTRB, ctxProbe.uXferLen, ctxProbe.cTRBLastED, ctxProbe.uXfrLenLastED, uTREP));
3343 if (rc == VERR_TRY_AGAIN && pTrb->gen.type == XHCI_TRB_NORMAL && ctxProbe.cTRBLastED)
3344 {
3345 /* The TD is incomplete, but we have at least one TD fragment. We can create a URB for
3346 * what we have but we can't safely queue any more because if any error occurs, the
3347 * TD needs to fail as a whole.
3348 * OS X Mavericks and Yosemite tend to trigger this case when reading from USB 3.0
3349 * MSDs (transfers up to 1MB).
3350 */
3351 fFragOnly = true;
3352
3353 /* Because we currently do not maintain the EDTLA across URBs, we have to only submit
3354 * TD fragments up to where we last saw an Event Data TRB. If there was no Event Data
3355 * TRB, we'll just try waiting a bit longer for the TD to be complete or an Event Data
3356 * TRB to show up. The guest is extremely likely to do one or the other, since otherwise
3357 * it has no way to tell when the transfer completed.
3358 */
3359 ctxProbe.cTRB = ctxProbe.cTRBLastED;
3360 ctxProbe.uXferLen = ctxProbe.uXfrLenLastED;
3361 }
3362 else
3363 return rc;
3364 }
3365
3366 /* Determine the transfer kind based on endpoint type. */
3367 switch (pEpCtx->ep_type)
3368 {
3369 case XHCI_EPTYPE_BULK_IN:
3370 case XHCI_EPTYPE_BULK_OUT:
3371 enmType = VUSBXFERTYPE_BULK;
3372 break;
3373 case XHCI_EPTYPE_INTR_IN:
3374 case XHCI_EPTYPE_INTR_OUT:
3375 enmType = VUSBXFERTYPE_INTR;
3376 break;
3377 case XHCI_EPTYPE_CONTROL:
3378 enmType = VUSBXFERTYPE_CTRL;
3379 break;
3380 case XHCI_EPTYPE_ISOCH_IN:
3381 case XHCI_EPTYPE_ISOCH_OUT:
3382 default:
3383 enmType = VUSBXFERTYPE_INVALID;
3384 AssertMsgFailed(("%#x\n", pEpCtx->ep_type));
3385 }
3386
3387 /* Determine the direction based on endpoint type. */
3388 switch (pEpCtx->ep_type)
3389 {
3390 case XHCI_EPTYPE_BULK_IN:
3391 case XHCI_EPTYPE_INTR_IN:
3392 enmDir = VUSBDIRECTION_IN;
3393 break;
3394 case XHCI_EPTYPE_BULK_OUT:
3395 case XHCI_EPTYPE_INTR_OUT:
3396 enmDir = VUSBDIRECTION_OUT;
3397 break;
3398 default:
3399 enmDir = VUSBDIRECTION_INVALID;
3400 AssertMsgFailed(("%#x\n", pEpCtx->ep_type));
3401 }
3402
3403 /* Allocate and initialize a URB. */
3404 PVUSBURB pUrb = VUSBIRhNewUrb(pRh->pIRhConn, uAddr, VUSB_DEVICE_PORT_INVALID, enmType, enmDir, ctxProbe.uXferLen, ctxProbe.cTRB, NULL);
3405 if (!pUrb)
3406 return VERR_OUT_OF_RESOURCES; /// @todo handle error!
3407
3408 STAM_COUNTER_ADD(&pThis->StatTRBsPerDtaUrb, ctxProbe.cTRB);
3409
3410 /* See 4.5.1 about xHCI vs. USB endpoint addressing. */
3411 Assert(uEpDCI);
3412
3413 pUrb->EndPt = uEpDCI / 2; /* DCI = EP * 2 + direction */
3414 pUrb->fShortNotOk = false; /* We detect short packets ourselves. */
3415 pUrb->enmStatus = VUSBSTATUS_OK;
3416
3417 /// @todo Cross check that the EP type corresponds to direction. Probably
3418 //should check when configuring device?
3419 pUrb->pHci->uSlotID = uSlotID;
3420
3421 /* For OUT transfers, copy the TD data into the URB. */
3422 if (pUrb->enmDir == VUSBDIRECTION_OUT)
3423 {
3424 ctxSubmit.pUrb = pUrb;
3425 ctxSubmit.uXferPos = 0;
3426 ctxSubmit.cTRB = 0;
3427 xhciR3WalkXferTrbChain(pDevIns, pThis, pEpCtx->trep, xhciR3WalkDataTRBsSubmit, &ctxSubmit, &uTREP);
3428 Assert(ctxProbe.cTRB == ctxSubmit.cTRB);
3429 ctxProbe.cTRB = ctxSubmit.cTRB;
3430 }
3431
3432 /* If only completing a fragment, remember the TRB count and increase
3433 * the in-flight count past the limit so we won't queue any more.
3434 */
3435 pUrb->pHci->cTRB = ctxProbe.cTRB;
3436 if (fFragOnly)
3437 /* Bit of a hack -- prevent further queuing. */
3438 pEpCtx->ifc += XHCI_NO_QUEUING_IN_FLIGHT;
3439 else
3440 /* Increment the in-flight counter before queuing more. */
3441 pEpCtx->ifc++;
3442
3443 /* Commit the updated TREP; submitting the URB may already invoke completion callbacks. */
3444 pEpCtx->trep = uTREP;
3445 xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uEpDCI, pEpCtx);
3446
3447 /*
3448 * Submit the URB.
3449 */
3450 STAM_COUNTER_ADD(&pThis->StatUrbSizeData, pUrb->cbData);
3451 Log(("%s: xhciR3QueueDataTD: Addr=%u, EndPt=%u, enmDir=%u cbData=%u\n",
3452 pUrb->pszDesc, pUrb->DstAddress, pUrb->EndPt, pUrb->enmDir, pUrb->cbData));
3453 RTCritSectLeave(&pThisCC->CritSectThrd);
3454 rc = VUSBIRhSubmitUrb(pRh->pIRhConn, pUrb, &pRh->Led);
3455 RTCritSectEnter(&pThisCC->CritSectThrd);
3456 if (RT_SUCCESS(rc))
3457 return VINF_SUCCESS;
3458
3459 /* Failure cleanup. Can happen if we're still resetting the device or out of resources,
3460 * or the user just ripped out the device.
3461 */
3462 /// @todo Mark the EP as halted and inactive and write back the changes.
3463
3464 return VERR_OUT_OF_RESOURCES;
3465}
3466
3467
3468/**
3469 * Queue an isochronous TD composed of isochronous and normal TRBs, event
3470 * data TRBs, and suchlike. This TD may either correspond to a single URB or
3471 * form one packet of an isochronous URB.
3472 *
3473 * @returns VBox status code.
3474 * @param pDevIns The device instance.
3475 * @param pThis The xHCI device state, shared edition.
3476 * @param pThisCC The xHCI device state, ring-3 edition.
3477 * @param pRh Root hub for the device.
3478 * @param GCPhysTRB Physical guest address of the TRB.
3479 * @param pTrb Pointer to the contents of the first TRB.
3480 * @param pEpCtx Pointer to the cached EP context.
3481 * @param uSlotID ID of the associated slot context.
3482 * @param uAddr The device address.
3483 * @param uEpDCI The DCI(!) of the endpoint.
3484 * @param pCtxIso Additional isochronous URB context.
3485 */
3486static int xhciR3QueueIsochTD(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, PXHCIROOTHUBR3 pRh, RTGCPHYS GCPhysTRB,
3487 XHCI_XFER_TRB *pTrb, XHCI_EP_CTX *pEpCtx, uint8_t uSlotID, uint8_t uAddr, uint8_t uEpDCI,
3488 XHCI_CTX_ISOCH *pCtxIso)
3489{
3490 RT_NOREF(GCPhysTRB, pTrb);
3491 XHCI_CTX_XFER_PROBE ctxProbe;
3492 XHCI_CTX_XFER_SUBMIT ctxSubmit;
3493 uint64_t uTREP;
3494 PVUSBURB pUrb;
3495 unsigned cIsoPackets;
3496 uint32_t cbPktMax;
3497
3498 /* Discover how big this TD is. */
3499 RT_ZERO(ctxProbe);
3500 xhciR3WalkXferTrbChain(pDevIns, pThis, pEpCtx->trep, xhciR3WalkDataTRBsProbe, &ctxProbe, &uTREP);
3501 LogFlowFunc(("Probed %u TRBs, %u bytes total, TREP@%RX64\n", ctxProbe.cTRB, ctxProbe.uXferLen, uTREP));
3502
3503 /* See 4.5.1 about xHCI vs. USB endpoint addressing. */
3504 Assert(uEpDCI);
3505
3506 /* For isochronous transfers, there's a bit of extra work to do. The interval
3507 * is key and determines whether the TD will directly correspond to a URB or
3508 * if it will only form part of a larger URB. In any case, one TD equals one
3509 * 'packet' of an isochronous URB.
3510 */
3511 switch (pEpCtx->interval)
3512 {
3513 case 0: /* Every 2^0 * 125us, i.e. 8 per frame. */
3514 cIsoPackets = 8;
3515 break;
3516 case 1: /* Every 2^1 * 125us, i.e. 4 per frame. */
3517 cIsoPackets = 4;
3518 break;
3519 case 2: /* Every 2^2 * 125us, i.e. 2 per frame. */
3520 cIsoPackets = 2;
3521 break;
3522 case 3: /* Every 2^3 * 125us, i.e. 1 per frame. */
3523 default:/* Or any larger interval (every n frames).*/
3524 cIsoPackets = 1;
3525 break;
3526 }
3527
3528 /* We do not know exactly how much data might be transferred until we
3529 * look at all TDs/packets that constitute the URB. However, we do know
3530 * the maximum possible size even without probing any TDs at all.
3531 * The actual size is expected to be the same or at most slightly smaller,
3532 * hence it makes sense to allocate the URB right away and copy data into
3533 * it as we go, rather than doing complicated probing first.
3534 * The Max Endpoint Service Interval Time (ESIT) Payload defines the
3535 * maximum number of bytes that can be transferred per interval (4.14.2).
3536 * Unfortunately Apple was lazy and their driver leaves the Max ESIT
3537 * Payload as zero, so we have to do the math ourselves.
3538 */
3539
3540 /* Calculate the maximum transfer size per (micro)frame. */
3541 /// @todo This ought to be stored within the URB somewhere.
3542 cbPktMax = pEpCtx->max_pkt_sz * (pEpCtx->max_brs_sz + 1) * (pEpCtx->mult + 1);
3543 if (!pCtxIso->pUrb)
3544 {
3545 uint32_t cbUrbMax = cIsoPackets * cbPktMax;
3546
3547 /* Validate endpoint type. */
3548 AssertMsg(pEpCtx->ep_type == XHCI_EPTYPE_ISOCH_IN || pEpCtx->ep_type == XHCI_EPTYPE_ISOCH_OUT,
3549 ("%#x\n", pEpCtx->ep_type));
3550
3551 /* Allocate and initialize a new URB. */
3552 pUrb = VUSBIRhNewUrb(pRh->pIRhConn, uAddr, VUSB_DEVICE_PORT_INVALID, VUSBXFERTYPE_ISOC,
3553 (pEpCtx->ep_type == XHCI_EPTYPE_ISOCH_IN) ? VUSBDIRECTION_IN : VUSBDIRECTION_OUT,
3554 cbUrbMax, ctxProbe.cTRB, NULL);
3555 if (!pUrb)
3556 return VERR_OUT_OF_RESOURCES; /// @todo handle error!
3557
3558 STAM_COUNTER_ADD(&pThis->StatTRBsPerIsoUrb, ctxProbe.cTRB);
3559
3560 LogFlowFunc(("Allocated URB with %u packets, %u bytes total (ESIT payload %u)\n", cIsoPackets, cbUrbMax, cbPktMax));
3561
3562 pUrb->EndPt = uEpDCI / 2; /* DCI = EP * 2 + direction */
3563 pUrb->fShortNotOk = false; /* We detect short packets ourselves. */
3564 pUrb->enmStatus = VUSBSTATUS_OK;
3565 pUrb->cIsocPkts = cIsoPackets;
3566 pUrb->pHci->uSlotID = uSlotID;
3567 pUrb->pHci->cTRB = ctxProbe.cTRB;
3568
3569 /* If TRB says so or if there are multiple packets per interval, don't even
3570 * bother with frame counting and schedule everything ASAP.
3571 */
3572 if (pTrb->isoc.sia || cIsoPackets != 1)
3573 pUrb->uStartFrameDelta = 0;
3574 else
3575 {
3576 uint16_t uFrameDelta;
3577 uint32_t uPort;
3578
3579 /* Abort the endpoint, i.e. cancel any outstanding URBs. This needs to be done after
3580 * writing back the EP state so that the completion callback can operate.
3581 */
3582 if (RT_SUCCESS(xhciR3FindRhDevBySlot(pDevIns, pThis, pThisCC, uSlotID, NULL, &uPort)))
3583 {
3584
3585 uFrameDelta = pRh->pIRhConn->pfnUpdateIsocFrameDelta(pRh->pIRhConn, uPort, uEpDCI / 2,
3586 uEpDCI & 1 ? VUSBDIRECTION_IN : VUSBDIRECTION_OUT,
3587 pTrb->isoc.frm_id, XHCI_FRAME_ID_BITS);
3588 pUrb->uStartFrameDelta = uFrameDelta;
3589 Log(("%s: Isoch frame delta set to %u\n", pUrb->pszDesc, uFrameDelta));
3590 }
3591 else
3592 {
3593 Log(("%s: Failed to find device for slot! Setting frame delta to zero.\n", pUrb->pszDesc));
3594 pUrb->uStartFrameDelta = 0;
3595 }
3596 }
3597
3598 Log(("%s: Addr=%u, EndPt=%u, enmDir=%u cIsocPkts=%u cbData=%u FrmID=%u Isoch URB created\n",
3599 pUrb->pszDesc, pUrb->DstAddress, pUrb->EndPt, pUrb->enmDir, pUrb->cIsocPkts, pUrb->cbData, pTrb->isoc.frm_id));
3600
3601 /* Set up the context for later use. */
3602 pCtxIso->pUrb = pUrb;
3603 /* Save the current TREP in case we need to rewind. */
3604 pCtxIso->uInitTREP = pEpCtx->trep;
3605 }
3606 else
3607 {
3608 Assert(cIsoPackets > 1);
3609 /* Grab the URB we initialized earlier. */
3610 pUrb = pCtxIso->pUrb;
3611 }
3612
3613 /* Set up the packet corresponding to this TD. */
3614 pUrb->aIsocPkts[pCtxIso->iPkt].cb = RT_MIN(ctxProbe.uXferLen, cbPktMax);
3615 pUrb->aIsocPkts[pCtxIso->iPkt].off = pCtxIso->offCur;
3616 pUrb->aIsocPkts[pCtxIso->iPkt].enmStatus = VUSBSTATUS_NOT_ACCESSED;
3617
3618 /* For OUT transfers, copy the TD data into the URB. */
3619 if (pUrb->enmDir == VUSBDIRECTION_OUT)
3620 {
3621 ctxSubmit.pUrb = pUrb;
3622 ctxSubmit.uXferPos = pCtxIso->offCur;
3623 ctxSubmit.cTRB = 0;
3624 xhciR3WalkXferTrbChain(pDevIns, pThis, pEpCtx->trep, xhciR3WalkDataTRBsSubmit, &ctxSubmit, &uTREP);
3625 Assert(ctxProbe.cTRB == ctxSubmit.cTRB);
3626 }
3627
3628 /* Done preparing this packet. */
3629 Assert(pCtxIso->iPkt < 8);
3630 pCtxIso->iPkt++;
3631 pCtxIso->offCur += ctxProbe.uXferLen;
3632 Assert(pCtxIso->offCur <= pUrb->cbData);
3633
3634 /* Increment the in-flight counter before queuing more. */
3635 if (pCtxIso->iPkt == pUrb->cIsocPkts)
3636 pEpCtx->ifc++;
3637
3638 /* Commit the updated TREP; submitting the URB may already invoke completion callbacks. */
3639 pEpCtx->trep = uTREP;
3640 xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uEpDCI, pEpCtx);
3641
3642 /* If the URB is complete, submit it. */
3643 if (pCtxIso->iPkt == pUrb->cIsocPkts)
3644 {
3645 /* Change cbData to reflect how much data should be transferred. This can differ
3646 * from how much data was allocated for the URB.
3647 */
3648 pUrb->cbData = pCtxIso->offCur;
3649 STAM_COUNTER_ADD(&pThis->StatUrbSizeIsoc, pUrb->cbData);
3650 Log(("%s: Addr=%u, EndPt=%u, enmDir=%u cIsocPkts=%u cbData=%u Isoch URB being submitted\n",
3651 pUrb->pszDesc, pUrb->DstAddress, pUrb->EndPt, pUrb->enmDir, pUrb->cIsocPkts, pUrb->cbData));
3652 RTCritSectLeave(&pThisCC->CritSectThrd);
3653 int rc = VUSBIRhSubmitUrb(pRh->pIRhConn, pUrb, &pRh->Led);
3654 RTCritSectEnter(&pThisCC->CritSectThrd);
3655 if (RT_FAILURE(rc))
3656 {
3657 /* Failure cleanup. Can happen if we're still resetting the device or out of resources,
3658 * or the user just ripped out the device.
3659 */
3660 pCtxIso->fSubmitFailed = true;
3661 /// @todo Mark the EP as halted and inactive and write back the changes.
3662 return VERR_OUT_OF_RESOURCES;
3663 }
3664 /* Clear the isochronous URB context. */
3665 RT_ZERO(*pCtxIso);
3666 }
3667
3668 return VINF_SUCCESS;
3669}
3670
3671
3672/**
3673 * Queue a control TD composed of setup/data/status stage TRBs, event data
3674 * TRBs, and suchlike.
3675 *
3676 * @returns VBox status code.
3677 * @param pDevIns The device instance.
3678 * @param pThis The xHCI device state, shared edition.
3679 * @param pThisCC The xHCI device state, ring-3 edition.
3680 * @param pRh Root hub for the device.
3681 * @param GCPhysTRB Physical guest address of th TRB.
3682 * @param pTrb Pointer to the contents of the first TRB.
3683 * @param pEpCtx Pointer to the cached EP context.
3684 * @param uSlotID ID of the associated slot context.
3685 * @param uAddr The device address.
3686 * @param uEpDCI The DCI(!) of the endpoint.
3687 */
3688static int xhciR3QueueControlTD(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, PXHCIROOTHUBR3 pRh, RTGCPHYS GCPhysTRB,
3689 XHCI_XFER_TRB *pTrb, XHCI_EP_CTX *pEpCtx, uint8_t uSlotID, uint8_t uAddr, uint8_t uEpDCI)
3690{
3691 RT_NOREF(GCPhysTRB);
3692 XHCI_CTX_XFER_PROBE ctxProbe;
3693 XHCI_CTX_XFER_SUBMIT ctxSubmit;
3694 uint64_t uTREP;
3695 int rc;
3696 VUSBDIRECTION enmDir;
3697
3698 /* Discover how big this TD is. */
3699 RT_ZERO(ctxProbe);
3700 rc = xhciR3WalkXferTrbChain(pDevIns, pThis, pEpCtx->trep, xhciR3WalkDataTRBsProbe, &ctxProbe, &uTREP);
3701 if (RT_SUCCESS(rc))
3702 LogFlowFunc(("Probed %u TRBs, %u bytes total, TREP@%RX64\n", ctxProbe.cTRB, ctxProbe.uXferLen, uTREP));
3703 else
3704 {
3705 LogFlowFunc(("Probing failed after %u TRBs, %u bytes total (last ED after %u TRBs and %u bytes), TREP@%RX64\n", ctxProbe.cTRB, ctxProbe.uXferLen, ctxProbe.cTRBLastED, ctxProbe.uXfrLenLastED, uTREP));
3706 return rc;
3707 }
3708
3709 /* Determine the transfer direction. */
3710 switch (pTrb->gen.type)
3711 {
3712 case XHCI_TRB_SETUP_STG:
3713 enmDir = VUSBDIRECTION_SETUP;
3714 /* For setup TRBs, there is always 8 bytes of immediate data. */
3715 Assert(sizeof(VUSBSETUP) == 8);
3716 Assert(ctxProbe.uXferLen == 8);
3717 Log2(("bmRequestType:%02X bRequest:%02X wValue:%04X wIndex:%04X wLength:%04X\n", pTrb->setup.bmRequestType,
3718 pTrb->setup.bRequest, pTrb->setup.wValue, pTrb->setup.wIndex, pTrb->setup.wLength));
3719 break;
3720 case XHCI_TRB_STATUS_STG:
3721 enmDir = pTrb->status.dir ? VUSBDIRECTION_IN : VUSBDIRECTION_OUT;
3722 break;
3723 case XHCI_TRB_DATA_STG:
3724 enmDir = pTrb->data.dir ? VUSBDIRECTION_IN : VUSBDIRECTION_OUT;
3725 break;
3726 default:
3727 AssertMsgFailed(("%#x\n", pTrb->gen.type)); /* Can't happen unless caller messed up. */
3728 return VERR_INTERNAL_ERROR;
3729 }
3730
3731 /* Allocate and initialize a URB. */
3732 PVUSBURB pUrb = VUSBIRhNewUrb(pRh->pIRhConn, uAddr, VUSB_DEVICE_PORT_INVALID, VUSBXFERTYPE_CTRL, enmDir, ctxProbe.uXferLen, ctxProbe.cTRB,
3733 NULL);
3734 if (!pUrb)
3735 return VERR_OUT_OF_RESOURCES; /// @todo handle error!
3736
3737 STAM_COUNTER_ADD(&pThis->StatTRBsPerCtlUrb, ctxProbe.cTRB);
3738
3739 /* See 4.5.1 about xHCI vs. USB endpoint addressing. */
3740 Assert(uEpDCI);
3741
3742 /* This had better be a control endpoint. */
3743 AssertMsg(pEpCtx->ep_type == XHCI_EPTYPE_CONTROL, ("%#x\n", pEpCtx->ep_type));
3744
3745 pUrb->EndPt = uEpDCI / 2; /* DCI = EP * 2 + direction */
3746 pUrb->fShortNotOk = false; /* We detect short packets ourselves. */
3747 pUrb->enmStatus = VUSBSTATUS_OK;
3748 pUrb->pHci->uSlotID = uSlotID;
3749
3750 /* For OUT/SETUP transfers, copy the TD data into the URB. */
3751 if (pUrb->enmDir == VUSBDIRECTION_OUT || pUrb->enmDir == VUSBDIRECTION_SETUP)
3752 {
3753 ctxSubmit.pUrb = pUrb;
3754 ctxSubmit.uXferPos = 0;
3755 ctxSubmit.cTRB = 0;
3756 xhciR3WalkXferTrbChain(pDevIns, pThis, pEpCtx->trep, xhciR3WalkDataTRBsSubmit, &ctxSubmit, &uTREP);
3757 Assert(ctxProbe.cTRB == ctxSubmit.cTRB);
3758 ctxProbe.cTRB = ctxSubmit.cTRB;
3759 }
3760
3761 pUrb->pHci->cTRB = ctxProbe.cTRB;
3762
3763 /* Commit the updated TREP; submitting the URB may already invoke completion callbacks. */
3764 pEpCtx->trep = uTREP;
3765 xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uEpDCI, pEpCtx);
3766
3767 /*
3768 * Submit the URB.
3769 */
3770 STAM_COUNTER_ADD(&pThis->StatUrbSizeCtrl, pUrb->cbData);
3771 Log(("%s: xhciR3QueueControlTD: Addr=%u, EndPt=%u, enmDir=%u cbData=%u\n",
3772 pUrb->pszDesc, pUrb->DstAddress, pUrb->EndPt, pUrb->enmDir, pUrb->cbData));
3773 RTCritSectLeave(&pThisCC->CritSectThrd);
3774 rc = VUSBIRhSubmitUrb(pRh->pIRhConn, pUrb, &pRh->Led);
3775 RTCritSectEnter(&pThisCC->CritSectThrd);
3776 if (RT_SUCCESS(rc))
3777 return VINF_SUCCESS;
3778
3779 /* Failure cleanup. Can happen if we're still resetting the device or out of resources,
3780 * or the user just ripped out the device.
3781 */
3782 /// @todo Mark the EP as halted and inactive and write back the changes.
3783
3784 return VERR_OUT_OF_RESOURCES;
3785}
3786
3787
3788/**
3789 * Process a device context (transfer data).
3790 *
3791 * @param pDevIns The device instance.
3792 * @param pThis The xHCI device state, shared edition.
3793 * @param pThisCC The xHCI device state, ring-3 edition.
3794 * @param uSlotID Slot/doorbell which had been rung.
3795 * @param uDBVal Value written to the doorbell.
3796 */
3797static int xhciR3ProcessDevCtx(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, uint8_t uSlotID, uint32_t uDBVal)
3798{
3799 uint8_t uDBTarget = uDBVal & XHCI_DB_TGT_MASK;
3800 XHCI_CTX_ISOCH ctxIsoch = {0};
3801 XHCI_SLOT_CTX slot_ctx;
3802 XHCI_EP_CTX ep_ctx;
3803 XHCI_XFER_TRB xfer;
3804 RTGCPHYS GCPhysXfrTRB;
3805 PXHCIROOTHUBR3 pRh;
3806 bool dcs;
3807 bool fContinue = true;
3808 int rc;
3809 unsigned cTrbs = 0;
3810
3811 LogFlowFunc(("Slot ID: %u, DB target %u, DB stream ID %u\n", uSlotID, uDBTarget, (uDBVal & XHCI_DB_STRMID_MASK) >> XHCI_DB_STRMID_SHIFT));
3812 Assert(uSlotID > 0);
3813 Assert(uSlotID <= XHCI_NDS);
3814 /// @todo report errors for bogus DB targets
3815 Assert(uDBTarget > 0);
3816 Assert(uDBTarget < 32);
3817
3818 /// @todo Check for aborts and the like?
3819
3820 /* Load the slot and endpoint contexts. */
3821 xhciR3FetchCtxAndEp(pDevIns, pThis, uSlotID, uDBTarget, &slot_ctx, &ep_ctx);
3822 /// @todo sanity check the context in here?
3823
3824 /* Select the root hub corresponding to the port. */
3825 pRh = GET_PORT_PRH(pThisCC, ID_TO_IDX(slot_ctx.rh_port));
3826
3827 /* Stopped endpoints automatically transition to running state. */
3828 if (RT_UNLIKELY(ep_ctx.ep_state == XHCI_EPST_STOPPED))
3829 {
3830 Log(("EP DCI %u stopped -> running\n", uDBTarget));
3831 ep_ctx.ep_state = XHCI_EPST_RUNNING;
3832 /* Update EP right here. Theoretically could be postponed, but we
3833 * must ensure that the EP does get written back even if there is
3834 * no other work to do.
3835 */
3836 xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uDBTarget, &ep_ctx);
3837 }
3838
3839 /* If the EP isn't running, get outta here. */
3840 if (RT_UNLIKELY(ep_ctx.ep_state != XHCI_EPST_RUNNING))
3841 {
3842 Log2(("EP DCI %u not running (state %u), bail!\n", uDBTarget, ep_ctx.ep_state));
3843 return VINF_SUCCESS;
3844 }
3845
3846 /* Get any non-transfer TRBs out of the way. */
3847 xhciR3ConsumeNonXferTRBs(pDevIns, pThis, uSlotID, uDBTarget, &ep_ctx, &xfer, &GCPhysXfrTRB);
3848 /// @todo This is inefficient.
3849 xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uDBTarget, &ep_ctx);
3850
3851 do
3852 {
3853 /* Fetch the contexts again and find the TRB address at enqueue point. */
3854 xhciR3FetchCtxAndEp(pDevIns, pThis, uSlotID, uDBTarget, &slot_ctx, &ep_ctx);
3855 GCPhysXfrTRB = ep_ctx.trep & XHCI_TRDP_ADDR_MASK;
3856 dcs = !!(ep_ctx.trep & XHCI_TRDP_DCS_MASK);
3857 LogFlowFunc(("Processing Transfer Ring, TREP: %RGp\n", GCPhysXfrTRB));
3858
3859 /* Fetch the transfer TRB. */
3860 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysXfrTRB, &xfer, sizeof(xfer));
3861
3862 /* Make sure the Cycle State matches. */
3863 if ((bool)xfer.gen.cycle == dcs)
3864 {
3865 Log2(("TRB @ %RGp, type %u (%s) %u bytes ENT=%u ISP=%u NS=%u CH=%u IOC=%u IDT=%u\n", GCPhysXfrTRB, xfer.gen.type,
3866 xfer.gen.type < RT_ELEMENTS(g_apszTrbNames) ? g_apszTrbNames[xfer.gen.type] : "WHAT?!!",
3867 xfer.gen.xfr_len, xfer.gen.ent, xfer.gen.isp, xfer.gen.ns, xfer.gen.ch, xfer.gen.ioc, xfer.gen.idt));
3868
3869 /* If there is an "in-flight" TRDP, check if we need to wait until the transfer completes. */
3870 if ((ep_ctx.trdp & XHCI_TRDP_ADDR_MASK) != GCPhysXfrTRB)
3871 {
3872 switch (xfer.gen.type) {
3873 case XHCI_TRB_ISOCH:
3874 if (ep_ctx.ifc >= XHCI_MAX_ISOC_IN_FLIGHT)
3875 {
3876 Log(("%u isoch URBs in flight, backing off\n", ep_ctx.ifc));
3877 fContinue = false;
3878 break;
3879 }
3880 RT_FALL_THRU();
3881 case XHCI_TRB_LINK:
3882 Log2(("TRB OK, continuing @ %RX64\n", GCPhysXfrTRB));
3883 break;
3884 case XHCI_TRB_NORMAL:
3885 if (XHCI_EP_XTYPE(ep_ctx.ep_type) != XHCI_XFTYPE_BULK)
3886 {
3887 Log2(("Normal TRB not bulk, not continuing @ %RX64\n", GCPhysXfrTRB));
3888 fContinue = false;
3889 break;
3890 }
3891 if (ep_ctx.ifc >= XHCI_MAX_BULK_IN_FLIGHT)
3892 {
3893 Log(("%u normal URBs in flight, backing off\n", ep_ctx.ifc));
3894 fContinue = false;
3895 break;
3896 }
3897 Log2(("Bulk TRB OK, continuing @ %RX64\n", GCPhysXfrTRB));
3898 break;
3899 case XHCI_TRB_EVT_DATA:
3900 case XHCI_TRB_NOOP_XFER:
3901 Log2(("TRB not OK, not continuing @ %RX64\n", GCPhysXfrTRB));
3902 fContinue = false;
3903 break;
3904 default:
3905 Log2(("Some other TRB (type %u), not continuing @ %RX64\n", xfer.gen.type, GCPhysXfrTRB));
3906 fContinue = false;
3907 break;
3908 }
3909 }
3910 if (!fContinue)
3911 break;
3912
3913 switch (xfer.gen.type) {
3914 case XHCI_TRB_NORMAL:
3915 Log(("Normal TRB: Ptr=%RGp IOC=%u CH=%u\n", xfer.norm.data_ptr, xfer.norm.ioc, xfer.norm.ch));
3916 rc = xhciR3QueueDataTD(pDevIns, pThis, pThisCC, pRh, GCPhysXfrTRB, &xfer, &ep_ctx, uSlotID,
3917 slot_ctx.dev_addr, uDBTarget);
3918 break;
3919 case XHCI_TRB_SETUP_STG:
3920 Log(("Setup stage TRB: IOC=%u IDT=%u\n", xfer.setup.ioc, xfer.setup.idt));
3921 rc = xhciR3QueueControlTD(pDevIns, pThis, pThisCC, pRh, GCPhysXfrTRB, &xfer, &ep_ctx, uSlotID,
3922 slot_ctx.dev_addr, uDBTarget);
3923 break;
3924 case XHCI_TRB_DATA_STG:
3925 Log(("Data stage TRB: Ptr=%RGp IOC=%u CH=%u DIR=%u\n", xfer.data.data_ptr, xfer.data.ioc, xfer.data.ch, xfer.data.dir));
3926 rc = xhciR3QueueControlTD(pDevIns, pThis, pThisCC, pRh, GCPhysXfrTRB, &xfer, &ep_ctx, uSlotID,
3927 slot_ctx.dev_addr, uDBTarget);
3928 break;
3929 case XHCI_TRB_STATUS_STG:
3930 Log(("Status stage TRB: IOC=%u CH=%u DIR=%u\n", xfer.status.ioc, xfer.status.ch, xfer.status.dir));
3931 rc = xhciR3QueueControlTD(pDevIns, pThis, pThisCC, pRh, GCPhysXfrTRB, &xfer, &ep_ctx, uSlotID,
3932 slot_ctx.dev_addr, uDBTarget);
3933 break;
3934 case XHCI_TRB_ISOCH:
3935 Log(("Isoch TRB: Ptr=%RGp IOC=%u CH=%u TLBPC=%u TBC=%u SIA=%u FrmID=%u\n", xfer.isoc.data_ptr, xfer.isoc.ioc, xfer.isoc.ch, xfer.isoc.tlbpc, xfer.isoc.tbc, xfer.isoc.sia, xfer.isoc.frm_id));
3936 rc = xhciR3QueueIsochTD(pDevIns, pThis, pThisCC, pRh, GCPhysXfrTRB, &xfer, &ep_ctx, uSlotID,
3937 slot_ctx.dev_addr, uDBTarget, &ctxIsoch);
3938 break;
3939 case XHCI_TRB_LINK:
3940 Log2(("Link extra-TD: Ptr=%RGp IOC=%u TC=%u CH=%u\n", xfer.link.rseg_ptr, xfer.link.ioc, xfer.link.toggle, xfer.link.chain));
3941 Assert(!xfer.link.chain);
3942 /* Set new TREP but leave DCS bit alone... */
3943 ep_ctx.trep = (xfer.link.rseg_ptr & XHCI_TRDP_ADDR_MASK) | (ep_ctx.trep & XHCI_TRDP_DCS_MASK);
3944 /* ...and flip the DCS bit if required. Then update the TREP. */
3945 if (xfer.link.toggle)
3946 ep_ctx.trep = (ep_ctx.trep & ~XHCI_TRDP_DCS_MASK) | (ep_ctx.trep ^ XHCI_TRDP_DCS_MASK);
3947 rc = xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uDBTarget, &ep_ctx);
3948 break;
3949 case XHCI_TRB_NOOP_XFER:
3950 Log2(("No op xfer: IOC=%u CH=%u ENT=%u\n", xfer.nop.ioc, xfer.nop.ch, xfer.nop.ent));
3951 /* A no-op transfer TRB must not be part of a chain. See 4.11.7. */
3952 Assert(!xfer.link.chain);
3953 /* Update enqueue pointer (TRB was not yet completed). */
3954 ep_ctx.trep += sizeof(XHCI_XFER_TRB);
3955 rc = xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uDBTarget, &ep_ctx);
3956 break;
3957 default:
3958 Log(("Unsupported TRB!!\n"));
3959 rc = VERR_NOT_SUPPORTED;
3960 break;
3961 }
3962 /* If queuing failed, stop right here. */
3963 if (RT_FAILURE(rc))
3964 fContinue = false;
3965 }
3966 else
3967 {
3968 LogFunc(("Transfer Ring empty\n"));
3969 fContinue = false;
3970
3971 /* If an isochronous ring is empty, this is an overrun/underrun. At this point
3972 * the ring will no longer be scheduled (until the doorbell is rung again)
3973 * but it remains in the Running state. This error is only reported if someone
3974 * rang the doorbell and there are no TDs available or in-flight.
3975 */
3976 if ( (ep_ctx.trep == ep_ctx.trdp) /* Nothing in-flight? */
3977 && (ep_ctx.ep_type == XHCI_EPTYPE_ISOCH_IN || ep_ctx.ep_type == XHCI_EPTYPE_ISOCH_OUT))
3978 {
3979 /* There is no TRB associated with this error; the slot context
3980 * determines the interrupter.
3981 */
3982 Log(("Isochronous ring %s, TRDP:%RGp\n", ep_ctx.ep_type == XHCI_EPTYPE_ISOCH_IN ? "overrun" : "underrun", ep_ctx.trdp & XHCI_TRDP_ADDR_MASK));
3983 rc = xhciR3PostXferEvent(pDevIns, pThis, slot_ctx.intr_tgt, 0,
3984 ep_ctx.ep_type == XHCI_EPTYPE_ISOCH_IN ? XHCI_TCC_RING_OVERRUN : XHCI_TCC_RING_UNDERRUN,
3985 uSlotID, uDBTarget, 0, false, false);
3986 }
3987
3988 }
3989
3990 /* Kill the xHC if the TRB list has no end in sight. */
3991 if (++cTrbs > XHCI_MAX_NUM_TRBS)
3992 {
3993 /* Stop the xHC with an error. */
3994 xhciR3EndlessTrbError(pDevIns, pThis);
3995
3996 /* Get out of the loop. */
3997 fContinue = false;
3998 rc = VERR_NOT_SUPPORTED; /* No good error code really... */
3999 }
4000 } while (fContinue);
4001
4002 /* It can unfortunately happen that for endpoints with more than one
4003 * transfer per USB frame, there won't be a complete multi-packet URB ready
4004 * when we go looking for it. If that happens, we'll "rewind" the TREP and
4005 * try again later. Since the URB construction is done under a lock, this
4006 * is safe as we won't be accessing the endpoint concurrently.
4007 */
4008 if (ctxIsoch.pUrb)
4009 {
4010 Log(("Unfinished ISOC URB (%u packets out of %u)!\n", ctxIsoch.iPkt, ctxIsoch.pUrb->cIsocPkts));
4011 /* If submitting failed, the URB is already freed. */
4012 if (!ctxIsoch.fSubmitFailed)
4013 VUSBIRhFreeUrb(pRh->pIRhConn, ctxIsoch.pUrb);
4014 ep_ctx.trep = ctxIsoch.uInitTREP;
4015 xhciR3WriteBackEp(pDevIns, pThis, uSlotID, uDBTarget, &ep_ctx);
4016 }
4017 return VINF_SUCCESS;
4018}
4019
4020
4021/**
4022 * A worker routine for Address Device command. Builds a URB containing
4023 * a SET_ADDRESS requests and (synchronously) submits it to VUSB, then
4024 * follows up with a status stage URB.
4025 *
4026 * @returns true on success.
4027 * @returns false on failure to submit.
4028 * @param pThisCC The xHCI device state, ring-3 edition.
4029 * @param uSlotID Slot ID to assign address to.
4030 * @param uDevAddr New device address.
4031 * @param iPort The xHCI root hub port index.
4032 */
4033static bool xhciR3IssueSetAddress(PXHCICC pThisCC, uint8_t uSlotID, uint8_t uDevAddr, unsigned iPort)
4034{
4035 PXHCIROOTHUBR3 pRh = GET_PORT_PRH(pThisCC, iPort);
4036
4037 Assert(uSlotID);
4038 LogFlowFunc(("Slot %u port idx %u: new address is %u\n", uSlotID, iPort, uDevAddr));
4039
4040 /* For USB3 devices, force the port number. This simulates the fact that USB3 uses directed (unicast) traffic. */
4041 if (!IS_USB3_PORT_IDX_R3(pThisCC, iPort))
4042 iPort = VUSB_DEVICE_PORT_INVALID;
4043 else
4044 iPort = GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort);
4045
4046 /* Allocate and initialize a URB. NB: Zero cTds indicates a URB not submitted by guest. */
4047 PVUSBURB pUrb = VUSBIRhNewUrb(pRh->pIRhConn, 0 /* address */, iPort, VUSBXFERTYPE_CTRL, VUSBDIRECTION_SETUP,
4048 sizeof(VUSBSETUP), 0 /* cTds */, NULL);
4049 if (!pUrb)
4050 return false;
4051
4052 pUrb->EndPt = 0;
4053 pUrb->fShortNotOk = true;
4054 pUrb->enmStatus = VUSBSTATUS_OK;
4055 pUrb->pHci->uSlotID = uSlotID;
4056 pUrb->pHci->cTRB = 0;
4057
4058 /* Build the request. */
4059 PVUSBSETUP pSetup = (PVUSBSETUP)pUrb->abData;
4060 pSetup->bmRequestType = VUSB_DIR_TO_DEVICE | VUSB_REQ_STANDARD | VUSB_TO_DEVICE;
4061 pSetup->bRequest = VUSB_REQ_SET_ADDRESS;
4062 pSetup->wValue = uDevAddr;
4063 pSetup->wIndex = 0;
4064 pSetup->wLength = 0;
4065
4066 /* NB: We assume the address assignment is a synchronous operation. */
4067
4068 /* Submit the setup URB. */
4069 Log(("%s: xhciSetAddress setup: cbData=%u\n", pUrb->pszDesc, pUrb->cbData));
4070 RTCritSectLeave(&pThisCC->CritSectThrd);
4071 int rc = VUSBIRhSubmitUrb(pRh->pIRhConn, pUrb, &pRh->Led);
4072 RTCritSectEnter(&pThisCC->CritSectThrd);
4073 if (RT_FAILURE(rc))
4074 {
4075 Log(("xhciSetAddress: setup stage failed pUrb=%p!!\n", pUrb));
4076 return false;
4077 }
4078
4079 /* To complete the SET_ADDRESS request, the status stage must succeed. */
4080 pUrb = VUSBIRhNewUrb(pRh->pIRhConn, 0 /* address */, iPort, VUSBXFERTYPE_CTRL, VUSBDIRECTION_IN, 0 /* cbData */, 0 /* cTds */,
4081 NULL);
4082 if (!pUrb)
4083 return false;
4084
4085 pUrb->EndPt = 0;
4086 pUrb->fShortNotOk = true;
4087 pUrb->enmStatus = VUSBSTATUS_OK;
4088 pUrb->pHci->uSlotID = uSlotID;
4089 pUrb->pHci->cTRB = 0;
4090
4091 /* Submit the setup URB. */
4092 Log(("%s: xhciSetAddress status: cbData=%u\n", pUrb->pszDesc, pUrb->cbData));
4093 RTCritSectLeave(&pThisCC->CritSectThrd);
4094 rc = VUSBIRhSubmitUrb(pRh->pIRhConn, pUrb, &pRh->Led);
4095 RTCritSectEnter(&pThisCC->CritSectThrd);
4096 if (RT_FAILURE(rc))
4097 {
4098 Log(("xhciSetAddress: status stage failed pUrb=%p!!\n", pUrb));
4099 return false;
4100 }
4101
4102 Log(("xhciSetAddress: set address succeeded\n"));
4103 return true;
4104}
4105
4106
4107/**
4108 * Address a device.
4109 *
4110 * @returns TRB completion code.
4111 * @param pDevIns The device instance.
4112 * @param pThis The xHCI device state, shared edition.
4113 * @param pThisCC The xHCI device state, ring-3 edition.
4114 * @param uInpCtxAddr Address of the input context.
4115 * @param uSlotID Slot ID to assign address to.
4116 * @param fBSR Block Set address Request flag.
4117 */
4118static unsigned xhciR3AddressDevice(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, uint64_t uInpCtxAddr,
4119 uint8_t uSlotID, bool fBSR)
4120{
4121 RTGCPHYS GCPhysInpCtx = uInpCtxAddr & XHCI_CTX_ADDR_MASK;
4122 RTGCPHYS GCPhysInpSlot;
4123 RTGCPHYS GCPhysOutSlot;
4124 XHCI_INPC_CTX icc; /* Input Control Context (ICI=0). */
4125 XHCI_SLOT_CTX inp_slot_ctx; /* Input Slot Context (ICI=1). */
4126 XHCI_EP_CTX ep_ctx; /* Endpoint Context (ICI=2+). */
4127 XHCI_SLOT_CTX out_slot_ctx; /* Output Slot Context. */
4128 uint8_t dev_addr;
4129 unsigned cc = XHCI_TCC_SUCCESS;
4130
4131 Assert(GCPhysInpCtx);
4132 Assert(uSlotID);
4133 LogFlowFunc(("Slot ID %u, input control context @ %RGp\n", uSlotID, GCPhysInpCtx));
4134
4135 /* Determine the address of the output slot context. */
4136 GCPhysOutSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
4137
4138 /* Fetch the output slot context. */
4139 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysOutSlot, &out_slot_ctx, sizeof(out_slot_ctx));
4140
4141 /// @todo Check for valid context (6.2.2.1, 6.2.3.1)
4142
4143 /* See 4.6.5 */
4144 do {
4145 /* Parameter validation depends on whether the BSR flag is set or not. */
4146 if (fBSR)
4147 {
4148 /* Check that the output slot context state is in Enabled state. */
4149 if (out_slot_ctx.slot_state >= XHCI_SLTST_DEFAULT)
4150 {
4151 Log(("Output slot context state (%u) wrong (BSR)!\n", out_slot_ctx.slot_state));
4152 cc = XHCI_TCC_CTX_STATE_ERR;
4153 break;
4154 }
4155 dev_addr = 0;
4156 }
4157 else
4158 {
4159 /* Check that the output slot context state is in Enabled or Default state. */
4160 if (out_slot_ctx.slot_state > XHCI_SLTST_DEFAULT)
4161 {
4162 Log(("Output slot context state (%u) wrong (no-BSR)!\n", out_slot_ctx.slot_state));
4163 cc = XHCI_TCC_CTX_STATE_ERR;
4164 break;
4165 }
4166 dev_addr = xhciR3SelectNewAddress(pThis, uSlotID);
4167 }
4168
4169 /* Fetch the input control context. */
4170 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysInpCtx, &icc, sizeof(icc));
4171 Assert(icc.add_flags == (RT_BIT(0) | RT_BIT(1))); /* Should have been already checked. */
4172 Assert(!icc.drop_flags);
4173
4174 /* Calculate the address of the input slot context (ICI=1/DCI=0). */
4175 GCPhysInpSlot = GCPhysInpCtx + sizeof(XHCI_INPC_CTX);
4176
4177 /* Read the input slot context. */
4178 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysInpSlot, &inp_slot_ctx, sizeof(inp_slot_ctx));
4179
4180 /* If BSR isn't set, issue the actual SET_ADDRESS request. */
4181 if (!fBSR) {
4182 unsigned iPort;
4183
4184 /* We have to dig out the port number/index to determine which virtual root hub to use. */
4185 iPort = ID_TO_IDX(inp_slot_ctx.rh_port);
4186 if (iPort >= XHCI_NDP_CFG(pThis))
4187 {
4188 Log(("Port out of range (index %u)!\n", iPort));
4189 cc = XHCI_TCC_USB_XACT_ERR;
4190 break;
4191 }
4192 if (!xhciR3IssueSetAddress(pThisCC, uSlotID, dev_addr, iPort))
4193 {
4194 Log(("SET_ADDRESS failed!\n"));
4195 cc = XHCI_TCC_USB_XACT_ERR;
4196 break;
4197 }
4198 }
4199
4200 /* Copy the slot context with appropriate modifications. */
4201 out_slot_ctx = inp_slot_ctx;
4202 if (fBSR)
4203 out_slot_ctx.slot_state = XHCI_SLTST_DEFAULT;
4204 else
4205 out_slot_ctx.slot_state = XHCI_SLTST_ADDRESSED;
4206 out_slot_ctx.dev_addr = dev_addr;
4207 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysOutSlot, &out_slot_ctx, sizeof(out_slot_ctx));
4208
4209 /* Point at the EP0 contexts. */
4210 GCPhysInpSlot += sizeof(inp_slot_ctx);
4211 GCPhysOutSlot += sizeof(out_slot_ctx);
4212
4213 /* Copy EP0 context with appropriate modifications. */
4214 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysInpSlot, &ep_ctx, sizeof(ep_ctx));
4215 xhciR3EnableEP(&ep_ctx);
4216 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysOutSlot, &ep_ctx, sizeof(ep_ctx));
4217 } while (0);
4218
4219 return cc;
4220}
4221
4222
4223/**
4224 * Reset a halted endpoint.
4225 *
4226 * @returns TRB completion code.
4227 * @param pDevIns The device instance.
4228 * @param pThis Pointer to the xHCI state.
4229 * @param uSlotID Slot ID to work with.
4230 * @param uDCI DCI of the endpoint to reset.
4231 * @param fTSP The Transfer State Preserve flag.
4232 */
4233static unsigned xhciR3ResetEndpoint(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID, uint8_t uDCI, bool fTSP)
4234{
4235 RT_NOREF(fTSP);
4236 RTGCPHYS GCPhysSlot;
4237 RTGCPHYS GCPhysEndp;
4238 XHCI_SLOT_CTX slot_ctx;
4239 XHCI_EP_CTX endp_ctx;
4240 unsigned cc = XHCI_TCC_SUCCESS;
4241
4242 Assert(uSlotID);
4243
4244 /* Determine the addresses of the contexts. */
4245 GCPhysSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
4246 GCPhysEndp = GCPhysSlot + uDCI * sizeof(XHCI_EP_CTX);
4247
4248 /* Fetch the slot context. */
4249 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysSlot, &slot_ctx, sizeof(slot_ctx));
4250
4251 /* See 4.6.8 */
4252 do {
4253 /* Check that the slot context state is Default, Addressed, or Configured. */
4254 if (slot_ctx.slot_state < XHCI_SLTST_DEFAULT)
4255 {
4256 Log(("Slot context state wrong (%u)!\n", slot_ctx.slot_state));
4257 cc = XHCI_TCC_CTX_STATE_ERR;
4258 break;
4259 }
4260
4261 /* Fetch the endpoint context. */
4262 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4263
4264 /* Check that the endpoint context state is Halted. */
4265 if (endp_ctx.ep_state != XHCI_EPST_HALTED)
4266 {
4267 Log(("Endpoint context state wrong (%u)!\n", endp_ctx.ep_state));
4268 cc = XHCI_TCC_CTX_STATE_ERR;
4269 break;
4270 }
4271
4272 /* Transition EP state. */
4273 endp_ctx.ep_state = XHCI_EPST_STOPPED;
4274
4275 /// @todo What can we do with the TSP flag?
4276 /// @todo Anything to do WRT enabling the corresponding doorbell register?
4277
4278 /* Write back the updated endpoint context. */
4279 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4280 } while (0);
4281
4282 return cc;
4283}
4284
4285
4286/**
4287 * Stop a running endpoint.
4288 *
4289 * @returns TRB completion code.
4290 * @param pDevIns The device instance.
4291 * @param pThis The xHCI device state, shared edition.
4292 * @param pThisCC The xHCI device state, ring-3 edition.
4293 * @param uSlotID Slot ID to work with.
4294 * @param uDCI DCI of the endpoint to stop.
4295 * @param fTSP The Suspend flag.
4296 */
4297static unsigned xhciR3StopEndpoint(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, uint8_t uSlotID, uint8_t uDCI, bool fTSP)
4298{
4299 RT_NOREF(fTSP);
4300 RTGCPHYS GCPhysSlot;
4301 RTGCPHYS GCPhysEndp;
4302 XHCI_SLOT_CTX slot_ctx;
4303 XHCI_EP_CTX endp_ctx;
4304 unsigned cc = XHCI_TCC_SUCCESS;
4305
4306 Assert(uSlotID);
4307
4308 /* Determine the addresses of the contexts. */
4309 GCPhysSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
4310 GCPhysEndp = GCPhysSlot + uDCI * sizeof(XHCI_EP_CTX);
4311
4312 /* Fetch the slot context. */
4313 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysSlot, &slot_ctx, sizeof(slot_ctx));
4314
4315 /* See 4.6.9 */
4316 do {
4317 /* Check that the slot context state is Default, Addressed, or Configured. */
4318 if (slot_ctx.slot_state < XHCI_SLTST_DEFAULT)
4319 {
4320 Log(("Slot context state wrong (%u)!\n", slot_ctx.slot_state));
4321 cc = XHCI_TCC_CTX_STATE_ERR;
4322 break;
4323 }
4324
4325 /* The doorbell could be ringing; stop it if so. */
4326 if (pThis->aBellsRung[ID_TO_IDX(uSlotID)] & (1 << uDCI))
4327 {
4328 Log(("Unring bell for slot ID %u, DCI %u\n", uSlotID, uDCI));
4329 ASMAtomicAndU32(&pThis->aBellsRung[ID_TO_IDX(uSlotID)], ~(1 << uDCI));
4330 }
4331
4332 /* Fetch the endpoint context. */
4333 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4334
4335 /* Check that the endpoint context state is Running. */
4336 if (endp_ctx.ep_state != XHCI_EPST_RUNNING)
4337 {
4338 Log(("Endpoint context state wrong (%u)!\n", endp_ctx.ep_state));
4339 cc = XHCI_TCC_CTX_STATE_ERR;
4340 break;
4341 }
4342
4343 /* Transition EP state. */
4344 endp_ctx.ep_state = XHCI_EPST_STOPPED;
4345
4346 /* Write back the updated endpoint context *now*, before actually canceling anyhing. */
4347 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4348
4349 /// @todo What can we do with the SP flag?
4350
4351 PXHCIROOTHUBR3 pRh;
4352 uint32_t uPort;
4353
4354 /* Abort the endpoint, i.e. cancel any outstanding URBs. This needs to be done after
4355 * writing back the EP state so that the completion callback can operate.
4356 */
4357 if (RT_SUCCESS(xhciR3FindRhDevBySlot(pDevIns, pThis, pThisCC, uSlotID, &pRh, &uPort)))
4358 {
4359 /* Temporarily give up the lock so that the completion callbacks can run. */
4360 RTCritSectLeave(&pThisCC->CritSectThrd);
4361 Log(("Aborting DCI %u -> ep=%u d=%u\n", uDCI, uDCI / 2, uDCI & 1 ? VUSBDIRECTION_IN : VUSBDIRECTION_OUT));
4362 pRh->pIRhConn->pfnAbortEp(pRh->pIRhConn, uPort, uDCI / 2, uDCI & 1 ? VUSBDIRECTION_IN : VUSBDIRECTION_OUT);
4363 RTCritSectEnter(&pThisCC->CritSectThrd);
4364 }
4365
4366 /// @todo The completion callbacks should do more work for canceled URBs.
4367 /* Once the completion callbacks had a chance to run, we have to adjust
4368 * the endpoint state.
4369 * NB: The guest may just ring the doorbell to continue and not execute
4370 * 'Set TRDP' after stopping the endpoint.
4371 */
4372 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4373
4374 bool fXferWasInProgress = endp_ctx.trep != endp_ctx.trdp;
4375
4376 /* Reset the TREP, but the EDTLA should be left alone. */
4377 endp_ctx.trep = endp_ctx.trdp;
4378
4379 if (fXferWasInProgress)
4380 {
4381 /* Fetch the transfer TRB to see the length. */
4382 RTGCPHYS GCPhysXfrTRB = endp_ctx.trdp & XHCI_TRDP_ADDR_MASK;
4383 XHCI_XFER_TRB XferTRB;
4384 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysXfrTRB, &XferTRB, sizeof(XferTRB));
4385
4386 xhciR3PostXferEvent(pDevIns, pThis, slot_ctx.intr_tgt, XferTRB.gen.xfr_len, XHCI_TCC_STOPPED, uSlotID, uDCI,
4387 GCPhysXfrTRB, false, false);
4388 }
4389 else
4390 {
4391 /* We need to generate a Force Stopped Event or FSE. Note that FSEs were optional
4392 * in xHCI 0.96 but aren't in 1.0.
4393 */
4394 xhciR3PostXferEvent(pDevIns, pThis, slot_ctx.intr_tgt, 0, XHCI_TCC_STP_INV_LEN, uSlotID, uDCI,
4395 endp_ctx.trdp & XHCI_TRDP_ADDR_MASK, false, false);
4396 }
4397
4398 /* Write back the updated endpoint context again. */
4399 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4400
4401 } while (0);
4402
4403 return cc;
4404}
4405
4406
4407/**
4408 * Set a new TR Dequeue Pointer for an endpoint.
4409 *
4410 * @returns TRB completion code.
4411 * @param pDevIns The device instance.
4412 * @param pThis Pointer to the xHCI state.
4413 * @param uSlotID Slot ID to work with.
4414 * @param uDCI DCI of the endpoint to reset.
4415 * @param uTRDP The TRDP including DCS/ flag.
4416 */
4417static unsigned xhciR3SetTRDP(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID, uint8_t uDCI, uint64_t uTRDP)
4418{
4419 RTGCPHYS GCPhysSlot;
4420 RTGCPHYS GCPhysEndp;
4421 XHCI_SLOT_CTX slot_ctx;
4422 XHCI_EP_CTX endp_ctx;
4423 unsigned cc = XHCI_TCC_SUCCESS;
4424
4425 Assert(uSlotID);
4426
4427 /* Determine the addresses of the contexts. */
4428 GCPhysSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
4429 GCPhysEndp = GCPhysSlot + uDCI * sizeof(XHCI_EP_CTX);
4430
4431 /* Fetch the slot context. */
4432 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysSlot, &slot_ctx, sizeof(slot_ctx));
4433
4434 /* See 4.6.10 */
4435 do {
4436 /* Check that the slot context state is Default, Addressed, or Configured. */
4437 if (slot_ctx.slot_state < XHCI_SLTST_DEFAULT)
4438 {
4439 Log(("Slot context state wrong (%u)!\n", slot_ctx.slot_state));
4440 cc = XHCI_TCC_CTX_STATE_ERR;
4441 break;
4442 }
4443
4444 /* Fetch the endpoint context. */
4445 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4446
4447 /* Check that the endpoint context state is Stopped or Error. */
4448 if (endp_ctx.ep_state != XHCI_EPST_STOPPED && endp_ctx.ep_state != XHCI_EPST_ERROR)
4449 {
4450 Log(("Endpoint context state wrong (%u)!\n", endp_ctx.ep_state));
4451 cc = XHCI_TCC_CTX_STATE_ERR;
4452 break;
4453 }
4454
4455 /* Update the TRDP/TREP and DCS. */
4456 endp_ctx.trdp = uTRDP;
4457 endp_ctx.trep = uTRDP;
4458
4459 /* Also clear the in-flight counter! */
4460 endp_ctx.ifc = 0;
4461
4462 /// @todo Handle streams
4463
4464 /* Write back the updated endpoint context. */
4465 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysEndp, &endp_ctx, sizeof(endp_ctx));
4466 } while (0);
4467
4468 return cc;
4469}
4470
4471
4472/**
4473 * Prepare for a device reset.
4474 *
4475 * @returns TRB completion code.
4476 * @param pDevIns The device instance.
4477 * @param pThis Pointer to the xHCI state.
4478 * @param uSlotID Slot ID to work with.
4479 */
4480static unsigned xhciR3ResetDevice(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uSlotID)
4481{
4482 RTGCPHYS GCPhysSlot;
4483 XHCI_SLOT_CTX slot_ctx;
4484 XHCI_DEV_CTX dc;
4485 unsigned num_ctx;
4486 unsigned i;
4487 unsigned cc = XHCI_TCC_SUCCESS;
4488
4489 Assert(uSlotID);
4490
4491 /* Determine the address of the slot/device context. */
4492 GCPhysSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
4493
4494 /* Fetch the slot context. */
4495 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysSlot, &slot_ctx, sizeof(slot_ctx));
4496
4497 /* See 4.6.11. */
4498 do {
4499 /* Check that the slot context state is Addressed or Configured. */
4500 if (slot_ctx.slot_state < XHCI_SLTST_ADDRESSED)
4501 {
4502 Log(("Slot context state wrong (%u)!\n", slot_ctx.slot_state));
4503 cc = XHCI_TCC_CTX_STATE_ERR;
4504 break;
4505 }
4506
4507 /* Read the entire Device Context. */
4508 num_ctx = slot_ctx.ctx_ent + 1; /* Slot context plus EPs. */
4509 Assert(num_ctx);
4510 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysSlot, &dc, num_ctx * sizeof(XHCI_SLOT_CTX));
4511
4512 /// @todo Abort any outstanding transfers!
4513
4514 /* Set slot state to Default and reset the USB device address. */
4515 dc.entry[0].sc.slot_state = XHCI_SLTST_DEFAULT;
4516 dc.entry[0].sc.dev_addr = 0;
4517
4518 /* Disable all endpoints except for EP 0 (aka DCI 1). */
4519 for (i = 2; i < num_ctx; ++i)
4520 dc.entry[i].ep.ep_state = XHCI_EPST_DISABLED;
4521
4522 /* Write back the updated device context. */
4523 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysSlot, &dc, num_ctx * sizeof(XHCI_SLOT_CTX));
4524 } while (0);
4525
4526 return cc;
4527}
4528
4529
4530/**
4531 * Configure a device (even though the relevant command is called 'Configure
4532 * Endpoint'. This includes adding/dropping endpoint contexts as directed by
4533 * the input control context bits.
4534 *
4535 * @returns TRB completion code.
4536 * @param pDevIns The device instance.
4537 * @param pThis Pointer to the xHCI state.
4538 * @param uInpCtxAddr Address of the input context.
4539 * @param uSlotID Slot ID associated with the context.
4540 * @param fDC Deconfigure flag set (input context unused).
4541 */
4542static unsigned xhciR3ConfigureDevice(PPDMDEVINS pDevIns, PXHCI pThis, uint64_t uInpCtxAddr, uint8_t uSlotID, bool fDC)
4543{
4544 RTGCPHYS GCPhysInpCtx = uInpCtxAddr & XHCI_CTX_ADDR_MASK;
4545 RTGCPHYS GCPhysInpSlot;
4546 RTGCPHYS GCPhysOutSlot;
4547 RTGCPHYS GCPhysOutEndp;
4548 XHCI_INPC_CTX icc; /* Input Control Context (ICI=0). */
4549 XHCI_SLOT_CTX out_slot_ctx; /* Slot context (DCI=0). */
4550 XHCI_EP_CTX out_endp_ctx; /* Endpoint Context (DCI=1). */
4551 unsigned cc = XHCI_TCC_SUCCESS;
4552 uint32_t uAddFlags;
4553 uint32_t uDropFlags;
4554 unsigned num_inp_ctx;
4555 unsigned num_out_ctx;
4556 XHCI_DEV_CTX dc_inp;
4557 XHCI_DEV_CTX dc_out;
4558 unsigned uDCI;
4559
4560 Assert(uSlotID);
4561 LogFlowFunc(("Slot ID %u, input control context @ %RGp\n", uSlotID, GCPhysInpCtx));
4562
4563 /* Determine the address of the output slot context. */
4564 GCPhysOutSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
4565 Assert(GCPhysOutSlot);
4566
4567 /* Fetch the output slot context. */
4568 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysOutSlot, &out_slot_ctx, sizeof(out_slot_ctx));
4569
4570 /* See 4.6.6 */
4571 do {
4572 /* Check that the output slot context state is Addressed, or Configured. */
4573 if (out_slot_ctx.slot_state < XHCI_SLTST_ADDRESSED)
4574 {
4575 Log(("Output slot context state wrong (%u)!\n", out_slot_ctx.slot_state));
4576 cc = XHCI_TCC_CTX_STATE_ERR;
4577 break;
4578 }
4579
4580 /* Check for deconfiguration request. */
4581 if (fDC) {
4582 if (out_slot_ctx.slot_state == XHCI_SLTST_CONFIGURED) {
4583 /* Disable all enabled endpoints. */
4584 uDropFlags = 0xFFFFFFFC; /** @todo r=bird: Why do you set uDropFlags and uAddFlags in a code path that doesn't use
4585 * them? This is a _very_ difficult function to get the hang of the way it's written.
4586 * Stuff like this looks like there's a control flow flaw (as to the do-break-while-false
4587 * loop which doesn't do any clean up or logging at the end and seems only sever the very
4588 * dubious purpose of making sure ther's only one return statement). The insistance on
4589 * C-style variable declarations (top of function), makes checking state harder, which is
4590 * why it's discouraged. */
4591 uAddFlags = 0;
4592
4593 /* Start with EP1. */
4594 GCPhysOutEndp = GCPhysOutSlot + sizeof(XHCI_SLOT_CTX) + sizeof(XHCI_EP_CTX);
4595
4596 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysOutEndp, &out_endp_ctx, sizeof(out_endp_ctx));
4597 out_endp_ctx.ep_state = XHCI_EPST_DISABLED;
4598 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysOutEndp, &out_endp_ctx, sizeof(out_endp_ctx));
4599 GCPhysOutEndp += sizeof(XHCI_EP_CTX); /* Point to the next EP context. */
4600
4601 /* Finally update the output slot context. */
4602 out_slot_ctx.ctx_ent = 1; /* Only EP0 left. */
4603 out_slot_ctx.slot_state = XHCI_SLTST_ADDRESSED;
4604 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysOutSlot, &out_slot_ctx, sizeof(out_slot_ctx));
4605 LogFlow(("Setting Output Slot State to Addressed, Context Entries = %u\n", out_slot_ctx.ctx_ent));
4606 }
4607 else
4608 /* NB: Attempts to deconfigure a slot in Addressed state are ignored. */
4609 Log(("Ignoring attempt to deconfigure slot in Addressed state!\n"));
4610 break;
4611 }
4612
4613 /* Fetch the input control context. */
4614 Assert(GCPhysInpCtx);
4615 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysInpCtx, &icc, sizeof(icc));
4616 Assert(icc.add_flags || icc.drop_flags); /* Make sure there's something to do. */
4617
4618 uAddFlags = icc.add_flags;
4619 uDropFlags = icc.drop_flags;
4620 LogFlowFunc(("Add Flags=%08X, Drop Flags=%08X\n", uAddFlags, uDropFlags));
4621
4622 /* If and only if any 'add context' flag is set, fetch the corresponding
4623 * input device context.
4624 */
4625 if (uAddFlags) {
4626 /* Calculate the address of the input slot context (ICI=1/DCI=0). */
4627 GCPhysInpSlot = GCPhysInpCtx + sizeof(XHCI_INPC_CTX);
4628
4629 /* Read the input Slot Context plus all Endpoint Contexts up to and
4630 * including the one with the highest 'add' bit set.
4631 */
4632 num_inp_ctx = ASMBitLastSetU32(uAddFlags);
4633 Assert(num_inp_ctx);
4634 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysInpSlot, &dc_inp, num_inp_ctx * sizeof(XHCI_DS_ENTRY));
4635
4636 /// @todo Check that the highest set add flag isn't beyond input slot Context Entries
4637
4638 /// @todo Check input slot context according to 6.2.2.2
4639 /// @todo Check input EP contexts according to 6.2.3.2
4640 }
4641/** @todo r=bird: Looks like MSC is right that dc_inp can be used uninitalized.
4642 *
4643 * However, this function is so hard to read I'm leaving the exorcism of it to
4644 * the author and just zeroing it in the mean time.
4645 *
4646 */
4647 else
4648 RT_ZERO(dc_inp);
4649
4650 /* Read the output Slot Context plus all Endpoint Contexts up to and
4651 * including the one with the highest 'add' or 'drop' bit set.
4652 */
4653 num_out_ctx = ASMBitLastSetU32(uAddFlags | uDropFlags);
4654 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysOutSlot, &dc_out, num_out_ctx * sizeof(XHCI_DS_ENTRY));
4655
4656 /* Drop contexts as directed by flags. */
4657 for (uDCI = 2; uDCI < 32; ++uDCI)
4658 {
4659 if (!((1 << uDCI) & uDropFlags))
4660 continue;
4661
4662 Log2(("Dropping EP DCI %u\n", uDCI));
4663 dc_out.entry[uDCI].ep.ep_state = XHCI_EPST_DISABLED;
4664 /// @todo Do we need to bother tracking resources/bandwidth?
4665 }
4666
4667 /* Now add contexts as directed by flags. */
4668 for (uDCI = 2; uDCI < 32; ++uDCI)
4669 {
4670 if (!((1 << uDCI) & uAddFlags))
4671 continue;
4672
4673 Assert(!fDC);
4674 /* Copy over EP context, set to running. */
4675 Log2(("Adding EP DCI %u\n", uDCI));
4676 dc_out.entry[uDCI].ep = dc_inp.entry[uDCI].ep;
4677 xhciR3EnableEP(&dc_out.entry[uDCI].ep);
4678 /// @todo Do we need to bother tracking resources/bandwidth?
4679 }
4680
4681 /* Finally update the device context. */
4682 if (fDC || dc_inp.entry[0].sc.ctx_ent == 1)
4683 {
4684 dc_out.entry[0].sc.slot_state = XHCI_SLTST_ADDRESSED;
4685 dc_out.entry[0].sc.ctx_ent = 1;
4686 LogFlow(("Setting Output Slot State to Addressed\n"));
4687 }
4688 else
4689 {
4690 uint32_t uKillFlags = uDropFlags & ~uAddFlags; /* Endpoints going away. */
4691
4692 /* At least one EP enabled. Update Context Entries and state. */
4693 Assert(dc_inp.entry[0].sc.ctx_ent);
4694 dc_out.entry[0].sc.slot_state = XHCI_SLTST_CONFIGURED;
4695 if (ID_TO_IDX(ASMBitLastSetU32(uAddFlags)) > dc_out.entry[0].sc.ctx_ent)
4696 {
4697 /* Adding new endpoints. */
4698 dc_out.entry[0].sc.ctx_ent = ID_TO_IDX(ASMBitLastSetU32(uAddFlags));
4699 }
4700 else if (ID_TO_IDX(ASMBitLastSetU32(uKillFlags)) == dc_out.entry[0].sc.ctx_ent)
4701 {
4702 /* Removing the last endpoint, find the last non-disabled one. */
4703 unsigned num_ctx_ent;
4704
4705 Assert(dc_out.entry[0].sc.ctx_ent + 1u == num_out_ctx);
4706 for (num_ctx_ent = dc_out.entry[0].sc.ctx_ent; num_ctx_ent > 1; --num_ctx_ent)
4707 if (dc_out.entry[num_ctx_ent].ep.ep_state != XHCI_EPST_DISABLED)
4708 break;
4709 dc_out.entry[0].sc.ctx_ent = num_ctx_ent; /* Last valid index to be precise. */
4710 }
4711 LogFlow(("Setting Output Slot State to Configured, Context Entries = %u\n", dc_out.entry[0].sc.ctx_ent));
4712 }
4713
4714 /* If there were no errors, write back the updated output context. */
4715 LogFlow(("Success, updating Output Context @ %RGp\n", GCPhysOutSlot));
4716 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysOutSlot, &dc_out, num_out_ctx * sizeof(XHCI_DS_ENTRY));
4717 } while (0);
4718
4719 return cc;
4720}
4721
4722
4723/**
4724 * Evaluate an input context. This involves modifying device and endpoint
4725 * contexts as directed by the input control context add bits.
4726 *
4727 * @returns TRB completion code.
4728 * @param pDevIns The device instance.
4729 * @param pThis Pointer to the xHCI state.
4730 * @param uInpCtxAddr Address of the input context.
4731 * @param uSlotID Slot ID associated with the context.
4732 */
4733static unsigned xhciR3EvalContext(PPDMDEVINS pDevIns, PXHCI pThis, uint64_t uInpCtxAddr, uint8_t uSlotID)
4734{
4735 RTGCPHYS GCPhysInpCtx = uInpCtxAddr & XHCI_CTX_ADDR_MASK;
4736 RTGCPHYS GCPhysInpSlot;
4737 RTGCPHYS GCPhysOutSlot;
4738 XHCI_INPC_CTX icc; /* Input Control Context (ICI=0). */
4739 XHCI_SLOT_CTX out_slot_ctx; /* Slot context (DCI=0). */
4740 unsigned cc = XHCI_TCC_SUCCESS;
4741 uint32_t uAddFlags;
4742 uint32_t uDropFlags;
4743 unsigned num_inp_ctx;
4744 unsigned num_out_ctx;
4745 XHCI_DEV_CTX dc_inp;
4746 XHCI_DEV_CTX dc_out;
4747 unsigned uDCI;
4748
4749 Assert(GCPhysInpCtx);
4750 Assert(uSlotID);
4751 LogFlowFunc(("Slot ID %u, input control context @ %RGp\n", uSlotID, GCPhysInpCtx));
4752
4753 /* Determine the address of the output slot context. */
4754 GCPhysOutSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
4755 Assert(GCPhysOutSlot);
4756
4757 /* Fetch the output slot context. */
4758 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysOutSlot, &out_slot_ctx, sizeof(out_slot_ctx));
4759
4760 /* See 4.6.7 */
4761 do {
4762 /* Check that the output slot context state is Default, Addressed, or Configured. */
4763 if (out_slot_ctx.slot_state < XHCI_SLTST_DEFAULT)
4764 {
4765 Log(("Output slot context state wrong (%u)!\n", out_slot_ctx.slot_state));
4766 cc = XHCI_TCC_CTX_STATE_ERR;
4767 break;
4768 }
4769
4770 /* Fetch the input control context. */
4771 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysInpCtx, &icc, sizeof(icc));
4772 uAddFlags = icc.add_flags;
4773 uDropFlags = icc.drop_flags;
4774 LogFlowFunc(("Add Flags=%08X, Drop Flags=%08X\n", uAddFlags, uDropFlags));
4775
4776 /* Drop flags "shall be cleared to 0" but also "do not apply" (4.6.7). Log & ignore. */
4777 if (uDropFlags)
4778 Log(("Drop flags set (%X) for evaluating context!\n", uDropFlags));
4779
4780 /* If no add flags are set, nothing will be done but an error is not reported
4781 * according to the logic flow in 4.6.7.
4782 */
4783 if (!uAddFlags)
4784 {
4785 Log(("Warning: no add flags set for evaluating context!\n"));
4786 break;
4787 }
4788
4789 /* Calculate the address of the input slot context (ICI=1/DCI=0). */
4790 GCPhysInpSlot = GCPhysInpCtx + sizeof(XHCI_INPC_CTX);
4791
4792 /* Read the output Slot Context plus all Endpoint Contexts up to and
4793 * including the one with the highest 'add' bit set.
4794 */
4795 num_inp_ctx = ASMBitLastSetU32(uAddFlags);
4796 Assert(num_inp_ctx);
4797 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysInpSlot, &dc_inp, num_inp_ctx * sizeof(XHCI_DS_ENTRY));
4798
4799 /* Read the output Slot Context plus all Endpoint Contexts up to and
4800 * including the one with the highest 'add' bit set.
4801 */
4802 num_out_ctx = ASMBitLastSetU32(uAddFlags);
4803 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysOutSlot, &dc_out, num_out_ctx * sizeof(XHCI_DS_ENTRY));
4804
4805 /// @todo Check input slot context according to 6.2.2.3
4806 /// @todo Check input EP contexts according to 6.2.3.3
4807 /// @todo Check that the highest set add flag isn't beyond input slot Context Entries
4808
4809 /* Evaluate endpoint contexts as directed by add flags. */
4810 /// @todo 6.2.3.3 suggests only the A1 bit matters? Anything besides A0/A1 is ignored??
4811 for (uDCI = 1; uDCI < 32; ++uDCI)
4812 {
4813 if (!((1 << uDCI) & uAddFlags))
4814 continue;
4815
4816 /* Evaluate Max Packet Size. */
4817 LogFunc(("DCI %u: Max Packet Size: %u -> %u\n", uDCI, dc_out.entry[uDCI].ep.max_pkt_sz, dc_inp.entry[uDCI].ep.max_pkt_sz));
4818 dc_out.entry[uDCI].ep.max_pkt_sz = dc_inp.entry[uDCI].ep.max_pkt_sz;
4819 }
4820
4821 /* Finally update the device context if directed to do so (A0 flag set). */
4822 if (uAddFlags & RT_BIT(0))
4823 {
4824 /* 6.2.2.3 - evaluate Interrupter Target and Max Exit Latency. */
4825 Log(("Interrupter Target: %u -> %u\n", dc_out.entry[0].sc.intr_tgt, dc_inp.entry[0].sc.intr_tgt));
4826 Log(("Max Exit Latency : %u -> %u\n", dc_out.entry[0].sc.max_lat, dc_inp.entry[0].sc.max_lat));
4827
4828 /// @todo Non-zero Max Exit Latency (see 4.6.7)
4829 dc_out.entry[0].sc.intr_tgt = dc_inp.entry[0].sc.intr_tgt;
4830 dc_out.entry[0].sc.max_lat = dc_inp.entry[0].sc.max_lat;
4831 }
4832
4833 /* If there were no errors, write back the updated output context. */
4834 LogFlow(("Success, updating Output Context @ %RGp\n", GCPhysOutSlot));
4835 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysOutSlot, &dc_out, num_out_ctx * sizeof(XHCI_DS_ENTRY));
4836 } while (0);
4837
4838 return cc;
4839}
4840
4841
4842/**
4843 * Query available port bandwidth.
4844 *
4845 * @returns TRB completion code.
4846 * @param pDevIns The device instance.
4847 * @param pThis Pointer to the xHCI state.
4848 * @param uDevSpd Speed of not yet attached devices.
4849 * @param uHubSlotID Hub Slot ID to query (unsupported).
4850 * @param uBwCtx Bandwidth context physical address.
4851 */
4852static unsigned xhciR3GetPortBandwidth(PPDMDEVINS pDevIns, PXHCI pThis, uint8_t uDevSpd, uint8_t uHubSlotID, uint64_t uBwCtx)
4853{
4854 RT_NOREF(uHubSlotID);
4855 RTGCPHYS GCPhysBwCtx;
4856 unsigned cc = XHCI_TCC_SUCCESS;
4857 unsigned ctx_size;
4858 unsigned iPort;
4859 uint8_t bw_ctx[RT_ALIGN_32(XHCI_NDP_MAX + 1, 4)] = {0};
4860 uint8_t dev_spd;
4861 uint8_t avail_bw;
4862
4863 Assert(!uHubSlotID);
4864 Assert(uBwCtx);
4865
4866 /* See 4.6.15. */
4867
4868 /* Hubs are not supported because guests will never see them. The
4869 * reported values are more or less dummy because we have no real
4870 * information about the bandwidth available on the host. The reported
4871 * values are optimistic, as if each port had its own separate Bus
4872 * Instance aka BI.
4873 */
4874
4875 GCPhysBwCtx = uBwCtx & XHCI_CTX_ADDR_MASK;
4876
4877 /* Number of ports + 1, rounded up to DWORDs. */
4878 ctx_size = RT_ALIGN_32(XHCI_NDP_CFG(pThis) + 1, 4);
4879 LogFlowFunc(("BW Context at %RGp, size %u\n", GCPhysBwCtx, ctx_size));
4880 Assert(ctx_size <= sizeof(bw_ctx));
4881
4882 /* Go over all the ports. */
4883 for (iPort = 0; iPort < XHCI_NDP_CFG(pThis); ++iPort)
4884 {
4885 /* Get the device speed from the port... */
4886 dev_spd = (pThis->aPorts[iPort].portsc & XHCI_PORT_PLS_MASK) >> XHCI_PORT_PLS_SHIFT;
4887 /* ...and if nothing is attached, use the provided default. */
4888 if (!dev_spd)
4889 dev_spd = uDevSpd;
4890
4891 /* For USB3 ports, report 90% available for SS devices (see 6.2.6). */
4892 if (IS_USB3_PORT_IDX_SHR(pThis, iPort))
4893 avail_bw = dev_spd == XHCI_SPD_SUPER ? 90 : 0;
4894 else
4895 /* For USB2 ports, report 80% available for HS and 90% for FS/LS. */
4896 switch (dev_spd)
4897 {
4898 case XHCI_SPD_HIGH:
4899 avail_bw = 80;
4900 break;
4901 case XHCI_SPD_FULL:
4902 case XHCI_SPD_LOW:
4903 avail_bw = 90;
4904 break;
4905 default:
4906 avail_bw = 0;
4907 }
4908
4909 /* The first entry in the context is reserved. */
4910 bw_ctx[iPort + 1] = avail_bw;
4911 }
4912
4913 /* Write back the bandwidth context. */
4914 PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysBwCtx, &bw_ctx, ctx_size);
4915
4916 return cc;
4917}
4918
4919#define NEC_MAGIC ('x' | ('H' << 8) | ('C' << 16) | ('I' << 24))
4920
4921/**
4922 * Take a 64-bit input, shake well, produce 32-bit token. This mechanism
4923 * prevents NEC/Renesas drivers from running on 3rd party hardware. Mirrors
4924 * code found in vendor's drivers.
4925 */
4926static uint32_t xhciR3NecAuthenticate(uint64_t cookie)
4927{
4928 uint32_t cookie_lo = RT_LODWORD(cookie);
4929 uint32_t cookie_hi = RT_HIDWORD(cookie);
4930 uint32_t shift_cnt;
4931 uint32_t token;
4932
4933 shift_cnt = (cookie_hi >> 8) & 31;
4934 token = ASMRotateRightU32(cookie_lo - NEC_MAGIC, shift_cnt);
4935 shift_cnt = cookie_hi & 31;
4936 token += ASMRotateLeftU32(cookie_lo + NEC_MAGIC, shift_cnt);
4937 shift_cnt = (cookie_lo >> 16) & 31;
4938 token -= ASMRotateLeftU32(cookie_hi ^ NEC_MAGIC, shift_cnt);
4939
4940 return ~token;
4941}
4942
4943/**
4944 * Process a single command TRB and post completion information.
4945 */
4946static int xhciR3ExecuteCommand(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC, XHCI_COMMAND_TRB *pCmd)
4947{
4948 XHCI_EVENT_TRB ed;
4949 uint32_t token;
4950 unsigned slot;
4951 unsigned cc;
4952 int rc = VINF_SUCCESS;
4953 LogFlowFunc(("Executing command %u (%s) @ %RGp\n", pCmd->gen.type,
4954 pCmd->gen.type < RT_ELEMENTS(g_apszTrbNames) ? g_apszTrbNames[pCmd->gen.type] : "WHAT?!!",
4955 (RTGCPHYS)pThis->cmdr_dqp));
4956
4957 switch (pCmd->gen.type)
4958 {
4959 case XHCI_TRB_NOOP_CMD:
4960 /* No-op, slot ID is always zero. */
4961 rc = xhciR3PostCmdCompletion(pDevIns, pThis, XHCI_TCC_SUCCESS, 0);
4962 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
4963 break;
4964
4965 case XHCI_TRB_LINK:
4966 /* Link; set the dequeue pointer. CH bit is ignored. */
4967 Log(("Link: Ptr=%RGp IOC=%u TC=%u\n", pCmd->link.rseg_ptr, pCmd->link.ioc, pCmd->link.toggle));
4968 if (pCmd->link.ioc) /* Command completion event is optional! */
4969 rc = xhciR3PostCmdCompletion(pDevIns, pThis, XHCI_TCC_SUCCESS, 0);
4970 /* Update the dequeue pointer and flip DCS if required. */
4971 pThis->cmdr_dqp = pCmd->link.rseg_ptr & XHCI_TRDP_ADDR_MASK;
4972 pThis->cmdr_ccs = pThis->cmdr_ccs ^ pCmd->link.toggle;
4973 break;
4974
4975 case XHCI_TRB_ENB_SLOT:
4976 /* Look for an empty device slot. */
4977 for (slot = 0; slot < RT_ELEMENTS(pThis->aSlotState); ++slot)
4978 {
4979 if (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY)
4980 {
4981 /* Found a slot - transition to enabled state. */
4982 pThis->aSlotState[slot] = XHCI_DEVSLOT_ENABLED;
4983 break;
4984 }
4985 }
4986 Log(("Enable Slot: found slot ID %u\n", IDX_TO_ID(slot)));
4987
4988 /* Post command completion event. */
4989 if (slot == RT_ELEMENTS(pThis->aSlotState))
4990 xhciR3PostCmdCompletion(pDevIns, pThis, XHCI_TCC_NO_SLOTS, 0);
4991 else
4992 xhciR3PostCmdCompletion(pDevIns, pThis, XHCI_TCC_SUCCESS, IDX_TO_ID(slot));
4993
4994 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
4995 break;
4996
4997 case XHCI_TRB_DIS_SLOT:
4998 /* Disable the given device slot. */
4999 Log(("Disable Slot: slot ID %u\n", pCmd->dsl.slot_id));
5000 cc = XHCI_TCC_SUCCESS;
5001 slot = ID_TO_IDX(pCmd->dsl.slot_id);
5002 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5003 cc = XHCI_TCC_SLOT_NOT_ENB;
5004 else
5005 {
5006 /// @todo set slot state of assoc. context to disabled
5007 pThis->aSlotState[slot] = XHCI_DEVSLOT_EMPTY;
5008 }
5009 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->dsl.slot_id);
5010 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5011 break;
5012
5013 case XHCI_TRB_ADDR_DEV:
5014 /* Address a device. */
5015 Log(("Address Device: slot ID %u, BSR=%u\n", pCmd->adr.slot_id, pCmd->adr.bsr));
5016 slot = ID_TO_IDX(pCmd->cfg.slot_id);
5017 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5018 cc = XHCI_TCC_SLOT_NOT_ENB;
5019 else
5020 cc = xhciR3AddressDevice(pDevIns, pThis, pThisCC, pCmd->adr.ctx_ptr, pCmd->adr.slot_id, pCmd->adr.bsr);
5021 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->adr.slot_id);
5022 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5023 break;
5024
5025 case XHCI_TRB_CFG_EP:
5026 /* Configure endpoint. */
5027 Log(("Configure endpoint: slot ID %u, DC=%u, Ctx @ %RGp\n", pCmd->cfg.slot_id, pCmd->cfg.dc, pCmd->cfg.ctx_ptr));
5028 slot = ID_TO_IDX(pCmd->cfg.slot_id);
5029 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5030 cc = XHCI_TCC_SLOT_NOT_ENB;
5031 else
5032 cc = xhciR3ConfigureDevice(pDevIns, pThis, pCmd->cfg.ctx_ptr, pCmd->cfg.slot_id, pCmd->cfg.dc);
5033 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->cfg.slot_id);
5034 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5035 break;
5036
5037 case XHCI_TRB_EVAL_CTX:
5038 /* Evaluate context. */
5039 Log(("Evaluate context: slot ID %u, Ctx @ %RGp\n", pCmd->evc.slot_id, pCmd->evc.ctx_ptr));
5040 slot = ID_TO_IDX(pCmd->evc.slot_id);
5041 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5042 cc = XHCI_TCC_SLOT_NOT_ENB;
5043 else
5044 cc = xhciR3EvalContext(pDevIns, pThis, pCmd->evc.ctx_ptr, pCmd->evc.slot_id);
5045 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->evc.slot_id);
5046 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5047 break;
5048
5049 case XHCI_TRB_RESET_EP:
5050 /* Reset the given endpoint. */
5051 Log(("Reset Endpoint: slot ID %u, EP ID %u, TSP=%u\n", pCmd->rse.slot_id, pCmd->rse.ep_id, pCmd->rse.tsp));
5052 cc = XHCI_TCC_SUCCESS;
5053 slot = ID_TO_IDX(pCmd->rse.slot_id);
5054 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5055 cc = XHCI_TCC_SLOT_NOT_ENB;
5056 else
5057 cc = xhciR3ResetEndpoint(pDevIns, pThis, pCmd->rse.slot_id, pCmd->rse.ep_id, pCmd->rse.tsp);
5058 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->stp.slot_id);
5059 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5060 break;
5061
5062 case XHCI_TRB_STOP_EP:
5063 /* Stop the given endpoint. */
5064 Log(("Stop Endpoint: slot ID %u, EP ID %u, SP=%u\n", pCmd->stp.slot_id, pCmd->stp.ep_id, pCmd->stp.sp));
5065 cc = XHCI_TCC_SUCCESS;
5066 slot = ID_TO_IDX(pCmd->stp.slot_id);
5067 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5068 cc = XHCI_TCC_SLOT_NOT_ENB;
5069 else
5070 cc = xhciR3StopEndpoint(pDevIns, pThis, pThisCC, pCmd->stp.slot_id, pCmd->stp.ep_id, pCmd->stp.sp);
5071 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->stp.slot_id);
5072 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5073 break;
5074
5075 case XHCI_TRB_SET_DEQ_PTR:
5076 /* Set TR Dequeue Pointer. */
5077 Log(("Set TRDP: slot ID %u, EP ID %u, TRDP=%RX64\n", pCmd->stdp.slot_id, pCmd->stdp.ep_id, pCmd->stdp.tr_dqp));
5078 cc = XHCI_TCC_SUCCESS;
5079 slot = ID_TO_IDX(pCmd->stdp.slot_id);
5080 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5081 cc = XHCI_TCC_SLOT_NOT_ENB;
5082 else
5083 cc = xhciR3SetTRDP(pDevIns, pThis, pCmd->stdp.slot_id, pCmd->stdp.ep_id, pCmd->stdp.tr_dqp);
5084 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->stdp.slot_id);
5085 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5086 break;
5087
5088 case XHCI_TRB_RESET_DEV:
5089 /* Reset a device. */
5090 Log(("Reset Device: slot ID %u\n", pCmd->rsd.slot_id));
5091 cc = XHCI_TCC_SUCCESS;
5092 slot = ID_TO_IDX(pCmd->rsd.slot_id);
5093 if ((slot >= RT_ELEMENTS(pThis->aSlotState)) || (pThis->aSlotState[slot] == XHCI_DEVSLOT_EMPTY))
5094 cc = XHCI_TCC_SLOT_NOT_ENB;
5095 else
5096 cc = xhciR3ResetDevice(pDevIns, pThis, pCmd->rsd.slot_id);
5097 xhciR3PostCmdCompletion(pDevIns, pThis, cc, pCmd->rsd.slot_id);
5098 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5099 break;
5100
5101 case XHCI_TRB_GET_PORT_BW:
5102 /* Get port bandwidth. */
5103 Log(("Get Port Bandwidth: Dev Speed %u, Hub Slot ID %u, Context=%RX64\n", pCmd->gpbw.spd, pCmd->gpbw.slot_id, pCmd->gpbw.pbctx_ptr));
5104 cc = XHCI_TCC_SUCCESS;
5105 if (pCmd->gpbw.slot_id)
5106 cc = XHCI_TCC_PARM_ERR; /* Potential undefined behavior, see 4.6.15. */
5107 else
5108 cc = xhciR3GetPortBandwidth(pDevIns, pThis, pCmd->gpbw.spd, pCmd->gpbw.slot_id, pCmd->gpbw.pbctx_ptr);
5109 xhciR3PostCmdCompletion(pDevIns, pThis, cc, 0);
5110 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5111 break;
5112
5113 case NEC_TRB_GET_FW_VER:
5114 /* Get NEC firmware version. */
5115 Log(("Get NEC firmware version\n"));
5116 cc = XHCI_TCC_SUCCESS;
5117
5118 RT_ZERO(ed);
5119 ed.nce.word1 = NEC_FW_REV;
5120 ed.nce.trb_ptr = pThis->cmdr_dqp;
5121 ed.nce.cc = cc;
5122 ed.nce.type = NEC_TRB_CMD_CMPL;
5123
5124 xhciR3WriteEvent(pDevIns, pThis, &ed, XHCI_PRIMARY_INTERRUPTER, false);
5125
5126 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5127 break;
5128
5129 case NEC_TRB_AUTHENTICATE:
5130 /* NEC authentication. */
5131 Log(("NEC authentication, cookie %RX64\n", pCmd->nac.cookie));
5132 cc = XHCI_TCC_SUCCESS;
5133
5134 token = xhciR3NecAuthenticate(pCmd->nac.cookie);
5135 RT_ZERO(ed);
5136 ed.nce.word1 = RT_LOWORD(token);
5137 ed.nce.word2 = RT_HIWORD(token);
5138 ed.nce.trb_ptr = pThis->cmdr_dqp;
5139 ed.nce.cc = cc;
5140 ed.nce.type = NEC_TRB_CMD_CMPL;
5141
5142 xhciR3WriteEvent(pDevIns, pThis, &ed, XHCI_PRIMARY_INTERRUPTER, false);
5143
5144 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5145 break;
5146
5147 default:
5148 Log(("Unsupported command!\n"));
5149 pThis->cmdr_dqp += sizeof(XHCI_COMMAND_TRB);
5150 break;
5151 }
5152
5153 return rc;
5154}
5155
5156
5157/**
5158 * Stop the Command Ring.
5159 */
5160static int xhciR3StopCommandRing(PPDMDEVINS pDevIns, PXHCI pThis)
5161{
5162 LogFlowFunc(("Command Ring stopping\n"));
5163
5164 Assert(pThis->crcr & (XHCI_CRCR_CA | XHCI_CRCR_CS));
5165 Assert(pThis->crcr & XHCI_CRCR_CRR);
5166 ASMAtomicAndU64(&pThis->crcr, ~(XHCI_CRCR_CRR | XHCI_CRCR_CA | XHCI_CRCR_CS));
5167 return xhciR3PostCmdCompletion(pDevIns, pThis, XHCI_TCC_CMDR_STOPPED, 0);
5168}
5169
5170
5171/**
5172 * Process the xHCI command ring.
5173 */
5174static int xhciR3ProcessCommandRing(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC)
5175{
5176 RTGCPHYS GCPhysCmdTRB;
5177 XHCI_COMMAND_TRB cmd; /* Command Descriptor */
5178 unsigned cCmds;
5179
5180 Assert(pThis->crcr & XHCI_CRCR_CRR);
5181 LogFlowFunc(("Processing commands...\n"));
5182
5183 for (cCmds = 0;; cCmds++)
5184 {
5185 /* First check if the xHC is running at all. */
5186 if (!(pThis->cmd & XHCI_CMD_RS))
5187 {
5188 /* Note that this will call xhciR3PostCmdCompletion() which will
5189 * end up doing nothing because R/S is clear.
5190 */
5191 xhciR3StopCommandRing(pDevIns, pThis);
5192 break;
5193 }
5194
5195 /* Check if Command Ring was stopped in the meantime. */
5196 if (pThis->crcr & (XHCI_CRCR_CS | XHCI_CRCR_CA))
5197 {
5198 /* NB: We currently do not abort commands. If we did, we would
5199 * abort the currently running command and complete it with
5200 * the XHCI_TCC_CMD_ABORTED status.
5201 */
5202 xhciR3StopCommandRing(pDevIns, pThis);
5203 break;
5204 }
5205
5206 /* Fetch the command TRB. */
5207 GCPhysCmdTRB = pThis->cmdr_dqp;
5208 PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysCmdTRB, &cmd, sizeof(cmd));
5209
5210 /* Make sure the Cycle State matches. */
5211 if ((bool)cmd.gen.cycle == pThis->cmdr_ccs)
5212 xhciR3ExecuteCommand(pDevIns, pThis, pThisCC, &cmd);
5213 else
5214 {
5215 Log(("Command Ring empty\n"));
5216 break;
5217 }
5218
5219 /* Check if we're being fed suspiciously many commands. */
5220 if (cCmds > XHCI_MAX_NUM_CMDS)
5221 {
5222 /* Clear the R/S bit and any command ring running bits.
5223 * Note that the caller (xhciR3WorkerLoop) will set XHCI_STATUS_HCH.
5224 */
5225 ASMAtomicAndU32(&pThis->cmd, ~XHCI_CMD_RS);
5226 ASMAtomicAndU64(&pThis->crcr, ~(XHCI_CRCR_CRR | XHCI_CRCR_CA | XHCI_CRCR_CS));
5227 ASMAtomicOrU32(&pThis->status, XHCI_STATUS_HCE);
5228 LogRelMax(10, ("xHCI: Attempted to execute too many commands, stopping xHC!\n"));
5229 break;
5230 }
5231 }
5232 return VINF_SUCCESS;
5233}
5234
5235
5236/**
5237 * The xHCI asynchronous worker thread.
5238 *
5239 * @returns VBox status code.
5240 * @param pDevIns The xHCI device instance.
5241 * @param pThread The worker thread.
5242 */
5243static DECLCALLBACK(int) xhciR3WorkerLoop(PPDMDEVINS pDevIns, PPDMTHREAD pThread)
5244{
5245 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
5246 PXHCICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PXHCICC);
5247 int rc;
5248
5249 LogFlow(("xHCI entering worker thread loop.\n"));
5250 if (pThread->enmState == PDMTHREADSTATE_INITIALIZING)
5251 return VINF_SUCCESS;
5252
5253 while (pThread->enmState == PDMTHREADSTATE_RUNNING)
5254 {
5255 uint32_t u32Tasks = 0;
5256 uint8_t uSlotID;
5257
5258 ASMAtomicWriteBool(&pThis->fWrkThreadSleeping, true);
5259 u32Tasks = ASMAtomicXchgU32(&pThis->u32TasksNew, 0);
5260 if (!u32Tasks)
5261 {
5262 Assert(ASMAtomicReadBool(&pThis->fWrkThreadSleeping));
5263 rc = PDMDevHlpSUPSemEventWaitNoResume(pDevIns, pThis->hEvtProcess, RT_INDEFINITE_WAIT);
5264 AssertLogRelMsgReturn(RT_SUCCESS(rc) || rc == VERR_INTERRUPTED, ("%Rrc\n", rc), rc);
5265 if (RT_UNLIKELY(pThread->enmState != PDMTHREADSTATE_RUNNING))
5266 break;
5267 LogFlowFunc(("Woken up with rc=%Rrc\n", rc));
5268 u32Tasks = ASMAtomicXchgU32(&pThis->u32TasksNew, 0);
5269 }
5270
5271 RTCritSectEnter(&pThisCC->CritSectThrd);
5272
5273 if (pThis->crcr & XHCI_CRCR_CRR)
5274 xhciR3ProcessCommandRing(pDevIns, pThis, pThisCC);
5275
5276 /* Run down the list of doorbells that are ringing. */
5277 for (uSlotID = 1; uSlotID < XHCI_NDS; ++uSlotID)
5278 {
5279 if (pThis->aSlotState[ID_TO_IDX(uSlotID)] >= XHCI_DEVSLOT_ENABLED)
5280 {
5281 while (pThis->aBellsRung[ID_TO_IDX(uSlotID)])
5282 {
5283 uint8_t bit;
5284 uint32_t uDBVal = 0;
5285
5286 for (bit = 0; bit < 32; ++bit)
5287 if (pThis->aBellsRung[ID_TO_IDX(uSlotID)] & (1 << bit))
5288 {
5289 uDBVal = bit;
5290 break;
5291 }
5292
5293 Log2(("Stop ringing bell for slot %u, DCI %u\n", uSlotID, uDBVal));
5294 ASMAtomicAndU32(&pThis->aBellsRung[ID_TO_IDX(uSlotID)], ~(1 << uDBVal));
5295 xhciR3ProcessDevCtx(pDevIns, pThis, pThisCC, uSlotID, uDBVal);
5296 }
5297 }
5298 }
5299
5300 /* If the R/S bit is no longer set, halt the xHC. */
5301 if (!(pThis->cmd & XHCI_CMD_RS))
5302 {
5303 Log(("R/S clear, halting the xHC.\n"));
5304 ASMAtomicOrU32(&pThis->status, XHCI_STATUS_HCH);
5305 }
5306
5307 RTCritSectLeave(&pThisCC->CritSectThrd);
5308
5309 ASMAtomicWriteBool(&pThis->fWrkThreadSleeping, false);
5310 } /* While running */
5311
5312 LogFlow(("xHCI worker thread exiting.\n"));
5313 return VINF_SUCCESS;
5314}
5315
5316
5317/**
5318 * Unblock the worker thread so it can respond to a state change.
5319 *
5320 * @returns VBox status code.
5321 * @param pDevIns The xHCI device instance.
5322 * @param pThread The worker thread.
5323 */
5324static DECLCALLBACK(int) xhciR3WorkerWakeUp(PPDMDEVINS pDevIns, PPDMTHREAD pThread)
5325{
5326 NOREF(pThread);
5327 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
5328
5329 return PDMDevHlpSUPSemEventSignal(pDevIns, pThis->hEvtProcess);
5330}
5331
5332
5333/**
5334 * @interface_method_impl{PDMIBASE,pfnQueryInterface}
5335 */
5336static DECLCALLBACK(void *) xhciR3RhQueryInterface(PPDMIBASE pInterface, const char *pszIID)
5337{
5338 PXHCIROOTHUBR3 pRh = RT_FROM_MEMBER(pInterface, XHCIROOTHUBR3, IBase);
5339 PDMIBASE_RETURN_INTERFACE(pszIID, PDMIBASE, &pRh->IBase);
5340 PDMIBASE_RETURN_INTERFACE(pszIID, VUSBIROOTHUBPORT, &pRh->IRhPort);
5341 return NULL;
5342}
5343
5344/**
5345 * @interface_method_impl{PDMIBASE,pfnQueryInterface}
5346 */
5347static DECLCALLBACK(void *) xhciR3QueryStatusInterface(PPDMIBASE pInterface, const char *pszIID)
5348{
5349 PXHCIR3 pThisCC = RT_FROM_MEMBER(pInterface, XHCIR3, IBase);
5350 PDMIBASE_RETURN_INTERFACE(pszIID, PDMIBASE, &pThisCC->IBase);
5351 PDMIBASE_RETURN_INTERFACE(pszIID, PDMILEDPORTS, &pThisCC->ILeds);
5352 return NULL;
5353}
5354
5355/**
5356 * Gets the pointer to the status LED of a unit.
5357 *
5358 * @returns VBox status code.
5359 * @param pInterface Pointer to the interface structure containing the called function pointer.
5360 * @param iLUN The unit which status LED we desire.
5361 * @param ppLed Where to store the LED pointer.
5362 */
5363static DECLCALLBACK(int) xhciR3QueryStatusLed(PPDMILEDPORTS pInterface, unsigned iLUN, PPDMLED *ppLed)
5364{
5365 PXHCICC pThisCC = RT_FROM_MEMBER(pInterface, XHCIR3, ILeds);
5366
5367 if (iLUN < XHCI_NUM_LUNS)
5368 {
5369 *ppLed = iLUN ? &pThisCC->RootHub3.Led : &pThisCC->RootHub2.Led;
5370 Assert((*ppLed)->u32Magic == PDMLED_MAGIC);
5371 return VINF_SUCCESS;
5372 }
5373 return VERR_PDM_LUN_NOT_FOUND;
5374}
5375
5376
5377/**
5378 * Get the number of ports available in the hub.
5379 *
5380 * @returns The number of ports available.
5381 * @param pInterface Pointer to this structure.
5382 * @param pAvailable Bitmap indicating the available ports. Set bit == available port.
5383 */
5384static DECLCALLBACK(unsigned) xhciR3RhGetAvailablePorts(PVUSBIROOTHUBPORT pInterface, PVUSBPORTBITMAP pAvailable)
5385{
5386 PXHCIROOTHUBR3 pRh = RT_FROM_MEMBER(pInterface, XHCIROOTHUBR3, IRhPort);
5387 PXHCICC pThisCC = pRh->pXhciR3;
5388 PPDMDEVINS pDevIns = pThisCC->pDevIns;
5389 unsigned iPort;
5390 unsigned cPorts = 0;
5391 LogFlow(("xhciR3RhGetAvailablePorts\n"));
5392
5393 memset(pAvailable, 0, sizeof(*pAvailable));
5394
5395 int const rcLock = PDMDevHlpCritSectEnter(pDevIns, pDevIns->pCritSectRoR3, VERR_IGNORED);
5396 PDM_CRITSECT_RELEASE_ASSERT_RC_DEV(pDevIns, pDevIns->pCritSectRoR3, rcLock);
5397
5398 for (iPort = pRh->uPortBase; iPort < (unsigned)pRh->uPortBase + pRh->cPortsImpl; iPort++)
5399 {
5400 Assert(iPort < XHCI_NDP_CFG(PDMDEVINS_2_DATA(pDevIns, PXHCI)));
5401 if (!pThisCC->aPorts[iPort].fAttached)
5402 {
5403 cPorts++;
5404 ASMBitSet(pAvailable, IDX_TO_ID(iPort - pRh->uPortBase));
5405 }
5406 }
5407
5408 PDMDevHlpCritSectLeave(pDevIns, pDevIns->pCritSectRoR3);
5409 return cPorts;
5410}
5411
5412
5413/**
5414 * Get the supported USB versions for USB2 hubs.
5415 *
5416 * @returns The mask of supported USB versions.
5417 * @param pInterface Pointer to this structure.
5418 */
5419static DECLCALLBACK(uint32_t) xhciR3RhGetUSBVersions2(PVUSBIROOTHUBPORT pInterface)
5420{
5421 RT_NOREF(pInterface);
5422 return VUSB_STDVER_11 | VUSB_STDVER_20;
5423}
5424
5425
5426/**
5427 * Get the supported USB versions for USB2 hubs.
5428 *
5429 * @returns The mask of supported USB versions.
5430 * @param pInterface Pointer to this structure.
5431 */
5432static DECLCALLBACK(uint32_t) xhciR3RhGetUSBVersions3(PVUSBIROOTHUBPORT pInterface)
5433{
5434 RT_NOREF(pInterface);
5435 return VUSB_STDVER_30;
5436}
5437
5438
5439/**
5440 * Start sending SOF tokens across the USB bus, lists are processed in the
5441 * next frame.
5442 */
5443static void xhciR3BusStart(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC)
5444{
5445 unsigned iPort;
5446
5447 pThisCC->RootHub2.pIRhConn->pfnPowerOn(pThisCC->RootHub2.pIRhConn);
5448 pThisCC->RootHub3.pIRhConn->pfnPowerOn(pThisCC->RootHub3.pIRhConn);
5449// xhciR3BumpFrameNumber(pThis);
5450
5451 Log(("xHCI: Bus started\n"));
5452
5453 Assert(pThis->status & XHCI_STATUS_HCH);
5454 ASMAtomicAndU32(&pThis->status, ~XHCI_STATUS_HCH);
5455
5456 /* HCH gates PSCEG (4.19.2). When clearing HCH, re-evaluate port changes. */
5457 for (iPort = 0; iPort < XHCI_NDP_CFG(pThis); ++iPort)
5458 {
5459 if (pThis->aPorts[iPort].portsc & XHCI_PORT_CHANGE_MASK)
5460 xhciR3GenPortChgEvent(pDevIns, pThis, IDX_TO_ID(iPort));
5461 }
5462
5463 /// @todo record the starting time?
5464// pThis->SofTime = TMTimerGet(pThis->CTX_SUFF(pEndOfFrameTimer)) - pThis->cTicksPerFrame;
5465}
5466
5467/**
5468 * Stop sending SOF tokens on the bus and processing the data.
5469 */
5470static void xhciR3BusStop(PPDMDEVINS pDevIns, PXHCI pThis, PXHCICC pThisCC)
5471{
5472 LogFlow(("xhciR3BusStop\n"));
5473
5474 /* Stop the controller and Command Ring. */
5475 pThis->cmd &= ~XHCI_CMD_RS;
5476 pThis->crcr |= XHCI_CRCR_CS;
5477
5478 /* Power off the root hubs. */
5479 pThisCC->RootHub2.pIRhConn->pfnPowerOff(pThisCC->RootHub2.pIRhConn);
5480 pThisCC->RootHub3.pIRhConn->pfnPowerOff(pThisCC->RootHub3.pIRhConn);
5481
5482 /* The worker thread will halt the HC (set HCH) when done. */
5483 xhciKickWorker(pDevIns, pThis, XHCI_JOB_PROCESS_CMDRING, 0);
5484}
5485
5486
5487/**
5488 * Power a port up or down
5489 */
5490static void xhciR3PortPower(PXHCI pThis, PXHCICC pThisCC, unsigned iPort, bool fPowerUp)
5491{
5492 PXHCIHUBPORT pPort = &pThis->aPorts[iPort];
5493 PXHCIHUBPORTR3 pPortR3 = &pThisCC->aPorts[iPort];
5494 PXHCIROOTHUBR3 pRh = GET_PORT_PRH(pThisCC, iPort);
5495
5496 bool fOldPPS = !!(pPort->portsc & XHCI_PORT_PP);
5497 LogFlow(("xhciR3PortPower (port %u) %s\n", IDX_TO_ID(iPort), fPowerUp ? "UP" : "DOWN"));
5498
5499 if (fPowerUp)
5500 {
5501 /* Power up a port. */
5502 if (pPortR3->fAttached)
5503 ASMAtomicOrU32(&pPort->portsc, XHCI_PORT_CCS);
5504 if (pPort->portsc & XHCI_PORT_CCS)
5505 ASMAtomicOrU32(&pPort->portsc, XHCI_PORT_PP);
5506 if (pPortR3->fAttached && !fOldPPS)
5507 VUSBIRhDevPowerOn(pRh->pIRhConn, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort));
5508 }
5509 else
5510 {
5511 /* Power down. */
5512 ASMAtomicAndU32(&pPort->portsc, ~(XHCI_PORT_PP | XHCI_PORT_CCS));
5513 if (pPortR3->fAttached && fOldPPS)
5514 VUSBIRhDevPowerOff(pRh->pIRhConn, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort));
5515 }
5516}
5517
5518
5519/**
5520 * Port reset done callback.
5521 *
5522 * @param pDevIns The device instance data.
5523 * @param iPort The XHCI port index of the port being resetted.
5524 */
5525static void xhciR3PortResetDone(PPDMDEVINS pDevIns, unsigned iPort)
5526{
5527 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
5528
5529 Log2(("xhciR3PortResetDone\n"));
5530
5531 AssertReturnVoid(iPort < XHCI_NDP_CFG(pThis));
5532
5533 /*
5534 * Successful reset.
5535 */
5536 Log2(("xhciR3PortResetDone: Reset completed.\n"));
5537
5538 uint32_t fChangeMask = XHCI_PORT_PED | XHCI_PORT_PRC;
5539 /* For USB2 ports, transition the link state. */
5540 if (!IS_USB3_PORT_IDX_SHR(pThis, iPort))
5541 {
5542 pThis->aPorts[iPort].portsc &= ~XHCI_PORT_PLS_MASK;
5543 pThis->aPorts[iPort].portsc |= XHCI_PLS_U0 << XHCI_PORT_PLS_SHIFT;
5544 }
5545 else
5546 {
5547 if (pThis->aPorts[iPort].portsc & XHCI_PORT_WPR)
5548 fChangeMask |= XHCI_PORT_WRC;
5549 }
5550
5551 ASMAtomicAndU32(&pThis->aPorts[iPort].portsc, ~(XHCI_PORT_PR | XHCI_PORT_WPR));
5552 ASMAtomicOrU32(&pThis->aPorts[iPort].portsc, fChangeMask);
5553 /// @todo Set USBSTS.PCD and manage PSCEG correctly!
5554 /// @todo just guessing?!
5555// ASMAtomicOrU32(&pThis->aPorts[iPort].portsc, XHCI_PORT_CSC | XHCI_PORT_PLC);
5556
5557 /// @todo Is this the right place?
5558 xhciR3GenPortChgEvent(pDevIns, pThis, IDX_TO_ID(iPort));
5559}
5560
5561
5562/**
5563 * Sets a flag in a port status register, but only if a device is connected;
5564 * if not, set ConnectStatusChange flag to force HCD to reevaluate connect status.
5565 *
5566 * @returns true if device was connected and the flag was cleared.
5567 */
5568static bool xhciR3RhPortSetIfConnected(PXHCI pThis, int iPort, uint32_t fValue)
5569{
5570 /*
5571 * Writing a 0 has no effect
5572 */
5573 if (fValue == 0)
5574 return false;
5575
5576 /*
5577 * The port might be still/already disconnected.
5578 */
5579 if (!(pThis->aPorts[iPort].portsc & XHCI_PORT_CCS))
5580 return false;
5581
5582 bool fRc = !(pThis->aPorts[iPort].portsc & fValue);
5583
5584 /* Set the bit. */
5585 ASMAtomicOrU32(&pThis->aPorts[iPort].portsc, fValue);
5586
5587 return fRc;
5588}
5589
5590
5591/** Translate VUSB speed enum to xHCI definition. */
5592static unsigned xhciR3UsbSpd2XhciSpd(VUSBSPEED enmSpeed)
5593{
5594 unsigned uSpd;
5595
5596 switch (enmSpeed)
5597 {
5598 default: AssertMsgFailed(("%d\n", enmSpeed));
5599 RT_FALL_THRU();
5600 case VUSB_SPEED_LOW: uSpd = XHCI_SPD_LOW; break;
5601 case VUSB_SPEED_FULL: uSpd = XHCI_SPD_FULL; break;
5602 case VUSB_SPEED_HIGH: uSpd = XHCI_SPD_HIGH; break;
5603 case VUSB_SPEED_SUPER: uSpd = XHCI_SPD_SUPER; break;
5604 }
5605 return uSpd;
5606}
5607
5608/** @interface_method_impl{VUSBIROOTHUBPORT,pfnAttach} */
5609static DECLCALLBACK(int) xhciR3RhAttach(PVUSBIROOTHUBPORT pInterface, unsigned uPort, VUSBSPEED enmSpeed)
5610{
5611 PXHCIROOTHUBR3 pRh = RT_FROM_MEMBER(pInterface, XHCIROOTHUBR3, IRhPort);
5612 PXHCICC pThisCC = pRh->pXhciR3;
5613 PPDMDEVINS pDevIns = pThisCC->pDevIns;
5614 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
5615 PXHCIHUBPORT pPort;
5616 unsigned iPort;
5617 LogFlow(("xhciR3RhAttach: uPort=%u (iPort=%u)\n", uPort, ID_TO_IDX(uPort) + pRh->uPortBase));
5618
5619 int const rcLock = PDMDevHlpCritSectEnter(pDevIns, pDevIns->pCritSectRoR3, VERR_IGNORED);
5620 AssertRCReturn(rcLock, rcLock);
5621
5622 /*
5623 * Validate and adjust input.
5624 */
5625 Assert(uPort >= 1 && uPort <= pRh->cPortsImpl);
5626 iPort = ID_TO_IDX(uPort) + pRh->uPortBase;
5627 Assert(iPort < XHCI_NDP_CFG(pThis));
5628 pPort = &pThis->aPorts[iPort];
5629 Assert(!pThisCC->aPorts[iPort].fAttached);
5630 Assert(enmSpeed != VUSB_SPEED_UNKNOWN);
5631
5632 /*
5633 * Attach it.
5634 */
5635 ASMAtomicOrU32(&pPort->portsc, XHCI_PORT_CCS | XHCI_PORT_CSC);
5636 pThisCC->aPorts[iPort].fAttached = true;
5637 xhciR3PortPower(pThis, pThisCC, iPort, 1 /* power on */);
5638
5639 /* USB3 ports automatically transition to Enabled state. */
5640 if (IS_USB3_PORT_IDX_R3(pThisCC, iPort))
5641 {
5642 Assert(enmSpeed == VUSB_SPEED_SUPER);
5643 pPort->portsc |= XHCI_PORT_PED;
5644 pPort->portsc &= ~XHCI_PORT_PLS_MASK;
5645 pPort->portsc |= XHCI_PLS_U0 << XHCI_PORT_PLS_SHIFT;
5646 pPort->portsc &= ~XHCI_PORT_SPD_MASK;
5647 pPort->portsc |= XHCI_SPD_SUPER << XHCI_PORT_SPD_SHIFT;
5648 VUSBIRhDevReset(pRh->pIRhConn, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort),
5649 false, NULL /* sync */, NULL, PDMDevHlpGetVM(pDevIns));
5650 }
5651 else
5652 {
5653 Assert(enmSpeed == VUSB_SPEED_LOW || enmSpeed == VUSB_SPEED_FULL || enmSpeed == VUSB_SPEED_HIGH);
5654 pPort->portsc &= ~XHCI_PORT_SPD_MASK;
5655 pPort->portsc |= xhciR3UsbSpd2XhciSpd(enmSpeed) << XHCI_PORT_SPD_SHIFT;
5656 }
5657
5658 xhciR3GenPortChgEvent(pDevIns, pThis, IDX_TO_ID(iPort));
5659
5660 PDMDevHlpCritSectLeave(pDevIns, pDevIns->pCritSectRoR3);
5661 return VINF_SUCCESS;
5662}
5663
5664
5665/**
5666 * A device is being detached from a port in the root hub.
5667 *
5668 * @param pInterface Pointer to this structure.
5669 * @param uPort The 1-based port number assigned to the device.
5670 */
5671static DECLCALLBACK(void) xhciR3RhDetach(PVUSBIROOTHUBPORT pInterface, unsigned uPort)
5672{
5673 PXHCIROOTHUBR3 pRh = RT_FROM_MEMBER(pInterface, XHCIROOTHUBR3, IRhPort);
5674 PXHCICC pThisCC = pRh->pXhciR3;
5675 PPDMDEVINS pDevIns = pThisCC->pDevIns;
5676 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
5677 PXHCIHUBPORT pPort;
5678 unsigned iPort;
5679 LogFlow(("xhciR3RhDetach: uPort=%u iPort=%u\n", uPort, ID_TO_IDX(uPort) + pRh->uPortBase));
5680 int const rcLock = PDMDevHlpCritSectEnter(pDevIns, pDevIns->pCritSectRoR3, VERR_IGNORED);
5681 PDM_CRITSECT_RELEASE_ASSERT_RC_DEV(pDevIns, pDevIns->pCritSectRoR3, rcLock);
5682
5683 /*
5684 * Validate and adjust input.
5685 */
5686 Assert(uPort >= 1 && uPort <= pRh->cPortsImpl);
5687 iPort = ID_TO_IDX(uPort) + pRh->uPortBase;
5688 Assert(iPort < XHCI_NDP_CFG(pThis));
5689 pPort = &pThis->aPorts[iPort];
5690 Assert(pThisCC->aPorts[iPort].fAttached);
5691
5692 /*
5693 * Detach it.
5694 */
5695 pThisCC->aPorts[iPort].fAttached = false;
5696 ASMAtomicAndU32(&pPort->portsc, ~(XHCI_PORT_CCS | XHCI_PORT_SPD_MASK | XHCI_PORT_PLS_MASK));
5697 ASMAtomicOrU32(&pPort->portsc, XHCI_PORT_CSC);
5698 /* Link state goes to RxDetect. */
5699 ASMAtomicOrU32(&pPort->portsc, XHCI_PLS_RXDETECT << XHCI_PORT_PLS_SHIFT);
5700 /* Disconnect clears the port enable bit. */
5701 if (pPort->portsc & XHCI_PORT_PED)
5702 ASMAtomicAndU32(&pPort->portsc, ~XHCI_PORT_PED);
5703
5704 xhciR3GenPortChgEvent(pDevIns, pThis, IDX_TO_ID(iPort));
5705
5706 PDMDevHlpCritSectLeave(pDevIns, pDevIns->pCritSectRoR3);
5707}
5708
5709
5710/**
5711 * One of the root hub devices has completed its reset
5712 * operation.
5713 *
5714 * Currently, we don't think anything is required to be done here
5715 * so it's just a stub for forcing async resetting of the devices
5716 * during a root hub reset.
5717 *
5718 * @param pDev The root hub device.
5719 * @param rc The result of the operation.
5720 * @param uPort The port number of the device on the roothub being resetted.
5721 * @param pvUser Pointer to the controller.
5722 */
5723static DECLCALLBACK(void) xhciR3RhResetDoneOneDev(PVUSBIDEVICE pDev, uint32_t uPort, int rc, void *pvUser)
5724{
5725 LogRel(("xHCI: Root hub-attached device reset completed with %Rrc\n", rc));
5726 RT_NOREF(pDev, uPort, rc, pvUser);
5727}
5728
5729
5730/**
5731 * Does a software or hardware reset of the controller.
5732 *
5733 * This is called in response to setting HcCommandStatus.HCR, hardware reset,
5734 * and device construction.
5735 *
5736 * @param pThis The shared XHCI instance data
5737 * @param pThisCC The ring-3 XHCI instance data
5738 * @param fNewMode The new mode of operation. This is UsbSuspend if
5739 * it's a software reset, and UsbReset if it's a
5740 * hardware reset / cold boot.
5741 * @param fTrueReset Set if we can do a real reset of the devices
5742 * attached to the root hub. This is really a just a
5743 * hack for the non-working linux device reset. Linux
5744 * has this feature called 'logical disconnect' if
5745 * device reset fails which prevents us from doing
5746 * resets when the guest asks for it - the guest will
5747 * get confused when the device seems to be
5748 * reconnected everytime it tries to reset it. But if
5749 * we're at hardware reset time, we can allow a device
5750 * to be 'reconnected' without upsetting the guest.
5751 *
5752 * @remark This has nothing to do with software setting the
5753 * mode to UsbReset.
5754 */
5755static void xhciR3DoReset(PXHCI pThis, PXHCICC pThisCC, uint32_t fNewMode, bool fTrueReset)
5756{
5757 LogFunc(("%s reset%s\n", fNewMode == XHCI_USB_RESET ? "Hardware" : "Software",
5758 fTrueReset ? " (really reset devices)" : ""));
5759
5760 /*
5761 * Cancel all outstanding URBs.
5762 *
5763 * We can't, and won't, deal with URBs until we're moved out of the
5764 * suspend/reset state. Also, a real HC isn't going to send anything
5765 * any more when a reset has been signaled.
5766 */
5767 pThisCC->RootHub2.pIRhConn->pfnCancelAllUrbs(pThisCC->RootHub2.pIRhConn);
5768 pThisCC->RootHub3.pIRhConn->pfnCancelAllUrbs(pThisCC->RootHub3.pIRhConn);
5769
5770 /*
5771 * Reset the hardware registers.
5772 */
5773 /** @todo other differences between hardware reset and VM reset? */
5774
5775 pThis->cmd = 0;
5776 pThis->status = XHCI_STATUS_HCH;
5777 pThis->dnctrl = 0;
5778 pThis->crcr = 0;
5779 pThis->dcbaap = 0;
5780 pThis->config = 0;
5781
5782 /*
5783 * Reset the internal state.
5784 */
5785 pThis->cmdr_dqp = 0;
5786 pThis->cmdr_ccs = 0;
5787
5788 RT_ZERO(pThis->aSlotState);
5789 RT_ZERO(pThis->aBellsRung);
5790
5791 /* Zap everything but the lock. */
5792 for (unsigned i = 0; i < RT_ELEMENTS(pThis->aInterrupters); ++i)
5793 {
5794 pThis->aInterrupters[i].iman = 0;
5795 pThis->aInterrupters[i].imod = 0;
5796 pThis->aInterrupters[i].erstsz = 0;
5797 pThis->aInterrupters[i].erstba = 0;
5798 pThis->aInterrupters[i].erdp = 0;
5799 pThis->aInterrupters[i].erep = 0;
5800 pThis->aInterrupters[i].erst_idx = 0;
5801 pThis->aInterrupters[i].trb_count = 0;
5802 pThis->aInterrupters[i].evtr_pcs = false;
5803 pThis->aInterrupters[i].ipe = false;
5804 }
5805
5806 if (fNewMode == XHCI_USB_RESET)
5807 {
5808 /* Only a hardware reset reinits the port registers. */
5809 for (unsigned i = 0; i < XHCI_NDP_CFG(pThis); i++)
5810 {
5811 /* Need to preserve the speed of attached devices. */
5812 pThis->aPorts[i].portsc &= XHCI_PORT_SPD_MASK;
5813 pThis->aPorts[i].portsc |= XHCI_PLS_RXDETECT << XHCI_PORT_PLS_SHIFT;
5814 /* If Port Power Control is not supported, ports are always powered on. */
5815 if (!(pThis->hcc_params & XHCI_HCC_PPC))
5816 pThis->aPorts[i].portsc |= XHCI_PORT_PP;
5817 }
5818 }
5819
5820 /*
5821 * If this is a hardware reset, we will initialize the root hub too.
5822 * Software resets doesn't do this according to the specs.
5823 * (It's not possible to have a device connected at the time of the
5824 * device construction, so nothing to worry about there.)
5825 */
5826 if (fNewMode == XHCI_USB_RESET)
5827 {
5828 pThisCC->RootHub2.pIRhConn->pfnReset(pThisCC->RootHub2.pIRhConn, fTrueReset);
5829 pThisCC->RootHub3.pIRhConn->pfnReset(pThisCC->RootHub3.pIRhConn, fTrueReset);
5830
5831 /*
5832 * Reattach the devices.
5833 */
5834 for (unsigned i = 0; i < XHCI_NDP_CFG(pThis); i++)
5835 {
5836 bool fAttached = pThisCC->aPorts[i].fAttached;
5837 PXHCIROOTHUBR3 pRh = GET_PORT_PRH(pThisCC, i);
5838 pThisCC->aPorts[i].fAttached = false;
5839
5840 if (fAttached)
5841 {
5842 VUSBSPEED enmSpeed = VUSBIRhDevGetSpeed(pRh->pIRhConn, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, i));
5843 xhciR3RhAttach(&pRh->IRhPort, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, i), enmSpeed);
5844 }
5845 }
5846 }
5847}
5848
5849/**
5850 * Reset the root hub.
5851 *
5852 * @returns VBox status code.
5853 * @param pInterface Pointer to this structure.
5854 * @param fTrueReset This is used to indicate whether we're at VM reset
5855 * time and can do real resets or if we're at any other
5856 * time where that isn't such a good idea.
5857 * @remark Do NOT call VUSBIDevReset on the root hub in an async fashion!
5858 * @thread EMT
5859 */
5860static DECLCALLBACK(int) xhciR3RhReset(PVUSBIROOTHUBPORT pInterface, bool fTrueReset)
5861{
5862 PXHCIROOTHUBR3 pRh = RT_FROM_MEMBER(pInterface, XHCIROOTHUBR3, IRhPort);
5863 PXHCICC pThisCC = pRh->pXhciR3;
5864 PPDMDEVINS pDevIns = pThisCC->pDevIns;
5865 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
5866
5867 Log(("xhciR3RhReset fTrueReset=%d\n", fTrueReset));
5868 int const rcLock = PDMDevHlpCritSectEnter(pDevIns, pDevIns->pCritSectRoR3, VERR_IGNORED);
5869 AssertRCReturn(rcLock, rcLock);
5870
5871 /* Soft reset first */
5872 xhciR3DoReset(pThis, pThisCC, XHCI_USB_SUSPEND, false /* N/A */);
5873
5874 /*
5875 * We're pretending to _reattach_ the devices without resetting them.
5876 * Except, during VM reset where we use the opportunity to do a proper
5877 * reset before the guest comes along and expects things.
5878 *
5879 * However, it's very very likely that we're not doing the right thing
5880 * here when end up here on request from the guest (USB Reset state).
5881 * The docs talk about root hub resetting, however what exact behaviour
5882 * in terms of root hub status and changed bits, and HC interrupts aren't
5883 * stated clearly. IF we get trouble and see the guest doing "USB Resets"
5884 * we will have to look into this. For the time being we stick with simple.
5885 */
5886 for (unsigned iPort = pRh->uPortBase; iPort < XHCI_NDP_CFG(pThis); iPort++)
5887 {
5888 if (pThisCC->aPorts[iPort].fAttached)
5889 {
5890 ASMAtomicOrU32(&pThis->aPorts[iPort].portsc, XHCI_PORT_CCS | XHCI_PORT_CSC);
5891 if (fTrueReset)
5892 VUSBIRhDevReset(pRh->pIRhConn, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort), fTrueReset,
5893 xhciR3RhResetDoneOneDev, pDevIns, PDMDevHlpGetVM(pDevIns));
5894 }
5895 }
5896
5897 PDMDevHlpCritSectLeave(pDevIns, pDevIns->pCritSectRoR3);
5898 return VINF_SUCCESS;
5899}
5900
5901#endif /* IN_RING3 */
5902
5903
5904
5905/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
5906/* xHCI Operational Register access routines */
5907/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
5908
5909
5910
5911/**
5912 * Read the USBCMD register of the host controller.
5913 */
5914static VBOXSTRICTRC HcUsbcmd_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
5915{
5916 RT_NOREF(pDevIns, iReg);
5917 STAM_COUNTER_INC(&pThis->StatRdUsbCmd);
5918 *pu32Value = pThis->cmd;
5919 return VINF_SUCCESS;
5920}
5921
5922/**
5923 * Write to the USBCMD register of the host controller.
5924 */
5925static VBOXSTRICTRC HcUsbcmd_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
5926{
5927#ifdef IN_RING3
5928 PXHCICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PXHCICC);
5929#endif
5930 RT_NOREF(iReg);
5931 STAM_COUNTER_INC(&pThis->StatWrUsbCmd);
5932#ifdef LOG_ENABLED
5933 Log(("HcUsbcmd_w old=%x new=%x\n", pThis->cmd, val));
5934 if (val & XHCI_CMD_RS)
5935 Log((" XHCI_CMD_RS\n"));
5936 if (val & XHCI_CMD_HCRST)
5937 Log((" XHCI_CMD_HCRST\n"));
5938 if (val & XHCI_CMD_INTE )
5939 Log((" XHCI_CMD_INTE\n"));
5940 if (val & XHCI_CMD_HSEE)
5941 Log((" XHCI_CMD_HSEE\n"));
5942 if (val & XHCI_CMD_LCRST)
5943 Log((" XHCI_CMD_LCRST\n"));
5944 if (val & XHCI_CMD_CSS)
5945 Log((" XHCI_CMD_CSS\n"));
5946 if (val & XHCI_CMD_CRS)
5947 Log((" XHCI_CMD_CRS\n"));
5948 if (val & XHCI_CMD_EWE)
5949 Log((" XHCI_CMD_EWE\n"));
5950 if (val & XHCI_CMD_EU3S)
5951 Log((" XHCI_CMD_EU3S\n"));
5952#endif
5953
5954 if (val & ~XHCI_CMD_MASK)
5955 Log(("Unknown USBCMD bits %#x are set!\n", val & ~XHCI_CMD_MASK));
5956
5957 uint32_t old_cmd = pThis->cmd;
5958#ifdef IN_RING3
5959 pThis->cmd = val;
5960#endif
5961
5962 if (val & XHCI_CMD_HCRST)
5963 {
5964#ifdef IN_RING3
5965 LogRel(("xHCI: Hardware reset\n"));
5966 xhciR3DoReset(pThis, pThisCC, XHCI_USB_RESET, true /* reset devices */);
5967#else
5968 return VINF_IOM_R3_MMIO_WRITE;
5969#endif
5970 }
5971 else if (val & XHCI_CMD_LCRST)
5972 {
5973#ifdef IN_RING3
5974 LogRel(("xHCI: Software reset\n"));
5975 xhciR3DoReset(pThis, pThisCC, XHCI_USB_SUSPEND, false /* N/A */);
5976#else
5977 return VINF_IOM_R3_MMIO_WRITE;
5978#endif
5979 }
5980 else if (pThis->status & XHCI_STATUS_HCE)
5981 {
5982 /* If HCE is set, don't restart the controller. Only a reset
5983 * will clear the HCE bit.
5984 */
5985 Log(("xHCI: HCE bit set, ignoring USBCMD register changes!\n"));
5986 pThis->cmd = old_cmd;
5987 return VINF_SUCCESS;
5988 }
5989 else
5990 {
5991 /* See what changed and take action on that. First the R/S bit. */
5992 uint32_t old_state = old_cmd & XHCI_CMD_RS;
5993 uint32_t new_state = val & XHCI_CMD_RS;
5994
5995 if (old_state != new_state)
5996 {
5997#ifdef IN_RING3
5998 switch (new_state)
5999 {
6000 case XHCI_CMD_RS:
6001 LogRel(("xHCI: USB Operational\n"));
6002 xhciR3BusStart(pDevIns, pThis, pThisCC);
6003 break;
6004 case 0:
6005 xhciR3BusStop(pDevIns, pThis, pThisCC);
6006 LogRel(("xHCI: USB Suspended\n"));
6007 break;
6008 }
6009#else
6010 return VINF_IOM_R3_MMIO_WRITE;
6011#endif
6012 }
6013
6014 /* Check EWE (Enable MFINDEX Wraparound Event) changes. */
6015 old_state = old_cmd & XHCI_CMD_EWE;
6016 new_state = val & XHCI_CMD_EWE;
6017
6018 if (old_state != new_state)
6019 {
6020 switch (new_state)
6021 {
6022 case XHCI_CMD_EWE:
6023 Log(("xHCI: MFINDEX Wrap timer started\n"));
6024 xhciSetWrapTimer(pDevIns, pThis);
6025 break;
6026 case 0:
6027 PDMDevHlpTimerStop(pDevIns, pThis->hWrapTimer);
6028 Log(("xHCI: MFINDEX Wrap timer stopped\n"));
6029 break;
6030 }
6031 }
6032
6033 /* INTE transitions need to twiddle interrupts. */
6034 old_state = old_cmd & XHCI_CMD_INTE;
6035 new_state = val & XHCI_CMD_INTE;
6036 if (old_state != new_state)
6037 {
6038 switch (new_state)
6039 {
6040 case XHCI_CMD_INTE:
6041 /* Check whether the event interrupt bit is set and trigger an interrupt. */
6042 if (pThis->status & XHCI_STATUS_EINT)
6043 PDMDevHlpPCISetIrq(pDevIns, 0, PDM_IRQ_LEVEL_HIGH);
6044 break;
6045 case 0:
6046 PDMDevHlpPCISetIrq(pDevIns, 0, PDM_IRQ_LEVEL_LOW);
6047 break;
6048 }
6049 }
6050
6051 /* We currently do nothing for state save/restore. If we did, the CSS/CRS command bits
6052 * would set the SSS/RSS status bits until the operation is done. The CSS/CRS bits are
6053 * never read as one.
6054 */
6055 /// @todo 4.9.4 describes internal state that needs to be saved/restored:
6056 /// ERSTE, ERST Count, EREP, and TRB Count
6057 /// Command Ring Dequeue Pointer?
6058 if (val & XHCI_CMD_CSS)
6059 {
6060 Log(("xHCI: Save State requested\n"));
6061 val &= ~XHCI_CMD_CSS;
6062 }
6063
6064 if (val & XHCI_CMD_CRS)
6065 {
6066 Log(("xHCI: Restore State requested\n"));
6067 val &= ~XHCI_CMD_CRS;
6068 }
6069 }
6070#ifndef IN_RING3
6071 pThis->cmd = val;
6072#endif
6073 return VINF_SUCCESS;
6074}
6075
6076#ifdef LOG_ENABLED
6077static void HcUsbstsLogBits(uint32_t val)
6078{
6079 if (val & XHCI_STATUS_HCH)
6080 Log((" XHCI_STATUS_HCH (HC Halted)\n"));
6081 if (val & XHCI_STATUS_HSE)
6082 Log((" XHCI_STATUS_HSE (Host System Error)\n"));
6083 if (val & XHCI_STATUS_EINT)
6084 Log((" XHCI_STATUS_EINT (Event Interrupt)\n"));
6085 if (val & XHCI_STATUS_PCD)
6086 Log((" XHCI_STATUS_PCD (Port Change Detect)\n"));
6087 if (val & XHCI_STATUS_SSS)
6088 Log((" XHCI_STATUS_SSS (Save State Status)\n"));
6089 if (val & XHCI_STATUS_RSS)
6090 Log((" XHCI_STATUS_RSS (Restore State Status)\n"));
6091 if (val & XHCI_STATUS_SRE)
6092 Log((" XHCI_STATUS_SRE (Save/Restore Error)\n"));
6093 if (val & XHCI_STATUS_CNR)
6094 Log((" XHCI_STATUS_CNR (Controller Not Ready)\n"));
6095 if (val & XHCI_STATUS_HCE)
6096 Log((" XHCI_STATUS_HCE (Host Controller Error)\n"));
6097}
6098#endif
6099
6100/**
6101 * Read the USBSTS register of the host controller.
6102 */
6103static VBOXSTRICTRC HcUsbsts_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6104{
6105#ifdef LOG_ENABLED
6106 Log(("HcUsbsts_r current value %x\n", pThis->status));
6107 HcUsbstsLogBits(pThis->status);
6108#endif
6109 RT_NOREF(pDevIns, iReg);
6110 STAM_COUNTER_INC(&pThis->StatRdUsbSts);
6111
6112 *pu32Value = pThis->status;
6113 return VINF_SUCCESS;
6114}
6115
6116/**
6117 * Write to the USBSTS register of the host controller.
6118 */
6119static VBOXSTRICTRC HcUsbsts_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
6120{
6121#ifdef LOG_ENABLED
6122 Log(("HcUsbsts_w current value %x; new %x\n", pThis->status, val));
6123 HcUsbstsLogBits(val);
6124#endif
6125 RT_NOREF(pDevIns, iReg);
6126 STAM_COUNTER_INC(&pThis->StatWrUsbSts);
6127
6128 if ( (val & ~XHCI_STATUS_WRMASK)
6129 && val != 0xffffffff /* Ignore clear-all-like requests. */)
6130 Log(("Unknown USBSTS bits %#x are set!\n", val & ~XHCI_STATUS_WRMASK));
6131
6132 /* Most bits are read-only. */
6133 val &= XHCI_STATUS_WRMASK;
6134
6135 /* "The Host Controller Driver may clear specific bits in this
6136 * register by writing '1' to bit positions to be cleared"
6137 */
6138 ASMAtomicAndU32(&pThis->status, ~val);
6139
6140 return VINF_SUCCESS;
6141}
6142
6143/**
6144 * Read the PAGESIZE register of the host controller.
6145 */
6146static VBOXSTRICTRC HcPagesize_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6147{
6148 RT_NOREF(pDevIns, pThis, iReg);
6149 STAM_COUNTER_INC(&pThis->StatRdPageSize);
6150 *pu32Value = 1; /* 2^(bit n + 12) -> 4K page size only. */
6151 return VINF_SUCCESS;
6152}
6153
6154/**
6155 * Read the DNCTRL (Device Notification Control) register.
6156 */
6157static VBOXSTRICTRC HcDevNotifyCtrl_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6158{
6159 RT_NOREF(pDevIns, iReg);
6160 STAM_COUNTER_INC(&pThis->StatRdDevNotifyCtrl);
6161 *pu32Value = pThis->dnctrl;
6162 return VINF_SUCCESS;
6163}
6164
6165/**
6166 * Write the DNCTRL (Device Notification Control) register.
6167 */
6168static VBOXSTRICTRC HcDevNotifyCtrl_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
6169{
6170 RT_NOREF(pDevIns, iReg);
6171 STAM_COUNTER_INC(&pThis->StatWrDevNotifyCtrl);
6172 pThis->dnctrl = val;
6173 return VINF_SUCCESS;
6174}
6175
6176/**
6177 * Read the low dword of CRCR (Command Ring Control) register.
6178 */
6179static VBOXSTRICTRC HcCmdRingCtlLo_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6180{
6181 RT_NOREF(pDevIns, iReg);
6182 STAM_COUNTER_INC(&pThis->StatRdCmdRingCtlLo);
6183 *pu32Value = (uint32_t)(pThis->crcr & XHCI_CRCR_RD_MASK);
6184 return VINF_SUCCESS;
6185}
6186
6187/**
6188 * Write the low dword of CRCR (Command Ring Control) register.
6189 */
6190static VBOXSTRICTRC HcCmdRingCtlLo_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
6191{
6192 RT_NOREF(iReg);
6193 STAM_COUNTER_INC(&pThis->StatWrCmdRingCtlLo);
6194 /* NB: A dword write to the low half clears the high half. */
6195
6196 /* Sticky Abort/Stop bits - update register and kick the worker thread. */
6197 if (val & (XHCI_CRCR_CA | XHCI_CRCR_CS))
6198 {
6199 pThis->crcr |= val & (XHCI_CRCR_CA | XHCI_CRCR_CS);
6200 xhciKickWorker(pDevIns, pThis, XHCI_JOB_PROCESS_CMDRING, 0);
6201 }
6202
6203 /*
6204 * If the command ring is not running, the internal dequeue pointer
6205 * and the cycle state is updated. Otherwise the update is ignored.
6206 */
6207 if (!(pThis->crcr & XHCI_CRCR_CRR))
6208 {
6209 pThis->crcr = (pThis->crcr & ~XHCI_CRCR_UPD_MASK) | (val & XHCI_CRCR_UPD_MASK);
6210 /// @todo cmdr_dqp: atomic? volatile?
6211 pThis->cmdr_dqp = pThis->crcr & XHCI_CRCR_ADDR_MASK;
6212 pThis->cmdr_ccs = pThis->crcr & XHCI_CRCR_RCS;
6213 }
6214
6215 return VINF_SUCCESS;
6216}
6217
6218/**
6219 * Read the high dword of CRCR (Command Ring Control) register.
6220 */
6221static VBOXSTRICTRC HcCmdRingCtlHi_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6222{
6223 RT_NOREF(pDevIns, iReg);
6224 STAM_COUNTER_INC(&pThis->StatRdCmdRingCtlHi);
6225 *pu32Value = pThis->crcr >> 32;
6226 return VINF_SUCCESS;
6227}
6228
6229/**
6230 * Write the high dword of CRCR (Command Ring Control) register.
6231 */
6232static VBOXSTRICTRC HcCmdRingCtlHi_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
6233{
6234 RT_NOREF(pDevIns, iReg);
6235 STAM_COUNTER_INC(&pThis->StatWrCmdRingCtlHi);
6236 if (!(pThis->crcr & XHCI_CRCR_CRR))
6237 {
6238 pThis->crcr = ((uint64_t)val << 32) | (uint32_t)pThis->crcr;
6239 pThis->cmdr_dqp = pThis->crcr & XHCI_CRCR_ADDR_MASK;
6240 }
6241 return VINF_SUCCESS;
6242}
6243
6244/**
6245 * Read the low dword of the DCBAAP register.
6246 */
6247static VBOXSTRICTRC HcDevCtxBAAPLo_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6248{
6249 RT_NOREF(pDevIns, iReg);
6250 STAM_COUNTER_INC(&pThis->StatRdDevCtxBaapLo);
6251 *pu32Value = (uint32_t)pThis->dcbaap;
6252 return VINF_SUCCESS;
6253}
6254
6255/**
6256 * Write the low dword of the DCBAAP register.
6257 */
6258static VBOXSTRICTRC HcDevCtxBAAPLo_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
6259{
6260 RT_NOREF(pDevIns, iReg);
6261 STAM_COUNTER_INC(&pThis->StatWrDevCtxBaapLo);
6262 /* NB: A dword write to the low half clears the high half. */
6263 /// @todo Should this mask off the reserved bits?
6264 pThis->dcbaap = val;
6265 return VINF_SUCCESS;
6266}
6267
6268/**
6269 * Read the high dword of the DCBAAP register.
6270 */
6271static VBOXSTRICTRC HcDevCtxBAAPHi_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6272{
6273 RT_NOREF(pDevIns, iReg);
6274 STAM_COUNTER_INC(&pThis->StatRdDevCtxBaapHi);
6275 *pu32Value = pThis->dcbaap >> 32;
6276 return VINF_SUCCESS;
6277}
6278
6279/**
6280 * Write the high dword of the DCBAAP register.
6281 */
6282static VBOXSTRICTRC HcDevCtxBAAPHi_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
6283{
6284 RT_NOREF(pDevIns, iReg);
6285 STAM_COUNTER_INC(&pThis->StatWrDevCtxBaapHi);
6286 pThis->dcbaap = ((uint64_t)val << 32) | (uint32_t)pThis->dcbaap;
6287 return VINF_SUCCESS;
6288}
6289
6290/**
6291 * Read the CONFIG register.
6292 */
6293static VBOXSTRICTRC HcConfig_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value)
6294{
6295 RT_NOREF(pDevIns, iReg);
6296 STAM_COUNTER_INC(&pThis->StatRdConfig);
6297 *pu32Value = pThis->config;
6298 return VINF_SUCCESS;
6299}
6300
6301/**
6302 * Write the CONFIG register.
6303 */
6304static VBOXSTRICTRC HcConfig_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t val)
6305{
6306 RT_NOREF(pDevIns, iReg);
6307 STAM_COUNTER_INC(&pThis->StatWrConfig);
6308 /// @todo side effects?
6309 pThis->config = val;
6310 return VINF_SUCCESS;
6311}
6312
6313
6314
6315/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
6316/* xHCI Port Register access routines */
6317/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
6318
6319
6320
6321/**
6322 * Read the PORTSC register.
6323 */
6324static VBOXSTRICTRC HcPortStatusCtrl_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iPort, uint32_t *pu32Value)
6325{
6326 PXHCIHUBPORT p = &pThis->aPorts[iPort];
6327 RT_NOREF(pDevIns);
6328 STAM_COUNTER_INC(&pThis->StatRdPortStatusCtrl);
6329
6330 Assert(!(pThis->hcc_params & XHCI_HCC_PPC));
6331
6332 if (p->portsc & XHCI_PORT_PR)
6333 {
6334/// @todo Probably not needed?
6335#ifdef IN_RING3
6336 Log2(("HcPortStatusCtrl_r(): port %u: Impatient guest!\n", IDX_TO_ID(iPort)));
6337 RTThreadYield();
6338#else
6339 Log2(("HcPortStatusCtrl_r: yield -> VINF_IOM_R3_MMIO_READ\n"));
6340 return VINF_IOM_R3_MMIO_READ;
6341#endif
6342 }
6343
6344 /* The WPR bit is always read as zero. */
6345 *pu32Value = p->portsc & ~XHCI_PORT_WPR;
6346 return VINF_SUCCESS;
6347}
6348
6349/**
6350 * Write the PORTSC register.
6351 */
6352static VBOXSTRICTRC HcPortStatusCtrl_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iPort, uint32_t val)
6353{
6354 PXHCIHUBPORT p = &pThis->aPorts[iPort];
6355#ifdef IN_RING3
6356 PXHCICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PXHCICC);
6357#endif
6358 STAM_COUNTER_INC(&pThis->StatWrPortStatusCtrl);
6359
6360 /* If no register change results, we're done. */
6361 if ( p->portsc == val
6362 && !(val & XHCI_PORT_CHANGE_MASK))
6363 return VINF_SUCCESS;
6364
6365 /* If port state is not changing (status bits are being cleared etc.), we can do it in any context.
6366 * This case occurs when the R/W control bits are not changing and the W1C bits are not being set.
6367 */
6368 if ( (p->portsc & XHCI_PORT_CTL_RW_MASK) == (val & XHCI_PORT_CTL_RW_MASK)
6369 && !(val & XHCI_PORT_CTL_W1_MASK))
6370 {
6371 Log(("HcPortStatusCtrl_w port %u (status only): old=%x new=%x\n", IDX_TO_ID(iPort), p->portsc, val));
6372
6373 if (val & XHCI_PORT_RESERVED)
6374 Log(("Reserved bits set %x!\n", val & XHCI_PORT_RESERVED));
6375
6376 /* A write to clear any of the change notification bits. */
6377 if (val & XHCI_PORT_CHANGE_MASK)
6378 p->portsc &= ~(val & XHCI_PORT_CHANGE_MASK);
6379
6380 /* Update the wake mask. */
6381 p->portsc &= ~XHCI_PORT_WAKE_MASK;
6382 p->portsc |= val & XHCI_PORT_WAKE_MASK;
6383
6384 /* There may still be differences between 'portsc' and 'val' in
6385 * the R/O bits; that does not count as a register change and is fine.
6386 * The RW1x control bits are not considered either since those only matter
6387 * if set in 'val'. Since the LWS bit was not set, the PLS bits should not
6388 * be compared. The port change bits may differ as well since the guest
6389 * could be clearing only some or none of them.
6390 */
6391 AssertMsg(!(val & XHCI_PORT_CTL_W1_MASK), ("val=%X\n", val));
6392 AssertMsg(!(val & XHCI_PORT_LWS), ("val=%X\n", val));
6393 AssertMsg((val & ~(XHCI_PORT_RO_MASK|XHCI_PORT_CTL_W1_MASK|XHCI_PORT_PLS_MASK|XHCI_PORT_CHANGE_MASK)) == (p->portsc & ~(XHCI_PORT_RO_MASK|XHCI_PORT_CTL_W1_MASK|XHCI_PORT_PLS_MASK|XHCI_PORT_CHANGE_MASK)), ("val=%X vs. portsc=%X\n", val, p->portsc));
6394 return VINF_SUCCESS;
6395 }
6396
6397 /* Actual USB port state changes need to be done in R3. */
6398#ifdef IN_RING3
6399 Log(("HcPortStatusCtrl_w port %u: old=%x new=%x\n", IDX_TO_ID(iPort), p->portsc, val));
6400 Assert(!(pThis->hcc_params & XHCI_HCC_PPC));
6401 Assert(p->portsc & XHCI_PORT_PP);
6402
6403 if (val & XHCI_PORT_RESERVED)
6404 Log(("Reserved bits set %x!\n", val & XHCI_PORT_RESERVED));
6405
6406 /* A write to clear any of the change notification bits. */
6407 if (val & XHCI_PORT_CHANGE_MASK)
6408 p->portsc &= ~(val & XHCI_PORT_CHANGE_MASK);
6409
6410 /* Writing the Port Enable/Disable bit as 1 disables a port; it cannot be
6411 * enabled that way. Writing the bit as zero does does nothing.
6412 */
6413 if ((val & XHCI_PORT_PED) && (p->portsc & XHCI_PORT_PED))
6414 {
6415 p->portsc &= ~XHCI_PORT_PED;
6416 Log(("HcPortStatusCtrl_w(): port %u: DISABLE\n", IDX_TO_ID(iPort)));
6417 }
6418
6419 if (!(val & XHCI_PORT_PP) && (p->portsc & XHCI_PORT_PP))
6420 {
6421 p->portsc &= ~XHCI_PORT_PP;
6422 Log(("HcPortStatusCtrl_w(): port %u: POWER OFF\n", IDX_TO_ID(iPort)));
6423 }
6424
6425 /* Warm Port Reset - USB3 only; see 4.19.5.1. */
6426 if ((val & XHCI_PORT_WPR) && IS_USB3_PORT_IDX_SHR(pThis, iPort))
6427 {
6428 Log(("HcPortStatusCtrl_w(): port %u: WARM RESET\n", IDX_TO_ID(iPort)));
6429 if (xhciR3RhPortSetIfConnected(pThis, iPort, XHCI_PORT_PR | XHCI_PORT_WPR))
6430 {
6431 PXHCIROOTHUBR3 pRh = GET_PORT_PRH(pThisCC, iPort);
6432
6433 VUSBIRhDevReset(pRh->pIRhConn, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort), false /* don't reset on linux */, NULL /* sync */, NULL, PDMDevHlpGetVM(pDevIns));
6434 xhciR3PortResetDone(pDevIns, iPort);
6435 }
6436 }
6437
6438 if (val & XHCI_PORT_PR)
6439 {
6440 Log(("HcPortStatusCtrl_w(): port %u: RESET\n", IDX_TO_ID(iPort)));
6441 if (xhciR3RhPortSetIfConnected(pThis, iPort, XHCI_PORT_PR))
6442 {
6443 PXHCIROOTHUBR3 pRh = GET_PORT_PRH(pThisCC, iPort);
6444
6445 VUSBIRhDevReset(pRh->pIRhConn, GET_VUSB_PORT_FROM_XHCI_PORT(pRh, iPort), false /* don't reset on linux */, NULL /* sync */, NULL, PDMDevHlpGetVM(pDevIns));
6446 xhciR3PortResetDone(pDevIns, iPort);
6447 }
6448 else if (p->portsc & XHCI_PORT_PR)
6449 {
6450 /* the guest is getting impatient. */
6451 Log2(("HcPortStatusCtrl_w(): port %u: Impatient guest!\n", IDX_TO_ID(iPort)));
6452 RTThreadYield();
6453 }
6454 }
6455
6456 /// @todo Do some sanity checking on the new link state?
6457 /* Update the link state if requested. */
6458 if (val & XHCI_PORT_LWS)
6459 {
6460 unsigned old_pls;
6461 unsigned new_pls;
6462
6463 old_pls = (p->portsc & XHCI_PORT_PLS_MASK) >> XHCI_PORT_PLS_SHIFT;
6464 new_pls = (val & XHCI_PORT_PLS_MASK) >> XHCI_PORT_PLS_SHIFT;
6465
6466 p->portsc &= ~XHCI_PORT_PLS_MASK;
6467 p->portsc |= new_pls << XHCI_PORT_PLS_SHIFT;
6468 Log2(("HcPortStatusCtrl_w(): port %u: Updating link state from %u to %u\n", IDX_TO_ID(iPort), old_pls, new_pls));
6469 /* U3->U0 (USB3) and Resume->U0 transitions set the PLC flag. See 4.15.2.2 */
6470 if (new_pls == XHCI_PLS_U0)
6471 if (old_pls == XHCI_PLS_U3 || old_pls == XHCI_PLS_RESUME)
6472 {
6473 p->portsc |= XHCI_PORT_PLC;
6474 xhciR3GenPortChgEvent(pDevIns, pThis, IDX_TO_ID(iPort));
6475 }
6476 }
6477
6478 /// @todo which other bits can we safely ignore?
6479
6480 /* Update the wake mask. */
6481 p->portsc &= ~XHCI_PORT_WAKE_MASK;
6482 p->portsc |= val & XHCI_PORT_WAKE_MASK;
6483
6484 return VINF_SUCCESS;
6485#else /* !IN_RING3 */
6486 RT_NOREF(pDevIns);
6487 return VINF_IOM_R3_MMIO_WRITE;
6488#endif /* !IN_RING3 */
6489}
6490
6491
6492/**
6493 * Read the PORTPMSC register.
6494 */
6495static VBOXSTRICTRC HcPortPowerMgmt_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iPort, uint32_t *pu32Value)
6496{
6497 PXHCIHUBPORT p = &pThis->aPorts[iPort];
6498 RT_NOREF(pDevIns);
6499 STAM_COUNTER_INC(&pThis->StatRdPortPowerMgmt);
6500
6501 *pu32Value = p->portpm;
6502 return VINF_SUCCESS;
6503}
6504
6505
6506/**
6507 * Write the PORTPMSC register.
6508 */
6509static VBOXSTRICTRC HcPortPowerMgmt_w(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iPort, uint32_t val)
6510{
6511 PXHCIHUBPORT p = &pThis->aPorts[iPort];
6512 RT_NOREF(pDevIns);
6513 STAM_COUNTER_INC(&pThis->StatWrPortPowerMgmt);
6514
6515 /// @todo anything to do here?
6516 p->portpm = val;
6517 return VINF_SUCCESS;
6518}
6519
6520
6521/**
6522 * Read the PORTLI register.
6523 */
6524static VBOXSTRICTRC HcPortLinkInfo_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iPort, uint32_t *pu32Value)
6525{
6526 PXHCIHUBPORT p = &pThis->aPorts[iPort];
6527 RT_NOREF(pDevIns);
6528 STAM_COUNTER_INC(&pThis->StatRdPortLinkInfo);
6529
6530 /* The link information is R/O; we probably can't get it at all. If we
6531 * do maintain it for USB3 ports, we also have to reset it (5.4.10).
6532 */
6533 *pu32Value = p->portli;
6534 return VINF_SUCCESS;
6535}
6536
6537/**
6538 * Read the reserved register. Linux likes to do this.
6539 */
6540static VBOXSTRICTRC HcPortRsvd_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iPort, uint32_t *pu32Value)
6541{
6542 RT_NOREF(pDevIns, pThis, iPort);
6543 STAM_COUNTER_INC(&pThis->StatRdPortRsvd);
6544 *pu32Value = 0;
6545 return VINF_SUCCESS;
6546}
6547
6548
6549
6550/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
6551/* xHCI Interrupter Register access routines */
6552/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
6553
6554
6555
6556/**
6557 * Read the IMAN register.
6558 */
6559static VBOXSTRICTRC HcIntrMgmt_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6560{
6561 RT_NOREF(pDevIns, pThis);
6562 STAM_COUNTER_INC(&pThis->StatRdIntrMgmt);
6563
6564 *pu32Value = ip->iman;
6565 return VINF_SUCCESS;
6566}
6567
6568/**
6569 * Write the IMAN register.
6570 */
6571static VBOXSTRICTRC HcIntrMgmt_w(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t val)
6572{
6573 uint32_t uNew = val & XHCI_IMAN_VALID_MASK;
6574 STAM_COUNTER_INC(&pThis->StatWrIntrMgmt);
6575
6576 if (val & ~XHCI_IMAN_VALID_MASK)
6577 Log(("Reserved bits set %x!\n", val & ~XHCI_IMAN_VALID_MASK));
6578
6579 /* If the Interrupt Pending (IP) bit is set, writing one clears it.
6580 * Note that when MSIs are enabled, the bit auto-clears almost immediately.
6581 */
6582 if (val & ip->iman & XHCI_IMAN_IP)
6583 {
6584 Log2(("clearing interrupt on interrupter %u\n", ip->index));
6585 PDMDevHlpPCISetIrq(pDevIns, 0, PDM_IRQ_LEVEL_LOW);
6586 STAM_COUNTER_INC(&pThis->StatIntrsCleared);
6587 uNew &= ~XHCI_IMAN_IP;
6588 }
6589 else
6590 {
6591 /* Preserve the current IP bit. */
6592 uNew = (uNew & ~XHCI_IMAN_IP) | (ip->iman & XHCI_IMAN_IP);
6593 }
6594
6595 /* Trigger an interrupt if the IP bit is set and IE transitions from 0 to 1. */
6596 if ( (uNew & XHCI_IMAN_IE)
6597 && !(ip->iman & XHCI_IMAN_IE)
6598 && (ip->iman & XHCI_IMAN_IP)
6599 && (pThis->cmd & XHCI_CMD_INTE))
6600 PDMDevHlpPCISetIrq(pDevIns, 0, PDM_IRQ_LEVEL_HIGH);
6601
6602 ip->iman = uNew;
6603 return VINF_SUCCESS;
6604}
6605
6606/**
6607 * Read the IMOD register.
6608 */
6609static VBOXSTRICTRC HcIntrMod_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6610{
6611 RT_NOREF(pDevIns, pThis);
6612 STAM_COUNTER_INC(&pThis->StatRdIntrMod);
6613
6614 *pu32Value = ip->imod;
6615 return VINF_SUCCESS;
6616}
6617
6618/**
6619 * Write the IMOD register.
6620 */
6621static VBOXSTRICTRC HcIntrMod_w(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t val)
6622{
6623 RT_NOREF(pDevIns, pThis);
6624 STAM_COUNTER_INC(&pThis->StatWrIntrMod);
6625
6626 /// @todo Does writing a zero to IMODC/IMODI potentially trigger
6627 /// an interrupt?
6628 ip->imod = val;
6629 return VINF_SUCCESS;
6630}
6631
6632/**
6633 * Read the ERSTSZ register.
6634 */
6635static VBOXSTRICTRC HcEvtRSTblSize_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6636{
6637 RT_NOREF(pDevIns, pThis);
6638 STAM_COUNTER_INC(&pThis->StatRdEvtRstblSize);
6639
6640 *pu32Value = ip->erstsz;
6641 return VINF_SUCCESS;
6642}
6643
6644/**
6645 * Write the ERSTSZ register.
6646 */
6647static VBOXSTRICTRC HcEvtRSTblSize_w(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t val)
6648{
6649 RT_NOREF(pDevIns, pThis);
6650 STAM_COUNTER_INC(&pThis->StatWrEvtRstblSize);
6651
6652 if (val & ~XHCI_ERSTSZ_MASK)
6653 Log(("Reserved bits set %x!\n", val & ~XHCI_ERSTSZ_MASK));
6654 if (val > XHCI_ERSTMAX)
6655 Log(("ERSTSZ (%u) > ERSTMAX (%u)!\n", val, XHCI_ERSTMAX));
6656
6657 /* Enforce the maximum size. */
6658 ip->erstsz = RT_MIN(val, XHCI_ERSTMAX);
6659
6660 if (!ip->index && !ip->erstsz) /* Windows 8 does this temporarily. Thanks guys... */
6661 Log(("ERSTSZ is zero for primary interrupter: undefined behavior!\n"));
6662
6663 return VINF_SUCCESS;
6664}
6665
6666/**
6667 * Read the reserved register. Linux likes to do this.
6668 */
6669static VBOXSTRICTRC HcEvtRsvd_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6670{
6671 RT_NOREF(pDevIns, pThis, ip);
6672 STAM_COUNTER_INC(&pThis->StatRdEvtRsvd);
6673 *pu32Value = 0;
6674 return VINF_SUCCESS;
6675}
6676
6677/**
6678 * Read the low dword of the ERSTBA register.
6679 */
6680static VBOXSTRICTRC HcEvtRSTblBaseLo_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6681{
6682 RT_NOREF(pDevIns, pThis);
6683 STAM_COUNTER_INC(&pThis->StatRdEvtRsTblBaseLo);
6684
6685 *pu32Value = (uint32_t)ip->erstba;
6686 return VINF_SUCCESS;
6687}
6688
6689
6690/**
6691 * Write the low dword of the ERSTBA register.
6692 */
6693static VBOXSTRICTRC HcEvtRSTblBaseLo_w(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t val)
6694{
6695 STAM_COUNTER_INC(&pThis->StatWrEvtRsTblBaseLo);
6696
6697 if (val & ~pThis->erst_addr_mask)
6698 Log(("Reserved bits set %x!\n", val & ~pThis->erst_addr_mask));
6699
6700 /* NB: A dword write to the low half clears the high half. */
6701 ip->erstba = val & pThis->erst_addr_mask;
6702
6703 /* Initialize the internal event ring state. */
6704 ip->evtr_pcs = 1;
6705 ip->erst_idx = 0;
6706 ip->ipe = false;
6707
6708 /* Fetch the first ERST entry now. Not later! That "sets the Event Ring
6709 * State Machine:EREP Advancement to the Start state"
6710 */
6711 xhciFetchErstEntry(pDevIns, pThis, ip);
6712
6713 return VINF_SUCCESS;
6714}
6715
6716/**
6717 * Read the high dword of the ERSTBA register.
6718 */
6719static VBOXSTRICTRC HcEvtRSTblBaseHi_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6720{
6721 RT_NOREF(pDevIns, pThis);
6722 STAM_COUNTER_INC(&pThis->StatRdEvtRsTblBaseHi);
6723
6724 *pu32Value = (uint32_t)(ip->erstba >> 32);
6725 return VINF_SUCCESS;
6726}
6727
6728/**
6729 * Write the high dword of the ERSTBA register.
6730 */
6731static VBOXSTRICTRC HcEvtRSTblBaseHi_w(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t val)
6732{
6733 STAM_COUNTER_INC(&pThis->StatWrEvtRsTblBaseHi);
6734
6735 /* Update the high dword while preserving the low one. */
6736 ip->erstba = ((uint64_t)val << 32) | (uint32_t)ip->erstba;
6737
6738 /* We shouldn't be doing this when AC64 is set. But High Sierra
6739 * ignores that because it "knows" the xHC handles 64-bit addressing,
6740 * so we're going to assume that OSes are not going to write junk into
6741 * ERSTBAH when they don't see AC64 set.
6742 */
6743 xhciFetchErstEntry(pDevIns, pThis, ip);
6744
6745 return VINF_SUCCESS;
6746}
6747
6748
6749/**
6750 * Read the low dword of the ERDP register.
6751 */
6752static VBOXSTRICTRC HcEvtRingDeqPtrLo_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6753{
6754 RT_NOREF(pThis);
6755 STAM_COUNTER_INC(&pThis->StatRdEvtRingDeqPtrLo);
6756
6757 /* Lock to avoid incomplete update being seen. */
6758 int rc = PDMDevHlpCritSectEnter(pDevIns, &ip->lock, VINF_IOM_R3_MMIO_READ);
6759 if (rc != VINF_SUCCESS)
6760 return rc;
6761
6762 *pu32Value = (uint32_t)ip->erdp;
6763
6764 PDMDevHlpCritSectLeave(pDevIns, &ip->lock);
6765
6766 return VINF_SUCCESS;
6767}
6768
6769/**
6770 * Write the low dword of the ERDP register.
6771 */
6772static VBOXSTRICTRC HcEvtRingDeqPtrLo_w(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t val)
6773{
6774 uint64_t old_erdp;
6775 uint64_t new_erdp;
6776 STAM_COUNTER_INC(&pThis->StatWrEvtRingDeqPtrLo);
6777
6778 /* NB: A dword write to the low half clears the high half.
6779 * The high dword should be ignored when AC64=0, but High Sierra
6780 * does not care what we report. Therefore a write to the low dword
6781 * handles all the control bits and a write to the high dword still
6782 * updates the ERDP address. On a 64-bit host, there must be a
6783 * back-to-back low dword + high dword access. We are going to boldly
6784 * assume that the guest will not place the event ring across the 4G
6785 * boundary (i.e. storing the bottom part in the firmware ROM).
6786 */
6787 int rc = PDMDevHlpCritSectEnter(pDevIns, &ip->lock, VINF_IOM_R3_MMIO_WRITE);
6788 if (rc != VINF_SUCCESS)
6789 return rc;
6790
6791 old_erdp = ip->erdp & XHCI_ERDP_ADDR_MASK; /* Remember old ERDP address. */
6792 new_erdp = ip->erdp & XHCI_ERDP_EHB; /* Preserve EHB */
6793
6794 /* If the Event Handler Busy (EHB) bit is set, writing a one clears it. */
6795 if (val & ip->erdp & XHCI_ERDP_EHB)
6796 {
6797 Log2(("clearing EHB on interrupter %p\n", ip));
6798 new_erdp &= ~XHCI_ERDP_EHB;
6799 }
6800 /// @todo Check if this might inadvertently set EHB!
6801
6802 new_erdp |= val & ~XHCI_ERDP_EHB;
6803 ip->erdp = new_erdp;
6804
6805 /* Check if the ERDP changed. See workaround below. */
6806 if (old_erdp != (new_erdp & XHCI_ERDP_ADDR_MASK))
6807 ip->erdp_rewrites = 0;
6808 else
6809 ++ip->erdp_rewrites;
6810
6811 LogFlowFunc(("ERDP: %RGp, EREP: %RGp\n", (RTGCPHYS)(ip->erdp & XHCI_ERDP_ADDR_MASK), (RTGCPHYS)ip->erep));
6812
6813 if ((ip->erdp & XHCI_ERDP_ADDR_MASK) == ip->erep)
6814 {
6815 Log2(("Event Ring empty, clearing IPE\n"));
6816 ip->ipe = false;
6817 }
6818 else if (ip->ipe && (val & XHCI_ERDP_EHB))
6819 {
6820 /* EHB is being cleared but the ring isn't empty and IPE is still set. */
6821 if (RT_UNLIKELY(old_erdp == (new_erdp & XHCI_ERDP_ADDR_MASK) && ip->erdp_rewrites > 2))
6822 {
6823 /* If guest does not advance the ERDP, do not trigger an interrupt
6824 * again. Workaround for buggy xHCI initialization in Linux 4.6 which
6825 * enables interrupts before setting up internal driver state. That
6826 * leads to the guest IRQ handler not actually handling events and
6827 * infinitely re-triggering interrupts. However, only do this if the
6828 * guest has already written the same ERDP value a few times. The Intel
6829 * xHCI driver always writes the same ERDP twice and we must still
6830 * re-trigger interrupts in that case.
6831 * See @bugref{8546}.
6832 */
6833 Log2(("Event Ring not empty, ERDP not advanced, not re-triggering interrupt!\n"));
6834 ip->ipe = false;
6835 }
6836 else
6837 {
6838 Log2(("Event Ring not empty, re-triggering interrupt\n"));
6839 xhciSetIntr(pDevIns, pThis, ip);
6840 }
6841 }
6842
6843 PDMDevHlpCritSectLeave(pDevIns, &ip->lock);
6844
6845 return VINF_SUCCESS;
6846}
6847
6848/**
6849 * Read the high dword of the ERDP register.
6850 */
6851static VBOXSTRICTRC HcEvtRingDeqPtrHi_r(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t *pu32Value)
6852{
6853 RT_NOREF(pDevIns, pThis);
6854 STAM_COUNTER_INC(&pThis->StatRdEvtRingDeqPtrHi);
6855
6856 *pu32Value = (uint32_t)(ip->erdp >> 32);
6857 return VINF_SUCCESS;
6858}
6859
6860/**
6861 * Write the high dword of the ERDP register.
6862 */
6863static VBOXSTRICTRC HcEvtRingDeqPtrHi_w(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR ip, uint32_t val)
6864{
6865 RT_NOREF(pThis);
6866 STAM_COUNTER_INC(&pThis->StatWrEvtRingDeqPtrHi);
6867
6868 /* See HcEvtRingDeqPtrLo_w for semantics. */
6869 int rc = PDMDevHlpCritSectEnter(pDevIns, &ip->lock, VINF_IOM_R3_MMIO_WRITE);
6870 if (rc != VINF_SUCCESS)
6871 return rc;
6872
6873 /* Update the high dword while preserving the low one. */
6874 ip->erdp = ((uint64_t)val << 32) | (uint32_t)ip->erdp;
6875
6876 PDMDevHlpCritSectLeave(pDevIns, &ip->lock);
6877
6878 return VINF_SUCCESS;
6879}
6880
6881
6882/**
6883 * xHCI register access routines.
6884 */
6885typedef struct
6886{
6887 const char *pszName;
6888 VBOXSTRICTRC (*pfnRead )(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t *pu32Value);
6889 VBOXSTRICTRC (*pfnWrite)(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t iReg, uint32_t u32Value);
6890} XHCIREGACC;
6891
6892/**
6893 * xHCI interrupter register access routines.
6894 */
6895typedef struct
6896{
6897 const char *pszName;
6898 VBOXSTRICTRC (*pfnIntrRead )(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR pIntr, uint32_t *pu32Value);
6899 VBOXSTRICTRC (*pfnIntrWrite)(PPDMDEVINS pDevIns, PXHCI pThis, PXHCIINTRPTR pIntr, uint32_t u32Value);
6900} XHCIINTRREGACC;
6901
6902/**
6903 * Operational registers descriptor table.
6904 */
6905static const XHCIREGACC g_aOpRegs[] =
6906{
6907 {"USBCMD" , HcUsbcmd_r, HcUsbcmd_w },
6908 {"USBSTS", HcUsbsts_r, HcUsbsts_w },
6909 {"PAGESIZE", HcPagesize_r, NULL },
6910 {"Unused", NULL, NULL },
6911 {"Unused", NULL, NULL },
6912 {"DNCTRL", HcDevNotifyCtrl_r, HcDevNotifyCtrl_w },
6913 {"CRCRL", HcCmdRingCtlLo_r, HcCmdRingCtlLo_w },
6914 {"CRCRH", HcCmdRingCtlHi_r, HcCmdRingCtlHi_w },
6915 {"Unused", NULL, NULL },
6916 {"Unused", NULL, NULL },
6917 {"Unused", NULL, NULL },
6918 {"Unused", NULL, NULL },
6919 {"DCBAAPL", HcDevCtxBAAPLo_r, HcDevCtxBAAPLo_w },
6920 {"DCBAAPH", HcDevCtxBAAPHi_r, HcDevCtxBAAPHi_w },
6921 {"CONFIG", HcConfig_r, HcConfig_w }
6922};
6923
6924
6925/**
6926 * Port registers descriptor table (for a single port). The number of ports
6927 * and their associated registers depends on the NDP value.
6928 */
6929static const XHCIREGACC g_aPortRegs[] =
6930{
6931 /*
6932 */
6933 {"PORTSC", HcPortStatusCtrl_r, HcPortStatusCtrl_w },
6934 {"PORTPMSC", HcPortPowerMgmt_r, HcPortPowerMgmt_w },
6935 {"PORTLI", HcPortLinkInfo_r, NULL },
6936 {"Reserved", HcPortRsvd_r, NULL }
6937};
6938AssertCompile(RT_ELEMENTS(g_aPortRegs) * sizeof(uint32_t) == 0x10);
6939
6940
6941/**
6942 * Interrupter runtime registers descriptor table (for a single interrupter).
6943 * The number of interrupters depends on the XHCI_NINTR value.
6944 */
6945static const XHCIINTRREGACC g_aIntrRegs[] =
6946{
6947 {"IMAN", HcIntrMgmt_r, HcIntrMgmt_w },
6948 {"IMOD", HcIntrMod_r, HcIntrMod_w },
6949 {"ERSTSZ", HcEvtRSTblSize_r, HcEvtRSTblSize_w },
6950 {"Reserved", HcEvtRsvd_r, NULL },
6951 {"ERSTBAL", HcEvtRSTblBaseLo_r, HcEvtRSTblBaseLo_w },
6952 {"ERSTBAH", HcEvtRSTblBaseHi_r, HcEvtRSTblBaseHi_w },
6953 {"ERDPL", HcEvtRingDeqPtrLo_r, HcEvtRingDeqPtrLo_w },
6954 {"ERDPH", HcEvtRingDeqPtrHi_r, HcEvtRingDeqPtrHi_w }
6955};
6956AssertCompile(RT_ELEMENTS(g_aIntrRegs) * sizeof(uint32_t) == 0x20);
6957
6958
6959/**
6960 * Read the MFINDEX register.
6961 */
6962static int HcMfIndex_r(PPDMDEVINS pDevIns, PXHCI pThis, uint32_t *pu32Value)
6963{
6964 uint64_t uNanoTime;
6965 uint64_t uMfTime;
6966 STAM_COUNTER_INC(&pThis->StatRdMfIndex);
6967
6968 /* MFINDEX increments once per micro-frame, i.e. 8 times per millisecond
6969 * or every 125us. The resolution is only 14 bits, meaning that MFINDEX
6970 * wraps around after it reaches 0x3FFF (16383) or every 2048 milliseconds.
6971 */
6972 /// @todo MFINDEX should only be running when R/S is set. May not matter.
6973 uNanoTime = PDMDevHlpTimerGet(pDevIns, pThis->hWrapTimer);
6974 uMfTime = uNanoTime / 125000;
6975
6976 *pu32Value = uMfTime & 0x3FFF;
6977 Log2(("MFINDEX read: %u\n", *pu32Value));
6978 return VINF_SUCCESS;
6979}
6980
6981/**
6982 * @callback_method_impl{FNIOMMMIONEWREAD, Read a MMIO register.}
6983 *
6984 * @note We only accept 32-bit writes that are 32-bit aligned.
6985 */
6986static DECLCALLBACK(VBOXSTRICTRC) xhciMmioRead(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS off, void *pv, unsigned cb)
6987{
6988 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
6989 const uint32_t offReg = (uint32_t)off;
6990 uint32_t * const pu32 = (uint32_t *)pv;
6991 uint32_t iReg;
6992 RT_NOREF(pvUser);
6993
6994 Log2(("xhciRead %RGp (offset %04X) size=%d\n", off, offReg, cb));
6995
6996 if (offReg < XHCI_CAPS_REG_SIZE)
6997 {
6998 switch (offReg)
6999 {
7000 case 0x0: /* CAPLENGTH + HCIVERSION */
7001 *pu32 = (pThis->hci_version << 16) | pThis->cap_length;
7002 break;
7003
7004 case 0x4: /* HCSPARAMS1 (structural) */
7005 Log2(("HCSPARAMS1 read\n"));
7006 *pu32 = pThis->hcs_params1;
7007 break;
7008
7009 case 0x8: /* HCSPARAMS2 (structural) */
7010 Log2(("HCSPARAMS2 read\n"));
7011 *pu32 = pThis->hcs_params2;
7012 break;
7013
7014 case 0xC: /* HCSPARAMS3 (structural) */
7015 Log2(("HCSPARAMS3 read\n"));
7016 *pu32 = pThis->hcs_params3;
7017 break;
7018
7019 case 0x10: /* HCCPARAMS1 (caps) */
7020 Log2(("HCCPARAMS1 read\n"));
7021 *pu32 = pThis->hcc_params;
7022 break;
7023
7024 case 0x14: /* DBOFF (doorbell offset) */
7025 Log2(("DBOFF read\n"));
7026 *pu32 = pThis->dbell_off;
7027 break;
7028
7029 case 0x18: /* RTSOFF (run-time register offset) */
7030 Log2(("RTSOFF read\n"));
7031 *pu32 = pThis->rts_off;
7032 break;
7033
7034 case 0x1C: /* HCCPARAMS2 (caps) */
7035 Log2(("HCCPARAMS2 read\n"));
7036 *pu32 = 0; /* xHCI 1.1 only */
7037 break;
7038
7039 default:
7040 Log(("xHCI: Trying to read unknown capability register %u!\n", offReg));
7041 STAM_COUNTER_INC(&pThis->StatRdUnknown);
7042 return VINF_IOM_MMIO_UNUSED_FF;
7043 }
7044 STAM_COUNTER_INC(&pThis->StatRdCaps);
7045 Log2(("xhciRead %RGp size=%d -> val=%x\n", off, cb, *pu32));
7046 return VINF_SUCCESS;
7047 }
7048
7049 /*
7050 * Validate the access (in case of IOM bugs or incorrect MMIO registration).
7051 */
7052 AssertMsgReturn(cb == sizeof(uint32_t), ("IOM bug? %RGp LB %d\n", off, cb),
7053 VINF_IOM_MMIO_UNUSED_FF /* No idea what really would happen... */);
7054 /** r=bird: If you don't have an idea what would happen for non-dword reads,
7055 * then the flags passed to IOM when creating the MMIO region are doubtful, right? */
7056 AssertMsgReturn(!(off & 0x3), ("IOM bug? %RGp LB %d\n", off, cb), VINF_IOM_MMIO_UNUSED_FF);
7057
7058 /*
7059 * Validate the register and call the read operator.
7060 */
7061 VBOXSTRICTRC rcStrict = VINF_IOM_MMIO_UNUSED_FF;
7062 if (offReg >= XHCI_DOORBELL_OFFSET)
7063 {
7064 /* The doorbell registers are effectively write-only and return 0 when read. */
7065 iReg = (offReg - XHCI_DOORBELL_OFFSET) >> 2;
7066 if (iReg < XHCI_NDS)
7067 {
7068 STAM_COUNTER_INC(&pThis->StatRdDoorBell);
7069 *pu32 = 0;
7070 rcStrict = VINF_SUCCESS;
7071 Log2(("xhciRead: DBellReg (DB %u) %RGp size=%d -> val=%x (rc=%d)\n", iReg, off, cb, *pu32, VBOXSTRICTRC_VAL(rcStrict)));
7072 }
7073 }
7074 else if (offReg >= XHCI_RTREG_OFFSET)
7075 {
7076 /* Run-time registers. */
7077 Assert(offReg < XHCI_DOORBELL_OFFSET);
7078 /* The MFINDEX register would be interrupter -1... */
7079 if (offReg < XHCI_RTREG_OFFSET + RT_ELEMENTS(g_aIntrRegs) * sizeof(uint32_t))
7080 {
7081 if (offReg == XHCI_RTREG_OFFSET)
7082 rcStrict = HcMfIndex_r(pDevIns, pThis, pu32);
7083 else
7084 {
7085 /* The silly Linux xHCI driver reads the reserved registers. */
7086 STAM_COUNTER_INC(&pThis->StatRdUnknown);
7087 *pu32 = 0;
7088 rcStrict = VINF_SUCCESS;
7089 }
7090 }
7091 else
7092 {
7093 Assert((offReg - XHCI_RTREG_OFFSET) / (RT_ELEMENTS(g_aIntrRegs) * sizeof(uint32_t)) > 0);
7094 const uint32_t iIntr = (offReg - XHCI_RTREG_OFFSET) / (RT_ELEMENTS(g_aIntrRegs) * sizeof(uint32_t)) - 1;
7095
7096 if (iIntr < XHCI_NINTR)
7097 {
7098 iReg = (offReg >> 2) & (RT_ELEMENTS(g_aIntrRegs) - 1);
7099 const XHCIINTRREGACC *pReg = &g_aIntrRegs[iReg];
7100 if (pReg->pfnIntrRead)
7101 {
7102 PXHCIINTRPTR pIntr = &pThis->aInterrupters[iIntr];
7103 rcStrict = pReg->pfnIntrRead(pDevIns, pThis, pIntr, pu32);
7104 Log2(("xhciRead: IntrReg (intr %u): %RGp (%s) size=%d -> val=%x (rc=%d)\n", iIntr, off, pReg->pszName, cb, *pu32, VBOXSTRICTRC_VAL(rcStrict)));
7105 }
7106 }
7107 }
7108 }
7109 else if (offReg >= XHCI_XECP_OFFSET)
7110 {
7111 /* Extended Capability registers. */
7112 Assert(offReg < XHCI_RTREG_OFFSET);
7113 uint32_t offXcp = offReg - XHCI_XECP_OFFSET;
7114
7115 if (offXcp + cb <= RT_MIN(pThis->cbExtCap, sizeof(pThis->abExtCap))) /* can't trust cbExtCap in ring-0. */
7116 {
7117 *pu32 = *(uint32_t *)&pThis->abExtCap[offXcp];
7118 rcStrict = VINF_SUCCESS;
7119 }
7120 Log2(("xhciRead: ExtCapReg %RGp size=%d -> val=%x (rc=%d)\n", off, cb, *pu32, VBOXSTRICTRC_VAL(rcStrict)));
7121 }
7122 else
7123 {
7124 /* Operational registers (incl. port registers). */
7125 Assert(offReg < XHCI_XECP_OFFSET);
7126 iReg = (offReg - XHCI_CAPS_REG_SIZE) >> 2;
7127 if (iReg < RT_ELEMENTS(g_aOpRegs))
7128 {
7129 const XHCIREGACC *pReg = &g_aOpRegs[iReg];
7130 if (pReg->pfnRead)
7131 {
7132 rcStrict = pReg->pfnRead(pDevIns, pThis, iReg, pu32);
7133 Log2(("xhciRead: OpReg %RGp (%s) size=%d -> val=%x (rc=%d)\n", off, pReg->pszName, cb, *pu32, VBOXSTRICTRC_VAL(rcStrict)));
7134 }
7135 }
7136 else if (iReg >= (XHCI_PORT_REG_OFFSET >> 2))
7137 {
7138 iReg -= (XHCI_PORT_REG_OFFSET >> 2);
7139 const uint32_t iPort = iReg / RT_ELEMENTS(g_aPortRegs);
7140 if (iPort < XHCI_NDP_CFG(pThis))
7141 {
7142 iReg = (offReg >> 2) & (RT_ELEMENTS(g_aPortRegs) - 1);
7143 Assert(iReg < RT_ELEMENTS(g_aPortRegs));
7144 const XHCIREGACC *pReg = &g_aPortRegs[iReg];
7145 if (pReg->pfnRead)
7146 {
7147 rcStrict = pReg->pfnRead(pDevIns, pThis, iPort, pu32);
7148 Log2(("xhciRead: PortReg (port %u): %RGp (%s) size=%d -> val=%x (rc=%d)\n", IDX_TO_ID(iPort), off, pReg->pszName, cb, *pu32, VBOXSTRICTRC_VAL(rcStrict)));
7149 }
7150 }
7151 }
7152 }
7153
7154 if (rcStrict != VINF_IOM_MMIO_UNUSED_FF)
7155 { /* likely */ }
7156 else
7157 {
7158 STAM_COUNTER_INC(&pThis->StatRdUnknown);
7159 Log(("xHCI: Trying to read unimplemented register at offset %04X!\n", offReg));
7160 }
7161
7162 return rcStrict;
7163}
7164
7165
7166/**
7167 * @callback_method_impl{FNIOMMMIONEWWRITE, Write to a MMIO register.}
7168 *
7169 * @note We only accept 32-bit writes that are 32-bit aligned.
7170 */
7171static DECLCALLBACK(VBOXSTRICTRC) xhciMmioWrite(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS off, void const *pv, unsigned cb)
7172{
7173 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
7174 const uint32_t offReg = (uint32_t)off;
7175 uint32_t * const pu32 = (uint32_t *)pv;
7176 uint32_t iReg;
7177 RT_NOREF(pvUser);
7178
7179 Log2(("xhciWrite %RGp (offset %04X) %x size=%d\n", off, offReg, *(uint32_t *)pv, cb));
7180
7181 if (offReg < XHCI_CAPS_REG_SIZE)
7182 {
7183 /* These are read-only */
7184 Log(("xHCI: Trying to write to register %u!\n", offReg));
7185 STAM_COUNTER_INC(&pThis->StatWrUnknown);
7186 return VINF_SUCCESS;
7187 }
7188
7189 /*
7190 * Validate the access (in case of IOM bug or incorrect MMIO registration).
7191 */
7192 AssertMsgReturn(cb == sizeof(uint32_t), ("IOM bug? %RGp LB %d\n", off, cb), VINF_SUCCESS);
7193 AssertMsgReturn(!(off & 0x3), ("IOM bug? %RGp LB %d\n", off, cb), VINF_SUCCESS);
7194
7195 /*
7196 * Validate the register and call the write operator.
7197 */
7198 VBOXSTRICTRC rcStrict = VINF_IOM_MMIO_UNUSED_FF;
7199 if (offReg >= XHCI_DOORBELL_OFFSET)
7200 {
7201 /* Let's spring into action... as long as the xHC is running. */
7202 iReg = (offReg - XHCI_DOORBELL_OFFSET) >> 2;
7203 if ((pThis->cmd & XHCI_CMD_RS) && iReg < XHCI_NDS)
7204 {
7205 if (iReg == 0)
7206 {
7207 /* DB0 aka Command Ring. */
7208 STAM_COUNTER_INC(&pThis->StatWrDoorBell0);
7209 if (*pu32 == 0)
7210 {
7211 /* Set the Command Ring state to Running if not already set. */
7212 if (!(pThis->crcr & XHCI_CRCR_CRR))
7213 {
7214 Log(("Command ring entered Running state\n"));
7215 ASMAtomicOrU64(&pThis->crcr, XHCI_CRCR_CRR);
7216 }
7217 xhciKickWorker(pDevIns, pThis, XHCI_JOB_PROCESS_CMDRING, 0);
7218 }
7219 else
7220 Log2(("Ignoring DB0 write with value %X!\n", *pu32));
7221 }
7222 else
7223 {
7224 /* Device context doorbell. Do basic parameter checking to avoid
7225 * waking up the worker thread needlessly.
7226 */
7227 STAM_COUNTER_INC(&pThis->StatWrDoorBellN);
7228 uint8_t uDBTarget = *pu32 & XHCI_DB_TGT_MASK;
7229 Assert(uDBTarget < 32); /// @todo Report an error? Or just ignore?
7230 if (uDBTarget < 32)
7231 {
7232 Log2(("Ring bell for slot %u, DCI %u\n", iReg, uDBTarget));
7233 ASMAtomicOrU32(&pThis->aBellsRung[ID_TO_IDX(iReg)], 1 << uDBTarget);
7234 xhciKickWorker(pDevIns, pThis, XHCI_JOB_DOORBELL, *pu32);
7235 }
7236 else
7237 Log2(("Ignoring DB%u write with bad target %u!\n", iReg, uDBTarget));
7238 }
7239 rcStrict = VINF_SUCCESS;
7240 Log2(("xhciWrite: DBellReg (DB %u) %RGp size=%d <- val=%x (rc=%d)\n", iReg, off, cb, *(uint32_t *)pv, VBOXSTRICTRC_VAL(rcStrict)));
7241 }
7242 }
7243 else if (offReg >= XHCI_RTREG_OFFSET)
7244 {
7245 /* Run-time registers. */
7246 Assert(offReg < XHCI_DOORBELL_OFFSET);
7247 /* NB: The MFINDEX register is R/O. */
7248 if (offReg >= XHCI_RTREG_OFFSET + (RT_ELEMENTS(g_aIntrRegs) * sizeof(uint32_t)))
7249 {
7250 Assert((offReg - XHCI_RTREG_OFFSET) / (RT_ELEMENTS(g_aIntrRegs) * sizeof(uint32_t)) > 0);
7251 const uint32_t iIntr = (offReg - XHCI_RTREG_OFFSET) / (RT_ELEMENTS(g_aIntrRegs) * sizeof(uint32_t)) - 1;
7252
7253 if (iIntr < XHCI_NINTR)
7254 {
7255 iReg = (offReg >> 2) & (RT_ELEMENTS(g_aIntrRegs) - 1);
7256 const XHCIINTRREGACC *pReg = &g_aIntrRegs[iReg];
7257 if (pReg->pfnIntrWrite)
7258 {
7259 PXHCIINTRPTR pIntr = &pThis->aInterrupters[iIntr];
7260 rcStrict = pReg->pfnIntrWrite(pDevIns, pThis, pIntr, *pu32);
7261 Log2(("xhciWrite: IntrReg (intr %u): %RGp (%s) size=%d <- val=%x (rc=%d)\n", iIntr, off, pReg->pszName, cb, *pu32, VBOXSTRICTRC_VAL(rcStrict)));
7262 }
7263 }
7264 }
7265 }
7266 else
7267 {
7268 /* Operational registers (incl. port registers). */
7269 Assert(offReg < XHCI_RTREG_OFFSET);
7270 iReg = (offReg - pThis->cap_length) >> 2;
7271 if (iReg < RT_ELEMENTS(g_aOpRegs))
7272 {
7273 const XHCIREGACC *pReg = &g_aOpRegs[iReg];
7274 if (pReg->pfnWrite)
7275 {
7276 rcStrict = pReg->pfnWrite(pDevIns, pThis, iReg, *(uint32_t *)pv);
7277 Log2(("xhciWrite: OpReg %RGp (%s) size=%d <- val=%x (rc=%d)\n", off, pReg->pszName, cb, *(uint32_t *)pv, VBOXSTRICTRC_VAL(rcStrict)));
7278 }
7279 }
7280 else if (iReg >= (XHCI_PORT_REG_OFFSET >> 2))
7281 {
7282 iReg -= (XHCI_PORT_REG_OFFSET >> 2);
7283 const uint32_t iPort = iReg / RT_ELEMENTS(g_aPortRegs);
7284 if (iPort < XHCI_NDP_CFG(pThis))
7285 {
7286 iReg = (offReg >> 2) & (RT_ELEMENTS(g_aPortRegs) - 1);
7287 Assert(iReg < RT_ELEMENTS(g_aPortRegs));
7288 const XHCIREGACC *pReg = &g_aPortRegs[iReg];
7289 if (pReg->pfnWrite)
7290 {
7291 rcStrict = pReg->pfnWrite(pDevIns, pThis, iPort, *pu32);
7292 Log2(("xhciWrite: PortReg (port %u): %RGp (%s) size=%d <- val=%x (rc=%d)\n", IDX_TO_ID(iPort), off, pReg->pszName, cb, *pu32, VBOXSTRICTRC_VAL(rcStrict)));
7293 }
7294 }
7295 }
7296 }
7297
7298 if (rcStrict != VINF_IOM_MMIO_UNUSED_FF)
7299 { /* likely */ }
7300 else
7301 {
7302 /* Ignore writes to unimplemented or read-only registers. */
7303 STAM_COUNTER_INC(&pThis->StatWrUnknown);
7304 Log(("xHCI: Trying to write unimplemented or R/O register at offset %04X!\n", offReg));
7305 rcStrict = VINF_SUCCESS;
7306 }
7307
7308 return rcStrict;
7309}
7310
7311
7312#ifdef IN_RING3
7313
7314/**
7315 * @callback_method_impl{FNTMTIMERDEV,
7316 * Provides periodic MFINDEX wrap events. See 4.14.2.}
7317 */
7318static DECLCALLBACK(void) xhciR3WrapTimer(PPDMDEVINS pDevIns, TMTIMERHANDLE hTimer, void *pvUser)
7319{
7320 PXHCI pThis = (PXHCI)pvUser;
7321 XHCI_EVENT_TRB ed;
7322 LogFlow(("xhciR3WrapTimer:\n"));
7323 RT_NOREF(hTimer);
7324
7325 /*
7326 * Post the MFINDEX Wrap event and rearm the timer. Only called
7327 * when the EWE bit is set in command register.
7328 */
7329 RT_ZERO(ed);
7330 ed.mwe.cc = XHCI_TCC_SUCCESS;
7331 ed.mwe.type = XHCI_TRB_MFIDX_WRAP;
7332 xhciR3WriteEvent(pDevIns, pThis, &ed, XHCI_PRIMARY_INTERRUPTER, false);
7333
7334 xhciSetWrapTimer(pDevIns, pThis);
7335}
7336
7337
7338/**
7339 * @callback_method_impl{FNSSMDEVSAVEEXEC}
7340 */
7341static DECLCALLBACK(int) xhciR3SaveExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM)
7342{
7343 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
7344 PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3;
7345 uint32_t iPort;
7346 uint32_t iSlot;
7347 uint32_t iIntr;
7348
7349 LogFlow(("xhciR3SaveExec: \n"));
7350
7351 /* Save HC operational registers. */
7352 pHlp->pfnSSMPutU32(pSSM, pThis->cmd);
7353 pHlp->pfnSSMPutU32(pSSM, pThis->status);
7354 pHlp->pfnSSMPutU32(pSSM, pThis->dnctrl);
7355 pHlp->pfnSSMPutU64(pSSM, pThis->crcr);
7356 pHlp->pfnSSMPutU64(pSSM, pThis->dcbaap);
7357 pHlp->pfnSSMPutU32(pSSM, pThis->config);
7358
7359 /* Save HC non-register state. */
7360 pHlp->pfnSSMPutU64(pSSM, pThis->cmdr_dqp);
7361 pHlp->pfnSSMPutBool(pSSM, pThis->cmdr_ccs);
7362
7363 /* Save per-slot state. */
7364 pHlp->pfnSSMPutU32(pSSM, XHCI_NDS);
7365 for (iSlot = 0; iSlot < XHCI_NDS; ++iSlot)
7366 {
7367 pHlp->pfnSSMPutU8 (pSSM, pThis->aSlotState[iSlot]);
7368 pHlp->pfnSSMPutU32(pSSM, pThis->aBellsRung[iSlot]);
7369 }
7370
7371 /* Save root hub (port) state. */
7372 pHlp->pfnSSMPutU32(pSSM, XHCI_NDP_CFG(pThis));
7373 for (iPort = 0; iPort < XHCI_NDP_CFG(pThis); ++iPort)
7374 {
7375 pHlp->pfnSSMPutU32(pSSM, pThis->aPorts[iPort].portsc);
7376 pHlp->pfnSSMPutU32(pSSM, pThis->aPorts[iPort].portpm);
7377 }
7378
7379 /* Save interrupter state. */
7380 pHlp->pfnSSMPutU32(pSSM, XHCI_NINTR);
7381 for (iIntr = 0; iIntr < XHCI_NINTR; ++iIntr)
7382 {
7383 pHlp->pfnSSMPutU32(pSSM, pThis->aInterrupters[iIntr].iman);
7384 pHlp->pfnSSMPutU32(pSSM, pThis->aInterrupters[iIntr].imod);
7385 pHlp->pfnSSMPutU32(pSSM, pThis->aInterrupters[iIntr].erstsz);
7386 pHlp->pfnSSMPutU64(pSSM, pThis->aInterrupters[iIntr].erstba);
7387 pHlp->pfnSSMPutU64(pSSM, pThis->aInterrupters[iIntr].erdp);
7388 pHlp->pfnSSMPutU64(pSSM, pThis->aInterrupters[iIntr].erep);
7389 pHlp->pfnSSMPutU16(pSSM, pThis->aInterrupters[iIntr].erst_idx);
7390 pHlp->pfnSSMPutU16(pSSM, pThis->aInterrupters[iIntr].trb_count);
7391 pHlp->pfnSSMPutBool(pSSM, pThis->aInterrupters[iIntr].evtr_pcs);
7392 pHlp->pfnSSMPutBool(pSSM, pThis->aInterrupters[iIntr].ipe);
7393 }
7394
7395 /* Terminator marker. */
7396 pHlp->pfnSSMPutU32(pSSM, UINT32_MAX);
7397
7398 /* If not continuing after save, force HC into non-running state to avoid trouble later. */
7399 if (pHlp->pfnSSMHandleGetAfter(pSSM) != SSMAFTER_CONTINUE)
7400 pThis->cmd &= ~XHCI_CMD_RS;
7401
7402 return VINF_SUCCESS;
7403}
7404
7405
7406/**
7407 * @callback_method_impl{FNSSMDEVLOADEXEC}
7408 */
7409static DECLCALLBACK(int) xhciR3LoadExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM, uint32_t uVersion, uint32_t uPass)
7410{
7411 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
7412 PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3;
7413 int rc;
7414 uint32_t cPorts;
7415 uint32_t iPort;
7416 uint32_t cSlots;
7417 uint32_t iSlot;
7418 uint32_t cIntrs;
7419 uint32_t iIntr;
7420 uint64_t u64Dummy;
7421 uint32_t u32Dummy;
7422 uint16_t u16Dummy;
7423 uint8_t u8Dummy;
7424 bool fDummy;
7425
7426 LogFlow(("xhciR3LoadExec:\n"));
7427
7428 Assert(uPass == SSM_PASS_FINAL); NOREF(uPass);
7429 if (uVersion != XHCI_SAVED_STATE_VERSION)
7430 return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION;
7431
7432 /* Load HC operational registers. */
7433 pHlp->pfnSSMGetU32(pSSM, &pThis->cmd);
7434 pHlp->pfnSSMGetU32(pSSM, &pThis->status);
7435 pHlp->pfnSSMGetU32(pSSM, &pThis->dnctrl);
7436 pHlp->pfnSSMGetU64(pSSM, &pThis->crcr);
7437 pHlp->pfnSSMGetU64(pSSM, &pThis->dcbaap);
7438 pHlp->pfnSSMGetU32(pSSM, &pThis->config);
7439
7440 /* Load HC non-register state. */
7441 pHlp->pfnSSMGetU64(pSSM, &pThis->cmdr_dqp);
7442 pHlp->pfnSSMGetBool(pSSM, &pThis->cmdr_ccs);
7443
7444 /* Load per-slot state. */
7445 rc = pHlp->pfnSSMGetU32(pSSM, &cSlots);
7446 AssertRCReturn(rc, rc);
7447 if (cSlots > 256) /* Sanity check. */
7448 return VERR_SSM_INVALID_STATE;
7449 for (iSlot = 0; iSlot < cSlots; ++iSlot)
7450 {
7451 /* Load only as many slots as we have; discard any extras. */
7452 if (iSlot < XHCI_NDS)
7453 {
7454 pHlp->pfnSSMGetU8 (pSSM, &pThis->aSlotState[iSlot]);
7455 pHlp->pfnSSMGetU32(pSSM, &pThis->aBellsRung[iSlot]);
7456 }
7457 else
7458 {
7459 pHlp->pfnSSMGetU8 (pSSM, &u8Dummy);
7460 pHlp->pfnSSMGetU32(pSSM, &u32Dummy);
7461 }
7462 }
7463
7464 /* Load root hub (port) state. */
7465 rc = pHlp->pfnSSMGetU32(pSSM, &cPorts);
7466 AssertRCReturn(rc, rc);
7467 if (cPorts > 256) /* Sanity check. */
7468 return VERR_SSM_INVALID_STATE;
7469
7470 for (iPort = 0; iPort < cPorts; ++iPort)
7471 {
7472 /* Load only as many ports as we have; discard any extras. */
7473 if (iPort < XHCI_NDP_CFG(pThis))
7474 {
7475 pHlp->pfnSSMGetU32(pSSM, &pThis->aPorts[iPort].portsc);
7476 pHlp->pfnSSMGetU32(pSSM, &pThis->aPorts[iPort].portpm);
7477 }
7478 else
7479 {
7480 pHlp->pfnSSMGetU32(pSSM, &u32Dummy);
7481 pHlp->pfnSSMGetU32(pSSM, &u32Dummy);
7482 }
7483 }
7484
7485 /* Load interrupter state. */
7486 rc = pHlp->pfnSSMGetU32(pSSM, &cIntrs);
7487 AssertRCReturn(rc, rc);
7488 if (cIntrs > 256) /* Sanity check. */
7489 return VERR_SSM_INVALID_STATE;
7490 for (iIntr = 0; iIntr < cIntrs; ++iIntr)
7491 {
7492 /* Load only as many interrupters as we have; discard any extras. */
7493 if (iIntr < XHCI_NINTR)
7494 {
7495 pHlp->pfnSSMGetU32(pSSM, &pThis->aInterrupters[iIntr].iman);
7496 pHlp->pfnSSMGetU32(pSSM, &pThis->aInterrupters[iIntr].imod);
7497 pHlp->pfnSSMGetU32(pSSM, &pThis->aInterrupters[iIntr].erstsz);
7498 pHlp->pfnSSMGetU64(pSSM, &pThis->aInterrupters[iIntr].erstba);
7499 pHlp->pfnSSMGetU64(pSSM, &pThis->aInterrupters[iIntr].erdp);
7500 pHlp->pfnSSMGetU64(pSSM, &pThis->aInterrupters[iIntr].erep);
7501 pHlp->pfnSSMGetU16(pSSM, &pThis->aInterrupters[iIntr].erst_idx);
7502 pHlp->pfnSSMGetU16(pSSM, &pThis->aInterrupters[iIntr].trb_count);
7503 pHlp->pfnSSMGetBool(pSSM, &pThis->aInterrupters[iIntr].evtr_pcs);
7504 pHlp->pfnSSMGetBool(pSSM, &pThis->aInterrupters[iIntr].ipe);
7505 }
7506 else
7507 {
7508 pHlp->pfnSSMGetU32(pSSM, &u32Dummy);
7509 pHlp->pfnSSMGetU32(pSSM, &u32Dummy);
7510 pHlp->pfnSSMGetU32(pSSM, &u32Dummy);
7511 pHlp->pfnSSMGetU64(pSSM, &u64Dummy);
7512 pHlp->pfnSSMGetU64(pSSM, &u64Dummy);
7513 pHlp->pfnSSMGetU64(pSSM, &u64Dummy);
7514 pHlp->pfnSSMGetU16(pSSM, &u16Dummy);
7515 pHlp->pfnSSMGetU16(pSSM, &u16Dummy);
7516 pHlp->pfnSSMGetBool(pSSM, &fDummy);
7517 pHlp->pfnSSMGetBool(pSSM, &fDummy);
7518 }
7519 }
7520
7521 /* Terminator marker. */
7522 rc = pHlp->pfnSSMGetU32(pSSM, &u32Dummy);
7523 AssertRCReturn(rc, rc);
7524 AssertReturn(u32Dummy == UINT32_MAX, VERR_SSM_DATA_UNIT_FORMAT_CHANGED);
7525
7526 return rc;
7527}
7528
7529
7530/* -=-=-=-=- DBGF -=-=-=-=- */
7531
7532/**
7533 * @callback_method_impl{FNDBGFHANDLERDEV, Dumps xHCI state.}
7534 */
7535static DECLCALLBACK(void) xhciR3Info(PPDMDEVINS pDevIns, PCDBGFINFOHLP pHlp, const char *pszArgs)
7536{
7537 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
7538 RTGCPHYS GPAddr;
7539 bool fVerbose = false;
7540 unsigned i, j;
7541 uint64_t u64Val;
7542
7543 /* Parse arguments. */
7544 if (pszArgs)
7545 fVerbose = strstr(pszArgs, "verbose") != NULL;
7546
7547#ifdef XHCI_ERROR_INJECTION
7548 if (pszArgs && strstr(pszArgs, "dropintrhw"))
7549 {
7550 pHlp->pfnPrintf(pHlp, "Dropping the next interrupt (external)!\n");
7551 pThis->fDropIntrHw = true;
7552 return;
7553 }
7554
7555 if (pszArgs && strstr(pszArgs, "dropintrint"))
7556 {
7557 pHlp->pfnPrintf(pHlp, "Dropping the next interrupt (internal)!\n");
7558 pThis->fDropIntrIpe = true;
7559 return;
7560 }
7561
7562 if (pszArgs && strstr(pszArgs, "dropurb"))
7563 {
7564 pHlp->pfnPrintf(pHlp, "Dropping the next URB!\n");
7565 pThis->fDropUrb = true;
7566 return;
7567 }
7568#endif
7569
7570 /* Show basic information. */
7571 pHlp->pfnPrintf(pHlp,
7572 "%s#%d: PCI MMIO=%RGp IRQ=%u MSI=%s R0=%RTbool RC=%RTbool\n",
7573 pDevIns->pReg->szName,
7574 pDevIns->iInstance,
7575 PDMDevHlpMmioGetMappingAddress(pDevIns, pThis->hMmio),
7576 PCIDevGetInterruptLine(pDevIns->apPciDevs[0]),
7577#ifdef VBOX_WITH_MSI_DEVICES
7578 xhciIsMSIEnabled(pDevIns->apPciDevs[0]) ? "on" : "off",
7579#else
7580 "none",
7581#endif
7582 pDevIns->fR0Enabled, pDevIns->fRCEnabled);
7583
7584 /* Command register. */
7585 pHlp->pfnPrintf(pHlp, "USBCMD: %X:", pThis->cmd);
7586 if (pThis->cmd & XHCI_CMD_EU3S) pHlp->pfnPrintf(pHlp, " EU3S" );
7587 if (pThis->cmd & XHCI_CMD_EWE) pHlp->pfnPrintf(pHlp, " EWE" );
7588 if (pThis->cmd & XHCI_CMD_CRS) pHlp->pfnPrintf(pHlp, " CRS" );
7589 if (pThis->cmd & XHCI_CMD_CSS) pHlp->pfnPrintf(pHlp, " CSS" );
7590 if (pThis->cmd & XHCI_CMD_LCRST) pHlp->pfnPrintf(pHlp, " LCRST" );
7591 if (pThis->cmd & XHCI_CMD_HSEE) pHlp->pfnPrintf(pHlp, " HSEE" );
7592 if (pThis->cmd & XHCI_CMD_INTE) pHlp->pfnPrintf(pHlp, " INTE" );
7593 if (pThis->cmd & XHCI_CMD_HCRST) pHlp->pfnPrintf(pHlp, " HCRST" );
7594 if (pThis->cmd & XHCI_CMD_RS) pHlp->pfnPrintf(pHlp, " RS" );
7595 pHlp->pfnPrintf(pHlp, "\n");
7596
7597 /* Status register. */
7598 pHlp->pfnPrintf(pHlp, "USBSTS: %X:", pThis->status);
7599 if (pThis->status & XHCI_STATUS_HCH) pHlp->pfnPrintf(pHlp, " HCH" );
7600 if (pThis->status & XHCI_STATUS_HSE) pHlp->pfnPrintf(pHlp, " HSE" );
7601 if (pThis->status & XHCI_STATUS_EINT) pHlp->pfnPrintf(pHlp, " EINT" );
7602 if (pThis->status & XHCI_STATUS_PCD) pHlp->pfnPrintf(pHlp, " PCD" );
7603 if (pThis->status & XHCI_STATUS_SSS) pHlp->pfnPrintf(pHlp, " SSS" );
7604 if (pThis->status & XHCI_STATUS_RSS) pHlp->pfnPrintf(pHlp, " RSS" );
7605 if (pThis->status & XHCI_STATUS_SRE) pHlp->pfnPrintf(pHlp, " SRE" );
7606 if (pThis->status & XHCI_STATUS_CNR) pHlp->pfnPrintf(pHlp, " CNR" );
7607 if (pThis->status & XHCI_STATUS_HCE) pHlp->pfnPrintf(pHlp, " HCE" );
7608 pHlp->pfnPrintf(pHlp, "\n");
7609
7610 /* Device Notification Control and Configure registers. */
7611 pHlp->pfnPrintf(pHlp, "DNCTRL: %X CONFIG: %X (%u slots)\n", pThis->dnctrl, pThis->config, pThis->config);
7612
7613 /* Device Context Base Address Array. */
7614 GPAddr = pThis->dcbaap & XHCI_DCBAA_ADDR_MASK;
7615 pHlp->pfnPrintf(pHlp, "DCBAA ptr: %RGp\n", GPAddr);
7616 /* The DCBAA must be valid in 'run' state. */
7617 if (fVerbose && (pThis->cmd & XHCI_CMD_RS))
7618 {
7619 PDMDevHlpPCIPhysRead(pDevIns, GPAddr, &u64Val, sizeof(u64Val));
7620 pHlp->pfnPrintf(pHlp, " Scratchpad buffer: %RX64\n", u64Val);
7621 }
7622
7623 /* Command Ring Control Register. */
7624 pHlp->pfnPrintf(pHlp, "CRCR: %X:", pThis->crcr & ~XHCI_CRCR_ADDR_MASK);
7625 if (pThis->crcr & XHCI_CRCR_RCS) pHlp->pfnPrintf(pHlp, " RCS");
7626 if (pThis->crcr & XHCI_CRCR_CS) pHlp->pfnPrintf(pHlp, " CS" );
7627 if (pThis->crcr & XHCI_CRCR_CA) pHlp->pfnPrintf(pHlp, " CA" );
7628 if (pThis->crcr & XHCI_CRCR_CRR) pHlp->pfnPrintf(pHlp, " CRR");
7629 pHlp->pfnPrintf(pHlp, "\n");
7630 GPAddr = pThis->crcr & XHCI_CRCR_ADDR_MASK;
7631 pHlp->pfnPrintf(pHlp, "CRCR ptr : %RGp\n", GPAddr);
7632
7633 /* Interrupters. */
7634 if (fVerbose)
7635 {
7636 for (i = 0; i < RT_ELEMENTS(pThis->aInterrupters); ++i)
7637 {
7638 if (pThis->aInterrupters[i].erstsz)
7639 {
7640 XHCIINTRPTR *ir = &pThis->aInterrupters[i];
7641
7642 pHlp->pfnPrintf(pHlp, "Interrupter %d (IPE=%u)\n", i, ir->ipe);
7643
7644 /* The Interrupt Management Register. */
7645 pHlp->pfnPrintf(pHlp, " IMAN : %X:", ir->iman);
7646 if (ir->iman & XHCI_IMAN_IP) pHlp->pfnPrintf(pHlp, " IP");
7647 if (ir->iman & XHCI_IMAN_IE) pHlp->pfnPrintf(pHlp, " IE");
7648 pHlp->pfnPrintf(pHlp, "\n");
7649
7650 /* The Interrupt Moderation Register. */
7651 pHlp->pfnPrintf(pHlp, " IMOD : %X:", ir->imod);
7652 pHlp->pfnPrintf(pHlp, " IMODI=%u", ir->imod & XHCI_IMOD_IMODI_MASK);
7653 pHlp->pfnPrintf(pHlp, " IMODC=%u", (ir->imod & XHCI_IMOD_IMODC_MASK) >> XHCI_IMOD_IMODC_SHIFT);
7654 pHlp->pfnPrintf(pHlp, "\n");
7655
7656 pHlp->pfnPrintf(pHlp, " ERSTSZ: %X\n", ir->erstsz);
7657 pHlp->pfnPrintf(pHlp, " ERSTBA: %RGp\n", (RTGCPHYS)ir->erstba);
7658
7659 pHlp->pfnPrintf(pHlp, " ERDP : %RGp:", (RTGCPHYS)ir->erdp);
7660 pHlp->pfnPrintf(pHlp, " EHB=%u", !!(ir->erdp & XHCI_ERDP_EHB));
7661 pHlp->pfnPrintf(pHlp, " DESI=%u", ir->erdp & XHCI_ERDP_DESI_MASK);
7662 pHlp->pfnPrintf(pHlp, " ptr=%RGp", ir->erdp & XHCI_ERDP_ADDR_MASK);
7663 pHlp->pfnPrintf(pHlp, "\n");
7664
7665 pHlp->pfnPrintf(pHlp, " EREP : %RGp", ir->erep);
7666 pHlp->pfnPrintf(pHlp, " Free TRBs in seg=%u", ir->trb_count);
7667 pHlp->pfnPrintf(pHlp, "\n");
7668 }
7669 }
7670 }
7671
7672 /* Port control/status. */
7673 for (i = 0; i < XHCI_NDP_CFG(pThis); ++i)
7674 {
7675 PXHCIHUBPORT p = &pThis->aPorts[i];
7676
7677 pHlp->pfnPrintf(pHlp, "Port %02u (USB%c): ", IDX_TO_ID(i), IS_USB3_PORT_IDX_SHR(pThis, i) ? '3' : '2');
7678
7679 /* Port Status register. */
7680 pHlp->pfnPrintf(pHlp, "PORTSC: %8X:", p->portsc);
7681 if (p->portsc & XHCI_PORT_CCS) pHlp->pfnPrintf(pHlp, " CCS" );
7682 if (p->portsc & XHCI_PORT_PED) pHlp->pfnPrintf(pHlp, " PED" );
7683 if (p->portsc & XHCI_PORT_OCA) pHlp->pfnPrintf(pHlp, " OCA" );
7684 if (p->portsc & XHCI_PORT_PR ) pHlp->pfnPrintf(pHlp, " PR" );
7685 pHlp->pfnPrintf(pHlp, " PLS=%u", (p->portsc & XHCI_PORT_PLS_MASK) >> XHCI_PORT_PLS_SHIFT);
7686 if (p->portsc & XHCI_PORT_PP ) pHlp->pfnPrintf(pHlp, " PP" );
7687 pHlp->pfnPrintf(pHlp, " SPD=%u", (p->portsc & XHCI_PORT_SPD_MASK) >> XHCI_PORT_SPD_SHIFT);
7688 if (p->portsc & XHCI_PORT_LWS) pHlp->pfnPrintf(pHlp, " LWS" );
7689 if (p->portsc & XHCI_PORT_CSC) pHlp->pfnPrintf(pHlp, " CSC" );
7690 if (p->portsc & XHCI_PORT_PEC) pHlp->pfnPrintf(pHlp, " PEC" );
7691 if (p->portsc & XHCI_PORT_WRC) pHlp->pfnPrintf(pHlp, " WRC" );
7692 if (p->portsc & XHCI_PORT_OCC) pHlp->pfnPrintf(pHlp, " OCC" );
7693 if (p->portsc & XHCI_PORT_PRC) pHlp->pfnPrintf(pHlp, " PRC" );
7694 if (p->portsc & XHCI_PORT_PLC) pHlp->pfnPrintf(pHlp, " PLC" );
7695 if (p->portsc & XHCI_PORT_CEC) pHlp->pfnPrintf(pHlp, " CEC" );
7696 if (p->portsc & XHCI_PORT_CAS) pHlp->pfnPrintf(pHlp, " CAS" );
7697 if (p->portsc & XHCI_PORT_WCE) pHlp->pfnPrintf(pHlp, " WCE" );
7698 if (p->portsc & XHCI_PORT_WDE) pHlp->pfnPrintf(pHlp, " WDE" );
7699 if (p->portsc & XHCI_PORT_WOE) pHlp->pfnPrintf(pHlp, " WOE" );
7700 if (p->portsc & XHCI_PORT_DR ) pHlp->pfnPrintf(pHlp, " DR" );
7701 if (p->portsc & XHCI_PORT_WPR) pHlp->pfnPrintf(pHlp, " WPR" );
7702 pHlp->pfnPrintf(pHlp, "\n");
7703 }
7704
7705 /* Device contexts. */
7706 if (fVerbose && (pThis->cmd & XHCI_CMD_RS))
7707 {
7708 for (i = 0; i < XHCI_NDS; ++i)
7709 {
7710 if (pThis->aSlotState[i] > XHCI_DEVSLOT_EMPTY)
7711 {
7712 RTGCPHYS GCPhysSlot;
7713 XHCI_DEV_CTX ctxDevice;
7714 XHCI_SLOT_CTX ctxSlot;
7715 const char *pcszDesc;
7716 uint8_t uSlotID = IDX_TO_ID(i);
7717
7718 /* Find the slot address/ */
7719 GCPhysSlot = xhciR3FetchDevCtxAddr(pDevIns, pThis, uSlotID);
7720 pHlp->pfnPrintf(pHlp, "Slot %d (device context @ %RGp)\n", uSlotID, GCPhysSlot);
7721 if (!GCPhysSlot)
7722 {
7723 pHlp->pfnPrintf(pHlp, "Bad context address, skipping!\n");
7724 continue;
7725 }
7726
7727 /* Just read in the whole lot and sort in which contexts are valid later. */
7728 PDMDevHlpPCIPhysRead(pDevIns, GCPhysSlot, &ctxDevice, sizeof(ctxDevice));
7729
7730 ctxSlot = ctxDevice.entry[0].sc;
7731 pcszDesc = ctxSlot.slot_state < RT_ELEMENTS(g_apszSltStates) ? g_apszSltStates[ctxSlot.slot_state] : "BAD!!!";
7732 pHlp->pfnPrintf(pHlp, " Speed:%u Entries:%u RhPort:%u", ctxSlot.speed, ctxSlot.ctx_ent, ctxSlot.rh_port);
7733 pHlp->pfnPrintf(pHlp, " Address:%u State:%s \n", ctxSlot.dev_addr, pcszDesc);
7734
7735 /* Endpoint contexts. */
7736 for (j = 1; j <= ctxSlot.ctx_ent; ++j)
7737 {
7738 XHCI_EP_CTX ctxEP = ctxDevice.entry[j].ep;
7739
7740 /* Skip disabled endpoints -- they may be unused and do not
7741 * contain valid data in any case.
7742 */
7743 if (ctxEP.ep_state == XHCI_EPST_DISABLED)
7744 continue;
7745
7746 pcszDesc = ctxEP.ep_state < RT_ELEMENTS(g_apszEpStates) ? g_apszEpStates[ctxEP.ep_state] : "BAD!!!";
7747 pHlp->pfnPrintf(pHlp, " Endpoint DCI %u State:%s", j, pcszDesc);
7748 pcszDesc = ctxEP.ep_type < RT_ELEMENTS(g_apszEpTypes) ? g_apszEpTypes[ctxEP.ep_type] : "BAD!!!";
7749 pHlp->pfnPrintf(pHlp, " Type:%s\n",pcszDesc);
7750
7751 pHlp->pfnPrintf(pHlp, " Mult:%u MaxPStreams:%u LSA:%u Interval:%u\n",
7752 ctxEP.mult, ctxEP.maxps, ctxEP.lsa, ctxEP.interval);
7753 pHlp->pfnPrintf(pHlp, " CErr:%u HID:%u MaxPS:%u MaxBS:%u",
7754 ctxEP.c_err, ctxEP.hid, ctxEP.max_pkt_sz, ctxEP.max_brs_sz);
7755 pHlp->pfnPrintf(pHlp, " AvgTRBLen:%u MaxESIT:%u",
7756 ctxEP.avg_trb_len, ctxEP.max_esit);
7757 pHlp->pfnPrintf(pHlp, " LastFrm:%u IFC:%u LastCC:%u\n",
7758 ctxEP.last_frm, ctxEP.ifc, ctxEP.last_cc);
7759 pHlp->pfnPrintf(pHlp, " TRDP:%RGp DCS:%u\n", (RTGCPHYS)(ctxEP.trdp & XHCI_TRDP_ADDR_MASK),
7760 ctxEP.trdp & XHCI_TRDP_DCS_MASK);
7761 pHlp->pfnPrintf(pHlp, " TREP:%RGp DCS:%u\n", (RTGCPHYS)(ctxEP.trep & XHCI_TRDP_ADDR_MASK),
7762 ctxEP.trep & XHCI_TRDP_DCS_MASK);
7763 }
7764 }
7765 }
7766 }
7767}
7768
7769
7770/**
7771 * @interface_method_impl{PDMDEVREG,pfnReset}
7772 */
7773static DECLCALLBACK(void) xhciR3Reset(PPDMDEVINS pDevIns)
7774{
7775 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
7776 PXHCICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PXHCICC);
7777 LogFlow(("xhciR3Reset:\n"));
7778
7779 /*
7780 * There is no distinction between cold boot, warm reboot and software reboots,
7781 * all of these are treated as cold boots. We are also doing the initialization
7782 * job of a BIOS or SMM driver.
7783 *
7784 * Important: Don't confuse UsbReset with hardware reset. Hardware reset is
7785 * just one way of getting into the UsbReset state.
7786 */
7787
7788 /* Set the HC Halted bit now to prevent completion callbacks from running
7789 *(there is really no point when resetting).
7790 */
7791 ASMAtomicOrU32(&pThis->status, XHCI_STATUS_HCH);
7792
7793 xhciR3BusStop(pDevIns, pThis, pThisCC);
7794 xhciR3DoReset(pThis, pThisCC, XHCI_USB_RESET, true /* reset devices */);
7795}
7796
7797
7798/**
7799 * @interface_method_impl{PDMDEVREG,pfnDestruct}
7800 */
7801static DECLCALLBACK(int) xhciR3Destruct(PPDMDEVINS pDevIns)
7802{
7803 PDMDEV_CHECK_VERSIONS_RETURN_QUIET(pDevIns);
7804 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
7805 PXHCICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PXHCICC);
7806 LogFlow(("xhciR3Destruct:\n"));
7807
7808 /*
7809 * Destroy interrupter locks.
7810 */
7811 for (unsigned i = 0; i < RT_ELEMENTS(pThis->aInterrupters); ++i)
7812 {
7813 if (PDMDevHlpCritSectIsInitialized(pDevIns, &pThis->aInterrupters[i].lock))
7814 PDMDevHlpCritSectDelete(pDevIns, &pThis->aInterrupters[i].lock);
7815 }
7816
7817 /*
7818 * Clean up the worker thread and associated machinery.
7819 */
7820 if (pThis->hEvtProcess != NIL_SUPSEMEVENT)
7821 {
7822 PDMDevHlpSUPSemEventClose(pDevIns, pThis->hEvtProcess);
7823 pThis->hEvtProcess = NIL_SUPSEMEVENT;
7824 }
7825 if (RTCritSectIsInitialized(&pThisCC->CritSectThrd))
7826 RTCritSectDelete(&pThisCC->CritSectThrd);
7827
7828 return VINF_SUCCESS;
7829}
7830
7831
7832/**
7833 * Worker for xhciR3Construct that registers a LUN (USB root hub).
7834 */
7835static int xhciR3RegisterHub(PPDMDEVINS pDevIns, PXHCIROOTHUBR3 pRh, int iLun, const char *pszDesc)
7836{
7837 int rc = PDMDevHlpDriverAttach(pDevIns, iLun, &pRh->IBase, &pRh->pIBase, pszDesc);
7838 AssertMsgRCReturn(rc, ("Configuration error: Failed to attach root hub driver to LUN #%d! (%Rrc)\n", iLun, rc), rc);
7839
7840 pRh->pIRhConn = PDMIBASE_QUERY_INTERFACE(pRh->pIBase, VUSBIROOTHUBCONNECTOR);
7841 AssertMsgReturn(pRh->pIRhConn,
7842 ("Configuration error: The driver doesn't provide the VUSBIROOTHUBCONNECTOR interface!\n"),
7843 VERR_PDM_MISSING_INTERFACE);
7844
7845 /* Set URB parameters. */
7846 rc = VUSBIRhSetUrbParams(pRh->pIRhConn, sizeof(VUSBURBHCIINT), 0);
7847 if (RT_FAILURE(rc))
7848 return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, N_("OHCI: Failed to set URB parameters"));
7849
7850 return rc;
7851}
7852
7853/**
7854 * @interface_method_impl{PDMDEVREG,pfnConstruct,XHCI
7855 * constructor}
7856 */
7857static DECLCALLBACK(int) xhciR3Construct(PPDMDEVINS pDevIns, int iInstance, PCFGMNODE pCfg)
7858{
7859 PDMDEV_CHECK_VERSIONS_RETURN(pDevIns);
7860 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
7861 PXHCICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PXHCICC);
7862 PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3;
7863 uint32_t cUsb2Ports;
7864 uint32_t cUsb3Ports;
7865 int rc;
7866 LogFlow(("xhciR3Construct:\n"));
7867 RT_NOREF(iInstance);
7868
7869 /*
7870 * Initialize data so the destructor runs smoothly.
7871 */
7872 pThis->hEvtProcess = NIL_SUPSEMEVENT;
7873
7874 /*
7875 * Validate and read configuration.
7876 */
7877 PDMDEV_VALIDATE_CONFIG_RETURN(pDevIns, "USB2Ports|USB3Ports|ChipType", "");
7878
7879 /* Number of USB2 ports option. */
7880 rc = pHlp->pfnCFGMQueryU32Def(pCfg, "USB2Ports", &cUsb2Ports, XHCI_NDP_20_DEFAULT);
7881 if (RT_FAILURE(rc))
7882 return PDMDEV_SET_ERROR(pDevIns, rc,
7883 N_("xHCI configuration error: failed to read USB2Ports as integer"));
7884
7885 if (cUsb2Ports == 0 || cUsb2Ports > XHCI_NDP_MAX)
7886 return PDMDevHlpVMSetError(pDevIns, VERR_INVALID_PARAMETER, RT_SRC_POS,
7887 N_("xHCI configuration error: USB2Ports must be in range [%u,%u]"),
7888 1, XHCI_NDP_MAX);
7889
7890 /* Number of USB3 ports option. */
7891 rc = pHlp->pfnCFGMQueryU32Def(pCfg, "USB3Ports", &cUsb3Ports, XHCI_NDP_30_DEFAULT);
7892 if (RT_FAILURE(rc))
7893 return PDMDEV_SET_ERROR(pDevIns, rc,
7894 N_("xHCI configuration error: failed to read USB3Ports as integer"));
7895
7896 if (cUsb3Ports == 0 || cUsb3Ports > XHCI_NDP_MAX)
7897 return PDMDevHlpVMSetError(pDevIns, VERR_INVALID_PARAMETER, RT_SRC_POS,
7898 N_("xHCI configuration error: USB3Ports must be in range [%u,%u]"),
7899 1, XHCI_NDP_MAX);
7900
7901 /* Check that the total number of ports is within limits.*/
7902 if (cUsb2Ports + cUsb3Ports > XHCI_NDP_MAX)
7903 return PDMDevHlpVMSetError(pDevIns, VERR_INVALID_PARAMETER, RT_SRC_POS,
7904 N_("xHCI configuration error: USB2Ports + USB3Ports must be in range [%u,%u]"),
7905 1, XHCI_NDP_MAX);
7906
7907 /* Determine the model. */
7908 char szChipType[16];
7909 rc = pHlp->pfnCFGMQueryStringDef(pCfg, "ChipType", &szChipType[0], sizeof(szChipType), "PantherPoint");
7910 if (RT_FAILURE(rc))
7911 return PDMDEV_SET_ERROR(pDevIns, VERR_PDM_DEVINS_UNKNOWN_CFG_VALUES,
7912 N_("xHCI configuration error: Querying \"ChipType\" as string failed"));
7913
7914 /*
7915 * The default model is Panther Point (8086:1E31), Intel's first and most widely
7916 * supported xHCI implementation. For debugging, the Lynx Point (8086:8C31) model
7917 * can be selected. These two models work with the 7 Series and 8 Series Intel xHCI
7918 * drivers for Windows 7, respectively. There is no functional difference.
7919 * For Windows XP support, it's also possible to present a Renesas uPD720201 xHC;
7920 * this is an evolution of the original NEC xHCI chip.
7921 */
7922 bool fChipLynxPoint = false;
7923 bool fChipRenesas = false;
7924 if (!strcmp(szChipType, "PantherPoint"))
7925 fChipLynxPoint = false;
7926 else if (!strcmp(szChipType, "LynxPoint"))
7927 fChipLynxPoint = true;
7928 else if (!strcmp(szChipType, "uPD720201"))
7929 fChipRenesas = true;
7930 else
7931 return PDMDevHlpVMSetError(pDevIns, VERR_PDM_DEVINS_UNKNOWN_CFG_VALUES, RT_SRC_POS,
7932 N_("xHCI configuration error: The \"ChipType\" value \"%s\" is unsupported"), szChipType);
7933
7934 LogFunc(("cUsb2Ports=%u cUsb3Ports=%u szChipType=%s (%d,%d) fR0Enabled=%d fRCEnabled=%d\n", cUsb2Ports, cUsb3Ports,
7935 szChipType, fChipLynxPoint, fChipRenesas, pDevIns->fR0Enabled, pDevIns->fRCEnabled));
7936
7937 /* Set up interrupter locks. */
7938 for (unsigned i = 0; i < RT_ELEMENTS(pThis->aInterrupters); ++i)
7939 {
7940 rc = PDMDevHlpCritSectInit(pDevIns, &pThis->aInterrupters[i].lock, RT_SRC_POS, "xHCIIntr#%u", i);
7941 if (RT_FAILURE(rc))
7942 return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS,
7943 N_("xHCI: Failed to create critical section for interrupter %u"), i);
7944 pThis->aInterrupters[i].index = i; /* Stash away index, mostly for logging/debugging. */
7945 }
7946
7947
7948 /*
7949 * Init instance data.
7950 */
7951 pThisCC->pDevIns = pDevIns;
7952
7953 PPDMPCIDEV pPciDev = pDevIns->apPciDevs[0];
7954 if (fChipRenesas)
7955 {
7956 pThis->erst_addr_mask = NEC_ERST_ADDR_MASK;
7957 PCIDevSetVendorId(pPciDev, 0x1912);
7958 PCIDevSetDeviceId(pPciDev, 0x0014);
7959 PCIDevSetByte(pPciDev, VBOX_PCI_REVISION_ID, 0x02);
7960 }
7961 else
7962 {
7963 pThis->erst_addr_mask = XHCI_ERST_ADDR_MASK;
7964 PCIDevSetVendorId(pPciDev, 0x8086);
7965 if (fChipLynxPoint)
7966 PCIDevSetDeviceId(pPciDev, 0x8C31); /* Lynx Point / 8 Series */
7967 else
7968 PCIDevSetDeviceId(pPciDev, 0x1E31); /* Panther Point / 7 Series */
7969 }
7970
7971 PCIDevSetClassProg(pPciDev, 0x30); /* xHCI */
7972 PCIDevSetClassSub(pPciDev, 0x03); /* USB 3.0 */
7973 PCIDevSetClassBase(pPciDev, 0x0C);
7974 PCIDevSetInterruptPin(pPciDev, 0x01);
7975#ifdef VBOX_WITH_MSI_DEVICES
7976 PCIDevSetStatus(pPciDev, VBOX_PCI_STATUS_CAP_LIST);
7977 PCIDevSetCapabilityList(pPciDev, 0x80);
7978#endif
7979 PDMPciDevSetByte(pPciDev, 0x60, 0x20); /* serial bus release number register; 0x20 = USB 2.0 */
7980 /** @todo USBLEGSUP & USBLEGCTLSTS? Legacy interface for the BIOS (0xEECP+0 & 0xEECP+4) */
7981
7982 pThis->cTotalPorts = (uint8_t)(cUsb2Ports + cUsb3Ports);
7983
7984 /* Set up the USB2 root hub interface. */
7985 pThis->cUsb2Ports = (uint8_t)cUsb2Ports;
7986 pThisCC->RootHub2.pXhciR3 = pThisCC;
7987 pThisCC->RootHub2.cPortsImpl = cUsb2Ports;
7988 pThisCC->RootHub2.uPortBase = 0;
7989 pThisCC->RootHub2.IBase.pfnQueryInterface = xhciR3RhQueryInterface;
7990 pThisCC->RootHub2.IRhPort.pfnGetAvailablePorts = xhciR3RhGetAvailablePorts;
7991 pThisCC->RootHub2.IRhPort.pfnGetUSBVersions = xhciR3RhGetUSBVersions2;
7992 pThisCC->RootHub2.IRhPort.pfnAttach = xhciR3RhAttach;
7993 pThisCC->RootHub2.IRhPort.pfnDetach = xhciR3RhDetach;
7994 pThisCC->RootHub2.IRhPort.pfnReset = xhciR3RhReset;
7995 pThisCC->RootHub2.IRhPort.pfnXferCompletion = xhciR3RhXferCompletion;
7996 pThisCC->RootHub2.IRhPort.pfnXferError = xhciR3RhXferError;
7997
7998 /* Now the USB3 root hub interface. */
7999 pThis->cUsb3Ports = (uint8_t)cUsb3Ports;
8000 pThisCC->RootHub3.pXhciR3 = pThisCC;
8001 pThisCC->RootHub3.cPortsImpl = cUsb3Ports;
8002 pThisCC->RootHub3.uPortBase = XHCI_NDP_USB2(pThisCC);
8003 pThisCC->RootHub3.IBase.pfnQueryInterface = xhciR3RhQueryInterface;
8004 pThisCC->RootHub3.IRhPort.pfnGetAvailablePorts = xhciR3RhGetAvailablePorts;
8005 pThisCC->RootHub3.IRhPort.pfnGetUSBVersions = xhciR3RhGetUSBVersions3;
8006 pThisCC->RootHub3.IRhPort.pfnAttach = xhciR3RhAttach;
8007 pThisCC->RootHub3.IRhPort.pfnDetach = xhciR3RhDetach;
8008 pThisCC->RootHub3.IRhPort.pfnReset = xhciR3RhReset;
8009 pThisCC->RootHub3.IRhPort.pfnXferCompletion = xhciR3RhXferCompletion;
8010 pThisCC->RootHub3.IRhPort.pfnXferError = xhciR3RhXferError;
8011
8012 /* USB LED */
8013 pThisCC->RootHub2.Led.u32Magic = PDMLED_MAGIC;
8014 pThisCC->RootHub3.Led.u32Magic = PDMLED_MAGIC;
8015 pThisCC->IBase.pfnQueryInterface = xhciR3QueryStatusInterface;
8016 pThisCC->ILeds.pfnQueryStatusLed = xhciR3QueryStatusLed;
8017
8018 /* Initialize the capability registers */
8019 pThis->cap_length = XHCI_CAPS_REG_SIZE;
8020 pThis->hci_version = 0x100; /* Version 1.0 */
8021 pThis->hcs_params1 = (XHCI_NDP_CFG(pThis) << 24) | (XHCI_NINTR << 8) | XHCI_NDS;
8022 pThis->hcs_params2 = (XHCI_ERSTMAX_LOG2 << 4) | XHCI_IST;
8023 pThis->hcs_params3 = (4 << 16) | 1; /* Matches Intel 7 Series xHCI. */
8024 /* Note: The Intel 7 Series xHCI does not have port power control (XHCI_HCC_PPC). */
8025 pThis->hcc_params = ((XHCI_XECP_OFFSET >> 2) << XHCI_HCC_XECP_SHIFT); /// @todo other fields
8026 pThis->dbell_off = XHCI_DOORBELL_OFFSET;
8027 pThis->rts_off = XHCI_RTREG_OFFSET;
8028
8029 /*
8030 * Set up extended capabilities.
8031 */
8032 rc = xhciR3BuildExtCaps(pThis, pThisCC);
8033 AssertRCReturn(rc, rc);
8034
8035 /*
8036 * Register PCI device and I/O region.
8037 */
8038 rc = PDMDevHlpPCIRegister(pDevIns, pPciDev);
8039 AssertRCReturn(rc, rc);
8040
8041#ifdef VBOX_WITH_MSI_DEVICES
8042 PDMMSIREG MsiReg;
8043 RT_ZERO(MsiReg);
8044 MsiReg.cMsiVectors = 1;
8045 MsiReg.iMsiCapOffset = XHCI_PCI_MSI_CAP_OFS;
8046 MsiReg.iMsiNextOffset = 0x00;
8047 rc = PDMDevHlpPCIRegisterMsi(pDevIns, &MsiReg);
8048 if (RT_FAILURE (rc))
8049 {
8050 PCIDevSetCapabilityList(pPciDev, 0x0);
8051 /* That's OK, we can work without MSI */
8052 }
8053#endif
8054
8055 rc = PDMDevHlpPCIIORegionCreateMmio(pDevIns, 0, XHCI_MMIO_SIZE, PCI_ADDRESS_SPACE_MEM,
8056 xhciMmioWrite, xhciMmioRead, NULL,
8057 IOMMMIO_FLAGS_READ_DWORD | IOMMMIO_FLAGS_WRITE_DWORD_ZEROED
8058 /*| IOMMMIO_FLAGS_DBGSTOP_ON_COMPLICATED_WRITE*/,
8059 "USB xHCI", &pThis->hMmio);
8060 AssertRCReturn(rc, rc);
8061
8062 /*
8063 * Register the saved state data unit.
8064 */
8065 rc = PDMDevHlpSSMRegisterEx(pDevIns, XHCI_SAVED_STATE_VERSION, sizeof(*pThis), NULL,
8066 NULL, NULL, NULL,
8067 NULL, xhciR3SaveExec, NULL,
8068 NULL, xhciR3LoadExec, NULL);
8069 AssertRCReturn(rc, rc);
8070
8071 /*
8072 * Attach to the VBox USB RootHub Driver on LUN #0 (USB3 root hub).
8073 * NB: USB3 must come first so that emulated devices which support both USB2
8074 * and USB3 are attached to the USB3 hub.
8075 */
8076 rc = xhciR3RegisterHub(pDevIns, &pThisCC->RootHub3, 0, "RootHubUSB3");
8077 AssertRCReturn(rc, rc);
8078
8079 /*
8080 * Attach to the VBox USB RootHub Driver on LUN #1 (USB2 root hub).
8081 */
8082 rc = xhciR3RegisterHub(pDevIns, &pThisCC->RootHub2, 1, "RootHubUSB2");
8083 AssertRCReturn(rc, rc);
8084
8085 /*
8086 * Attach the status LED (optional).
8087 */
8088 PPDMIBASE pBase;
8089 rc = PDMDevHlpDriverAttach(pDevIns, PDM_STATUS_LUN, &pThisCC->IBase, &pBase, "Status Port");
8090 if (RT_SUCCESS(rc))
8091 pThisCC->pLedsConnector = PDMIBASE_QUERY_INTERFACE(pBase, PDMILEDCONNECTORS);
8092 else if (rc != VERR_PDM_NO_ATTACHED_DRIVER)
8093 {
8094 AssertMsgFailed(("xHCI: Failed to attach to status driver. rc=%Rrc\n", rc));
8095 return PDMDEV_SET_ERROR(pDevIns, rc, N_("xHCI cannot attach to status driver"));
8096 }
8097
8098 /*
8099 * Create the MFINDEX wrap event timer.
8100 */
8101 rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, xhciR3WrapTimer, pThis,
8102 TMTIMER_FLAGS_NO_CRIT_SECT | TMTIMER_FLAGS_RING0, "xHCI MFINDEX Wrap", &pThis->hWrapTimer);
8103 AssertRCReturn(rc, rc);
8104
8105 /*
8106 * Set up the worker thread.
8107 */
8108 rc = PDMDevHlpSUPSemEventCreate(pDevIns, &pThis->hEvtProcess);
8109 AssertLogRelRCReturn(rc, rc);
8110
8111 rc = RTCritSectInit(&pThisCC->CritSectThrd);
8112 AssertLogRelRCReturn(rc, rc);
8113
8114 rc = PDMDevHlpThreadCreate(pDevIns, &pThisCC->pWorkerThread, pThis, xhciR3WorkerLoop, xhciR3WorkerWakeUp,
8115 0, RTTHREADTYPE_IO, "xHCI");
8116 AssertLogRelRCReturn(rc, rc);
8117
8118 /*
8119 * Do a hardware reset.
8120 */
8121 xhciR3DoReset(pThis, pThisCC, XHCI_USB_RESET, false /* don't reset devices */);
8122
8123# ifdef VBOX_WITH_STATISTICS
8124 /*
8125 * Register statistics.
8126 */
8127 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatErrorIsocUrbs, STAMTYPE_COUNTER, "IsocUrbsErr", STAMUNIT_OCCURENCES, "Isoch URBs completed w/error.");
8128 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatErrorIsocPkts, STAMTYPE_COUNTER, "IsocPktsErr", STAMUNIT_OCCURENCES, "Isoch packets completed w/error.");
8129 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatEventsWritten, STAMTYPE_COUNTER, "EventsWritten", STAMUNIT_OCCURENCES, "Event TRBs delivered.");
8130 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatEventsDropped, STAMTYPE_COUNTER, "EventsDropped", STAMUNIT_OCCURENCES, "Event TRBs dropped (HC stopped).");
8131 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIntrsPending, STAMTYPE_COUNTER, "IntrsPending", STAMUNIT_OCCURENCES, "Requests to set the IP bit.");
8132 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIntrsSet, STAMTYPE_COUNTER, "IntrsSet", STAMUNIT_OCCURENCES, "Actual interrupts delivered.");
8133 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIntrsNotSet, STAMTYPE_COUNTER, "IntrsNotSet", STAMUNIT_OCCURENCES, "Interrupts not delivered/disabled.");
8134 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIntrsCleared, STAMTYPE_COUNTER, "IntrsCleared", STAMUNIT_OCCURENCES, "Interrupts cleared by guest.");
8135 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTRBsPerCtlUrb, STAMTYPE_COUNTER, "UrbTrbsCtl", STAMUNIT_COUNT, "TRBs per one control URB.");
8136 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTRBsPerDtaUrb, STAMTYPE_COUNTER, "UrbTrbsDta", STAMUNIT_COUNT, "TRBs per one data (bulk/intr) URB.");
8137 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTRBsPerIsoUrb, STAMTYPE_COUNTER, "UrbTrbsIso", STAMUNIT_COUNT, "TRBs per one isochronous URB.");
8138 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatUrbSizeCtrl, STAMTYPE_COUNTER, "UrbSizeCtl", STAMUNIT_COUNT, "Size of a control URB in bytes.");
8139 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatUrbSizeData, STAMTYPE_COUNTER, "UrbSizeDta", STAMUNIT_COUNT, "Size of a data (bulk/intr) URB in bytes.");
8140 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatUrbSizeIsoc, STAMTYPE_COUNTER, "UrbSizeIso", STAMUNIT_COUNT, "Size of an isochronous URB in bytes.");
8141
8142 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdCaps, STAMTYPE_COUNTER, "Regs/RdCaps", STAMUNIT_COUNT, "");
8143 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdCmdRingCtlHi, STAMTYPE_COUNTER, "Regs/RdCmdRingCtlHi", STAMUNIT_COUNT, "");
8144 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdCmdRingCtlLo, STAMTYPE_COUNTER, "Regs/RdCmdRingCtlLo", STAMUNIT_COUNT, "");
8145 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdConfig, STAMTYPE_COUNTER, "Regs/RdConfig", STAMUNIT_COUNT, "");
8146 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdDevCtxBaapHi, STAMTYPE_COUNTER, "Regs/RdDevCtxBaapHi", STAMUNIT_COUNT, "");
8147 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdDevCtxBaapLo, STAMTYPE_COUNTER, "Regs/RdDevCtxBaapLo", STAMUNIT_COUNT, "");
8148 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdDevNotifyCtrl, STAMTYPE_COUNTER, "Regs/RdDevNotifyCtrl", STAMUNIT_COUNT, "");
8149 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdDoorBell, STAMTYPE_COUNTER, "Regs/RdDoorBell", STAMUNIT_COUNT, "");
8150 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdEvtRingDeqPtrHi, STAMTYPE_COUNTER, "Regs/RdEvtRingDeqPtrHi", STAMUNIT_COUNT, "");
8151 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdEvtRingDeqPtrLo, STAMTYPE_COUNTER, "Regs/RdEvtRingDeqPtrLo", STAMUNIT_COUNT, "");
8152 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdEvtRsTblBaseHi, STAMTYPE_COUNTER, "Regs/RdEvtRsTblBaseHi", STAMUNIT_COUNT, "");
8153 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdEvtRsTblBaseLo, STAMTYPE_COUNTER, "Regs/RdEvtRsTblBaseLo", STAMUNIT_COUNT, "");
8154 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdEvtRstblSize, STAMTYPE_COUNTER, "Regs/RdEvtRstblSize", STAMUNIT_COUNT, "");
8155 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdEvtRsvd, STAMTYPE_COUNTER, "Regs/RdEvtRsvd", STAMUNIT_COUNT, "");
8156 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdIntrMgmt, STAMTYPE_COUNTER, "Regs/RdIntrMgmt", STAMUNIT_COUNT, "");
8157 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdIntrMod, STAMTYPE_COUNTER, "Regs/RdIntrMod", STAMUNIT_COUNT, "");
8158 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdMfIndex, STAMTYPE_COUNTER, "Regs/RdMfIndex", STAMUNIT_COUNT, "");
8159 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdPageSize, STAMTYPE_COUNTER, "Regs/RdPageSize", STAMUNIT_COUNT, "");
8160 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdPortLinkInfo, STAMTYPE_COUNTER, "Regs/RdPortLinkInfo", STAMUNIT_COUNT, "");
8161 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdPortPowerMgmt, STAMTYPE_COUNTER, "Regs/RdPortPowerMgmt", STAMUNIT_COUNT, "");
8162 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdPortRsvd, STAMTYPE_COUNTER, "Regs/RdPortRsvd", STAMUNIT_COUNT, "");
8163 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdPortStatusCtrl, STAMTYPE_COUNTER, "Regs/RdPortStatusCtrl", STAMUNIT_COUNT, "");
8164 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdUsbCmd, STAMTYPE_COUNTER, "Regs/RdUsbCmd", STAMUNIT_COUNT, "");
8165 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdUsbSts, STAMTYPE_COUNTER, "Regs/RdUsbSts", STAMUNIT_COUNT, "");
8166 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRdUnknown, STAMTYPE_COUNTER, "Regs/RdUnknown", STAMUNIT_COUNT, "");
8167
8168 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrCmdRingCtlHi, STAMTYPE_COUNTER, "Regs/WrCmdRingCtlHi", STAMUNIT_COUNT, "");
8169 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrCmdRingCtlLo, STAMTYPE_COUNTER, "Regs/WrCmdRingCtlLo", STAMUNIT_COUNT, "");
8170 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrConfig, STAMTYPE_COUNTER, "Regs/WrConfig", STAMUNIT_COUNT, "");
8171 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrDevCtxBaapHi, STAMTYPE_COUNTER, "Regs/WrDevCtxBaapHi", STAMUNIT_COUNT, "");
8172 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrDevCtxBaapLo, STAMTYPE_COUNTER, "Regs/WrDevCtxBaapLo", STAMUNIT_COUNT, "");
8173 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrDevNotifyCtrl, STAMTYPE_COUNTER, "Regs/WrDevNotifyCtrl", STAMUNIT_COUNT, "");
8174 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrDoorBell0, STAMTYPE_COUNTER, "Regs/WrDoorBell0", STAMUNIT_COUNT, "");
8175 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrDoorBellN, STAMTYPE_COUNTER, "Regs/WrDoorBellN", STAMUNIT_COUNT, "");
8176 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrEvtRingDeqPtrHi, STAMTYPE_COUNTER, "Regs/WrEvtRingDeqPtrHi", STAMUNIT_COUNT, "");
8177 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrEvtRingDeqPtrLo, STAMTYPE_COUNTER, "Regs/WrEvtRingDeqPtrLo", STAMUNIT_COUNT, "");
8178 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrEvtRsTblBaseHi, STAMTYPE_COUNTER, "Regs/WrEvtRsTblBaseHi", STAMUNIT_COUNT, "");
8179 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrEvtRsTblBaseLo, STAMTYPE_COUNTER, "Regs/WrEvtRsTblBaseLo", STAMUNIT_COUNT, "");
8180 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrEvtRstblSize, STAMTYPE_COUNTER, "Regs/WrEvtRstblSize", STAMUNIT_COUNT, "");
8181 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrIntrMgmt, STAMTYPE_COUNTER, "Regs/WrIntrMgmt", STAMUNIT_COUNT, "");
8182 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrIntrMod, STAMTYPE_COUNTER, "Regs/WrIntrMod", STAMUNIT_COUNT, "");
8183 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrPortPowerMgmt, STAMTYPE_COUNTER, "Regs/WrPortPowerMgmt", STAMUNIT_COUNT, "");
8184 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrPortStatusCtrl, STAMTYPE_COUNTER, "Regs/WrPortStatusCtrl", STAMUNIT_COUNT, "");
8185 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrUsbCmd, STAMTYPE_COUNTER, "Regs/WrUsbCmd", STAMUNIT_COUNT, "");
8186 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrUsbSts, STAMTYPE_COUNTER, "Regs/WrUsbSts", STAMUNIT_COUNT, "");
8187 PDMDevHlpSTAMRegister(pDevIns, &pThis->StatWrUnknown, STAMTYPE_COUNTER, "Regs/WrUnknown", STAMUNIT_COUNT, "");
8188# endif /* VBOX_WITH_STATISTICS */
8189
8190 /*
8191 * Register debugger info callbacks.
8192 */
8193 PDMDevHlpDBGFInfoRegister(pDevIns, "xhci", "xHCI registers.", xhciR3Info);
8194
8195 return VINF_SUCCESS;
8196}
8197
8198#else /* !IN_RING3 */
8199
8200/**
8201 * @callback_method_impl{PDMDEVREGR0,pfnConstruct}
8202 */
8203static DECLCALLBACK(int) xhciRZConstruct(PPDMDEVINS pDevIns)
8204{
8205 PDMDEV_CHECK_VERSIONS_RETURN(pDevIns);
8206 PXHCI pThis = PDMDEVINS_2_DATA(pDevIns, PXHCI);
8207
8208 int rc = PDMDevHlpMmioSetUpContext(pDevIns, pThis->hMmio, xhciMmioWrite, xhciMmioRead, NULL /*pvUser*/);
8209 AssertRCReturn(rc, rc);
8210
8211 return VINF_SUCCESS;
8212}
8213
8214#endif /* !IN_RING3 */
8215
8216/* Without this, g_DeviceXHCI won't be visible outside this module! */
8217extern "C" const PDMDEVREG g_DeviceXHCI;
8218
8219const PDMDEVREG g_DeviceXHCI =
8220{
8221 /* .u32version = */ PDM_DEVREG_VERSION,
8222 /* .uReserved0 = */ 0,
8223 /* .szName = */ "usb-xhci",
8224 /* .fFlags = */ PDM_DEVREG_FLAGS_DEFAULT_BITS | PDM_DEVREG_FLAGS_RZ | PDM_DEVREG_FLAGS_NEW_STYLE,
8225 /* .fClass = */ PDM_DEVREG_CLASS_BUS_USB,
8226 /* .cMaxInstances = */ ~0U,
8227 /* .uSharedVersion = */ 42,
8228 /* .cbInstanceShared = */ sizeof(XHCI),
8229 /* .cbInstanceCC = */ sizeof(XHCICC),
8230 /* .cbInstanceRC = */ sizeof(XHCIRC),
8231 /* .cMaxPciDevices = */ 1,
8232 /* .cMaxMsixVectors = */ 0,
8233 /* .pszDescription = */ "xHCI USB controller.\n",
8234#if defined(IN_RING3)
8235# ifdef VBOX_IN_EXTPACK
8236 /* .pszRCMod = */ "VBoxEhciRC.rc",
8237 /* .pszR0Mod = */ "VBoxEhciR0.r0",
8238# else
8239 /* .pszRCMod = */ "VBoxDDRC.rc",
8240 /* .pszR0Mod = */ "VBoxDDR0.r0",
8241# endif
8242 /* .pfnConstruct = */ xhciR3Construct,
8243 /* .pfnDestruct = */ xhciR3Destruct,
8244 /* .pfnRelocate = */ NULL,
8245 /* .pfnMemSetup = */ NULL,
8246 /* .pfnPowerOn = */ NULL,
8247 /* .pfnReset = */ xhciR3Reset,
8248 /* .pfnSuspend = */ NULL,
8249 /* .pfnResume = */ NULL,
8250 /* .pfnAttach = */ NULL,
8251 /* .pfnDetach = */ NULL,
8252 /* .pfnQueryInterface = */ NULL,
8253 /* .pfnInitComplete = */ NULL,
8254 /* .pfnPowerOff = */ NULL,
8255 /* .pfnSoftReset = */ NULL,
8256 /* .pfnReserved0 = */ NULL,
8257 /* .pfnReserved1 = */ NULL,
8258 /* .pfnReserved2 = */ NULL,
8259 /* .pfnReserved3 = */ NULL,
8260 /* .pfnReserved4 = */ NULL,
8261 /* .pfnReserved5 = */ NULL,
8262 /* .pfnReserved6 = */ NULL,
8263 /* .pfnReserved7 = */ NULL,
8264#elif defined(IN_RING0)
8265 /* .pfnEarlyConstruct = */ NULL,
8266 /* .pfnConstruct = */ xhciRZConstruct,
8267 /* .pfnDestruct = */ NULL,
8268 /* .pfnFinalDestruct = */ NULL,
8269 /* .pfnRequest = */ NULL,
8270 /* .pfnReserved0 = */ NULL,
8271 /* .pfnReserved1 = */ NULL,
8272 /* .pfnReserved2 = */ NULL,
8273 /* .pfnReserved3 = */ NULL,
8274 /* .pfnReserved4 = */ NULL,
8275 /* .pfnReserved5 = */ NULL,
8276 /* .pfnReserved6 = */ NULL,
8277 /* .pfnReserved7 = */ NULL,
8278#elif defined(IN_RC)
8279 /* .pfnConstruct = */ xhciRZConstruct,
8280 /* .pfnReserved0 = */ NULL,
8281 /* .pfnReserved1 = */ NULL,
8282 /* .pfnReserved2 = */ NULL,
8283 /* .pfnReserved3 = */ NULL,
8284 /* .pfnReserved4 = */ NULL,
8285 /* .pfnReserved5 = */ NULL,
8286 /* .pfnReserved6 = */ NULL,
8287 /* .pfnReserved7 = */ NULL,
8288#else
8289# error "Not in IN_RING3, IN_RING0 or IN_RC!"
8290#endif
8291 /* .u32VersionEnd = */ PDM_DEVREG_VERSION
8292};
8293
8294#endif /* !VBOX_DEVICE_STRUCT_TESTCASE */
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