qemu/hw/usb/hcd-xhci.c

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/*
* USB xHCI controller emulation
*
* Copyright (c) 2011 Securiforest
* Date: 2011-05-11 ; Author: Hector Martin <hector@marcansoft.com>
* Based on usb-ohci.c, emulates Renesas NEC USB 3.0
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
#include "qemu/osdep.h"
#include "hw/hw.h"
#include "qemu/timer.h"
#include "qemu/queue.h"
#include "hw/usb.h"
#include "hw/pci/pci.h"
#include "hw/pci/msi.h"
#include "hw/pci/msix.h"
#include "trace.h"
#include "qapi/error.h"
#include "hcd-xhci.h"
//#define DEBUG_XHCI
//#define DEBUG_DATA
#ifdef DEBUG_XHCI
#define DPRINTF(...) fprintf(stderr, __VA_ARGS__)
#else
#define DPRINTF(...) do {} while (0)
#endif
#define FIXME(_msg) do { fprintf(stderr, "FIXME %s:%d %s\n", \
__func__, __LINE__, _msg); abort(); } while (0)
#define TRB_LINK_LIMIT 32
#define COMMAND_LIMIT 256
#define TRANSFER_LIMIT 256
#define LEN_CAP 0x40
#define LEN_OPER (0x400 + 0x10 * MAXPORTS)
#define LEN_RUNTIME ((MAXINTRS + 1) * 0x20)
#define LEN_DOORBELL ((MAXSLOTS + 1) * 0x20)
#define OFF_OPER LEN_CAP
#define OFF_RUNTIME 0x1000
#define OFF_DOORBELL 0x2000
#define OFF_MSIX_TABLE 0x3000
#define OFF_MSIX_PBA 0x3800
/* must be power of 2 */
#define LEN_REGS 0x4000
#if (OFF_OPER + LEN_OPER) > OFF_RUNTIME
#error Increase OFF_RUNTIME
#endif
#if (OFF_RUNTIME + LEN_RUNTIME) > OFF_DOORBELL
#error Increase OFF_DOORBELL
#endif
#if (OFF_DOORBELL + LEN_DOORBELL) > LEN_REGS
# error Increase LEN_REGS
#endif
/* bit definitions */
#define USBCMD_RS (1<<0)
#define USBCMD_HCRST (1<<1)
#define USBCMD_INTE (1<<2)
#define USBCMD_HSEE (1<<3)
#define USBCMD_LHCRST (1<<7)
#define USBCMD_CSS (1<<8)
#define USBCMD_CRS (1<<9)
#define USBCMD_EWE (1<<10)
#define USBCMD_EU3S (1<<11)
#define USBSTS_HCH (1<<0)
#define USBSTS_HSE (1<<2)
#define USBSTS_EINT (1<<3)
#define USBSTS_PCD (1<<4)
#define USBSTS_SSS (1<<8)
#define USBSTS_RSS (1<<9)
#define USBSTS_SRE (1<<10)
#define USBSTS_CNR (1<<11)
#define USBSTS_HCE (1<<12)
#define PORTSC_CCS (1<<0)
#define PORTSC_PED (1<<1)
#define PORTSC_OCA (1<<3)
#define PORTSC_PR (1<<4)
#define PORTSC_PLS_SHIFT 5
#define PORTSC_PLS_MASK 0xf
#define PORTSC_PP (1<<9)
#define PORTSC_SPEED_SHIFT 10
#define PORTSC_SPEED_MASK 0xf
#define PORTSC_SPEED_FULL (1<<10)
#define PORTSC_SPEED_LOW (2<<10)
#define PORTSC_SPEED_HIGH (3<<10)
#define PORTSC_SPEED_SUPER (4<<10)
#define PORTSC_PIC_SHIFT 14
#define PORTSC_PIC_MASK 0x3
#define PORTSC_LWS (1<<16)
#define PORTSC_CSC (1<<17)
#define PORTSC_PEC (1<<18)
#define PORTSC_WRC (1<<19)
#define PORTSC_OCC (1<<20)
#define PORTSC_PRC (1<<21)
#define PORTSC_PLC (1<<22)
#define PORTSC_CEC (1<<23)
#define PORTSC_CAS (1<<24)
#define PORTSC_WCE (1<<25)
#define PORTSC_WDE (1<<26)
#define PORTSC_WOE (1<<27)
#define PORTSC_DR (1<<30)
#define PORTSC_WPR (1<<31)
#define CRCR_RCS (1<<0)
#define CRCR_CS (1<<1)
#define CRCR_CA (1<<2)
#define CRCR_CRR (1<<3)
#define IMAN_IP (1<<0)
#define IMAN_IE (1<<1)
#define ERDP_EHB (1<<3)
#define TRB_SIZE 16
typedef struct XHCITRB {
uint64_t parameter;
uint32_t status;
uint32_t control;
dma_addr_t addr;
bool ccs;
} XHCITRB;
enum {
PLS_U0 = 0,
PLS_U1 = 1,
PLS_U2 = 2,
PLS_U3 = 3,
PLS_DISABLED = 4,
PLS_RX_DETECT = 5,
PLS_INACTIVE = 6,
PLS_POLLING = 7,
PLS_RECOVERY = 8,
PLS_HOT_RESET = 9,
PLS_COMPILANCE_MODE = 10,
PLS_TEST_MODE = 11,
PLS_RESUME = 15,
};
#define CR_LINK TR_LINK
#define TRB_C (1<<0)
#define TRB_TYPE_SHIFT 10
#define TRB_TYPE_MASK 0x3f
#define TRB_TYPE(t) (((t).control >> TRB_TYPE_SHIFT) & TRB_TYPE_MASK)
#define TRB_EV_ED (1<<2)
#define TRB_TR_ENT (1<<1)
#define TRB_TR_ISP (1<<2)
#define TRB_TR_NS (1<<3)
#define TRB_TR_CH (1<<4)
#define TRB_TR_IOC (1<<5)
#define TRB_TR_IDT (1<<6)
#define TRB_TR_TBC_SHIFT 7
#define TRB_TR_TBC_MASK 0x3
#define TRB_TR_BEI (1<<9)
#define TRB_TR_TLBPC_SHIFT 16
#define TRB_TR_TLBPC_MASK 0xf
#define TRB_TR_FRAMEID_SHIFT 20
#define TRB_TR_FRAMEID_MASK 0x7ff
#define TRB_TR_SIA (1<<31)
#define TRB_TR_DIR (1<<16)
#define TRB_CR_SLOTID_SHIFT 24
#define TRB_CR_SLOTID_MASK 0xff
#define TRB_CR_EPID_SHIFT 16
#define TRB_CR_EPID_MASK 0x1f
#define TRB_CR_BSR (1<<9)
#define TRB_CR_DC (1<<9)
#define TRB_LK_TC (1<<1)
#define TRB_INTR_SHIFT 22
#define TRB_INTR_MASK 0x3ff
#define TRB_INTR(t) (((t).status >> TRB_INTR_SHIFT) & TRB_INTR_MASK)
#define EP_TYPE_MASK 0x7
#define EP_TYPE_SHIFT 3
#define EP_STATE_MASK 0x7
#define EP_DISABLED (0<<0)
#define EP_RUNNING (1<<0)
#define EP_HALTED (2<<0)
#define EP_STOPPED (3<<0)
#define EP_ERROR (4<<0)
#define SLOT_STATE_MASK 0x1f
#define SLOT_STATE_SHIFT 27
#define SLOT_STATE(s) (((s)>>SLOT_STATE_SHIFT)&SLOT_STATE_MASK)
#define SLOT_ENABLED 0
#define SLOT_DEFAULT 1
#define SLOT_ADDRESSED 2
#define SLOT_CONFIGURED 3
#define SLOT_CONTEXT_ENTRIES_MASK 0x1f
#define SLOT_CONTEXT_ENTRIES_SHIFT 27
#define get_field(data, field) \
(((data) >> field##_SHIFT) & field##_MASK)
#define set_field(data, newval, field) do { \
uint32_t val = *data; \
val &= ~(field##_MASK << field##_SHIFT); \
val |= ((newval) & field##_MASK) << field##_SHIFT; \
*data = val; \
} while (0)
typedef enum EPType {
ET_INVALID = 0,
ET_ISO_OUT,
ET_BULK_OUT,
ET_INTR_OUT,
ET_CONTROL,
ET_ISO_IN,
ET_BULK_IN,
ET_INTR_IN,
} EPType;
typedef struct XHCITransfer {
XHCIEPContext *epctx;
USBPacket packet;
QEMUSGList sgl;
bool running_async;
bool running_retry;
bool complete;
bool int_req;
unsigned int iso_pkts;
unsigned int streamid;
bool in_xfer;
bool iso_xfer;
bool timed_xfer;
unsigned int trb_count;
XHCITRB *trbs;
TRBCCode status;
unsigned int pkts;
unsigned int pktsize;
unsigned int cur_pkt;
uint64_t mfindex_kick;
QTAILQ_ENTRY(XHCITransfer) next;
} XHCITransfer;
struct XHCIStreamContext {
dma_addr_t pctx;
unsigned int sct;
XHCIRing ring;
};
struct XHCIEPContext {
XHCIState *xhci;
unsigned int slotid;
unsigned int epid;
XHCIRing ring;
uint32_t xfer_count;
QTAILQ_HEAD(, XHCITransfer) transfers;
XHCITransfer *retry;
EPType type;
dma_addr_t pctx;
unsigned int max_psize;
uint32_t state;
uint32_t kick_active;
/* streams */
unsigned int max_pstreams;
bool lsa;
unsigned int nr_pstreams;
XHCIStreamContext *pstreams;
/* iso xfer scheduling */
unsigned int interval;
int64_t mfindex_last;
QEMUTimer *kick_timer;
};
typedef struct XHCIEvRingSeg {
uint32_t addr_low;
uint32_t addr_high;
uint32_t size;
uint32_t rsvd;
} XHCIEvRingSeg;
static void xhci_kick_ep(XHCIState *xhci, unsigned int slotid,
unsigned int epid, unsigned int streamid);
static void xhci_kick_epctx(XHCIEPContext *epctx, unsigned int streamid);
static TRBCCode xhci_disable_ep(XHCIState *xhci, unsigned int slotid,
unsigned int epid);
static void xhci_xfer_report(XHCITransfer *xfer);
static void xhci_event(XHCIState *xhci, XHCIEvent *event, int v);
static void xhci_write_event(XHCIState *xhci, XHCIEvent *event, int v);
static USBEndpoint *xhci_epid_to_usbep(XHCIEPContext *epctx);
static const char *TRBType_names[] = {
[TRB_RESERVED] = "TRB_RESERVED",
[TR_NORMAL] = "TR_NORMAL",
[TR_SETUP] = "TR_SETUP",
[TR_DATA] = "TR_DATA",
[TR_STATUS] = "TR_STATUS",
[TR_ISOCH] = "TR_ISOCH",
[TR_LINK] = "TR_LINK",
[TR_EVDATA] = "TR_EVDATA",
[TR_NOOP] = "TR_NOOP",
[CR_ENABLE_SLOT] = "CR_ENABLE_SLOT",
[CR_DISABLE_SLOT] = "CR_DISABLE_SLOT",
[CR_ADDRESS_DEVICE] = "CR_ADDRESS_DEVICE",
[CR_CONFIGURE_ENDPOINT] = "CR_CONFIGURE_ENDPOINT",
[CR_EVALUATE_CONTEXT] = "CR_EVALUATE_CONTEXT",
[CR_RESET_ENDPOINT] = "CR_RESET_ENDPOINT",
[CR_STOP_ENDPOINT] = "CR_STOP_ENDPOINT",
[CR_SET_TR_DEQUEUE] = "CR_SET_TR_DEQUEUE",
[CR_RESET_DEVICE] = "CR_RESET_DEVICE",
[CR_FORCE_EVENT] = "CR_FORCE_EVENT",
[CR_NEGOTIATE_BW] = "CR_NEGOTIATE_BW",
[CR_SET_LATENCY_TOLERANCE] = "CR_SET_LATENCY_TOLERANCE",
[CR_GET_PORT_BANDWIDTH] = "CR_GET_PORT_BANDWIDTH",
[CR_FORCE_HEADER] = "CR_FORCE_HEADER",
[CR_NOOP] = "CR_NOOP",
[ER_TRANSFER] = "ER_TRANSFER",
[ER_COMMAND_COMPLETE] = "ER_COMMAND_COMPLETE",
[ER_PORT_STATUS_CHANGE] = "ER_PORT_STATUS_CHANGE",
[ER_BANDWIDTH_REQUEST] = "ER_BANDWIDTH_REQUEST",
[ER_DOORBELL] = "ER_DOORBELL",
[ER_HOST_CONTROLLER] = "ER_HOST_CONTROLLER",
[ER_DEVICE_NOTIFICATION] = "ER_DEVICE_NOTIFICATION",
[ER_MFINDEX_WRAP] = "ER_MFINDEX_WRAP",
[CR_VENDOR_NEC_FIRMWARE_REVISION] = "CR_VENDOR_NEC_FIRMWARE_REVISION",
[CR_VENDOR_NEC_CHALLENGE_RESPONSE] = "CR_VENDOR_NEC_CHALLENGE_RESPONSE",
};
static const char *TRBCCode_names[] = {
[CC_INVALID] = "CC_INVALID",
[CC_SUCCESS] = "CC_SUCCESS",
[CC_DATA_BUFFER_ERROR] = "CC_DATA_BUFFER_ERROR",
[CC_BABBLE_DETECTED] = "CC_BABBLE_DETECTED",
[CC_USB_TRANSACTION_ERROR] = "CC_USB_TRANSACTION_ERROR",
[CC_TRB_ERROR] = "CC_TRB_ERROR",
[CC_STALL_ERROR] = "CC_STALL_ERROR",
[CC_RESOURCE_ERROR] = "CC_RESOURCE_ERROR",
[CC_BANDWIDTH_ERROR] = "CC_BANDWIDTH_ERROR",
[CC_NO_SLOTS_ERROR] = "CC_NO_SLOTS_ERROR",
[CC_INVALID_STREAM_TYPE_ERROR] = "CC_INVALID_STREAM_TYPE_ERROR",
[CC_SLOT_NOT_ENABLED_ERROR] = "CC_SLOT_NOT_ENABLED_ERROR",
[CC_EP_NOT_ENABLED_ERROR] = "CC_EP_NOT_ENABLED_ERROR",
[CC_SHORT_PACKET] = "CC_SHORT_PACKET",
[CC_RING_UNDERRUN] = "CC_RING_UNDERRUN",
[CC_RING_OVERRUN] = "CC_RING_OVERRUN",
[CC_VF_ER_FULL] = "CC_VF_ER_FULL",
[CC_PARAMETER_ERROR] = "CC_PARAMETER_ERROR",
[CC_BANDWIDTH_OVERRUN] = "CC_BANDWIDTH_OVERRUN",
[CC_CONTEXT_STATE_ERROR] = "CC_CONTEXT_STATE_ERROR",
[CC_NO_PING_RESPONSE_ERROR] = "CC_NO_PING_RESPONSE_ERROR",
[CC_EVENT_RING_FULL_ERROR] = "CC_EVENT_RING_FULL_ERROR",
[CC_INCOMPATIBLE_DEVICE_ERROR] = "CC_INCOMPATIBLE_DEVICE_ERROR",
[CC_MISSED_SERVICE_ERROR] = "CC_MISSED_SERVICE_ERROR",
[CC_COMMAND_RING_STOPPED] = "CC_COMMAND_RING_STOPPED",
[CC_COMMAND_ABORTED] = "CC_COMMAND_ABORTED",
[CC_STOPPED] = "CC_STOPPED",
[CC_STOPPED_LENGTH_INVALID] = "CC_STOPPED_LENGTH_INVALID",
[CC_MAX_EXIT_LATENCY_TOO_LARGE_ERROR]
= "CC_MAX_EXIT_LATENCY_TOO_LARGE_ERROR",
[CC_ISOCH_BUFFER_OVERRUN] = "CC_ISOCH_BUFFER_OVERRUN",
[CC_EVENT_LOST_ERROR] = "CC_EVENT_LOST_ERROR",
[CC_UNDEFINED_ERROR] = "CC_UNDEFINED_ERROR",
[CC_INVALID_STREAM_ID_ERROR] = "CC_INVALID_STREAM_ID_ERROR",
[CC_SECONDARY_BANDWIDTH_ERROR] = "CC_SECONDARY_BANDWIDTH_ERROR",
[CC_SPLIT_TRANSACTION_ERROR] = "CC_SPLIT_TRANSACTION_ERROR",
};
static const char *ep_state_names[] = {
[EP_DISABLED] = "disabled",
[EP_RUNNING] = "running",
[EP_HALTED] = "halted",
[EP_STOPPED] = "stopped",
[EP_ERROR] = "error",
};
static const char *lookup_name(uint32_t index, const char **list, uint32_t llen)
{
if (index >= llen || list[index] == NULL) {
return "???";
}
return list[index];
}
static const char *trb_name(XHCITRB *trb)
{
return lookup_name(TRB_TYPE(*trb), TRBType_names,
ARRAY_SIZE(TRBType_names));
}
static const char *event_name(XHCIEvent *event)
{
return lookup_name(event->ccode, TRBCCode_names,
ARRAY_SIZE(TRBCCode_names));
}
static const char *ep_state_name(uint32_t state)
{
return lookup_name(state, ep_state_names,
ARRAY_SIZE(ep_state_names));
}
static bool xhci_get_flag(XHCIState *xhci, enum xhci_flags bit)
{
return xhci->flags & (1 << bit);
}
static void xhci_set_flag(XHCIState *xhci, enum xhci_flags bit)
{
xhci->flags |= (1 << bit);
}
static uint64_t xhci_mfindex_get(XHCIState *xhci)
{
int64_t now = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL);
return (now - xhci->mfindex_start) / 125000;
}
static void xhci_mfwrap_update(XHCIState *xhci)
{
const uint32_t bits = USBCMD_RS | USBCMD_EWE;
uint32_t mfindex, left;
int64_t now;
if ((xhci->usbcmd & bits) == bits) {
now = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL);
mfindex = ((now - xhci->mfindex_start) / 125000) & 0x3fff;
left = 0x4000 - mfindex;
timer_mod(xhci->mfwrap_timer, now + left * 125000);
} else {
timer_del(xhci->mfwrap_timer);
}
}
static void xhci_mfwrap_timer(void *opaque)
{
XHCIState *xhci = opaque;
XHCIEvent wrap = { ER_MFINDEX_WRAP, CC_SUCCESS };
xhci_event(xhci, &wrap, 0);
xhci_mfwrap_update(xhci);
}
static inline dma_addr_t xhci_addr64(uint32_t low, uint32_t high)
{
if (sizeof(dma_addr_t) == 4) {
return low;
} else {
return low | (((dma_addr_t)high << 16) << 16);
}
}
static inline dma_addr_t xhci_mask64(uint64_t addr)
{
if (sizeof(dma_addr_t) == 4) {
return addr & 0xffffffff;
} else {
return addr;
}
}
static inline void xhci_dma_read_u32s(XHCIState *xhci, dma_addr_t addr,
uint32_t *buf, size_t len)
{
int i;
assert((len % sizeof(uint32_t)) == 0);
pci_dma_read(PCI_DEVICE(xhci), addr, buf, len);
for (i = 0; i < (len / sizeof(uint32_t)); i++) {
buf[i] = le32_to_cpu(buf[i]);
}
}
static inline void xhci_dma_write_u32s(XHCIState *xhci, dma_addr_t addr,
uint32_t *buf, size_t len)
{
int i;
uint32_t tmp[5];
uint32_t n = len / sizeof(uint32_t);
assert((len % sizeof(uint32_t)) == 0);
assert(n <= ARRAY_SIZE(tmp));
for (i = 0; i < n; i++) {
tmp[i] = cpu_to_le32(buf[i]);
}
pci_dma_write(PCI_DEVICE(xhci), addr, tmp, len);
}
static XHCIPort *xhci_lookup_port(XHCIState *xhci, struct USBPort *uport)
{
int index;
if (!uport->dev) {
return NULL;
}
switch (uport->dev->speed) {
case USB_SPEED_LOW:
case USB_SPEED_FULL:
case USB_SPEED_HIGH:
if (xhci_get_flag(xhci, XHCI_FLAG_SS_FIRST)) {
index = uport->index + xhci->numports_3;
} else {
index = uport->index;
}
break;
case USB_SPEED_SUPER:
if (xhci_get_flag(xhci, XHCI_FLAG_SS_FIRST)) {
index = uport->index;
} else {
index = uport->index + xhci->numports_2;
}
break;
default:
return NULL;
}
return &xhci->ports[index];
}
static void xhci_intx_update(XHCIState *xhci)
{
PCIDevice *pci_dev = PCI_DEVICE(xhci);
int level = 0;
if (msix_enabled(pci_dev) ||
msi_enabled(pci_dev)) {
return;
}
if (xhci->intr[0].iman & IMAN_IP &&
xhci->intr[0].iman & IMAN_IE &&
xhci->usbcmd & USBCMD_INTE) {
level = 1;
}
trace_usb_xhci_irq_intx(level);
pci_set_irq(pci_dev, level);
}
static void xhci_msix_update(XHCIState *xhci, int v)
{
PCIDevice *pci_dev = PCI_DEVICE(xhci);
bool enabled;
if (!msix_enabled(pci_dev)) {
return;
}
enabled = xhci->intr[v].iman & IMAN_IE;
if (enabled == xhci->intr[v].msix_used) {
return;
}
if (enabled) {
trace_usb_xhci_irq_msix_use(v);
msix_vector_use(pci_dev, v);
xhci->intr[v].msix_used = true;
} else {
trace_usb_xhci_irq_msix_unuse(v);
msix_vector_unuse(pci_dev, v);
xhci->intr[v].msix_used = false;
}
}
static void xhci_intr_raise(XHCIState *xhci, int v)
{
PCIDevice *pci_dev = PCI_DEVICE(xhci);
xhci: fix event queue IRQ handling The qemu xhci emulation doesn't handle the ERDP_EHB flag correctly. When the host adapter queues a new event the ERDP_EHB flag is set. The flag is cleared (via w1c) by the guest when it updates the ERDP (event ring dequeue pointer) register to notify the host adapter which events it has fetched. An IRQ must be raised in case the ERDP_EHB flag flips from clear to set. If the flag is set already (which implies there are events queued up which are not yet processed by the guest) xhci must *not* raise a IRQ. Qemu got that wrong and raised an IRQ on every event, thereby generating spurious interrupts in case we've queued events faster than the guest processed them. This patch fixes that. With that change in place we also have to check ERDP updates, to see whenever the guest has fetched all queued events. In case there are still pending events set ERDP_EHB and raise an IRQ again, to make sure the events don't linger unseen forever. The linux kernel driver and the microsoft windows driver (shipped with win8+) can deal with the spurious interrupts without problems. The renesas windows driver (v2.1.39) which can be used on older windows versions is quite upset though. It does spurious ERDP updates now and then (not every time, seems we must hit a race window for this to happen), which in turn makes the qemu xhci emulation think the event ring is full. Things go south from here ... tl;dr: This is the "fix xhci on win7" patch. Cc: M.Cerveny@computer.org Cc: 1373228@bugs.launchpad.net Signed-off-by: Gerd Hoffmann <kraxel@redhat.com> Message-id: 1486104705-13761-1-git-send-email-kraxel@redhat.com
2017-02-03 09:51:45 +03:00
bool pending = (xhci->intr[v].erdp_low & ERDP_EHB);
xhci->intr[v].erdp_low |= ERDP_EHB;
xhci->intr[v].iman |= IMAN_IP;
xhci->usbsts |= USBSTS_EINT;
xhci: fix event queue IRQ handling The qemu xhci emulation doesn't handle the ERDP_EHB flag correctly. When the host adapter queues a new event the ERDP_EHB flag is set. The flag is cleared (via w1c) by the guest when it updates the ERDP (event ring dequeue pointer) register to notify the host adapter which events it has fetched. An IRQ must be raised in case the ERDP_EHB flag flips from clear to set. If the flag is set already (which implies there are events queued up which are not yet processed by the guest) xhci must *not* raise a IRQ. Qemu got that wrong and raised an IRQ on every event, thereby generating spurious interrupts in case we've queued events faster than the guest processed them. This patch fixes that. With that change in place we also have to check ERDP updates, to see whenever the guest has fetched all queued events. In case there are still pending events set ERDP_EHB and raise an IRQ again, to make sure the events don't linger unseen forever. The linux kernel driver and the microsoft windows driver (shipped with win8+) can deal with the spurious interrupts without problems. The renesas windows driver (v2.1.39) which can be used on older windows versions is quite upset though. It does spurious ERDP updates now and then (not every time, seems we must hit a race window for this to happen), which in turn makes the qemu xhci emulation think the event ring is full. Things go south from here ... tl;dr: This is the "fix xhci on win7" patch. Cc: M.Cerveny@computer.org Cc: 1373228@bugs.launchpad.net Signed-off-by: Gerd Hoffmann <kraxel@redhat.com> Message-id: 1486104705-13761-1-git-send-email-kraxel@redhat.com
2017-02-03 09:51:45 +03:00
if (pending) {
return;
}
if (!(xhci->intr[v].iman & IMAN_IE)) {
return;
}
if (!(xhci->usbcmd & USBCMD_INTE)) {
return;
}
if (msix_enabled(pci_dev)) {
trace_usb_xhci_irq_msix(v);
msix_notify(pci_dev, v);
return;
}
if (msi_enabled(pci_dev)) {
trace_usb_xhci_irq_msi(v);
msi_notify(pci_dev, v);
return;
}
if (v == 0) {
trace_usb_xhci_irq_intx(1);
pci_irq_assert(pci_dev);
}
}
static inline int xhci_running(XHCIState *xhci)
{
return !(xhci->usbsts & USBSTS_HCH);
}
static void xhci_die(XHCIState *xhci)
{
xhci->usbsts |= USBSTS_HCE;
DPRINTF("xhci: asserted controller error\n");
}
static void xhci_write_event(XHCIState *xhci, XHCIEvent *event, int v)
{
PCIDevice *pci_dev = PCI_DEVICE(xhci);
XHCIInterrupter *intr = &xhci->intr[v];
XHCITRB ev_trb;
dma_addr_t addr;
ev_trb.parameter = cpu_to_le64(event->ptr);
ev_trb.status = cpu_to_le32(event->length | (event->ccode << 24));
ev_trb.control = (event->slotid << 24) | (event->epid << 16) |
event->flags | (event->type << TRB_TYPE_SHIFT);
if (intr->er_pcs) {
ev_trb.control |= TRB_C;
}
ev_trb.control = cpu_to_le32(ev_trb.control);
trace_usb_xhci_queue_event(v, intr->er_ep_idx, trb_name(&ev_trb),
event_name(event), ev_trb.parameter,
ev_trb.status, ev_trb.control);
addr = intr->er_start + TRB_SIZE*intr->er_ep_idx;
pci_dma_write(pci_dev, addr, &ev_trb, TRB_SIZE);
intr->er_ep_idx++;
if (intr->er_ep_idx >= intr->er_size) {
intr->er_ep_idx = 0;
intr->er_pcs = !intr->er_pcs;
}
}
static void xhci_event(XHCIState *xhci, XHCIEvent *event, int v)
{
XHCIInterrupter *intr;
dma_addr_t erdp;
unsigned int dp_idx;
if (v >= xhci->numintrs) {
DPRINTF("intr nr out of range (%d >= %d)\n", v, xhci->numintrs);
return;
}
intr = &xhci->intr[v];
erdp = xhci_addr64(intr->erdp_low, intr->erdp_high);
if (erdp < intr->er_start ||
erdp >= (intr->er_start + TRB_SIZE*intr->er_size)) {
DPRINTF("xhci: ERDP out of bounds: "DMA_ADDR_FMT"\n", erdp);
DPRINTF("xhci: ER[%d] at "DMA_ADDR_FMT" len %d\n",
v, intr->er_start, intr->er_size);
xhci_die(xhci);
return;
}
dp_idx = (erdp - intr->er_start) / TRB_SIZE;
assert(dp_idx < intr->er_size);
if ((intr->er_ep_idx + 2) % intr->er_size == dp_idx) {
DPRINTF("xhci: ER %d full, send ring full error\n", v);
XHCIEvent full = {ER_HOST_CONTROLLER, CC_EVENT_RING_FULL_ERROR};
xhci_write_event(xhci, &full, v);
} else if ((intr->er_ep_idx + 1) % intr->er_size == dp_idx) {
DPRINTF("xhci: ER %d full, drop event\n", v);
} else {
xhci_write_event(xhci, event, v);
}
xhci_intr_raise(xhci, v);
}
static void xhci_ring_init(XHCIState *xhci, XHCIRing *ring,
dma_addr_t base)
{
ring->dequeue = base;
ring->ccs = 1;
}
static TRBType xhci_ring_fetch(XHCIState *xhci, XHCIRing *ring, XHCITRB *trb,
dma_addr_t *addr)
{
PCIDevice *pci_dev = PCI_DEVICE(xhci);
uint32_t link_cnt = 0;
while (1) {
TRBType type;
pci_dma_read(pci_dev, ring->dequeue, trb, TRB_SIZE);
trb->addr = ring->dequeue;
trb->ccs = ring->ccs;
le64_to_cpus(&trb->parameter);
le32_to_cpus(&trb->status);
le32_to_cpus(&trb->control);
trace_usb_xhci_fetch_trb(ring->dequeue, trb_name(trb),
trb->parameter, trb->status, trb->control);
if ((trb->control & TRB_C) != ring->ccs) {
return 0;
}
type = TRB_TYPE(*trb);
if (type != TR_LINK) {
if (addr) {
*addr = ring->dequeue;
}
ring->dequeue += TRB_SIZE;
return type;
} else {
if (++link_cnt > TRB_LINK_LIMIT) {
trace_usb_xhci_enforced_limit("trb-link");
return 0;
}
ring->dequeue = xhci_mask64(trb->parameter);
if (trb->control & TRB_LK_TC) {
ring->ccs = !ring->ccs;
}
}
}
}
static int xhci_ring_chain_length(XHCIState *xhci, const XHCIRing *ring)
{
PCIDevice *pci_dev = PCI_DEVICE(xhci);
XHCITRB trb;
int length = 0;
dma_addr_t dequeue = ring->dequeue;
bool ccs = ring->ccs;
/* hack to bundle together the two/three TDs that make a setup transfer */
bool control_td_set = 0;
uint32_t link_cnt = 0;
while (1) {
TRBType type;
pci_dma_read(pci_dev, dequeue, &trb, TRB_SIZE);
le64_to_cpus(&trb.parameter);
le32_to_cpus(&trb.status);
le32_to_cpus(&trb.control);
if ((trb.control & TRB_C) != ccs) {
return -length;
}
type = TRB_TYPE(trb);
if (type == TR_LINK) {
if (++link_cnt > TRB_LINK_LIMIT) {
return -length;
}
dequeue = xhci_mask64(trb.parameter);
if (trb.control & TRB_LK_TC) {
ccs = !ccs;
}
continue;
}
length += 1;
dequeue += TRB_SIZE;
if (type == TR_SETUP) {
control_td_set = 1;
} else if (type == TR_STATUS) {
control_td_set = 0;
}
if (!control_td_set && !(trb.control & TRB_TR_CH)) {
return length;
}
}
}
static void xhci_er_reset(XHCIState *xhci, int v)
{
XHCIInterrupter *intr = &xhci->intr[v];
XHCIEvRingSeg seg;
dma_addr_t erstba = xhci_addr64(intr->erstba_low, intr->erstba_high);
if (intr->erstsz == 0 || erstba == 0) {
/* disabled */
intr->er_start = 0;
intr->er_size = 0;
return;
}
/* cache the (sole) event ring segment location */
if (intr->erstsz != 1) {
DPRINTF("xhci: invalid value for ERSTSZ: %d\n", intr->erstsz);
xhci_die(xhci);
return;
}
pci_dma_read(PCI_DEVICE(xhci), erstba, &seg, sizeof(seg));
le32_to_cpus(&seg.addr_low);
le32_to_cpus(&seg.addr_high);
le32_to_cpus(&seg.size);
if (seg.size < 16 || seg.size > 4096) {
DPRINTF("xhci: invalid value for segment size: %d\n", seg.size);
xhci_die(xhci);
return;
}
intr->er_start = xhci_addr64(seg.addr_low, seg.addr_high);
intr->er_size = seg.size;
intr->er_ep_idx = 0;
intr->er_pcs = 1;
DPRINTF("xhci: event ring[%d]:" DMA_ADDR_FMT " [%d]\n",
v, intr->er_start, intr->er_size);
}
static void xhci_run(XHCIState *xhci)
{
trace_usb_xhci_run();
xhci->usbsts &= ~USBSTS_HCH;
xhci->mfindex_start = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL);
}
static void xhci_stop(XHCIState *xhci)
{
trace_usb_xhci_stop();
xhci->usbsts |= USBSTS_HCH;
xhci->crcr_low &= ~CRCR_CRR;
}
static XHCIStreamContext *xhci_alloc_stream_contexts(unsigned count,
dma_addr_t base)
{
XHCIStreamContext *stctx;
unsigned int i;
stctx = g_new0(XHCIStreamContext, count);
for (i = 0; i < count; i++) {
stctx[i].pctx = base + i * 16;
stctx[i].sct = -1;
}
return stctx;
}
static void xhci_reset_streams(XHCIEPContext *epctx)
{
unsigned int i;
for (i = 0; i < epctx->nr_pstreams; i++) {
epctx->pstreams[i].sct = -1;
}
}
static void xhci_alloc_streams(XHCIEPContext *epctx, dma_addr_t base)
{
assert(epctx->pstreams == NULL);
epctx->nr_pstreams = 2 << epctx->max_pstreams;
epctx->pstreams = xhci_alloc_stream_contexts(epctx->nr_pstreams, base);
}
static void xhci_free_streams(XHCIEPContext *epctx)
{
assert(epctx->pstreams != NULL);
g_free(epctx->pstreams);
epctx->pstreams = NULL;
epctx->nr_pstreams = 0;
}
static int xhci_epmask_to_eps_with_streams(XHCIState *xhci,
unsigned int slotid,
uint32_t epmask,
XHCIEPContext **epctxs,
USBEndpoint **eps)
{
XHCISlot *slot;
XHCIEPContext *epctx;
USBEndpoint *ep;
int i, j;
assert(slotid >= 1 && slotid <= xhci->numslots);
slot = &xhci->slots[slotid - 1];
for (i = 2, j = 0; i <= 31; i++) {
if (!(epmask & (1u << i))) {
continue;
}
epctx = slot->eps[i - 1];
ep = xhci_epid_to_usbep(epctx);
if (!epctx || !epctx->nr_pstreams || !ep) {
continue;
}
if (epctxs) {
epctxs[j] = epctx;
}
eps[j++] = ep;
}
return j;
}
static void xhci_free_device_streams(XHCIState *xhci, unsigned int slotid,
uint32_t epmask)
{
USBEndpoint *eps[30];
int nr_eps;
nr_eps = xhci_epmask_to_eps_with_streams(xhci, slotid, epmask, NULL, eps);
if (nr_eps) {
usb_device_free_streams(eps[0]->dev, eps, nr_eps);
}
}
static TRBCCode xhci_alloc_device_streams(XHCIState *xhci, unsigned int slotid,
uint32_t epmask)
{
XHCIEPContext *epctxs[30];
USBEndpoint *eps[30];
int i, r, nr_eps, req_nr_streams, dev_max_streams;
nr_eps = xhci_epmask_to_eps_with_streams(xhci, slotid, epmask, epctxs,
eps);
if (nr_eps == 0) {
return CC_SUCCESS;
}
req_nr_streams = epctxs[0]->nr_pstreams;
dev_max_streams = eps[0]->max_streams;
for (i = 1; i < nr_eps; i++) {
/*
* HdG: I don't expect these to ever trigger, but if they do we need
* to come up with another solution, ie group identical endpoints
* together and make an usb_device_alloc_streams call per group.
*/
if (epctxs[i]->nr_pstreams != req_nr_streams) {
FIXME("guest streams config not identical for all eps");
return CC_RESOURCE_ERROR;
}
if (eps[i]->max_streams != dev_max_streams) {
FIXME("device streams config not identical for all eps");
return CC_RESOURCE_ERROR;
}
}
/*
* max-streams in both the device descriptor and in the controller is a
* power of 2. But stream id 0 is reserved, so if a device can do up to 4
* streams the guest will ask for 5 rounded up to the next power of 2 which
* becomes 8. For emulated devices usb_device_alloc_streams is a nop.
*
* For redirected devices however this is an issue, as there we must ask
* the real xhci controller to alloc streams, and the host driver for the
* real xhci controller will likely disallow allocating more streams then
* the device can handle.
*
* So we limit the requested nr_streams to the maximum number the device
* can handle.
*/
if (req_nr_streams > dev_max_streams) {
req_nr_streams = dev_max_streams;
}
r = usb_device_alloc_streams(eps[0]->dev, eps, nr_eps, req_nr_streams);
if (r != 0) {
DPRINTF("xhci: alloc streams failed\n");
return CC_RESOURCE_ERROR;
}
return CC_SUCCESS;
}
static XHCIStreamContext *xhci_find_stream(XHCIEPContext *epctx,
unsigned int streamid,
uint32_t *cc_error)
{
XHCIStreamContext *sctx;
dma_addr_t base;
uint32_t ctx[2], sct;
assert(streamid != 0);
if (epctx->lsa) {
if (streamid >= epctx->nr_pstreams) {
*cc_error = CC_INVALID_STREAM_ID_ERROR;
return NULL;
}
sctx = epctx->pstreams + streamid;
} else {
FIXME("secondary streams not implemented yet");
}
if (sctx->sct == -1) {
xhci_dma_read_u32s(epctx->xhci, sctx->pctx, ctx, sizeof(ctx));
sct = (ctx[0] >> 1) & 0x07;
if (epctx->lsa && sct != 1) {
*cc_error = CC_INVALID_STREAM_TYPE_ERROR;
return NULL;
}
sctx->sct = sct;
base = xhci_addr64(ctx[0] & ~0xf, ctx[1]);
xhci_ring_init(epctx->xhci, &sctx->ring, base);
}
return sctx;
}
static void xhci_set_ep_state(XHCIState *xhci, XHCIEPContext *epctx,
XHCIStreamContext *sctx, uint32_t state)
{
XHCIRing *ring = NULL;
uint32_t ctx[5];
uint32_t ctx2[2];
xhci_dma_read_u32s(xhci, epctx->pctx, ctx, sizeof(ctx));
ctx[0] &= ~EP_STATE_MASK;
ctx[0] |= state;
/* update ring dequeue ptr */
if (epctx->nr_pstreams) {
if (sctx != NULL) {
ring = &sctx->ring;
xhci_dma_read_u32s(xhci, sctx->pctx, ctx2, sizeof(ctx2));
ctx2[0] &= 0xe;
ctx2[0] |= sctx->ring.dequeue | sctx->ring.ccs;
ctx2[1] = (sctx->ring.dequeue >> 16) >> 16;
xhci_dma_write_u32s(xhci, sctx->pctx, ctx2, sizeof(ctx2));
}
} else {
ring = &epctx->ring;
}
if (ring) {
ctx[2] = ring->dequeue | ring->ccs;
ctx[3] = (ring->dequeue >> 16) >> 16;
DPRINTF("xhci: set epctx: " DMA_ADDR_FMT " state=%d dequeue=%08x%08x\n",
epctx->pctx, state, ctx[3], ctx[2]);
}
xhci_dma_write_u32s(xhci, epctx->pctx, ctx, sizeof(ctx));
if (epctx->state != state) {
trace_usb_xhci_ep_state(epctx->slotid, epctx->epid,
ep_state_name(epctx->state),
ep_state_name(state));
}
epctx->state = state;
}
static void xhci_ep_kick_timer(void *opaque)
{
XHCIEPContext *epctx = opaque;
xhci_kick_epctx(epctx, 0);
}
static XHCIEPContext *xhci_alloc_epctx(XHCIState *xhci,
unsigned int slotid,
unsigned int epid)
{
XHCIEPContext *epctx;
epctx = g_new0(XHCIEPContext, 1);
epctx->xhci = xhci;
epctx->slotid = slotid;
epctx->epid = epid;
QTAILQ_INIT(&epctx->transfers);
epctx->kick_timer = timer_new_ns(QEMU_CLOCK_VIRTUAL, xhci_ep_kick_timer, epctx);
return epctx;
}
static void xhci_init_epctx(XHCIEPContext *epctx,
dma_addr_t pctx, uint32_t *ctx)
{
dma_addr_t dequeue;
dequeue = xhci_addr64(ctx[2] & ~0xf, ctx[3]);
epctx->type = (ctx[1] >> EP_TYPE_SHIFT) & EP_TYPE_MASK;
epctx->pctx = pctx;
epctx->max_psize = ctx[1]>>16;
epctx->max_psize *= 1+((ctx[1]>>8)&0xff);
epctx->max_pstreams = (ctx[0] >> 10) & epctx->xhci->max_pstreams_mask;
epctx->lsa = (ctx[0] >> 15) & 1;
if (epctx->max_pstreams) {
xhci_alloc_streams(epctx, dequeue);
} else {
xhci_ring_init(epctx->xhci, &epctx->ring, dequeue);
epctx->ring.ccs = ctx[2] & 1;
}
epctx->interval = 1 << ((ctx[0] >> 16) & 0xff);
}
static TRBCCode xhci_enable_ep(XHCIState *xhci, unsigned int slotid,
unsigned int epid, dma_addr_t pctx,
uint32_t *ctx)
{
XHCISlot *slot;
XHCIEPContext *epctx;
trace_usb_xhci_ep_enable(slotid, epid);
assert(slotid >= 1 && slotid <= xhci->numslots);
assert(epid >= 1 && epid <= 31);
slot = &xhci->slots[slotid-1];
if (slot->eps[epid-1]) {
xhci_disable_ep(xhci, slotid, epid);
}
epctx = xhci_alloc_epctx(xhci, slotid, epid);
slot->eps[epid-1] = epctx;
xhci_init_epctx(epctx, pctx, ctx);
DPRINTF("xhci: endpoint %d.%d type is %d, max transaction (burst) "
"size is %d\n", epid/2, epid%2, epctx->type, epctx->max_psize);
epctx->mfindex_last = 0;
epctx->state = EP_RUNNING;
ctx[0] &= ~EP_STATE_MASK;
ctx[0] |= EP_RUNNING;
return CC_SUCCESS;
}
static XHCITransfer *xhci_ep_alloc_xfer(XHCIEPContext *epctx,
uint32_t length)
{
uint32_t limit = epctx->nr_pstreams + 16;
XHCITransfer *xfer;
if (epctx->xfer_count >= limit) {
return NULL;
}
xfer = g_new0(XHCITransfer, 1);
xfer->epctx = epctx;
xfer->trbs = g_new(XHCITRB, length);
xfer->trb_count = length;
usb_packet_init(&xfer->packet);
QTAILQ_INSERT_TAIL(&epctx->transfers, xfer, next);
epctx->xfer_count++;
return xfer;
}
static void xhci_ep_free_xfer(XHCITransfer *xfer)
{
QTAILQ_REMOVE(&xfer->epctx->transfers, xfer, next);
xfer->epctx->xfer_count--;
usb_packet_cleanup(&xfer->packet);
g_free(xfer->trbs);
g_free(xfer);
}
static int xhci_ep_nuke_one_xfer(XHCITransfer *t, TRBCCode report)
{
int killed = 0;
if (report && (t->running_async || t->running_retry)) {
t->status = report;
xhci_xfer_report(t);
}
if (t->running_async) {
usb_cancel_packet(&t->packet);
t->running_async = 0;
killed = 1;
}
if (t->running_retry) {
if (t->epctx) {
t->epctx->retry = NULL;
timer_del(t->epctx->kick_timer);
}
t->running_retry = 0;
killed = 1;
}
g_free(t->trbs);
t->trbs = NULL;
t->trb_count = 0;
return killed;
}
static int xhci_ep_nuke_xfers(XHCIState *xhci, unsigned int slotid,
unsigned int epid, TRBCCode report)
{
XHCISlot *slot;
XHCIEPContext *epctx;
XHCITransfer *xfer;
int killed = 0;
USBEndpoint *ep = NULL;
assert(slotid >= 1 && slotid <= xhci->numslots);
assert(epid >= 1 && epid <= 31);
DPRINTF("xhci_ep_nuke_xfers(%d, %d)\n", slotid, epid);
slot = &xhci->slots[slotid-1];
if (!slot->eps[epid-1]) {
return 0;
}
epctx = slot->eps[epid-1];
for (;;) {
xfer = QTAILQ_FIRST(&epctx->transfers);
if (xfer == NULL) {
break;
}
killed += xhci_ep_nuke_one_xfer(xfer, report);
if (killed) {
report = 0; /* Only report once */
}
xhci_ep_free_xfer(xfer);
}
ep = xhci_epid_to_usbep(epctx);
if (ep) {
usb_device_ep_stopped(ep->dev, ep);
}
return killed;
}
static TRBCCode xhci_disable_ep(XHCIState *xhci, unsigned int slotid,
unsigned int epid)
{
XHCISlot *slot;
XHCIEPContext *epctx;
trace_usb_xhci_ep_disable(slotid, epid);
assert(slotid >= 1 && slotid <= xhci->numslots);
assert(epid >= 1 && epid <= 31);
slot = &xhci->slots[slotid-1];
if (!slot->eps[epid-1]) {
DPRINTF("xhci: slot %d ep %d already disabled\n", slotid, epid);
return CC_SUCCESS;
}
xhci_ep_nuke_xfers(xhci, slotid, epid, 0);
epctx = slot->eps[epid-1];
if (epctx->nr_pstreams) {
xhci_free_streams(epctx);
}
/* only touch guest RAM if we're not resetting the HC */
if (xhci->dcbaap_low || xhci->dcbaap_high) {
xhci_set_ep_state(xhci, epctx, NULL, EP_DISABLED);
}
timer_free(epctx->kick_timer);
g_free(epctx);
slot->eps[epid-1] = NULL;
return CC_SUCCESS;
}
static TRBCCode xhci_stop_ep(XHCIState *xhci, unsigned int slotid,
unsigned int epid)
{
XHCISlot *slot;
XHCIEPContext *epctx;
trace_usb_xhci_ep_stop(slotid, epid);
assert(slotid >= 1 && slotid <= xhci->numslots);
if (epid < 1 || epid > 31) {
DPRINTF("xhci: bad ep %d\n", epid);
return CC_TRB_ERROR;
}
slot = &xhci->slots[slotid-1];
if (!slot->eps[epid-1]) {
DPRINTF("xhci: slot %d ep %d not enabled\n", slotid, epid);
return CC_EP_NOT_ENABLED_ERROR;
}
if (xhci_ep_nuke_xfers(xhci, slotid, epid, CC_STOPPED) > 0) {
DPRINTF("xhci: FIXME: endpoint stopped w/ xfers running, "
"data might be lost\n");
}
epctx = slot->eps[epid-1];
xhci_set_ep_state(xhci, epctx, NULL, EP_STOPPED);
if (epctx->nr_pstreams) {
xhci_reset_streams(epctx);
}
return CC_SUCCESS;
}
static TRBCCode xhci_reset_ep(XHCIState *xhci, unsigned int slotid,
unsigned int epid)
{
XHCISlot *slot;
XHCIEPContext *epctx;
trace_usb_xhci_ep_reset(slotid, epid);
assert(slotid >= 1 && slotid <= xhci->numslots);
if (epid < 1 || epid > 31) {
DPRINTF("xhci: bad ep %d\n", epid);
return CC_TRB_ERROR;
}
slot = &xhci->slots[slotid-1];
if (!slot->eps[epid-1]) {
DPRINTF("xhci: slot %d ep %d not enabled\n", slotid, epid);
return CC_EP_NOT_ENABLED_ERROR;
}
epctx = slot->eps[epid-1];
if (epctx->state != EP_HALTED) {
DPRINTF("xhci: reset EP while EP %d not halted (%d)\n",
epid, epctx->state);
return CC_CONTEXT_STATE_ERROR;
}
if (xhci_ep_nuke_xfers(xhci, slotid, epid, 0) > 0) {
DPRINTF("xhci: FIXME: endpoint reset w/ xfers running, "
"data might be lost\n");
}
if (!xhci->slots[slotid-1].uport ||
!xhci->slots[slotid-1].uport->dev ||
!xhci->slots[slotid-1].uport->dev->attached) {
return CC_USB_TRANSACTION_ERROR;
}
xhci_set_ep_state(xhci, epctx, NULL, EP_STOPPED);
if (epctx->nr_pstreams) {
xhci_reset_streams(epctx);
}
return CC_SUCCESS;
}
static TRBCCode xhci_set_ep_dequeue(XHCIState *xhci, unsigned int slotid,
unsigned int epid, unsigned int streamid,
uint64_t pdequeue)
{
XHCISlot *slot;
XHCIEPContext *epctx;
XHCIStreamContext *sctx;
dma_addr_t dequeue;
assert(slotid >= 1 && slotid <= xhci->numslots);
if (epid < 1 || epid > 31) {
DPRINTF("xhci: bad ep %d\n", epid);
return CC_TRB_ERROR;
}
trace_usb_xhci_ep_set_dequeue(slotid, epid, streamid, pdequeue);
dequeue = xhci_mask64(pdequeue);
slot = &xhci->slots[slotid-1];
if (!slot->eps[epid-1]) {
DPRINTF("xhci: slot %d ep %d not enabled\n", slotid, epid);
return CC_EP_NOT_ENABLED_ERROR;
}
epctx = slot->eps[epid-1];
if (epctx->state != EP_STOPPED) {
DPRINTF("xhci: set EP dequeue pointer while EP %d not stopped\n", epid);
return CC_CONTEXT_STATE_ERROR;
}
if (epctx->nr_pstreams) {
uint32_t err;
sctx = xhci_find_stream(epctx, streamid, &err);
if (sctx == NULL) {
return err;
}
xhci_ring_init(xhci, &sctx->ring, dequeue & ~0xf);
sctx->ring.ccs = dequeue & 1;
} else {
sctx = NULL;
xhci_ring_init(xhci, &epctx->ring, dequeue & ~0xF);
epctx->ring.ccs = dequeue & 1;
}
xhci_set_ep_state(xhci, epctx, sctx, EP_STOPPED);
return CC_SUCCESS;
}
static int xhci_xfer_create_sgl(XHCITransfer *xfer, int in_xfer)
{
XHCIState *xhci = xfer->epctx->xhci;
int i;
xfer->int_req = false;
pci_dma_sglist_init(&xfer->sgl, PCI_DEVICE(xhci), xfer->trb_count);
for (i = 0; i < xfer->trb_count; i++) {
XHCITRB *trb = &xfer->trbs[i];
dma_addr_t addr;
unsigned int chunk = 0;
if (trb->control & TRB_TR_IOC) {
xfer->int_req = true;
}
switch (TRB_TYPE(*trb)) {
case TR_DATA:
if ((!(trb->control & TRB_TR_DIR)) != (!in_xfer)) {
DPRINTF("xhci: data direction mismatch for TR_DATA\n");
goto err;
}
/* fallthrough */
case TR_NORMAL:
case TR_ISOCH:
addr = xhci_mask64(trb->parameter);
chunk = trb->status & 0x1ffff;
if (trb->control & TRB_TR_IDT) {
if (chunk > 8 || in_xfer) {
DPRINTF("xhci: invalid immediate data TRB\n");
goto err;
}
qemu_sglist_add(&xfer->sgl, trb->addr, chunk);
} else {
qemu_sglist_add(&xfer->sgl, addr, chunk);
}
break;
}
}
return 0;
err:
qemu_sglist_destroy(&xfer->sgl);
xhci_die(xhci);
return -1;
}
static void xhci_xfer_unmap(XHCITransfer *xfer)
{
usb_packet_unmap(&xfer->packet, &xfer->sgl);
qemu_sglist_destroy(&xfer->sgl);
}
static void xhci_xfer_report(XHCITransfer *xfer)
{
uint32_t edtla = 0;
unsigned int left;
bool reported = 0;
bool shortpkt = 0;
XHCIEvent event = {ER_TRANSFER, CC_SUCCESS};
XHCIState *xhci = xfer->epctx->xhci;
int i;
left = xfer->packet.actual_length;
for (i = 0; i < xfer->trb_count; i++) {
XHCITRB *trb = &xfer->trbs[i];
unsigned int chunk = 0;
switch (TRB_TYPE(*trb)) {
case TR_SETUP:
chunk = trb->status & 0x1ffff;
if (chunk > 8) {
chunk = 8;
}
break;
case TR_DATA:
case TR_NORMAL:
case TR_ISOCH:
chunk = trb->status & 0x1ffff;
if (chunk > left) {
chunk = left;
if (xfer->status == CC_SUCCESS) {
shortpkt = 1;
}
}
left -= chunk;
edtla += chunk;
break;
case TR_STATUS:
reported = 0;
shortpkt = 0;
break;
}
if (!reported && ((trb->control & TRB_TR_IOC) ||
(shortpkt && (trb->control & TRB_TR_ISP)) ||
(xfer->status != CC_SUCCESS && left == 0))) {
event.slotid = xfer->epctx->slotid;
event.epid = xfer->epctx->epid;
event.length = (trb->status & 0x1ffff) - chunk;
event.flags = 0;
event.ptr = trb->addr;
if (xfer->status == CC_SUCCESS) {
event.ccode = shortpkt ? CC_SHORT_PACKET : CC_SUCCESS;
} else {
event.ccode = xfer->status;
}
if (TRB_TYPE(*trb) == TR_EVDATA) {
event.ptr = trb->parameter;
event.flags |= TRB_EV_ED;
event.length = edtla & 0xffffff;
DPRINTF("xhci_xfer_data: EDTLA=%d\n", event.length);
edtla = 0;
}
xhci_event(xhci, &event, TRB_INTR(*trb));
reported = 1;
if (xfer->status != CC_SUCCESS) {
return;
}
}
switch (TRB_TYPE(*trb)) {
case TR_SETUP:
reported = 0;
shortpkt = 0;
break;
}
}
}
static void xhci_stall_ep(XHCITransfer *xfer)
{
XHCIEPContext *epctx = xfer->epctx;
XHCIState *xhci = epctx->xhci;
uint32_t err;
XHCIStreamContext *sctx;
if (epctx->nr_pstreams) {
sctx = xhci_find_stream(epctx, xfer->streamid, &err);
if (sctx == NULL) {
return;
}
sctx->ring.dequeue = xfer->trbs[0].addr;
sctx->ring.ccs = xfer->trbs[0].ccs;
xhci_set_ep_state(xhci, epctx, sctx, EP_HALTED);
} else {
epctx->ring.dequeue = xfer->trbs[0].addr;
epctx->ring.ccs = xfer->trbs[0].ccs;
xhci_set_ep_state(xhci, epctx, NULL, EP_HALTED);
}
}
static int xhci_setup_packet(XHCITransfer *xfer)
{
USBEndpoint *ep;
int dir;
dir = xfer->in_xfer ? USB_TOKEN_IN : USB_TOKEN_OUT;
if (xfer->packet.ep) {
ep = xfer->packet.ep;
} else {
ep = xhci_epid_to_usbep(xfer->epctx);
if (!ep) {
DPRINTF("xhci: slot %d has no device\n",
xfer->epctx->slotid);
return -1;
}
}
xhci_xfer_create_sgl(xfer, dir == USB_TOKEN_IN); /* Also sets int_req */
usb_packet_setup(&xfer->packet, dir, ep, xfer->streamid,
xfer->trbs[0].addr, false, xfer->int_req);
usb_packet_map(&xfer->packet, &xfer->sgl);
DPRINTF("xhci: setup packet pid 0x%x addr %d ep %d\n",
xfer->packet.pid, ep->dev->addr, ep->nr);
return 0;
}
static int xhci_try_complete_packet(XHCITransfer *xfer)
{
if (xfer->packet.status == USB_RET_ASYNC) {
trace_usb_xhci_xfer_async(xfer);
xfer->running_async = 1;
xfer->running_retry = 0;
xfer->complete = 0;
return 0;
} else if (xfer->packet.status == USB_RET_NAK) {
trace_usb_xhci_xfer_nak(xfer);
xfer->running_async = 0;
xfer->running_retry = 1;
xfer->complete = 0;
return 0;
} else {
xfer->running_async = 0;
xfer->running_retry = 0;
xfer->complete = 1;
xhci_xfer_unmap(xfer);
}
if (xfer->packet.status == USB_RET_SUCCESS) {
trace_usb_xhci_xfer_success(xfer, xfer->packet.actual_length);
xfer->status = CC_SUCCESS;
xhci_xfer_report(xfer);
return 0;
}
/* error */
trace_usb_xhci_xfer_error(xfer, xfer->packet.status);
switch (xfer->packet.status) {
case USB_RET_NODEV:
case USB_RET_IOERROR:
xfer->status = CC_USB_TRANSACTION_ERROR;
xhci_xfer_report(xfer);
xhci_stall_ep(xfer);
break;
case USB_RET_STALL:
xfer->status = CC_STALL_ERROR;
xhci_xfer_report(xfer);
xhci_stall_ep(xfer);
break;
case USB_RET_BABBLE:
xfer->status = CC_BABBLE_DETECTED;
xhci_xfer_report(xfer);
xhci_stall_ep(xfer);
break;
default:
DPRINTF("%s: FIXME: status = %d\n", __func__,
xfer->packet.status);
FIXME("unhandled USB_RET_*");
}
return 0;
}
static int xhci_fire_ctl_transfer(XHCIState *xhci, XHCITransfer *xfer)
{
XHCITRB *trb_setup, *trb_status;
uint8_t bmRequestType;
trb_setup = &xfer->trbs[0];
trb_status = &xfer->trbs[xfer->trb_count-1];
trace_usb_xhci_xfer_start(xfer, xfer->epctx->slotid,
xfer->epctx->epid, xfer->streamid);
/* at most one Event Data TRB allowed after STATUS */
if (TRB_TYPE(*trb_status) == TR_EVDATA && xfer->trb_count > 2) {
trb_status--;
}
/* do some sanity checks */
if (TRB_TYPE(*trb_setup) != TR_SETUP) {
DPRINTF("xhci: ep0 first TD not SETUP: %d\n",
TRB_TYPE(*trb_setup));
return -1;
}
if (TRB_TYPE(*trb_status) != TR_STATUS) {
DPRINTF("xhci: ep0 last TD not STATUS: %d\n",
TRB_TYPE(*trb_status));
return -1;
}
if (!(trb_setup->control & TRB_TR_IDT)) {
DPRINTF("xhci: Setup TRB doesn't have IDT set\n");
return -1;
}
if ((trb_setup->status & 0x1ffff) != 8) {
DPRINTF("xhci: Setup TRB has bad length (%d)\n",
(trb_setup->status & 0x1ffff));
return -1;
}
bmRequestType = trb_setup->parameter;
xfer->in_xfer = bmRequestType & USB_DIR_IN;
xfer->iso_xfer = false;
xfer->timed_xfer = false;
if (xhci_setup_packet(xfer) < 0) {
return -1;
}
xfer->packet.parameter = trb_setup->parameter;
usb_handle_packet(xfer->packet.ep->dev, &xfer->packet);
xhci_try_complete_packet(xfer);
return 0;
}
static void xhci_calc_intr_kick(XHCIState *xhci, XHCITransfer *xfer,
XHCIEPContext *epctx, uint64_t mfindex)
{
uint64_t asap = ((mfindex + epctx->interval - 1) &
~(epctx->interval-1));
uint64_t kick = epctx->mfindex_last + epctx->interval;
assert(epctx->interval != 0);
xfer->mfindex_kick = MAX(asap, kick);
}
static void xhci_calc_iso_kick(XHCIState *xhci, XHCITransfer *xfer,
XHCIEPContext *epctx, uint64_t mfindex)
{
if (xfer->trbs[0].control & TRB_TR_SIA) {
uint64_t asap = ((mfindex + epctx->interval - 1) &
~(epctx->interval-1));
if (asap >= epctx->mfindex_last &&
asap <= epctx->mfindex_last + epctx->interval * 4) {
xfer->mfindex_kick = epctx->mfindex_last + epctx->interval;
} else {
xfer->mfindex_kick = asap;
}
} else {
xfer->mfindex_kick = ((xfer->trbs[0].control >> TRB_TR_FRAMEID_SHIFT)
& TRB_TR_FRAMEID_MASK) << 3;
xfer->mfindex_kick |= mfindex & ~0x3fff;
if (xfer->mfindex_kick + 0x100 < mfindex) {
xfer->mfindex_kick += 0x4000;
}
}
}
static void xhci_check_intr_iso_kick(XHCIState *xhci, XHCITransfer *xfer,
XHCIEPContext *epctx, uint64_t mfindex)
{
if (xfer->mfindex_kick > mfindex) {
timer_mod(epctx->kick_timer, qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL) +
(xfer->mfindex_kick - mfindex) * 125000);
xfer->running_retry = 1;
} else {
epctx->mfindex_last = xfer->mfindex_kick;
timer_del(epctx->kick_timer);
xfer->running_retry = 0;
}
}
static int xhci_submit(XHCIState *xhci, XHCITransfer *xfer, XHCIEPContext *epctx)
{
uint64_t mfindex;
DPRINTF("xhci_submit(slotid=%d,epid=%d)\n", epctx->slotid, epctx->epid);
xfer->in_xfer = epctx->type>>2;
switch(epctx->type) {
case ET_INTR_OUT:
case ET_INTR_IN:
xfer->pkts = 0;
xfer->iso_xfer = false;
xfer->timed_xfer = true;
mfindex = xhci_mfindex_get(xhci);
xhci_calc_intr_kick(xhci, xfer, epctx, mfindex);
xhci_check_intr_iso_kick(xhci, xfer, epctx, mfindex);
if (xfer->running_retry) {
return -1;
}
break;
case ET_BULK_OUT:
case ET_BULK_IN:
xfer->pkts = 0;
xfer->iso_xfer = false;
xfer->timed_xfer = false;
break;
case ET_ISO_OUT:
case ET_ISO_IN:
xfer->pkts = 1;
xfer->iso_xfer = true;
xfer->timed_xfer = true;
mfindex = xhci_mfindex_get(xhci);
xhci_calc_iso_kick(xhci, xfer, epctx, mfindex);
xhci_check_intr_iso_kick(xhci, xfer, epctx, mfindex);
if (xfer->running_retry) {
return -1;
}
break;
default:
trace_usb_xhci_unimplemented("endpoint type", epctx->type);
return -1;
}
if (xhci_setup_packet(xfer) < 0) {
return -1;
}
usb_handle_packet(xfer->packet.ep->dev, &xfer->packet);
xhci_try_complete_packet(xfer);
return 0;
}
static int xhci_fire_transfer(XHCIState *xhci, XHCITransfer *xfer, XHCIEPContext *epctx)
{
trace_usb_xhci_xfer_start(xfer, xfer->epctx->slotid,
xfer->epctx->epid, xfer->streamid);
return xhci_submit(xhci, xfer, epctx);
}
static void xhci_kick_ep(XHCIState *xhci, unsigned int slotid,
unsigned int epid, unsigned int streamid)
{
XHCIEPContext *epctx;
assert(slotid >= 1 && slotid <= xhci->numslots);
assert(epid >= 1 && epid <= 31);
if (!xhci->slots[slotid-1].enabled) {
DPRINTF("xhci: xhci_kick_ep for disabled slot %d\n", slotid);
return;
}
epctx = xhci->slots[slotid-1].eps[epid-1];
if (!epctx) {
DPRINTF("xhci: xhci_kick_ep for disabled endpoint %d,%d\n",
epid, slotid);
return;
}
if (epctx->kick_active) {
return;
}
xhci_kick_epctx(epctx, streamid);
}
static void xhci_kick_epctx(XHCIEPContext *epctx, unsigned int streamid)
{
XHCIState *xhci = epctx->xhci;
XHCIStreamContext *stctx = NULL;
XHCITransfer *xfer;
XHCIRing *ring;
USBEndpoint *ep = NULL;
uint64_t mfindex;
unsigned int count = 0;
int length;
int i;
trace_usb_xhci_ep_kick(epctx->slotid, epctx->epid, streamid);
assert(!epctx->kick_active);
/* If the device has been detached, but the guest has not noticed this
yet the 2 above checks will succeed, but we must NOT continue */
if (!xhci->slots[epctx->slotid - 1].uport ||
!xhci->slots[epctx->slotid - 1].uport->dev ||
!xhci->slots[epctx->slotid - 1].uport->dev->attached) {
return;
}
if (epctx->retry) {
XHCITransfer *xfer = epctx->retry;
trace_usb_xhci_xfer_retry(xfer);
assert(xfer->running_retry);
if (xfer->timed_xfer) {
/* time to kick the transfer? */
mfindex = xhci_mfindex_get(xhci);
xhci_check_intr_iso_kick(xhci, xfer, epctx, mfindex);
if (xfer->running_retry) {
return;
}
xfer->timed_xfer = 0;
xfer->running_retry = 1;
}
if (xfer->iso_xfer) {
/* retry iso transfer */
if (xhci_setup_packet(xfer) < 0) {
return;
}
usb_handle_packet(xfer->packet.ep->dev, &xfer->packet);
assert(xfer->packet.status != USB_RET_NAK);
xhci_try_complete_packet(xfer);
} else {
/* retry nak'ed transfer */
if (xhci_setup_packet(xfer) < 0) {
return;
}
usb_handle_packet(xfer->packet.ep->dev, &xfer->packet);
if (xfer->packet.status == USB_RET_NAK) {
return;
}
xhci_try_complete_packet(xfer);
}
assert(!xfer->running_retry);
if (xfer->complete) {
/* update ring dequeue ptr */
xhci_set_ep_state(xhci, epctx, stctx, epctx->state);
xhci_ep_free_xfer(epctx->retry);
}
epctx->retry = NULL;
}
if (epctx->state == EP_HALTED) {
DPRINTF("xhci: ep halted, not running schedule\n");
return;
}
if (epctx->nr_pstreams) {
uint32_t err;
stctx = xhci_find_stream(epctx, streamid, &err);
if (stctx == NULL) {
return;
}
ring = &stctx->ring;
xhci_set_ep_state(xhci, epctx, stctx, EP_RUNNING);
} else {
ring = &epctx->ring;
streamid = 0;
xhci_set_ep_state(xhci, epctx, NULL, EP_RUNNING);
}
assert(ring->dequeue != 0);
epctx->kick_active++;
while (1) {
length = xhci_ring_chain_length(xhci, ring);
if (length <= 0) {
break;
}
xfer = xhci_ep_alloc_xfer(epctx, length);
if (xfer == NULL) {
break;
}
for (i = 0; i < length; i++) {
TRBType type;
type = xhci_ring_fetch(xhci, ring, &xfer->trbs[i], NULL);
assert(type);
}
xfer->streamid = streamid;
if (epctx->epid == 1) {
xhci_fire_ctl_transfer(xhci, xfer);
} else {
xhci_fire_transfer(xhci, xfer, epctx);
}
if (xfer->complete) {
/* update ring dequeue ptr */
xhci_set_ep_state(xhci, epctx, stctx, epctx->state);
xhci_ep_free_xfer(xfer);
xfer = NULL;
}
if (epctx->state == EP_HALTED) {
break;
}
if (xfer != NULL && xfer->running_retry) {
DPRINTF("xhci: xfer nacked, stopping schedule\n");
epctx->retry = xfer;
break;
}
if (count++ > TRANSFER_LIMIT) {
trace_usb_xhci_enforced_limit("transfers");
break;
}
}
epctx->kick_active--;
ep = xhci_epid_to_usbep(epctx);
if (ep) {
usb_device_flush_ep_queue(ep->dev, ep);
}
}
static TRBCCode xhci_enable_slot(XHCIState *xhci, unsigned int slotid)
{
trace_usb_xhci_slot_enable(slotid);
assert(slotid >= 1 && slotid <= xhci->numslots);
xhci->slots[slotid-1].enabled = 1;
xhci->slots[slotid-1].uport = NULL;
memset(xhci->slots[slotid-1].eps, 0, sizeof(XHCIEPContext*)*31);
return CC_SUCCESS;
}
static TRBCCode xhci_disable_slot(XHCIState *xhci, unsigned int slotid)
{
int i;
trace_usb_xhci_slot_disable(slotid);
assert(slotid >= 1 && slotid <= xhci->numslots);
for (i = 1; i <= 31; i++) {
if (xhci->slots[slotid-1].eps[i-1]) {
xhci_disable_ep(xhci, slotid, i);
}
}
xhci->slots[slotid-1].enabled = 0;
xhci->slots[slotid-1].addressed = 0;
xhci->slots[slotid-1].uport = NULL;
return CC_SUCCESS;
}
static USBPort *xhci_lookup_uport(XHCIState *xhci, uint32_t *slot_ctx)
{
USBPort *uport;
char path[32];
int i, pos, port;
port = (slot_ctx[1]>>16) & 0xFF;
if (port < 1 || port > xhci->numports) {
return NULL;
}
port = xhci->ports[port-1].uport->index+1;
pos = snprintf(path, sizeof(path), "%d", port);
for (i = 0; i < 5; i++) {
port = (slot_ctx[0] >> 4*i) & 0x0f;
if (!port) {
break;
}
pos += snprintf(path + pos, sizeof(path) - pos, ".%d", port);
}
QTAILQ_FOREACH(uport, &xhci->bus.used, next) {
if (strcmp(uport->path, path) == 0) {
return uport;
}
}
return NULL;
}
static TRBCCode xhci_address_slot(XHCIState *xhci, unsigned int slotid,
uint64_t pictx, bool bsr)
{
XHCISlot *slot;
USBPort *uport;
USBDevice *dev;
dma_addr_t ictx, octx, dcbaap;
uint64_t poctx;
uint32_t ictl_ctx[2];
uint32_t slot_ctx[4];
uint32_t ep0_ctx[5];
int i;
TRBCCode res;
assert(slotid >= 1 && slotid <= xhci->numslots);
dcbaap = xhci_addr64(xhci->dcbaap_low, xhci->dcbaap_high);
poctx = ldq_le_pci_dma(PCI_DEVICE(xhci), dcbaap + 8 * slotid);
ictx = xhci_mask64(pictx);
octx = xhci_mask64(poctx);
DPRINTF("xhci: input context at "DMA_ADDR_FMT"\n", ictx);
DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx);
xhci_dma_read_u32s(xhci, ictx, ictl_ctx, sizeof(ictl_ctx));
if (ictl_ctx[0] != 0x0 || ictl_ctx[1] != 0x3) {
DPRINTF("xhci: invalid input context control %08x %08x\n",
ictl_ctx[0], ictl_ctx[1]);
return CC_TRB_ERROR;
}
xhci_dma_read_u32s(xhci, ictx+32, slot_ctx, sizeof(slot_ctx));
xhci_dma_read_u32s(xhci, ictx+64, ep0_ctx, sizeof(ep0_ctx));
DPRINTF("xhci: input slot context: %08x %08x %08x %08x\n",
slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]);
DPRINTF("xhci: input ep0 context: %08x %08x %08x %08x %08x\n",
ep0_ctx[0], ep0_ctx[1], ep0_ctx[2], ep0_ctx[3], ep0_ctx[4]);
uport = xhci_lookup_uport(xhci, slot_ctx);
if (uport == NULL) {
DPRINTF("xhci: port not found\n");
return CC_TRB_ERROR;
}
trace_usb_xhci_slot_address(slotid, uport->path);
dev = uport->dev;
if (!dev || !dev->attached) {
DPRINTF("xhci: port %s not connected\n", uport->path);
return CC_USB_TRANSACTION_ERROR;
}
for (i = 0; i < xhci->numslots; i++) {
if (i == slotid-1) {
continue;
}
if (xhci->slots[i].uport == uport) {
DPRINTF("xhci: port %s already assigned to slot %d\n",
uport->path, i+1);
return CC_TRB_ERROR;
}
}
slot = &xhci->slots[slotid-1];
slot->uport = uport;
slot->ctx = octx;
/* Make sure device is in USB_STATE_DEFAULT state */
usb_device_reset(dev);
if (bsr) {
slot_ctx[3] = SLOT_DEFAULT << SLOT_STATE_SHIFT;
} else {
USBPacket p;
uint8_t buf[1];
slot_ctx[3] = (SLOT_ADDRESSED << SLOT_STATE_SHIFT) | slotid;
memset(&p, 0, sizeof(p));
usb_packet_addbuf(&p, buf, sizeof(buf));
usb_packet_setup(&p, USB_TOKEN_OUT,
usb_ep_get(dev, USB_TOKEN_OUT, 0), 0,
0, false, false);
usb_device_handle_control(dev, &p,
DeviceOutRequest | USB_REQ_SET_ADDRESS,
slotid, 0, 0, NULL);
assert(p.status != USB_RET_ASYNC);
}
res = xhci_enable_ep(xhci, slotid, 1, octx+32, ep0_ctx);
DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n",
slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]);
DPRINTF("xhci: output ep0 context: %08x %08x %08x %08x %08x\n",
ep0_ctx[0], ep0_ctx[1], ep0_ctx[2], ep0_ctx[3], ep0_ctx[4]);
xhci_dma_write_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
xhci_dma_write_u32s(xhci, octx+32, ep0_ctx, sizeof(ep0_ctx));
xhci->slots[slotid-1].addressed = 1;
return res;
}
static TRBCCode xhci_configure_slot(XHCIState *xhci, unsigned int slotid,
uint64_t pictx, bool dc)
{
dma_addr_t ictx, octx;
uint32_t ictl_ctx[2];
uint32_t slot_ctx[4];
uint32_t islot_ctx[4];
uint32_t ep_ctx[5];
int i;
TRBCCode res;
trace_usb_xhci_slot_configure(slotid);
assert(slotid >= 1 && slotid <= xhci->numslots);
ictx = xhci_mask64(pictx);
octx = xhci->slots[slotid-1].ctx;
DPRINTF("xhci: input context at "DMA_ADDR_FMT"\n", ictx);
DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx);
if (dc) {
for (i = 2; i <= 31; i++) {
if (xhci->slots[slotid-1].eps[i-1]) {
xhci_disable_ep(xhci, slotid, i);
}
}
xhci_dma_read_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
slot_ctx[3] &= ~(SLOT_STATE_MASK << SLOT_STATE_SHIFT);
slot_ctx[3] |= SLOT_ADDRESSED << SLOT_STATE_SHIFT;
DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n",
slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]);
xhci_dma_write_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
return CC_SUCCESS;
}
xhci_dma_read_u32s(xhci, ictx, ictl_ctx, sizeof(ictl_ctx));
if ((ictl_ctx[0] & 0x3) != 0x0 || (ictl_ctx[1] & 0x3) != 0x1) {
DPRINTF("xhci: invalid input context control %08x %08x\n",
ictl_ctx[0], ictl_ctx[1]);
return CC_TRB_ERROR;
}
xhci_dma_read_u32s(xhci, ictx+32, islot_ctx, sizeof(islot_ctx));
xhci_dma_read_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
if (SLOT_STATE(slot_ctx[3]) < SLOT_ADDRESSED) {
DPRINTF("xhci: invalid slot state %08x\n", slot_ctx[3]);
return CC_CONTEXT_STATE_ERROR;
}
xhci_free_device_streams(xhci, slotid, ictl_ctx[0] | ictl_ctx[1]);
for (i = 2; i <= 31; i++) {
if (ictl_ctx[0] & (1<<i)) {
xhci_disable_ep(xhci, slotid, i);
}
if (ictl_ctx[1] & (1<<i)) {
xhci_dma_read_u32s(xhci, ictx+32+(32*i), ep_ctx, sizeof(ep_ctx));
DPRINTF("xhci: input ep%d.%d context: %08x %08x %08x %08x %08x\n",
i/2, i%2, ep_ctx[0], ep_ctx[1], ep_ctx[2],
ep_ctx[3], ep_ctx[4]);
xhci_disable_ep(xhci, slotid, i);
res = xhci_enable_ep(xhci, slotid, i, octx+(32*i), ep_ctx);
if (res != CC_SUCCESS) {
return res;
}
DPRINTF("xhci: output ep%d.%d context: %08x %08x %08x %08x %08x\n",
i/2, i%2, ep_ctx[0], ep_ctx[1], ep_ctx[2],
ep_ctx[3], ep_ctx[4]);
xhci_dma_write_u32s(xhci, octx+(32*i), ep_ctx, sizeof(ep_ctx));
}
}
res = xhci_alloc_device_streams(xhci, slotid, ictl_ctx[1]);
if (res != CC_SUCCESS) {
for (i = 2; i <= 31; i++) {
if (ictl_ctx[1] & (1u << i)) {
xhci_disable_ep(xhci, slotid, i);
}
}
return res;
}
slot_ctx[3] &= ~(SLOT_STATE_MASK << SLOT_STATE_SHIFT);
slot_ctx[3] |= SLOT_CONFIGURED << SLOT_STATE_SHIFT;
slot_ctx[0] &= ~(SLOT_CONTEXT_ENTRIES_MASK << SLOT_CONTEXT_ENTRIES_SHIFT);
slot_ctx[0] |= islot_ctx[0] & (SLOT_CONTEXT_ENTRIES_MASK <<
SLOT_CONTEXT_ENTRIES_SHIFT);
DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n",
slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]);
xhci_dma_write_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
return CC_SUCCESS;
}
static TRBCCode xhci_evaluate_slot(XHCIState *xhci, unsigned int slotid,
uint64_t pictx)
{
dma_addr_t ictx, octx;
uint32_t ictl_ctx[2];
uint32_t iep0_ctx[5];
uint32_t ep0_ctx[5];
uint32_t islot_ctx[4];
uint32_t slot_ctx[4];
trace_usb_xhci_slot_evaluate(slotid);
assert(slotid >= 1 && slotid <= xhci->numslots);
ictx = xhci_mask64(pictx);
octx = xhci->slots[slotid-1].ctx;
DPRINTF("xhci: input context at "DMA_ADDR_FMT"\n", ictx);
DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx);
xhci_dma_read_u32s(xhci, ictx, ictl_ctx, sizeof(ictl_ctx));
if (ictl_ctx[0] != 0x0 || ictl_ctx[1] & ~0x3) {
DPRINTF("xhci: invalid input context control %08x %08x\n",
ictl_ctx[0], ictl_ctx[1]);
return CC_TRB_ERROR;
}
if (ictl_ctx[1] & 0x1) {
xhci_dma_read_u32s(xhci, ictx+32, islot_ctx, sizeof(islot_ctx));
DPRINTF("xhci: input slot context: %08x %08x %08x %08x\n",
islot_ctx[0], islot_ctx[1], islot_ctx[2], islot_ctx[3]);
xhci_dma_read_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
slot_ctx[1] &= ~0xFFFF; /* max exit latency */
slot_ctx[1] |= islot_ctx[1] & 0xFFFF;
slot_ctx[2] &= ~0xFF00000; /* interrupter target */
slot_ctx[2] |= islot_ctx[2] & 0xFF000000;
DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n",
slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]);
xhci_dma_write_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
}
if (ictl_ctx[1] & 0x2) {
xhci_dma_read_u32s(xhci, ictx+64, iep0_ctx, sizeof(iep0_ctx));
DPRINTF("xhci: input ep0 context: %08x %08x %08x %08x %08x\n",
iep0_ctx[0], iep0_ctx[1], iep0_ctx[2],
iep0_ctx[3], iep0_ctx[4]);
xhci_dma_read_u32s(xhci, octx+32, ep0_ctx, sizeof(ep0_ctx));
ep0_ctx[1] &= ~0xFFFF0000; /* max packet size*/
ep0_ctx[1] |= iep0_ctx[1] & 0xFFFF0000;
DPRINTF("xhci: output ep0 context: %08x %08x %08x %08x %08x\n",
ep0_ctx[0], ep0_ctx[1], ep0_ctx[2], ep0_ctx[3], ep0_ctx[4]);
xhci_dma_write_u32s(xhci, octx+32, ep0_ctx, sizeof(ep0_ctx));
}
return CC_SUCCESS;
}
static TRBCCode xhci_reset_slot(XHCIState *xhci, unsigned int slotid)
{
uint32_t slot_ctx[4];
dma_addr_t octx;
int i;
trace_usb_xhci_slot_reset(slotid);
assert(slotid >= 1 && slotid <= xhci->numslots);
octx = xhci->slots[slotid-1].ctx;
DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx);
for (i = 2; i <= 31; i++) {
if (xhci->slots[slotid-1].eps[i-1]) {
xhci_disable_ep(xhci, slotid, i);
}
}
xhci_dma_read_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
slot_ctx[3] &= ~(SLOT_STATE_MASK << SLOT_STATE_SHIFT);
slot_ctx[3] |= SLOT_DEFAULT << SLOT_STATE_SHIFT;
DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n",
slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]);
xhci_dma_write_u32s(xhci, octx, slot_ctx, sizeof(slot_ctx));
return CC_SUCCESS;
}
static unsigned int xhci_get_slot(XHCIState *xhci, XHCIEvent *event, XHCITRB *trb)
{
unsigned int slotid;
slotid = (trb->control >> TRB_CR_SLOTID_SHIFT) & TRB_CR_SLOTID_MASK;
if (slotid < 1 || slotid > xhci->numslots) {
DPRINTF("xhci: bad slot id %d\n", slotid);
event->ccode = CC_TRB_ERROR;
return 0;
} else if (!xhci->slots[slotid-1].enabled) {
DPRINTF("xhci: slot id %d not enabled\n", slotid);
event->ccode = CC_SLOT_NOT_ENABLED_ERROR;
return 0;
}
return slotid;
}
/* cleanup slot state on usb device detach */
static void xhci_detach_slot(XHCIState *xhci, USBPort *uport)
{
int slot, ep;
for (slot = 0; slot < xhci->numslots; slot++) {
if (xhci->slots[slot].uport == uport) {
break;
}
}
if (slot == xhci->numslots) {
return;
}
for (ep = 0; ep < 31; ep++) {
if (xhci->slots[slot].eps[ep]) {
xhci_ep_nuke_xfers(xhci, slot + 1, ep + 1, 0);
}
}
xhci->slots[slot].uport = NULL;
}
static TRBCCode xhci_get_port_bandwidth(XHCIState *xhci, uint64_t pctx)
{
dma_addr_t ctx;
uint8_t bw_ctx[xhci->numports+1];
DPRINTF("xhci_get_port_bandwidth()\n");
ctx = xhci_mask64(pctx);
DPRINTF("xhci: bandwidth context at "DMA_ADDR_FMT"\n", ctx);
/* TODO: actually implement real values here */
bw_ctx[0] = 0;
memset(&bw_ctx[1], 80, xhci->numports); /* 80% */
pci_dma_write(PCI_DEVICE(xhci), ctx, bw_ctx, sizeof(bw_ctx));
return CC_SUCCESS;
}
static uint32_t rotl(uint32_t v, unsigned count)
{
count &= 31;
return (v << count) | (v >> (32 - count));
}
static uint32_t xhci_nec_challenge(uint32_t hi, uint32_t lo)
{
uint32_t val;
val = rotl(lo - 0x49434878, 32 - ((hi>>8) & 0x1F));
val += rotl(lo + 0x49434878, hi & 0x1F);
val -= rotl(hi ^ 0x49434878, (lo >> 16) & 0x1F);
return ~val;
}
static void xhci_process_commands(XHCIState *xhci)
{
XHCITRB trb;
TRBType type;
XHCIEvent event = {ER_COMMAND_COMPLETE, CC_SUCCESS};
dma_addr_t addr;
unsigned int i, slotid = 0, count = 0;
DPRINTF("xhci_process_commands()\n");
if (!xhci_running(xhci)) {
DPRINTF("xhci_process_commands() called while xHC stopped or paused\n");
return;
}
xhci->crcr_low |= CRCR_CRR;
while ((type = xhci_ring_fetch(xhci, &xhci->cmd_ring, &trb, &addr))) {
event.ptr = addr;
switch (type) {
case CR_ENABLE_SLOT:
for (i = 0; i < xhci->numslots; i++) {
if (!xhci->slots[i].enabled) {
break;
}
}
if (i >= xhci->numslots) {
DPRINTF("xhci: no device slots available\n");
event.ccode = CC_NO_SLOTS_ERROR;
} else {
slotid = i+1;
event.ccode = xhci_enable_slot(xhci, slotid);
}
break;
case CR_DISABLE_SLOT:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
event.ccode = xhci_disable_slot(xhci, slotid);
}
break;
case CR_ADDRESS_DEVICE:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
event.ccode = xhci_address_slot(xhci, slotid, trb.parameter,
trb.control & TRB_CR_BSR);
}
break;
case CR_CONFIGURE_ENDPOINT:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
event.ccode = xhci_configure_slot(xhci, slotid, trb.parameter,
trb.control & TRB_CR_DC);
}
break;
case CR_EVALUATE_CONTEXT:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
event.ccode = xhci_evaluate_slot(xhci, slotid, trb.parameter);
}
break;
case CR_STOP_ENDPOINT:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
unsigned int epid = (trb.control >> TRB_CR_EPID_SHIFT)
& TRB_CR_EPID_MASK;
event.ccode = xhci_stop_ep(xhci, slotid, epid);
}
break;
case CR_RESET_ENDPOINT:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
unsigned int epid = (trb.control >> TRB_CR_EPID_SHIFT)
& TRB_CR_EPID_MASK;
event.ccode = xhci_reset_ep(xhci, slotid, epid);
}
break;
case CR_SET_TR_DEQUEUE:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
unsigned int epid = (trb.control >> TRB_CR_EPID_SHIFT)
& TRB_CR_EPID_MASK;
unsigned int streamid = (trb.status >> 16) & 0xffff;
event.ccode = xhci_set_ep_dequeue(xhci, slotid,
epid, streamid,
trb.parameter);
}
break;
case CR_RESET_DEVICE:
slotid = xhci_get_slot(xhci, &event, &trb);
if (slotid) {
event.ccode = xhci_reset_slot(xhci, slotid);
}
break;
case CR_GET_PORT_BANDWIDTH:
event.ccode = xhci_get_port_bandwidth(xhci, trb.parameter);
break;
case CR_VENDOR_NEC_FIRMWARE_REVISION:
if (xhci->nec_quirks) {
event.type = 48; /* NEC reply */
event.length = 0x3025;
} else {
event.ccode = CC_TRB_ERROR;
}
break;
case CR_VENDOR_NEC_CHALLENGE_RESPONSE:
if (xhci->nec_quirks) {
uint32_t chi = trb.parameter >> 32;
uint32_t clo = trb.parameter;
uint32_t val = xhci_nec_challenge(chi, clo);
event.length = val & 0xFFFF;
event.epid = val >> 16;
slotid = val >> 24;
event.type = 48; /* NEC reply */
} else {
event.ccode = CC_TRB_ERROR;
}
break;
default:
trace_usb_xhci_unimplemented("command", type);
event.ccode = CC_TRB_ERROR;
break;
}
event.slotid = slotid;
xhci_event(xhci, &event, 0);
if (count++ > COMMAND_LIMIT) {
trace_usb_xhci_enforced_limit("commands");
return;
}
}
}
static bool xhci_port_have_device(XHCIPort *port)
{
if (!port->uport->dev || !port->uport->dev->attached) {
return false; /* no device present */
}
if (!((1 << port->uport->dev->speed) & port->speedmask)) {
return false; /* speed mismatch */
}
return true;
}
static void xhci_port_notify(XHCIPort *port, uint32_t bits)
{
XHCIEvent ev = { ER_PORT_STATUS_CHANGE, CC_SUCCESS,
port->portnr << 24 };
if ((port->portsc & bits) == bits) {
return;
}
trace_usb_xhci_port_notify(port->portnr, bits);
port->portsc |= bits;
if (!xhci_running(port->xhci)) {
return;
}
xhci_event(port->xhci, &ev, 0);
}
static void xhci_port_update(XHCIPort *port, int is_detach)
{
uint32_t pls = PLS_RX_DETECT;
port->portsc = PORTSC_PP;
if (!is_detach && xhci_port_have_device(port)) {
port->portsc |= PORTSC_CCS;
switch (port->uport->dev->speed) {
case USB_SPEED_LOW:
port->portsc |= PORTSC_SPEED_LOW;
pls = PLS_POLLING;
break;
case USB_SPEED_FULL:
port->portsc |= PORTSC_SPEED_FULL;
pls = PLS_POLLING;
break;
case USB_SPEED_HIGH:
port->portsc |= PORTSC_SPEED_HIGH;
pls = PLS_POLLING;
break;
case USB_SPEED_SUPER:
port->portsc |= PORTSC_SPEED_SUPER;
port->portsc |= PORTSC_PED;
pls = PLS_U0;
break;
}
}
set_field(&port->portsc, pls, PORTSC_PLS);
trace_usb_xhci_port_link(port->portnr, pls);
xhci_port_notify(port, PORTSC_CSC);
}
static void xhci_port_reset(XHCIPort *port, bool warm_reset)
{
trace_usb_xhci_port_reset(port->portnr, warm_reset);
if (!xhci_port_have_device(port)) {
return;
}
usb_device_reset(port->uport->dev);
switch (port->uport->dev->speed) {
case USB_SPEED_SUPER:
if (warm_reset) {
port->portsc |= PORTSC_WRC;
}
/* fall through */
case USB_SPEED_LOW:
case USB_SPEED_FULL:
case USB_SPEED_HIGH:
set_field(&port->portsc, PLS_U0, PORTSC_PLS);
trace_usb_xhci_port_link(port->portnr, PLS_U0);
port->portsc |= PORTSC_PED;
break;
}
port->portsc &= ~PORTSC_PR;
xhci_port_notify(port, PORTSC_PRC);
}
static void xhci_reset(DeviceState *dev)
{
XHCIState *xhci = XHCI(dev);
int i;
trace_usb_xhci_reset();
if (!(xhci->usbsts & USBSTS_HCH)) {
DPRINTF("xhci: reset while running!\n");
}
xhci->usbcmd = 0;
xhci->usbsts = USBSTS_HCH;
xhci->dnctrl = 0;
xhci->crcr_low = 0;
xhci->crcr_high = 0;
xhci->dcbaap_low = 0;
xhci->dcbaap_high = 0;
xhci->config = 0;
for (i = 0; i < xhci->numslots; i++) {
xhci_disable_slot(xhci, i+1);
}
for (i = 0; i < xhci->numports; i++) {
xhci_port_update(xhci->ports + i, 0);
}
for (i = 0; i < xhci->numintrs; i++) {
xhci->intr[i].iman = 0;
xhci->intr[i].imod = 0;
xhci->intr[i].erstsz = 0;
xhci->intr[i].erstba_low = 0;
xhci->intr[i].erstba_high = 0;
xhci->intr[i].erdp_low = 0;
xhci->intr[i].erdp_high = 0;
xhci->intr[i].msix_used = 0;
xhci->intr[i].er_ep_idx = 0;
xhci->intr[i].er_pcs = 1;
xhci->intr[i].ev_buffer_put = 0;
xhci->intr[i].ev_buffer_get = 0;
}
xhci->mfindex_start = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL);
xhci_mfwrap_update(xhci);
}
static uint64_t xhci_cap_read(void *ptr, hwaddr reg, unsigned size)
{
XHCIState *xhci = ptr;
uint32_t ret;
switch (reg) {
case 0x00: /* HCIVERSION, CAPLENGTH */
ret = 0x01000000 | LEN_CAP;
break;
case 0x04: /* HCSPARAMS 1 */
ret = ((xhci->numports_2+xhci->numports_3)<<24)
| (xhci->numintrs<<8) | xhci->numslots;
break;
case 0x08: /* HCSPARAMS 2 */
ret = 0x0000000f;
break;
case 0x0c: /* HCSPARAMS 3 */
ret = 0x00000000;
break;
case 0x10: /* HCCPARAMS */
if (sizeof(dma_addr_t) == 4) {
ret = 0x00080000 | (xhci->max_pstreams_mask << 12);
} else {
ret = 0x00080001 | (xhci->max_pstreams_mask << 12);
}
break;
case 0x14: /* DBOFF */
ret = OFF_DOORBELL;
break;
case 0x18: /* RTSOFF */
ret = OFF_RUNTIME;
break;
/* extended capabilities */
case 0x20: /* Supported Protocol:00 */
ret = 0x02000402; /* USB 2.0 */
break;
case 0x24: /* Supported Protocol:04 */
ret = 0x20425355; /* "USB " */
break;
case 0x28: /* Supported Protocol:08 */
if (xhci_get_flag(xhci, XHCI_FLAG_SS_FIRST)) {
ret = (xhci->numports_2<<8) | (xhci->numports_3+1);
} else {
ret = (xhci->numports_2<<8) | 1;
}
break;
case 0x2c: /* Supported Protocol:0c */
ret = 0x00000000; /* reserved */
break;
case 0x30: /* Supported Protocol:00 */
ret = 0x03000002; /* USB 3.0 */
break;
case 0x34: /* Supported Protocol:04 */
ret = 0x20425355; /* "USB " */
break;
case 0x38: /* Supported Protocol:08 */
if (xhci_get_flag(xhci, XHCI_FLAG_SS_FIRST)) {
ret = (xhci->numports_3<<8) | 1;
} else {
ret = (xhci->numports_3<<8) | (xhci->numports_2+1);
}
break;
case 0x3c: /* Supported Protocol:0c */
ret = 0x00000000; /* reserved */
break;
default:
trace_usb_xhci_unimplemented("cap read", reg);
ret = 0;
}
trace_usb_xhci_cap_read(reg, ret);
return ret;
}
static uint64_t xhci_port_read(void *ptr, hwaddr reg, unsigned size)
{
XHCIPort *port = ptr;
uint32_t ret;
switch (reg) {
case 0x00: /* PORTSC */
ret = port->portsc;
break;
case 0x04: /* PORTPMSC */
case 0x08: /* PORTLI */
ret = 0;
break;
case 0x0c: /* reserved */
default:
trace_usb_xhci_unimplemented("port read", reg);
ret = 0;
}
trace_usb_xhci_port_read(port->portnr, reg, ret);
return ret;
}
static void xhci_port_write(void *ptr, hwaddr reg,
uint64_t val, unsigned size)
{
XHCIPort *port = ptr;
uint32_t portsc, notify;
trace_usb_xhci_port_write(port->portnr, reg, val);
switch (reg) {
case 0x00: /* PORTSC */
/* write-1-to-start bits */
if (val & PORTSC_WPR) {
xhci_port_reset(port, true);
break;
}
if (val & PORTSC_PR) {
xhci_port_reset(port, false);
break;
}
portsc = port->portsc;
notify = 0;
/* write-1-to-clear bits*/
portsc &= ~(val & (PORTSC_CSC|PORTSC_PEC|PORTSC_WRC|PORTSC_OCC|
PORTSC_PRC|PORTSC_PLC|PORTSC_CEC));
if (val & PORTSC_LWS) {
/* overwrite PLS only when LWS=1 */
uint32_t old_pls = get_field(port->portsc, PORTSC_PLS);
uint32_t new_pls = get_field(val, PORTSC_PLS);
switch (new_pls) {
case PLS_U0:
if (old_pls != PLS_U0) {
set_field(&portsc, new_pls, PORTSC_PLS);
trace_usb_xhci_port_link(port->portnr, new_pls);
notify = PORTSC_PLC;
}
break;
case PLS_U3:
if (old_pls < PLS_U3) {
set_field(&portsc, new_pls, PORTSC_PLS);
trace_usb_xhci_port_link(port->portnr, new_pls);
}
break;
case PLS_RESUME:
/* windows does this for some reason, don't spam stderr */
break;
default:
DPRINTF("%s: ignore pls write (old %d, new %d)\n",
__func__, old_pls, new_pls);
break;
}
}
/* read/write bits */
portsc &= ~(PORTSC_PP|PORTSC_WCE|PORTSC_WDE|PORTSC_WOE);
portsc |= (val & (PORTSC_PP|PORTSC_WCE|PORTSC_WDE|PORTSC_WOE));
port->portsc = portsc;
if (notify) {
xhci_port_notify(port, notify);
}
break;
case 0x04: /* PORTPMSC */
case 0x08: /* PORTLI */
default:
trace_usb_xhci_unimplemented("port write", reg);
}
}
static uint64_t xhci_oper_read(void *ptr, hwaddr reg, unsigned size)
{
XHCIState *xhci = ptr;
uint32_t ret;
switch (reg) {
case 0x00: /* USBCMD */
ret = xhci->usbcmd;
break;
case 0x04: /* USBSTS */
ret = xhci->usbsts;
break;
case 0x08: /* PAGESIZE */
ret = 1; /* 4KiB */
break;
case 0x14: /* DNCTRL */
ret = xhci->dnctrl;
break;
case 0x18: /* CRCR low */
ret = xhci->crcr_low & ~0xe;
break;
case 0x1c: /* CRCR high */
ret = xhci->crcr_high;
break;
case 0x30: /* DCBAAP low */
ret = xhci->dcbaap_low;
break;
case 0x34: /* DCBAAP high */
ret = xhci->dcbaap_high;
break;
case 0x38: /* CONFIG */
ret = xhci->config;
break;
default:
trace_usb_xhci_unimplemented("oper read", reg);
ret = 0;
}
trace_usb_xhci_oper_read(reg, ret);
return ret;
}
static void xhci_oper_write(void *ptr, hwaddr reg,
uint64_t val, unsigned size)
{
XHCIState *xhci = ptr;
DeviceState *d = DEVICE(ptr);
trace_usb_xhci_oper_write(reg, val);
switch (reg) {
case 0x00: /* USBCMD */
if ((val & USBCMD_RS) && !(xhci->usbcmd & USBCMD_RS)) {
xhci_run(xhci);
} else if (!(val & USBCMD_RS) && (xhci->usbcmd & USBCMD_RS)) {
xhci_stop(xhci);
}
if (val & USBCMD_CSS) {
/* save state */
xhci->usbsts &= ~USBSTS_SRE;
}
if (val & USBCMD_CRS) {
/* restore state */
xhci->usbsts |= USBSTS_SRE;
}
xhci->usbcmd = val & 0xc0f;
xhci_mfwrap_update(xhci);
if (val & USBCMD_HCRST) {
xhci_reset(d);
}
xhci_intx_update(xhci);
break;
case 0x04: /* USBSTS */
/* these bits are write-1-to-clear */
xhci->usbsts &= ~(val & (USBSTS_HSE|USBSTS_EINT|USBSTS_PCD|USBSTS_SRE));
xhci_intx_update(xhci);
break;
case 0x14: /* DNCTRL */
xhci->dnctrl = val & 0xffff;
break;
case 0x18: /* CRCR low */
xhci->crcr_low = (val & 0xffffffcf) | (xhci->crcr_low & CRCR_CRR);
break;
case 0x1c: /* CRCR high */
xhci->crcr_high = val;
if (xhci->crcr_low & (CRCR_CA|CRCR_CS) && (xhci->crcr_low & CRCR_CRR)) {
XHCIEvent event = {ER_COMMAND_COMPLETE, CC_COMMAND_RING_STOPPED};
xhci->crcr_low &= ~CRCR_CRR;
xhci_event(xhci, &event, 0);
DPRINTF("xhci: command ring stopped (CRCR=%08x)\n", xhci->crcr_low);
} else {
dma_addr_t base = xhci_addr64(xhci->crcr_low & ~0x3f, val);
xhci_ring_init(xhci, &xhci->cmd_ring, base);
}
xhci->crcr_low &= ~(CRCR_CA | CRCR_CS);
break;
case 0x30: /* DCBAAP low */
xhci->dcbaap_low = val & 0xffffffc0;
break;
case 0x34: /* DCBAAP high */
xhci->dcbaap_high = val;
break;
case 0x38: /* CONFIG */
xhci->config = val & 0xff;
break;
default:
trace_usb_xhci_unimplemented("oper write", reg);
}
}
static uint64_t xhci_runtime_read(void *ptr, hwaddr reg,
unsigned size)
{
XHCIState *xhci = ptr;
uint32_t ret = 0;
if (reg < 0x20) {
switch (reg) {
case 0x00: /* MFINDEX */
ret = xhci_mfindex_get(xhci) & 0x3fff;
break;
default:
trace_usb_xhci_unimplemented("runtime read", reg);
break;
}
} else {
int v = (reg - 0x20) / 0x20;
XHCIInterrupter *intr = &xhci->intr[v];
switch (reg & 0x1f) {
case 0x00: /* IMAN */
ret = intr->iman;
break;
case 0x04: /* IMOD */
ret = intr->imod;
break;
case 0x08: /* ERSTSZ */
ret = intr->erstsz;
break;
case 0x10: /* ERSTBA low */
ret = intr->erstba_low;
break;
case 0x14: /* ERSTBA high */
ret = intr->erstba_high;
break;
case 0x18: /* ERDP low */
ret = intr->erdp_low;
break;
case 0x1c: /* ERDP high */
ret = intr->erdp_high;
break;
}
}
trace_usb_xhci_runtime_read(reg, ret);
return ret;
}
static void xhci_runtime_write(void *ptr, hwaddr reg,
uint64_t val, unsigned size)
{
XHCIState *xhci = ptr;
int v = (reg - 0x20) / 0x20;
XHCIInterrupter *intr = &xhci->intr[v];
trace_usb_xhci_runtime_write(reg, val);
if (reg < 0x20) {
trace_usb_xhci_unimplemented("runtime write", reg);
return;
}
switch (reg & 0x1f) {
case 0x00: /* IMAN */
if (val & IMAN_IP) {
intr->iman &= ~IMAN_IP;
}
intr->iman &= ~IMAN_IE;
intr->iman |= val & IMAN_IE;
if (v == 0) {
xhci_intx_update(xhci);
}
xhci_msix_update(xhci, v);
break;
case 0x04: /* IMOD */
intr->imod = val;
break;
case 0x08: /* ERSTSZ */
intr->erstsz = val & 0xffff;
break;
case 0x10: /* ERSTBA low */
if (xhci->nec_quirks) {
/* NEC driver bug: it doesn't align this to 64 bytes */
intr->erstba_low = val & 0xfffffff0;
} else {
intr->erstba_low = val & 0xffffffc0;
}
break;
case 0x14: /* ERSTBA high */
intr->erstba_high = val;
xhci_er_reset(xhci, v);
break;
case 0x18: /* ERDP low */
if (val & ERDP_EHB) {
intr->erdp_low &= ~ERDP_EHB;
}
intr->erdp_low = (val & ~ERDP_EHB) | (intr->erdp_low & ERDP_EHB);
xhci: fix event queue IRQ handling The qemu xhci emulation doesn't handle the ERDP_EHB flag correctly. When the host adapter queues a new event the ERDP_EHB flag is set. The flag is cleared (via w1c) by the guest when it updates the ERDP (event ring dequeue pointer) register to notify the host adapter which events it has fetched. An IRQ must be raised in case the ERDP_EHB flag flips from clear to set. If the flag is set already (which implies there are events queued up which are not yet processed by the guest) xhci must *not* raise a IRQ. Qemu got that wrong and raised an IRQ on every event, thereby generating spurious interrupts in case we've queued events faster than the guest processed them. This patch fixes that. With that change in place we also have to check ERDP updates, to see whenever the guest has fetched all queued events. In case there are still pending events set ERDP_EHB and raise an IRQ again, to make sure the events don't linger unseen forever. The linux kernel driver and the microsoft windows driver (shipped with win8+) can deal with the spurious interrupts without problems. The renesas windows driver (v2.1.39) which can be used on older windows versions is quite upset though. It does spurious ERDP updates now and then (not every time, seems we must hit a race window for this to happen), which in turn makes the qemu xhci emulation think the event ring is full. Things go south from here ... tl;dr: This is the "fix xhci on win7" patch. Cc: M.Cerveny@computer.org Cc: 1373228@bugs.launchpad.net Signed-off-by: Gerd Hoffmann <kraxel@redhat.com> Message-id: 1486104705-13761-1-git-send-email-kraxel@redhat.com
2017-02-03 09:51:45 +03:00
if (val & ERDP_EHB) {
dma_addr_t erdp = xhci_addr64(intr->erdp_low, intr->erdp_high);
unsigned int dp_idx = (erdp - intr->er_start) / TRB_SIZE;
if (erdp >= intr->er_start &&
erdp < (intr->er_start + TRB_SIZE * intr->er_size) &&
dp_idx != intr->er_ep_idx) {
xhci_intr_raise(xhci, v);
}
}
break;
case 0x1c: /* ERDP high */
intr->erdp_high = val;
break;
default:
trace_usb_xhci_unimplemented("oper write", reg);
}
}
static uint64_t xhci_doorbell_read(void *ptr, hwaddr reg,
unsigned size)
{
/* doorbells always read as 0 */
trace_usb_xhci_doorbell_read(reg, 0);
return 0;
}
static void xhci_doorbell_write(void *ptr, hwaddr reg,
uint64_t val, unsigned size)
{
XHCIState *xhci = ptr;
unsigned int epid, streamid;
trace_usb_xhci_doorbell_write(reg, val);
if (!xhci_running(xhci)) {
DPRINTF("xhci: wrote doorbell while xHC stopped or paused\n");
return;
}
reg >>= 2;
if (reg == 0) {
if (val == 0) {
xhci_process_commands(xhci);
} else {
DPRINTF("xhci: bad doorbell 0 write: 0x%x\n",
(uint32_t)val);
}
} else {
epid = val & 0xff;
streamid = (val >> 16) & 0xffff;
if (reg > xhci->numslots) {
DPRINTF("xhci: bad doorbell %d\n", (int)reg);
} else if (epid > 31) {
DPRINTF("xhci: bad doorbell %d write: 0x%x\n",
(int)reg, (uint32_t)val);
} else {
xhci_kick_ep(xhci, reg, epid, streamid);
}
}
}
static void xhci_cap_write(void *opaque, hwaddr addr, uint64_t val,
unsigned width)
{
/* nothing */
}
static const MemoryRegionOps xhci_cap_ops = {
.read = xhci_cap_read,
.write = xhci_cap_write,
.valid.min_access_size = 1,
.valid.max_access_size = 4,
.impl.min_access_size = 4,
.impl.max_access_size = 4,
.endianness = DEVICE_LITTLE_ENDIAN,
};
static const MemoryRegionOps xhci_oper_ops = {
.read = xhci_oper_read,
.write = xhci_oper_write,
.valid.min_access_size = 4,
.valid.max_access_size = 4,
.endianness = DEVICE_LITTLE_ENDIAN,
};
static const MemoryRegionOps xhci_port_ops = {
.read = xhci_port_read,
.write = xhci_port_write,
.valid.min_access_size = 4,
.valid.max_access_size = 4,
.endianness = DEVICE_LITTLE_ENDIAN,
};
static const MemoryRegionOps xhci_runtime_ops = {
.read = xhci_runtime_read,
.write = xhci_runtime_write,
.valid.min_access_size = 4,
.valid.max_access_size = 4,
.endianness = DEVICE_LITTLE_ENDIAN,
};
static const MemoryRegionOps xhci_doorbell_ops = {
.read = xhci_doorbell_read,
.write = xhci_doorbell_write,
.valid.min_access_size = 4,
.valid.max_access_size = 4,
.endianness = DEVICE_LITTLE_ENDIAN,
};
static void xhci_attach(USBPort *usbport)
{
XHCIState *xhci = usbport->opaque;
XHCIPort *port = xhci_lookup_port(xhci, usbport);
xhci_port_update(port, 0);
}
static void xhci_detach(USBPort *usbport)
{
XHCIState *xhci = usbport->opaque;
XHCIPort *port = xhci_lookup_port(xhci, usbport);
xhci_detach_slot(xhci, usbport);
xhci_port_update(port, 1);
}
static void xhci_wakeup(USBPort *usbport)
{
XHCIState *xhci = usbport->opaque;
XHCIPort *port = xhci_lookup_port(xhci, usbport);
if (get_field(port->portsc, PORTSC_PLS) != PLS_U3) {
return;
}
set_field(&port->portsc, PLS_RESUME, PORTSC_PLS);
xhci_port_notify(port, PORTSC_PLC);
}
static void xhci_complete(USBPort *port, USBPacket *packet)
{
XHCITransfer *xfer = container_of(packet, XHCITransfer, packet);
if (packet->status == USB_RET_REMOVE_FROM_QUEUE) {
xhci_ep_nuke_one_xfer(xfer, 0);
return;
}
xhci_try_complete_packet(xfer);
xhci_kick_epctx(xfer->epctx, xfer->streamid);
if (xfer->complete) {
xhci_ep_free_xfer(xfer);
}
}
static void xhci_child_detach(USBPort *uport, USBDevice *child)
{
USBBus *bus = usb_bus_from_device(child);
XHCIState *xhci = container_of(bus, XHCIState, bus);
xhci_detach_slot(xhci, child->port);
}
static USBPortOps xhci_uport_ops = {
.attach = xhci_attach,
.detach = xhci_detach,
.wakeup = xhci_wakeup,
.complete = xhci_complete,
.child_detach = xhci_child_detach,
};
static int xhci_find_epid(USBEndpoint *ep)
{
if (ep->nr == 0) {
return 1;
}
if (ep->pid == USB_TOKEN_IN) {
return ep->nr * 2 + 1;
} else {
return ep->nr * 2;
}
}
static USBEndpoint *xhci_epid_to_usbep(XHCIEPContext *epctx)
{
USBPort *uport;
uint32_t token;
if (!epctx) {
return NULL;
}
uport = epctx->xhci->slots[epctx->slotid - 1].uport;
token = (epctx->epid & 1) ? USB_TOKEN_IN : USB_TOKEN_OUT;
if (!uport) {
return NULL;
}
return usb_ep_get(uport->dev, token, epctx->epid >> 1);
}
static void xhci_wakeup_endpoint(USBBus *bus, USBEndpoint *ep,
unsigned int stream)
{
XHCIState *xhci = container_of(bus, XHCIState, bus);
int slotid;
DPRINTF("%s\n", __func__);
slotid = ep->dev->addr;
if (slotid == 0 || !xhci->slots[slotid-1].enabled) {
DPRINTF("%s: oops, no slot for dev %d\n", __func__, ep->dev->addr);
return;
}
xhci_kick_ep(xhci, slotid, xhci_find_epid(ep), stream);
}
static USBBusOps xhci_bus_ops = {
.wakeup_endpoint = xhci_wakeup_endpoint,
};
static void usb_xhci_init(XHCIState *xhci)
{
DeviceState *dev = DEVICE(xhci);
XHCIPort *port;
int i, usbports, speedmask;
xhci->usbsts = USBSTS_HCH;
if (xhci->numports_2 > MAXPORTS_2) {
xhci->numports_2 = MAXPORTS_2;
}
if (xhci->numports_3 > MAXPORTS_3) {
xhci->numports_3 = MAXPORTS_3;
}
usbports = MAX(xhci->numports_2, xhci->numports_3);
xhci->numports = xhci->numports_2 + xhci->numports_3;
usb_bus_new(&xhci->bus, sizeof(xhci->bus), &xhci_bus_ops, dev);
for (i = 0; i < usbports; i++) {
speedmask = 0;
if (i < xhci->numports_2) {
if (xhci_get_flag(xhci, XHCI_FLAG_SS_FIRST)) {
port = &xhci->ports[i + xhci->numports_3];
port->portnr = i + 1 + xhci->numports_3;
} else {
port = &xhci->ports[i];
port->portnr = i + 1;
}
port->uport = &xhci->uports[i];
port->speedmask =
USB_SPEED_MASK_LOW |
USB_SPEED_MASK_FULL |
USB_SPEED_MASK_HIGH;
snprintf(port->name, sizeof(port->name), "usb2 port #%d", i+1);
speedmask |= port->speedmask;
}
if (i < xhci->numports_3) {
if (xhci_get_flag(xhci, XHCI_FLAG_SS_FIRST)) {
port = &xhci->ports[i];
port->portnr = i + 1;
} else {
port = &xhci->ports[i + xhci->numports_2];
port->portnr = i + 1 + xhci->numports_2;
}
port->uport = &xhci->uports[i];
port->speedmask = USB_SPEED_MASK_SUPER;
snprintf(port->name, sizeof(port->name), "usb3 port #%d", i+1);
speedmask |= port->speedmask;
}
usb_register_port(&xhci->bus, &xhci->uports[i], xhci, i,
&xhci_uport_ops, speedmask);
}
}
static void usb_xhci_realize(struct PCIDevice *dev, Error **errp)
{
int i, ret;
Error *err = NULL;
XHCIState *xhci = XHCI(dev);
dev->config[PCI_CLASS_PROG] = 0x30; /* xHCI */
dev->config[PCI_INTERRUPT_PIN] = 0x01; /* interrupt pin 1 */
dev->config[PCI_CACHE_LINE_SIZE] = 0x10;
dev->config[0x60] = 0x30; /* release number */
if (strcmp(object_get_typename(OBJECT(dev)), TYPE_NEC_XHCI) == 0) {
xhci->nec_quirks = true;
}
if (xhci->numintrs > MAXINTRS) {
xhci->numintrs = MAXINTRS;
}
while (xhci->numintrs & (xhci->numintrs - 1)) { /* ! power of 2 */
xhci->numintrs++;
}
if (xhci->numintrs < 1) {
xhci->numintrs = 1;
}
if (xhci->numslots > MAXSLOTS) {
xhci->numslots = MAXSLOTS;
}
if (xhci->numslots < 1) {
xhci->numslots = 1;
}
if (xhci_get_flag(xhci, XHCI_FLAG_ENABLE_STREAMS)) {
xhci->max_pstreams_mask = 7; /* == 256 primary streams */
} else {
xhci->max_pstreams_mask = 0;
}
if (xhci->msi != ON_OFF_AUTO_OFF) {
ret = msi_init(dev, 0x70, xhci->numintrs, true, false, &err);
/* Any error other than -ENOTSUP(board's MSI support is broken)
* is a programming error */
assert(!ret || ret == -ENOTSUP);
if (ret && xhci->msi == ON_OFF_AUTO_ON) {
/* Can't satisfy user's explicit msi=on request, fail */
error_append_hint(&err, "You have to use msi=auto (default) or "
"msi=off with this machine type.\n");
error_propagate(errp, err);
return;
}
assert(!err || xhci->msi == ON_OFF_AUTO_AUTO);
/* With msi=auto, we fall back to MSI off silently */
error_free(err);
}
usb_xhci_init(xhci);
xhci->mfwrap_timer = timer_new_ns(QEMU_CLOCK_VIRTUAL, xhci_mfwrap_timer, xhci);
memory_region_init(&xhci->mem, OBJECT(xhci), "xhci", LEN_REGS);
memory_region_init_io(&xhci->mem_cap, OBJECT(xhci), &xhci_cap_ops, xhci,
"capabilities", LEN_CAP);
memory_region_init_io(&xhci->mem_oper, OBJECT(xhci), &xhci_oper_ops, xhci,
"operational", 0x400);
memory_region_init_io(&xhci->mem_runtime, OBJECT(xhci), &xhci_runtime_ops, xhci,
"runtime", LEN_RUNTIME);
memory_region_init_io(&xhci->mem_doorbell, OBJECT(xhci), &xhci_doorbell_ops, xhci,
"doorbell", LEN_DOORBELL);
memory_region_add_subregion(&xhci->mem, 0, &xhci->mem_cap);
memory_region_add_subregion(&xhci->mem, OFF_OPER, &xhci->mem_oper);
memory_region_add_subregion(&xhci->mem, OFF_RUNTIME, &xhci->mem_runtime);
memory_region_add_subregion(&xhci->mem, OFF_DOORBELL, &xhci->mem_doorbell);
for (i = 0; i < xhci->numports; i++) {
XHCIPort *port = &xhci->ports[i];
uint32_t offset = OFF_OPER + 0x400 + 0x10 * i;
port->xhci = xhci;
memory_region_init_io(&port->mem, OBJECT(xhci), &xhci_port_ops, port,
port->name, 0x10);
memory_region_add_subregion(&xhci->mem, offset, &port->mem);
}
pci_register_bar(dev, 0,
PCI_BASE_ADDRESS_SPACE_MEMORY|PCI_BASE_ADDRESS_MEM_TYPE_64,
&xhci->mem);
if (pci_bus_is_express(dev->bus) ||
xhci_get_flag(xhci, XHCI_FLAG_FORCE_PCIE_ENDCAP)) {
ret = pcie_endpoint_cap_init(dev, 0xa0);
assert(ret > 0);
}
if (xhci->msix != ON_OFF_AUTO_OFF) {
/* TODO check for errors, and should fail when msix=on */
msix_init(dev, xhci->numintrs,
&xhci->mem, 0, OFF_MSIX_TABLE,
&xhci->mem, 0, OFF_MSIX_PBA,
0x90, NULL);
}
}
static void usb_xhci_exit(PCIDevice *dev)
{
int i;
XHCIState *xhci = XHCI(dev);
trace_usb_xhci_exit();
for (i = 0; i < xhci->numslots; i++) {
xhci_disable_slot(xhci, i + 1);
}
if (xhci->mfwrap_timer) {
timer_del(xhci->mfwrap_timer);
timer_free(xhci->mfwrap_timer);
xhci->mfwrap_timer = NULL;
}
memory_region_del_subregion(&xhci->mem, &xhci->mem_cap);
memory_region_del_subregion(&xhci->mem, &xhci->mem_oper);
memory_region_del_subregion(&xhci->mem, &xhci->mem_runtime);
memory_region_del_subregion(&xhci->mem, &xhci->mem_doorbell);
for (i = 0; i < xhci->numports; i++) {
XHCIPort *port = &xhci->ports[i];
memory_region_del_subregion(&xhci->mem, &port->mem);
}
/* destroy msix memory region */
if (dev->msix_table && dev->msix_pba
&& dev->msix_entry_used) {
msix_uninit(dev, &xhci->mem, &xhci->mem);
}
usb_bus_release(&xhci->bus);
}
static int usb_xhci_post_load(void *opaque, int version_id)
{
XHCIState *xhci = opaque;
PCIDevice *pci_dev = PCI_DEVICE(xhci);
XHCISlot *slot;
XHCIEPContext *epctx;
dma_addr_t dcbaap, pctx;
uint32_t slot_ctx[4];
uint32_t ep_ctx[5];
int slotid, epid, state, intr;
dcbaap = xhci_addr64(xhci->dcbaap_low, xhci->dcbaap_high);
for (slotid = 1; slotid <= xhci->numslots; slotid++) {
slot = &xhci->slots[slotid-1];
if (!slot->addressed) {
continue;
}
slot->ctx =
xhci_mask64(ldq_le_pci_dma(pci_dev, dcbaap + 8 * slotid));
xhci_dma_read_u32s(xhci, slot->ctx, slot_ctx, sizeof(slot_ctx));
slot->uport = xhci_lookup_uport(xhci, slot_ctx);
if (!slot->uport) {
/* should not happen, but may trigger on guest bugs */
slot->enabled = 0;
slot->addressed = 0;
continue;
}
assert(slot->uport && slot->uport->dev);
for (epid = 1; epid <= 31; epid++) {
pctx = slot->ctx + 32 * epid;
xhci_dma_read_u32s(xhci, pctx, ep_ctx, sizeof(ep_ctx));
state = ep_ctx[0] & EP_STATE_MASK;
if (state == EP_DISABLED) {
continue;
}
epctx = xhci_alloc_epctx(xhci, slotid, epid);
slot->eps[epid-1] = epctx;
xhci_init_epctx(epctx, pctx, ep_ctx);
epctx->state = state;
if (state == EP_RUNNING) {
/* kick endpoint after vmload is finished */
timer_mod(epctx->kick_timer, qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL));
}
}
}
for (intr = 0; intr < xhci->numintrs; intr++) {
if (xhci->intr[intr].msix_used) {
msix_vector_use(pci_dev, intr);
} else {
msix_vector_unuse(pci_dev, intr);
}
}
return 0;
}
static const VMStateDescription vmstate_xhci_ring = {
.name = "xhci-ring",
.version_id = 1,
.fields = (VMStateField[]) {
VMSTATE_UINT64(dequeue, XHCIRing),
VMSTATE_BOOL(ccs, XHCIRing),
VMSTATE_END_OF_LIST()
}
};
static const VMStateDescription vmstate_xhci_port = {
.name = "xhci-port",
.version_id = 1,
.fields = (VMStateField[]) {
VMSTATE_UINT32(portsc, XHCIPort),
VMSTATE_END_OF_LIST()
}
};
static const VMStateDescription vmstate_xhci_slot = {
.name = "xhci-slot",
.version_id = 1,
.fields = (VMStateField[]) {
VMSTATE_BOOL(enabled, XHCISlot),
VMSTATE_BOOL(addressed, XHCISlot),
VMSTATE_END_OF_LIST()
}
};
static const VMStateDescription vmstate_xhci_event = {
.name = "xhci-event",
.version_id = 1,
.fields = (VMStateField[]) {
VMSTATE_UINT32(type, XHCIEvent),
VMSTATE_UINT32(ccode, XHCIEvent),
VMSTATE_UINT64(ptr, XHCIEvent),
VMSTATE_UINT32(length, XHCIEvent),
VMSTATE_UINT32(flags, XHCIEvent),
VMSTATE_UINT8(slotid, XHCIEvent),
VMSTATE_UINT8(epid, XHCIEvent),
VMSTATE_END_OF_LIST()
}
};
static bool xhci_er_full(void *opaque, int version_id)
{
return false;
}
static const VMStateDescription vmstate_xhci_intr = {
.name = "xhci-intr",
.version_id = 1,
.fields = (VMStateField[]) {
/* registers */
VMSTATE_UINT32(iman, XHCIInterrupter),
VMSTATE_UINT32(imod, XHCIInterrupter),
VMSTATE_UINT32(erstsz, XHCIInterrupter),
VMSTATE_UINT32(erstba_low, XHCIInterrupter),
VMSTATE_UINT32(erstba_high, XHCIInterrupter),
VMSTATE_UINT32(erdp_low, XHCIInterrupter),
VMSTATE_UINT32(erdp_high, XHCIInterrupter),
/* state */
VMSTATE_BOOL(msix_used, XHCIInterrupter),
VMSTATE_BOOL(er_pcs, XHCIInterrupter),
VMSTATE_UINT64(er_start, XHCIInterrupter),
VMSTATE_UINT32(er_size, XHCIInterrupter),
VMSTATE_UINT32(er_ep_idx, XHCIInterrupter),
/* event queue (used if ring is full) */
VMSTATE_BOOL(er_full_unused, XHCIInterrupter),
VMSTATE_UINT32_TEST(ev_buffer_put, XHCIInterrupter, xhci_er_full),
VMSTATE_UINT32_TEST(ev_buffer_get, XHCIInterrupter, xhci_er_full),
VMSTATE_STRUCT_ARRAY_TEST(ev_buffer, XHCIInterrupter, EV_QUEUE,
xhci_er_full, 1,
vmstate_xhci_event, XHCIEvent),
VMSTATE_END_OF_LIST()
}
};
static const VMStateDescription vmstate_xhci = {
.name = "xhci",
.version_id = 1,
.post_load = usb_xhci_post_load,
.fields = (VMStateField[]) {
VMSTATE_PCI_DEVICE(parent_obj, XHCIState),
VMSTATE_MSIX(parent_obj, XHCIState),
VMSTATE_STRUCT_VARRAY_UINT32(ports, XHCIState, numports, 1,
vmstate_xhci_port, XHCIPort),
VMSTATE_STRUCT_VARRAY_UINT32(slots, XHCIState, numslots, 1,
vmstate_xhci_slot, XHCISlot),
VMSTATE_STRUCT_VARRAY_UINT32(intr, XHCIState, numintrs, 1,
vmstate_xhci_intr, XHCIInterrupter),
/* Operational Registers */
VMSTATE_UINT32(usbcmd, XHCIState),
VMSTATE_UINT32(usbsts, XHCIState),
VMSTATE_UINT32(dnctrl, XHCIState),
VMSTATE_UINT32(crcr_low, XHCIState),
VMSTATE_UINT32(crcr_high, XHCIState),
VMSTATE_UINT32(dcbaap_low, XHCIState),
VMSTATE_UINT32(dcbaap_high, XHCIState),
VMSTATE_UINT32(config, XHCIState),
/* Runtime Registers & state */
VMSTATE_INT64(mfindex_start, XHCIState),
VMSTATE_TIMER_PTR(mfwrap_timer, XHCIState),
VMSTATE_STRUCT(cmd_ring, XHCIState, 1, vmstate_xhci_ring, XHCIRing),
VMSTATE_END_OF_LIST()
}
};
static Property xhci_properties[] = {
DEFINE_PROP_BIT("streams", XHCIState, flags,
XHCI_FLAG_ENABLE_STREAMS, true),
DEFINE_PROP_UINT32("p2", XHCIState, numports_2, 4),
DEFINE_PROP_UINT32("p3", XHCIState, numports_3, 4),
DEFINE_PROP_END_OF_LIST(),
};
static void xhci_class_init(ObjectClass *klass, void *data)
{
PCIDeviceClass *k = PCI_DEVICE_CLASS(klass);
DeviceClass *dc = DEVICE_CLASS(klass);
dc->vmsd = &vmstate_xhci;
dc->props = xhci_properties;
dc->reset = xhci_reset;
set_bit(DEVICE_CATEGORY_USB, dc->categories);
k->realize = usb_xhci_realize;
k->exit = usb_xhci_exit;
k->class_id = PCI_CLASS_SERIAL_USB;
k->is_express = 1;
}
static const TypeInfo xhci_info = {
.name = TYPE_XHCI,
.parent = TYPE_PCI_DEVICE,
.instance_size = sizeof(XHCIState),
.class_init = xhci_class_init,
.abstract = true,
};
static void qemu_xhci_class_init(ObjectClass *klass, void *data)
{
PCIDeviceClass *k = PCI_DEVICE_CLASS(klass);
k->vendor_id = PCI_VENDOR_ID_REDHAT;
k->device_id = PCI_DEVICE_ID_REDHAT_XHCI;
k->revision = 0x01;
}
static void qemu_xhci_instance_init(Object *obj)
{
XHCIState *xhci = XHCI(obj);
xhci->msi = ON_OFF_AUTO_OFF;
xhci->msix = ON_OFF_AUTO_AUTO;
xhci->numintrs = MAXINTRS;
xhci->numslots = MAXSLOTS;
xhci_set_flag(xhci, XHCI_FLAG_SS_FIRST);
}
static const TypeInfo qemu_xhci_info = {
.name = TYPE_QEMU_XHCI,
.parent = TYPE_XHCI,
.class_init = qemu_xhci_class_init,
.instance_init = qemu_xhci_instance_init,
};
static void xhci_register_types(void)
{
type_register_static(&xhci_info);
type_register_static(&qemu_xhci_info);
}
type_init(xhci_register_types)