freebsd-nq/usr.sbin/bhyve/pci_xhci.c
John Baldwin 6a284cacb1 bhyve: Remove vmctx argument from PCI device model methods.
Most of these arguments were unused.  Device models which do need
access to the vmctx in one of these methods can obtain it from the
pi_vmctx member of the pci_devinst argument instead.

Reviewed by:	corvink, markj
Differential Revision:	https://reviews.freebsd.org/D38096
2023-01-19 10:30:18 -08:00

3211 lines
83 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2014 Leon Dang <ldang@nahannisys.com>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
/*
XHCI options:
-s <n>,xhci,{devices}
devices:
tablet USB tablet mouse
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/uio.h>
#include <sys/types.h>
#include <sys/queue.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include <errno.h>
#include <pthread.h>
#include <unistd.h>
#include <machine/vmm_snapshot.h>
#include <dev/usb/usbdi.h>
#include <dev/usb/usb.h>
#include <dev/usb/usb_freebsd.h>
#include <xhcireg.h>
#include "bhyverun.h"
#include "config.h"
#include "debug.h"
#include "pci_emul.h"
#include "pci_xhci.h"
#include "usb_emul.h"
static int xhci_debug = 0;
#define DPRINTF(params) if (xhci_debug) PRINTLN params
#define WPRINTF(params) PRINTLN params
#define XHCI_NAME "xhci"
#define XHCI_MAX_DEVS 8 /* 4 USB3 + 4 USB2 devs */
#define XHCI_MAX_SLOTS 64 /* min allowed by Windows drivers */
/*
* XHCI data structures can be up to 64k, but limit paddr_guest2host mapping
* to 4k to avoid going over the guest physical memory barrier.
*/
#define XHCI_PADDR_SZ 4096 /* paddr_guest2host max size */
#define XHCI_ERST_MAX 0 /* max 2^entries event ring seg tbl */
#define XHCI_CAPLEN (4*8) /* offset of op register space */
#define XHCI_HCCPRAMS2 0x1C /* offset of HCCPARAMS2 register */
#define XHCI_PORTREGS_START 0x400
#define XHCI_DOORBELL_MAX 256
#define XHCI_STREAMS_MAX 1 /* 4-15 in XHCI spec */
/* caplength and hci-version registers */
#define XHCI_SET_CAPLEN(x) ((x) & 0xFF)
#define XHCI_SET_HCIVERSION(x) (((x) & 0xFFFF) << 16)
#define XHCI_GET_HCIVERSION(x) (((x) >> 16) & 0xFFFF)
/* hcsparams1 register */
#define XHCI_SET_HCSP1_MAXSLOTS(x) ((x) & 0xFF)
#define XHCI_SET_HCSP1_MAXINTR(x) (((x) & 0x7FF) << 8)
#define XHCI_SET_HCSP1_MAXPORTS(x) (((x) & 0xFF) << 24)
/* hcsparams2 register */
#define XHCI_SET_HCSP2_IST(x) ((x) & 0x0F)
#define XHCI_SET_HCSP2_ERSTMAX(x) (((x) & 0x0F) << 4)
#define XHCI_SET_HCSP2_MAXSCRATCH_HI(x) (((x) & 0x1F) << 21)
#define XHCI_SET_HCSP2_MAXSCRATCH_LO(x) (((x) & 0x1F) << 27)
/* hcsparams3 register */
#define XHCI_SET_HCSP3_U1EXITLATENCY(x) ((x) & 0xFF)
#define XHCI_SET_HCSP3_U2EXITLATENCY(x) (((x) & 0xFFFF) << 16)
/* hccparams1 register */
#define XHCI_SET_HCCP1_AC64(x) ((x) & 0x01)
#define XHCI_SET_HCCP1_BNC(x) (((x) & 0x01) << 1)
#define XHCI_SET_HCCP1_CSZ(x) (((x) & 0x01) << 2)
#define XHCI_SET_HCCP1_PPC(x) (((x) & 0x01) << 3)
#define XHCI_SET_HCCP1_PIND(x) (((x) & 0x01) << 4)
#define XHCI_SET_HCCP1_LHRC(x) (((x) & 0x01) << 5)
#define XHCI_SET_HCCP1_LTC(x) (((x) & 0x01) << 6)
#define XHCI_SET_HCCP1_NSS(x) (((x) & 0x01) << 7)
#define XHCI_SET_HCCP1_PAE(x) (((x) & 0x01) << 8)
#define XHCI_SET_HCCP1_SPC(x) (((x) & 0x01) << 9)
#define XHCI_SET_HCCP1_SEC(x) (((x) & 0x01) << 10)
#define XHCI_SET_HCCP1_CFC(x) (((x) & 0x01) << 11)
#define XHCI_SET_HCCP1_MAXPSA(x) (((x) & 0x0F) << 12)
#define XHCI_SET_HCCP1_XECP(x) (((x) & 0xFFFF) << 16)
/* hccparams2 register */
#define XHCI_SET_HCCP2_U3C(x) ((x) & 0x01)
#define XHCI_SET_HCCP2_CMC(x) (((x) & 0x01) << 1)
#define XHCI_SET_HCCP2_FSC(x) (((x) & 0x01) << 2)
#define XHCI_SET_HCCP2_CTC(x) (((x) & 0x01) << 3)
#define XHCI_SET_HCCP2_LEC(x) (((x) & 0x01) << 4)
#define XHCI_SET_HCCP2_CIC(x) (((x) & 0x01) << 5)
/* other registers */
#define XHCI_SET_DOORBELL(x) ((x) & ~0x03)
#define XHCI_SET_RTSOFFSET(x) ((x) & ~0x0F)
/* register masks */
#define XHCI_PS_PLS_MASK (0xF << 5) /* port link state */
#define XHCI_PS_SPEED_MASK (0xF << 10) /* port speed */
#define XHCI_PS_PIC_MASK (0x3 << 14) /* port indicator */
/* port register set */
#define XHCI_PORTREGS_BASE 0x400 /* base offset */
#define XHCI_PORTREGS_PORT0 0x3F0
#define XHCI_PORTREGS_SETSZ 0x10 /* size of a set */
#define MASK_64_HI(x) ((x) & ~0xFFFFFFFFULL)
#define MASK_64_LO(x) ((x) & 0xFFFFFFFFULL)
#define FIELD_REPLACE(a,b,m,s) (((a) & ~((m) << (s))) | \
(((b) & (m)) << (s)))
#define FIELD_COPY(a,b,m,s) (((a) & ~((m) << (s))) | \
(((b) & ((m) << (s)))))
#define SNAP_DEV_NAME_LEN 128
struct pci_xhci_trb_ring {
uint64_t ringaddr; /* current dequeue guest address */
uint32_t ccs; /* consumer cycle state */
};
/* device endpoint transfer/stream rings */
struct pci_xhci_dev_ep {
union {
struct xhci_trb *_epu_tr;
struct xhci_stream_ctx *_epu_sctx;
} _ep_trbsctx;
#define ep_tr _ep_trbsctx._epu_tr
#define ep_sctx _ep_trbsctx._epu_sctx
/*
* Caches the value of MaxPStreams from the endpoint context
* when an endpoint is initialized and is used to validate the
* use of ep_ringaddr vs ep_sctx_trbs[] as well as the length
* of ep_sctx_trbs[].
*/
uint32_t ep_MaxPStreams;
union {
struct pci_xhci_trb_ring _epu_trb;
struct pci_xhci_trb_ring *_epu_sctx_trbs;
} _ep_trb_rings;
#define ep_ringaddr _ep_trb_rings._epu_trb.ringaddr
#define ep_ccs _ep_trb_rings._epu_trb.ccs
#define ep_sctx_trbs _ep_trb_rings._epu_sctx_trbs
struct usb_data_xfer *ep_xfer; /* transfer chain */
};
/* device context base address array: maps slot->device context */
struct xhci_dcbaa {
uint64_t dcba[USB_MAX_DEVICES+1]; /* xhci_dev_ctx ptrs */
};
/* port status registers */
struct pci_xhci_portregs {
uint32_t portsc; /* port status and control */
uint32_t portpmsc; /* port pwr mgmt status & control */
uint32_t portli; /* port link info */
uint32_t porthlpmc; /* port hardware LPM control */
} __packed;
#define XHCI_PS_SPEED_SET(x) (((x) & 0xF) << 10)
/* xHC operational registers */
struct pci_xhci_opregs {
uint32_t usbcmd; /* usb command */
uint32_t usbsts; /* usb status */
uint32_t pgsz; /* page size */
uint32_t dnctrl; /* device notification control */
uint64_t crcr; /* command ring control */
uint64_t dcbaap; /* device ctx base addr array ptr */
uint32_t config; /* configure */
/* guest mapped addresses: */
struct xhci_trb *cr_p; /* crcr dequeue */
struct xhci_dcbaa *dcbaa_p; /* dev ctx array ptr */
};
/* xHC runtime registers */
struct pci_xhci_rtsregs {
uint32_t mfindex; /* microframe index */
struct { /* interrupter register set */
uint32_t iman; /* interrupter management */
uint32_t imod; /* interrupter moderation */
uint32_t erstsz; /* event ring segment table size */
uint32_t rsvd;
uint64_t erstba; /* event ring seg-tbl base addr */
uint64_t erdp; /* event ring dequeue ptr */
} intrreg __packed;
/* guest mapped addresses */
struct xhci_event_ring_seg *erstba_p;
struct xhci_trb *erst_p; /* event ring segment tbl */
int er_deq_seg; /* event ring dequeue segment */
int er_enq_idx; /* event ring enqueue index - xHCI */
int er_enq_seg; /* event ring enqueue segment */
uint32_t er_events_cnt; /* number of events in ER */
uint32_t event_pcs; /* producer cycle state flag */
};
struct pci_xhci_softc;
/*
* USB device emulation container.
* This is referenced from usb_hci->hci_sc; 1 pci_xhci_dev_emu for each
* emulated device instance.
*/
struct pci_xhci_dev_emu {
struct pci_xhci_softc *xsc;
/* XHCI contexts */
struct xhci_dev_ctx *dev_ctx;
struct pci_xhci_dev_ep eps[XHCI_MAX_ENDPOINTS];
int dev_slotstate;
struct usb_devemu *dev_ue; /* USB emulated dev */
void *dev_sc; /* device's softc */
struct usb_hci hci;
};
struct pci_xhci_softc {
struct pci_devinst *xsc_pi;
pthread_mutex_t mtx;
uint32_t caplength; /* caplen & hciversion */
uint32_t hcsparams1; /* structural parameters 1 */
uint32_t hcsparams2; /* structural parameters 2 */
uint32_t hcsparams3; /* structural parameters 3 */
uint32_t hccparams1; /* capability parameters 1 */
uint32_t dboff; /* doorbell offset */
uint32_t rtsoff; /* runtime register space offset */
uint32_t hccparams2; /* capability parameters 2 */
uint32_t regsend; /* end of configuration registers */
struct pci_xhci_opregs opregs;
struct pci_xhci_rtsregs rtsregs;
struct pci_xhci_portregs *portregs;
struct pci_xhci_dev_emu **devices; /* XHCI[port] = device */
struct pci_xhci_dev_emu **slots; /* slots assigned from 1 */
int usb2_port_start;
int usb3_port_start;
};
/* port and slot numbering start from 1 */
#define XHCI_PORTREG_PTR(x,n) &((x)->portregs[(n) - 1])
#define XHCI_DEVINST_PTR(x,n) ((x)->devices[(n) - 1])
#define XHCI_SLOTDEV_PTR(x,n) ((x)->slots[(n) - 1])
#define XHCI_HALTED(sc) ((sc)->opregs.usbsts & XHCI_STS_HCH)
#define XHCI_GADDR_SIZE(a) (XHCI_PADDR_SZ - \
(((uint64_t) (a)) & (XHCI_PADDR_SZ - 1)))
#define XHCI_GADDR(sc,a) paddr_guest2host((sc)->xsc_pi->pi_vmctx, \
(a), XHCI_GADDR_SIZE(a))
static int xhci_in_use;
/* map USB errors to XHCI */
static const int xhci_usb_errors[USB_ERR_MAX] = {
[USB_ERR_NORMAL_COMPLETION] = XHCI_TRB_ERROR_SUCCESS,
[USB_ERR_PENDING_REQUESTS] = XHCI_TRB_ERROR_RESOURCE,
[USB_ERR_NOT_STARTED] = XHCI_TRB_ERROR_ENDP_NOT_ON,
[USB_ERR_INVAL] = XHCI_TRB_ERROR_INVALID,
[USB_ERR_NOMEM] = XHCI_TRB_ERROR_RESOURCE,
[USB_ERR_CANCELLED] = XHCI_TRB_ERROR_STOPPED,
[USB_ERR_BAD_ADDRESS] = XHCI_TRB_ERROR_PARAMETER,
[USB_ERR_BAD_BUFSIZE] = XHCI_TRB_ERROR_PARAMETER,
[USB_ERR_BAD_FLAG] = XHCI_TRB_ERROR_PARAMETER,
[USB_ERR_NO_CALLBACK] = XHCI_TRB_ERROR_STALL,
[USB_ERR_IN_USE] = XHCI_TRB_ERROR_RESOURCE,
[USB_ERR_NO_ADDR] = XHCI_TRB_ERROR_RESOURCE,
[USB_ERR_NO_PIPE] = XHCI_TRB_ERROR_RESOURCE,
[USB_ERR_ZERO_NFRAMES] = XHCI_TRB_ERROR_UNDEFINED,
[USB_ERR_ZERO_MAXP] = XHCI_TRB_ERROR_UNDEFINED,
[USB_ERR_SET_ADDR_FAILED] = XHCI_TRB_ERROR_RESOURCE,
[USB_ERR_NO_POWER] = XHCI_TRB_ERROR_ENDP_NOT_ON,
[USB_ERR_TOO_DEEP] = XHCI_TRB_ERROR_RESOURCE,
[USB_ERR_IOERROR] = XHCI_TRB_ERROR_TRB,
[USB_ERR_NOT_CONFIGURED] = XHCI_TRB_ERROR_ENDP_NOT_ON,
[USB_ERR_TIMEOUT] = XHCI_TRB_ERROR_CMD_ABORTED,
[USB_ERR_SHORT_XFER] = XHCI_TRB_ERROR_SHORT_PKT,
[USB_ERR_STALLED] = XHCI_TRB_ERROR_STALL,
[USB_ERR_INTERRUPTED] = XHCI_TRB_ERROR_CMD_ABORTED,
[USB_ERR_DMA_LOAD_FAILED] = XHCI_TRB_ERROR_DATA_BUF,
[USB_ERR_BAD_CONTEXT] = XHCI_TRB_ERROR_TRB,
[USB_ERR_NO_ROOT_HUB] = XHCI_TRB_ERROR_UNDEFINED,
[USB_ERR_NO_INTR_THREAD] = XHCI_TRB_ERROR_UNDEFINED,
[USB_ERR_NOT_LOCKED] = XHCI_TRB_ERROR_UNDEFINED,
};
#define USB_TO_XHCI_ERR(e) ((e) < USB_ERR_MAX ? xhci_usb_errors[(e)] : \
XHCI_TRB_ERROR_INVALID)
static int pci_xhci_insert_event(struct pci_xhci_softc *sc,
struct xhci_trb *evtrb, int do_intr);
static void pci_xhci_dump_trb(struct xhci_trb *trb);
static void pci_xhci_assert_interrupt(struct pci_xhci_softc *sc);
static void pci_xhci_reset_slot(struct pci_xhci_softc *sc, int slot);
static void pci_xhci_reset_port(struct pci_xhci_softc *sc, int portn, int warm);
static void pci_xhci_update_ep_ring(struct pci_xhci_softc *sc,
struct pci_xhci_dev_emu *dev, struct pci_xhci_dev_ep *devep,
struct xhci_endp_ctx *ep_ctx, uint32_t streamid,
uint64_t ringaddr, int ccs);
static void
pci_xhci_set_evtrb(struct xhci_trb *evtrb, uint64_t port, uint32_t errcode,
uint32_t evtype)
{
evtrb->qwTrb0 = port << 24;
evtrb->dwTrb2 = XHCI_TRB_2_ERROR_SET(errcode);
evtrb->dwTrb3 = XHCI_TRB_3_TYPE_SET(evtype);
}
/* controller reset */
static void
pci_xhci_reset(struct pci_xhci_softc *sc)
{
int i;
sc->rtsregs.er_enq_idx = 0;
sc->rtsregs.er_events_cnt = 0;
sc->rtsregs.event_pcs = 1;
for (i = 1; i <= XHCI_MAX_SLOTS; i++) {
pci_xhci_reset_slot(sc, i);
}
}
static uint32_t
pci_xhci_usbcmd_write(struct pci_xhci_softc *sc, uint32_t cmd)
{
int do_intr = 0;
int i;
if (cmd & XHCI_CMD_RS) {
do_intr = (sc->opregs.usbcmd & XHCI_CMD_RS) == 0;
sc->opregs.usbcmd |= XHCI_CMD_RS;
sc->opregs.usbsts &= ~XHCI_STS_HCH;
sc->opregs.usbsts |= XHCI_STS_PCD;
/* Queue port change event on controller run from stop */
if (do_intr)
for (i = 1; i <= XHCI_MAX_DEVS; i++) {
struct pci_xhci_dev_emu *dev;
struct pci_xhci_portregs *port;
struct xhci_trb evtrb;
if ((dev = XHCI_DEVINST_PTR(sc, i)) == NULL)
continue;
port = XHCI_PORTREG_PTR(sc, i);
port->portsc |= XHCI_PS_CSC | XHCI_PS_CCS;
port->portsc &= ~XHCI_PS_PLS_MASK;
/*
* XHCI 4.19.3 USB2 RxDetect->Polling,
* USB3 Polling->U0
*/
if (dev->dev_ue->ue_usbver == 2)
port->portsc |=
XHCI_PS_PLS_SET(UPS_PORT_LS_POLL);
else
port->portsc |=
XHCI_PS_PLS_SET(UPS_PORT_LS_U0);
pci_xhci_set_evtrb(&evtrb, i,
XHCI_TRB_ERROR_SUCCESS,
XHCI_TRB_EVENT_PORT_STS_CHANGE);
if (pci_xhci_insert_event(sc, &evtrb, 0) !=
XHCI_TRB_ERROR_SUCCESS)
break;
}
} else {
sc->opregs.usbcmd &= ~XHCI_CMD_RS;
sc->opregs.usbsts |= XHCI_STS_HCH;
sc->opregs.usbsts &= ~XHCI_STS_PCD;
}
/* start execution of schedule; stop when set to 0 */
cmd |= sc->opregs.usbcmd & XHCI_CMD_RS;
if (cmd & XHCI_CMD_HCRST) {
/* reset controller */
pci_xhci_reset(sc);
cmd &= ~XHCI_CMD_HCRST;
}
cmd &= ~(XHCI_CMD_CSS | XHCI_CMD_CRS);
if (do_intr)
pci_xhci_assert_interrupt(sc);
return (cmd);
}
static void
pci_xhci_portregs_write(struct pci_xhci_softc *sc, uint64_t offset,
uint64_t value)
{
struct xhci_trb evtrb;
struct pci_xhci_portregs *p;
int port;
uint32_t oldpls, newpls;
if (sc->portregs == NULL)
return;
port = (offset - XHCI_PORTREGS_PORT0) / XHCI_PORTREGS_SETSZ;
offset = (offset - XHCI_PORTREGS_PORT0) % XHCI_PORTREGS_SETSZ;
DPRINTF(("pci_xhci: portregs wr offset 0x%lx, port %u: 0x%lx",
offset, port, value));
assert(port >= 0);
if (port > XHCI_MAX_DEVS) {
DPRINTF(("pci_xhci: portregs_write port %d > ndevices",
port));
return;
}
if (XHCI_DEVINST_PTR(sc, port) == NULL) {
DPRINTF(("pci_xhci: portregs_write to unattached port %d",
port));
}
p = XHCI_PORTREG_PTR(sc, port);
switch (offset) {
case 0:
/* port reset or warm reset */
if (value & (XHCI_PS_PR | XHCI_PS_WPR)) {
pci_xhci_reset_port(sc, port, value & XHCI_PS_WPR);
break;
}
if ((p->portsc & XHCI_PS_PP) == 0) {
WPRINTF(("pci_xhci: portregs_write to unpowered "
"port %d", port));
break;
}
/* Port status and control register */
oldpls = XHCI_PS_PLS_GET(p->portsc);
newpls = XHCI_PS_PLS_GET(value);
p->portsc &= XHCI_PS_PED | XHCI_PS_PLS_MASK |
XHCI_PS_SPEED_MASK | XHCI_PS_PIC_MASK;
if (XHCI_DEVINST_PTR(sc, port))
p->portsc |= XHCI_PS_CCS;
p->portsc |= (value &
~(XHCI_PS_OCA |
XHCI_PS_PR |
XHCI_PS_PED |
XHCI_PS_PLS_MASK | /* link state */
XHCI_PS_SPEED_MASK |
XHCI_PS_PIC_MASK | /* port indicator */
XHCI_PS_LWS | XHCI_PS_DR | XHCI_PS_WPR));
/* clear control bits */
p->portsc &= ~(value &
(XHCI_PS_CSC |
XHCI_PS_PEC |
XHCI_PS_WRC |
XHCI_PS_OCC |
XHCI_PS_PRC |
XHCI_PS_PLC |
XHCI_PS_CEC |
XHCI_PS_CAS));
/* port disable request; for USB3, don't care */
if (value & XHCI_PS_PED)
DPRINTF(("Disable port %d request", port));
if (!(value & XHCI_PS_LWS))
break;
DPRINTF(("Port new PLS: %d", newpls));
switch (newpls) {
case 0: /* U0 */
case 3: /* U3 */
if (oldpls != newpls) {
p->portsc &= ~XHCI_PS_PLS_MASK;
p->portsc |= XHCI_PS_PLS_SET(newpls) |
XHCI_PS_PLC;
if (oldpls != 0 && newpls == 0) {
pci_xhci_set_evtrb(&evtrb, port,
XHCI_TRB_ERROR_SUCCESS,
XHCI_TRB_EVENT_PORT_STS_CHANGE);
pci_xhci_insert_event(sc, &evtrb, 1);
}
}
break;
default:
DPRINTF(("Unhandled change port %d PLS %u",
port, newpls));
break;
}
break;
case 4:
/* Port power management status and control register */
p->portpmsc = value;
break;
case 8:
/* Port link information register */
DPRINTF(("pci_xhci attempted write to PORTLI, port %d",
port));
break;
case 12:
/*
* Port hardware LPM control register.
* For USB3, this register is reserved.
*/
p->porthlpmc = value;
break;
default:
DPRINTF(("pci_xhci: unaligned portreg write offset %#lx",
offset));
break;
}
}
static struct xhci_dev_ctx *
pci_xhci_get_dev_ctx(struct pci_xhci_softc *sc, uint32_t slot)
{
uint64_t devctx_addr;
struct xhci_dev_ctx *devctx;
assert(slot > 0 && slot <= XHCI_MAX_DEVS);
assert(XHCI_SLOTDEV_PTR(sc, slot) != NULL);
assert(sc->opregs.dcbaa_p != NULL);
devctx_addr = sc->opregs.dcbaa_p->dcba[slot];
if (devctx_addr == 0) {
DPRINTF(("get_dev_ctx devctx_addr == 0"));
return (NULL);
}
DPRINTF(("pci_xhci: get dev ctx, slot %u devctx addr %016lx",
slot, devctx_addr));
devctx = XHCI_GADDR(sc, devctx_addr & ~0x3FUL);
return (devctx);
}
static struct xhci_trb *
pci_xhci_trb_next(struct pci_xhci_softc *sc, struct xhci_trb *curtrb,
uint64_t *guestaddr)
{
struct xhci_trb *next;
assert(curtrb != NULL);
if (XHCI_TRB_3_TYPE_GET(curtrb->dwTrb3) == XHCI_TRB_TYPE_LINK) {
if (guestaddr)
*guestaddr = curtrb->qwTrb0 & ~0xFUL;
next = XHCI_GADDR(sc, curtrb->qwTrb0 & ~0xFUL);
} else {
if (guestaddr)
*guestaddr += sizeof(struct xhci_trb) & ~0xFUL;
next = curtrb + 1;
}
return (next);
}
static void
pci_xhci_assert_interrupt(struct pci_xhci_softc *sc)
{
sc->rtsregs.intrreg.erdp |= XHCI_ERDP_LO_BUSY;
sc->rtsregs.intrreg.iman |= XHCI_IMAN_INTR_PEND;
sc->opregs.usbsts |= XHCI_STS_EINT;
/* only trigger interrupt if permitted */
if ((sc->opregs.usbcmd & XHCI_CMD_INTE) &&
(sc->rtsregs.intrreg.iman & XHCI_IMAN_INTR_ENA)) {
if (pci_msi_enabled(sc->xsc_pi))
pci_generate_msi(sc->xsc_pi, 0);
else
pci_lintr_assert(sc->xsc_pi);
}
}
static void
pci_xhci_deassert_interrupt(struct pci_xhci_softc *sc)
{
if (!pci_msi_enabled(sc->xsc_pi))
pci_lintr_assert(sc->xsc_pi);
}
static void
pci_xhci_init_ep(struct pci_xhci_dev_emu *dev, int epid)
{
struct xhci_dev_ctx *dev_ctx;
struct pci_xhci_dev_ep *devep;
struct xhci_endp_ctx *ep_ctx;
uint32_t i, pstreams;
dev_ctx = dev->dev_ctx;
ep_ctx = &dev_ctx->ctx_ep[epid];
devep = &dev->eps[epid];
pstreams = XHCI_EPCTX_0_MAXP_STREAMS_GET(ep_ctx->dwEpCtx0);
if (pstreams > 0) {
DPRINTF(("init_ep %d with pstreams %d", epid, pstreams));
assert(devep->ep_sctx_trbs == NULL);
devep->ep_sctx = XHCI_GADDR(dev->xsc, ep_ctx->qwEpCtx2 &
XHCI_EPCTX_2_TR_DQ_PTR_MASK);
devep->ep_sctx_trbs = calloc(pstreams,
sizeof(struct pci_xhci_trb_ring));
for (i = 0; i < pstreams; i++) {
devep->ep_sctx_trbs[i].ringaddr =
devep->ep_sctx[i].qwSctx0 &
XHCI_SCTX_0_TR_DQ_PTR_MASK;
devep->ep_sctx_trbs[i].ccs =
XHCI_SCTX_0_DCS_GET(devep->ep_sctx[i].qwSctx0);
}
} else {
DPRINTF(("init_ep %d with no pstreams", epid));
devep->ep_ringaddr = ep_ctx->qwEpCtx2 &
XHCI_EPCTX_2_TR_DQ_PTR_MASK;
devep->ep_ccs = XHCI_EPCTX_2_DCS_GET(ep_ctx->qwEpCtx2);
devep->ep_tr = XHCI_GADDR(dev->xsc, devep->ep_ringaddr);
DPRINTF(("init_ep tr DCS %x", devep->ep_ccs));
}
devep->ep_MaxPStreams = pstreams;
if (devep->ep_xfer == NULL) {
devep->ep_xfer = malloc(sizeof(struct usb_data_xfer));
USB_DATA_XFER_INIT(devep->ep_xfer);
}
}
static void
pci_xhci_disable_ep(struct pci_xhci_dev_emu *dev, int epid)
{
struct xhci_dev_ctx *dev_ctx;
struct pci_xhci_dev_ep *devep;
struct xhci_endp_ctx *ep_ctx;
DPRINTF(("pci_xhci disable_ep %d", epid));
dev_ctx = dev->dev_ctx;
ep_ctx = &dev_ctx->ctx_ep[epid];
ep_ctx->dwEpCtx0 = (ep_ctx->dwEpCtx0 & ~0x7) | XHCI_ST_EPCTX_DISABLED;
devep = &dev->eps[epid];
if (devep->ep_MaxPStreams > 0)
free(devep->ep_sctx_trbs);
if (devep->ep_xfer != NULL) {
free(devep->ep_xfer);
devep->ep_xfer = NULL;
}
memset(devep, 0, sizeof(struct pci_xhci_dev_ep));
}
/* reset device at slot and data structures related to it */
static void
pci_xhci_reset_slot(struct pci_xhci_softc *sc, int slot)
{
struct pci_xhci_dev_emu *dev;
dev = XHCI_SLOTDEV_PTR(sc, slot);
if (!dev) {
DPRINTF(("xhci reset unassigned slot (%d)?", slot));
} else {
dev->dev_slotstate = XHCI_ST_DISABLED;
}
/* TODO: reset ring buffer pointers */
}
static int
pci_xhci_insert_event(struct pci_xhci_softc *sc, struct xhci_trb *evtrb,
int do_intr)
{
struct pci_xhci_rtsregs *rts;
uint64_t erdp;
int erdp_idx;
int err;
struct xhci_trb *evtrbptr;
err = XHCI_TRB_ERROR_SUCCESS;
rts = &sc->rtsregs;
erdp = rts->intrreg.erdp & ~0xF;
erdp_idx = (erdp - rts->erstba_p[rts->er_deq_seg].qwEvrsTablePtr) /
sizeof(struct xhci_trb);
DPRINTF(("pci_xhci: insert event 0[%lx] 2[%x] 3[%x]",
evtrb->qwTrb0, evtrb->dwTrb2, evtrb->dwTrb3));
DPRINTF(("\terdp idx %d/seg %d, enq idx %d/seg %d, pcs %u",
erdp_idx, rts->er_deq_seg, rts->er_enq_idx,
rts->er_enq_seg, rts->event_pcs));
DPRINTF(("\t(erdp=0x%lx, erst=0x%lx, tblsz=%u, do_intr %d)",
erdp, rts->erstba_p->qwEvrsTablePtr,
rts->erstba_p->dwEvrsTableSize, do_intr));
evtrbptr = &rts->erst_p[rts->er_enq_idx];
/* TODO: multi-segment table */
if (rts->er_events_cnt >= rts->erstba_p->dwEvrsTableSize) {
DPRINTF(("pci_xhci[%d] cannot insert event; ring full",
__LINE__));
err = XHCI_TRB_ERROR_EV_RING_FULL;
goto done;
}
if (rts->er_events_cnt == rts->erstba_p->dwEvrsTableSize - 1) {
struct xhci_trb errev;
if ((evtrbptr->dwTrb3 & 0x1) == (rts->event_pcs & 0x1)) {
DPRINTF(("pci_xhci[%d] insert evt err: ring full",
__LINE__));
errev.qwTrb0 = 0;
errev.dwTrb2 = XHCI_TRB_2_ERROR_SET(
XHCI_TRB_ERROR_EV_RING_FULL);
errev.dwTrb3 = XHCI_TRB_3_TYPE_SET(
XHCI_TRB_EVENT_HOST_CTRL) |
rts->event_pcs;
rts->er_events_cnt++;
memcpy(&rts->erst_p[rts->er_enq_idx], &errev,
sizeof(struct xhci_trb));
rts->er_enq_idx = (rts->er_enq_idx + 1) %
rts->erstba_p->dwEvrsTableSize;
err = XHCI_TRB_ERROR_EV_RING_FULL;
do_intr = 1;
goto done;
}
} else {
rts->er_events_cnt++;
}
evtrb->dwTrb3 &= ~XHCI_TRB_3_CYCLE_BIT;
evtrb->dwTrb3 |= rts->event_pcs;
memcpy(&rts->erst_p[rts->er_enq_idx], evtrb, sizeof(struct xhci_trb));
rts->er_enq_idx = (rts->er_enq_idx + 1) %
rts->erstba_p->dwEvrsTableSize;
if (rts->er_enq_idx == 0)
rts->event_pcs ^= 1;
done:
if (do_intr)
pci_xhci_assert_interrupt(sc);
return (err);
}
static uint32_t
pci_xhci_cmd_enable_slot(struct pci_xhci_softc *sc, uint32_t *slot)
{
struct pci_xhci_dev_emu *dev;
uint32_t cmderr;
int i;
cmderr = XHCI_TRB_ERROR_NO_SLOTS;
if (sc->portregs != NULL)
for (i = 1; i <= XHCI_MAX_SLOTS; i++) {
dev = XHCI_SLOTDEV_PTR(sc, i);
if (dev && dev->dev_slotstate == XHCI_ST_DISABLED) {
*slot = i;
dev->dev_slotstate = XHCI_ST_ENABLED;
cmderr = XHCI_TRB_ERROR_SUCCESS;
dev->hci.hci_address = i;
break;
}
}
DPRINTF(("pci_xhci enable slot (error=%d) slot %u",
cmderr != XHCI_TRB_ERROR_SUCCESS, *slot));
return (cmderr);
}
static uint32_t
pci_xhci_cmd_disable_slot(struct pci_xhci_softc *sc, uint32_t slot)
{
struct pci_xhci_dev_emu *dev;
uint32_t cmderr;
DPRINTF(("pci_xhci disable slot %u", slot));
cmderr = XHCI_TRB_ERROR_NO_SLOTS;
if (sc->portregs == NULL)
goto done;
if (slot > XHCI_MAX_SLOTS) {
cmderr = XHCI_TRB_ERROR_SLOT_NOT_ON;
goto done;
}
dev = XHCI_SLOTDEV_PTR(sc, slot);
if (dev) {
if (dev->dev_slotstate == XHCI_ST_DISABLED) {
cmderr = XHCI_TRB_ERROR_SLOT_NOT_ON;
} else {
dev->dev_slotstate = XHCI_ST_DISABLED;
cmderr = XHCI_TRB_ERROR_SUCCESS;
/* TODO: reset events and endpoints */
}
} else
cmderr = XHCI_TRB_ERROR_SLOT_NOT_ON;
done:
return (cmderr);
}
static uint32_t
pci_xhci_cmd_reset_device(struct pci_xhci_softc *sc, uint32_t slot)
{
struct pci_xhci_dev_emu *dev;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep_ctx;
uint32_t cmderr;
int i;
cmderr = XHCI_TRB_ERROR_NO_SLOTS;
if (sc->portregs == NULL)
goto done;
DPRINTF(("pci_xhci reset device slot %u", slot));
dev = XHCI_SLOTDEV_PTR(sc, slot);
if (!dev || dev->dev_slotstate == XHCI_ST_DISABLED)
cmderr = XHCI_TRB_ERROR_SLOT_NOT_ON;
else {
dev->dev_slotstate = XHCI_ST_DEFAULT;
dev->hci.hci_address = 0;
dev_ctx = pci_xhci_get_dev_ctx(sc, slot);
/* slot state */
dev_ctx->ctx_slot.dwSctx3 = FIELD_REPLACE(
dev_ctx->ctx_slot.dwSctx3, XHCI_ST_SLCTX_DEFAULT,
0x1F, 27);
/* number of contexts */
dev_ctx->ctx_slot.dwSctx0 = FIELD_REPLACE(
dev_ctx->ctx_slot.dwSctx0, 1, 0x1F, 27);
/* reset all eps other than ep-0 */
for (i = 2; i <= 31; i++) {
ep_ctx = &dev_ctx->ctx_ep[i];
ep_ctx->dwEpCtx0 = FIELD_REPLACE( ep_ctx->dwEpCtx0,
XHCI_ST_EPCTX_DISABLED, 0x7, 0);
}
cmderr = XHCI_TRB_ERROR_SUCCESS;
}
pci_xhci_reset_slot(sc, slot);
done:
return (cmderr);
}
static uint32_t
pci_xhci_cmd_address_device(struct pci_xhci_softc *sc, uint32_t slot,
struct xhci_trb *trb)
{
struct pci_xhci_dev_emu *dev;
struct xhci_input_dev_ctx *input_ctx;
struct xhci_slot_ctx *islot_ctx;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep0_ctx;
uint32_t cmderr;
input_ctx = XHCI_GADDR(sc, trb->qwTrb0 & ~0xFUL);
islot_ctx = &input_ctx->ctx_slot;
ep0_ctx = &input_ctx->ctx_ep[1];
cmderr = XHCI_TRB_ERROR_SUCCESS;
DPRINTF(("pci_xhci: address device, input ctl: D 0x%08x A 0x%08x,",
input_ctx->ctx_input.dwInCtx0, input_ctx->ctx_input.dwInCtx1));
DPRINTF((" slot %08x %08x %08x %08x",
islot_ctx->dwSctx0, islot_ctx->dwSctx1,
islot_ctx->dwSctx2, islot_ctx->dwSctx3));
DPRINTF((" ep0 %08x %08x %016lx %08x",
ep0_ctx->dwEpCtx0, ep0_ctx->dwEpCtx1, ep0_ctx->qwEpCtx2,
ep0_ctx->dwEpCtx4));
/* when setting address: drop-ctx=0, add-ctx=slot+ep0 */
if ((input_ctx->ctx_input.dwInCtx0 != 0) ||
(input_ctx->ctx_input.dwInCtx1 & 0x03) != 0x03) {
DPRINTF(("pci_xhci: address device, input ctl invalid"));
cmderr = XHCI_TRB_ERROR_TRB;
goto done;
}
/* assign address to slot */
dev_ctx = pci_xhci_get_dev_ctx(sc, slot);
DPRINTF(("pci_xhci: address device, dev ctx"));
DPRINTF((" slot %08x %08x %08x %08x",
dev_ctx->ctx_slot.dwSctx0, dev_ctx->ctx_slot.dwSctx1,
dev_ctx->ctx_slot.dwSctx2, dev_ctx->ctx_slot.dwSctx3));
dev = XHCI_SLOTDEV_PTR(sc, slot);
assert(dev != NULL);
dev->hci.hci_address = slot;
dev->dev_ctx = dev_ctx;
if (dev->dev_ue->ue_reset == NULL ||
dev->dev_ue->ue_reset(dev->dev_sc) < 0) {
cmderr = XHCI_TRB_ERROR_ENDP_NOT_ON;
goto done;
}
memcpy(&dev_ctx->ctx_slot, islot_ctx, sizeof(struct xhci_slot_ctx));
dev_ctx->ctx_slot.dwSctx3 =
XHCI_SCTX_3_SLOT_STATE_SET(XHCI_ST_SLCTX_ADDRESSED) |
XHCI_SCTX_3_DEV_ADDR_SET(slot);
memcpy(&dev_ctx->ctx_ep[1], ep0_ctx, sizeof(struct xhci_endp_ctx));
ep0_ctx = &dev_ctx->ctx_ep[1];
ep0_ctx->dwEpCtx0 = (ep0_ctx->dwEpCtx0 & ~0x7) |
XHCI_EPCTX_0_EPSTATE_SET(XHCI_ST_EPCTX_RUNNING);
pci_xhci_init_ep(dev, 1);
dev->dev_slotstate = XHCI_ST_ADDRESSED;
DPRINTF(("pci_xhci: address device, output ctx"));
DPRINTF((" slot %08x %08x %08x %08x",
dev_ctx->ctx_slot.dwSctx0, dev_ctx->ctx_slot.dwSctx1,
dev_ctx->ctx_slot.dwSctx2, dev_ctx->ctx_slot.dwSctx3));
DPRINTF((" ep0 %08x %08x %016lx %08x",
ep0_ctx->dwEpCtx0, ep0_ctx->dwEpCtx1, ep0_ctx->qwEpCtx2,
ep0_ctx->dwEpCtx4));
done:
return (cmderr);
}
static uint32_t
pci_xhci_cmd_config_ep(struct pci_xhci_softc *sc, uint32_t slot,
struct xhci_trb *trb)
{
struct xhci_input_dev_ctx *input_ctx;
struct pci_xhci_dev_emu *dev;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep_ctx, *iep_ctx;
uint32_t cmderr;
int i;
cmderr = XHCI_TRB_ERROR_SUCCESS;
DPRINTF(("pci_xhci config_ep slot %u", slot));
dev = XHCI_SLOTDEV_PTR(sc, slot);
assert(dev != NULL);
if ((trb->dwTrb3 & XHCI_TRB_3_DCEP_BIT) != 0) {
DPRINTF(("pci_xhci config_ep - deconfigure ep slot %u",
slot));
if (dev->dev_ue->ue_stop != NULL)
dev->dev_ue->ue_stop(dev->dev_sc);
dev->dev_slotstate = XHCI_ST_ADDRESSED;
dev->hci.hci_address = 0;
dev_ctx = pci_xhci_get_dev_ctx(sc, slot);
/* number of contexts */
dev_ctx->ctx_slot.dwSctx0 = FIELD_REPLACE(
dev_ctx->ctx_slot.dwSctx0, 1, 0x1F, 27);
/* slot state */
dev_ctx->ctx_slot.dwSctx3 = FIELD_REPLACE(
dev_ctx->ctx_slot.dwSctx3, XHCI_ST_SLCTX_ADDRESSED,
0x1F, 27);
/* disable endpoints */
for (i = 2; i < 32; i++)
pci_xhci_disable_ep(dev, i);
cmderr = XHCI_TRB_ERROR_SUCCESS;
goto done;
}
if (dev->dev_slotstate < XHCI_ST_ADDRESSED) {
DPRINTF(("pci_xhci: config_ep slotstate x%x != addressed",
dev->dev_slotstate));
cmderr = XHCI_TRB_ERROR_SLOT_NOT_ON;
goto done;
}
/* In addressed/configured state;
* for each drop endpoint ctx flag:
* ep->state = DISABLED
* for each add endpoint ctx flag:
* cp(ep-in, ep-out)
* ep->state = RUNNING
* for each drop+add endpoint flag:
* reset ep resources
* cp(ep-in, ep-out)
* ep->state = RUNNING
* if input->DisabledCtx[2-31] < 30: (at least 1 ep not disabled)
* slot->state = configured
*/
input_ctx = XHCI_GADDR(sc, trb->qwTrb0 & ~0xFUL);
dev_ctx = dev->dev_ctx;
DPRINTF(("pci_xhci: config_ep inputctx: D:x%08x A:x%08x 7:x%08x",
input_ctx->ctx_input.dwInCtx0, input_ctx->ctx_input.dwInCtx1,
input_ctx->ctx_input.dwInCtx7));
for (i = 2; i <= 31; i++) {
ep_ctx = &dev_ctx->ctx_ep[i];
if (input_ctx->ctx_input.dwInCtx0 &
XHCI_INCTX_0_DROP_MASK(i)) {
DPRINTF((" config ep - dropping ep %d", i));
pci_xhci_disable_ep(dev, i);
}
if (input_ctx->ctx_input.dwInCtx1 &
XHCI_INCTX_1_ADD_MASK(i)) {
iep_ctx = &input_ctx->ctx_ep[i];
DPRINTF((" enable ep[%d] %08x %08x %016lx %08x",
i, iep_ctx->dwEpCtx0, iep_ctx->dwEpCtx1,
iep_ctx->qwEpCtx2, iep_ctx->dwEpCtx4));
memcpy(ep_ctx, iep_ctx, sizeof(struct xhci_endp_ctx));
pci_xhci_init_ep(dev, i);
/* ep state */
ep_ctx->dwEpCtx0 = FIELD_REPLACE(
ep_ctx->dwEpCtx0, XHCI_ST_EPCTX_RUNNING, 0x7, 0);
}
}
/* slot state to configured */
dev_ctx->ctx_slot.dwSctx3 = FIELD_REPLACE(
dev_ctx->ctx_slot.dwSctx3, XHCI_ST_SLCTX_CONFIGURED, 0x1F, 27);
dev_ctx->ctx_slot.dwSctx0 = FIELD_COPY(
dev_ctx->ctx_slot.dwSctx0, input_ctx->ctx_slot.dwSctx0, 0x1F, 27);
dev->dev_slotstate = XHCI_ST_CONFIGURED;
DPRINTF(("EP configured; slot %u [0]=0x%08x [1]=0x%08x [2]=0x%08x "
"[3]=0x%08x",
slot, dev_ctx->ctx_slot.dwSctx0, dev_ctx->ctx_slot.dwSctx1,
dev_ctx->ctx_slot.dwSctx2, dev_ctx->ctx_slot.dwSctx3));
done:
return (cmderr);
}
static uint32_t
pci_xhci_cmd_reset_ep(struct pci_xhci_softc *sc, uint32_t slot,
struct xhci_trb *trb)
{
struct pci_xhci_dev_emu *dev;
struct pci_xhci_dev_ep *devep;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep_ctx;
uint32_t cmderr, epid;
uint32_t type;
epid = XHCI_TRB_3_EP_GET(trb->dwTrb3);
DPRINTF(("pci_xhci: reset ep %u: slot %u", epid, slot));
cmderr = XHCI_TRB_ERROR_SUCCESS;
type = XHCI_TRB_3_TYPE_GET(trb->dwTrb3);
dev = XHCI_SLOTDEV_PTR(sc, slot);
assert(dev != NULL);
if (type == XHCI_TRB_TYPE_STOP_EP &&
(trb->dwTrb3 & XHCI_TRB_3_SUSP_EP_BIT) != 0) {
/* XXX suspend endpoint for 10ms */
}
if (epid < 1 || epid > 31) {
DPRINTF(("pci_xhci: reset ep: invalid epid %u", epid));
cmderr = XHCI_TRB_ERROR_TRB;
goto done;
}
devep = &dev->eps[epid];
if (devep->ep_xfer != NULL)
USB_DATA_XFER_RESET(devep->ep_xfer);
dev_ctx = dev->dev_ctx;
assert(dev_ctx != NULL);
ep_ctx = &dev_ctx->ctx_ep[epid];
ep_ctx->dwEpCtx0 = (ep_ctx->dwEpCtx0 & ~0x7) | XHCI_ST_EPCTX_STOPPED;
if (devep->ep_MaxPStreams == 0)
ep_ctx->qwEpCtx2 = devep->ep_ringaddr | devep->ep_ccs;
DPRINTF(("pci_xhci: reset ep[%u] %08x %08x %016lx %08x",
epid, ep_ctx->dwEpCtx0, ep_ctx->dwEpCtx1, ep_ctx->qwEpCtx2,
ep_ctx->dwEpCtx4));
if (type == XHCI_TRB_TYPE_RESET_EP &&
(dev->dev_ue->ue_reset == NULL ||
dev->dev_ue->ue_reset(dev->dev_sc) < 0)) {
cmderr = XHCI_TRB_ERROR_ENDP_NOT_ON;
goto done;
}
done:
return (cmderr);
}
static uint32_t
pci_xhci_find_stream(struct pci_xhci_softc *sc, struct xhci_endp_ctx *ep,
struct pci_xhci_dev_ep *devep, uint32_t streamid)
{
struct xhci_stream_ctx *sctx;
if (devep->ep_MaxPStreams == 0)
return (XHCI_TRB_ERROR_TRB);
if (devep->ep_MaxPStreams > XHCI_STREAMS_MAX)
return (XHCI_TRB_ERROR_INVALID_SID);
if (XHCI_EPCTX_0_LSA_GET(ep->dwEpCtx0) == 0) {
DPRINTF(("pci_xhci: find_stream; LSA bit not set"));
return (XHCI_TRB_ERROR_INVALID_SID);
}
/* only support primary stream */
if (streamid > devep->ep_MaxPStreams)
return (XHCI_TRB_ERROR_STREAM_TYPE);
sctx = (struct xhci_stream_ctx *)XHCI_GADDR(sc, ep->qwEpCtx2 & ~0xFUL) +
streamid;
if (!XHCI_SCTX_0_SCT_GET(sctx->qwSctx0))
return (XHCI_TRB_ERROR_STREAM_TYPE);
return (XHCI_TRB_ERROR_SUCCESS);
}
static uint32_t
pci_xhci_cmd_set_tr(struct pci_xhci_softc *sc, uint32_t slot,
struct xhci_trb *trb)
{
struct pci_xhci_dev_emu *dev;
struct pci_xhci_dev_ep *devep;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep_ctx;
uint32_t cmderr, epid;
uint32_t streamid;
cmderr = XHCI_TRB_ERROR_SUCCESS;
dev = XHCI_SLOTDEV_PTR(sc, slot);
assert(dev != NULL);
DPRINTF(("pci_xhci set_tr: new-tr x%016lx, SCT %u DCS %u",
(trb->qwTrb0 & ~0xF), (uint32_t)((trb->qwTrb0 >> 1) & 0x7),
(uint32_t)(trb->qwTrb0 & 0x1)));
DPRINTF((" stream-id %u, slot %u, epid %u, C %u",
(trb->dwTrb2 >> 16) & 0xFFFF,
XHCI_TRB_3_SLOT_GET(trb->dwTrb3),
XHCI_TRB_3_EP_GET(trb->dwTrb3), trb->dwTrb3 & 0x1));
epid = XHCI_TRB_3_EP_GET(trb->dwTrb3);
if (epid < 1 || epid > 31) {
DPRINTF(("pci_xhci: set_tr_deq: invalid epid %u", epid));
cmderr = XHCI_TRB_ERROR_TRB;
goto done;
}
dev_ctx = dev->dev_ctx;
assert(dev_ctx != NULL);
ep_ctx = &dev_ctx->ctx_ep[epid];
devep = &dev->eps[epid];
switch (XHCI_EPCTX_0_EPSTATE_GET(ep_ctx->dwEpCtx0)) {
case XHCI_ST_EPCTX_STOPPED:
case XHCI_ST_EPCTX_ERROR:
break;
default:
DPRINTF(("pci_xhci cmd set_tr invalid state %x",
XHCI_EPCTX_0_EPSTATE_GET(ep_ctx->dwEpCtx0)));
cmderr = XHCI_TRB_ERROR_CONTEXT_STATE;
goto done;
}
streamid = XHCI_TRB_2_STREAM_GET(trb->dwTrb2);
if (devep->ep_MaxPStreams > 0) {
cmderr = pci_xhci_find_stream(sc, ep_ctx, devep, streamid);
if (cmderr == XHCI_TRB_ERROR_SUCCESS) {
assert(devep->ep_sctx != NULL);
devep->ep_sctx[streamid].qwSctx0 = trb->qwTrb0;
devep->ep_sctx_trbs[streamid].ringaddr =
trb->qwTrb0 & ~0xF;
devep->ep_sctx_trbs[streamid].ccs =
XHCI_EPCTX_2_DCS_GET(trb->qwTrb0);
}
} else {
if (streamid != 0) {
DPRINTF(("pci_xhci cmd set_tr streamid %x != 0",
streamid));
}
ep_ctx->qwEpCtx2 = trb->qwTrb0 & ~0xFUL;
devep->ep_ringaddr = ep_ctx->qwEpCtx2 & ~0xFUL;
devep->ep_ccs = trb->qwTrb0 & 0x1;
devep->ep_tr = XHCI_GADDR(sc, devep->ep_ringaddr);
DPRINTF(("pci_xhci set_tr first TRB:"));
pci_xhci_dump_trb(devep->ep_tr);
}
ep_ctx->dwEpCtx0 = (ep_ctx->dwEpCtx0 & ~0x7) | XHCI_ST_EPCTX_STOPPED;
done:
return (cmderr);
}
static uint32_t
pci_xhci_cmd_eval_ctx(struct pci_xhci_softc *sc, uint32_t slot,
struct xhci_trb *trb)
{
struct xhci_input_dev_ctx *input_ctx;
struct xhci_slot_ctx *islot_ctx;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep0_ctx;
uint32_t cmderr;
input_ctx = XHCI_GADDR(sc, trb->qwTrb0 & ~0xFUL);
islot_ctx = &input_ctx->ctx_slot;
ep0_ctx = &input_ctx->ctx_ep[1];
cmderr = XHCI_TRB_ERROR_SUCCESS;
DPRINTF(("pci_xhci: eval ctx, input ctl: D 0x%08x A 0x%08x,",
input_ctx->ctx_input.dwInCtx0, input_ctx->ctx_input.dwInCtx1));
DPRINTF((" slot %08x %08x %08x %08x",
islot_ctx->dwSctx0, islot_ctx->dwSctx1,
islot_ctx->dwSctx2, islot_ctx->dwSctx3));
DPRINTF((" ep0 %08x %08x %016lx %08x",
ep0_ctx->dwEpCtx0, ep0_ctx->dwEpCtx1, ep0_ctx->qwEpCtx2,
ep0_ctx->dwEpCtx4));
/* this command expects drop-ctx=0 & add-ctx=slot+ep0 */
if ((input_ctx->ctx_input.dwInCtx0 != 0) ||
(input_ctx->ctx_input.dwInCtx1 & 0x03) == 0) {
DPRINTF(("pci_xhci: eval ctx, input ctl invalid"));
cmderr = XHCI_TRB_ERROR_TRB;
goto done;
}
/* assign address to slot; in this emulation, slot_id = address */
dev_ctx = pci_xhci_get_dev_ctx(sc, slot);
DPRINTF(("pci_xhci: eval ctx, dev ctx"));
DPRINTF((" slot %08x %08x %08x %08x",
dev_ctx->ctx_slot.dwSctx0, dev_ctx->ctx_slot.dwSctx1,
dev_ctx->ctx_slot.dwSctx2, dev_ctx->ctx_slot.dwSctx3));
if (input_ctx->ctx_input.dwInCtx1 & 0x01) { /* slot ctx */
/* set max exit latency */
dev_ctx->ctx_slot.dwSctx1 = FIELD_COPY(
dev_ctx->ctx_slot.dwSctx1, input_ctx->ctx_slot.dwSctx1,
0xFFFF, 0);
/* set interrupter target */
dev_ctx->ctx_slot.dwSctx2 = FIELD_COPY(
dev_ctx->ctx_slot.dwSctx2, input_ctx->ctx_slot.dwSctx2,
0x3FF, 22);
}
if (input_ctx->ctx_input.dwInCtx1 & 0x02) { /* control ctx */
/* set max packet size */
dev_ctx->ctx_ep[1].dwEpCtx1 = FIELD_COPY(
dev_ctx->ctx_ep[1].dwEpCtx1, ep0_ctx->dwEpCtx1,
0xFFFF, 16);
ep0_ctx = &dev_ctx->ctx_ep[1];
}
DPRINTF(("pci_xhci: eval ctx, output ctx"));
DPRINTF((" slot %08x %08x %08x %08x",
dev_ctx->ctx_slot.dwSctx0, dev_ctx->ctx_slot.dwSctx1,
dev_ctx->ctx_slot.dwSctx2, dev_ctx->ctx_slot.dwSctx3));
DPRINTF((" ep0 %08x %08x %016lx %08x",
ep0_ctx->dwEpCtx0, ep0_ctx->dwEpCtx1, ep0_ctx->qwEpCtx2,
ep0_ctx->dwEpCtx4));
done:
return (cmderr);
}
static int
pci_xhci_complete_commands(struct pci_xhci_softc *sc)
{
struct xhci_trb evtrb;
struct xhci_trb *trb;
uint64_t crcr;
uint32_t ccs; /* cycle state (XHCI 4.9.2) */
uint32_t type;
uint32_t slot;
uint32_t cmderr;
int error;
error = 0;
sc->opregs.crcr |= XHCI_CRCR_LO_CRR;
trb = sc->opregs.cr_p;
ccs = sc->opregs.crcr & XHCI_CRCR_LO_RCS;
crcr = sc->opregs.crcr & ~0xF;
while (1) {
sc->opregs.cr_p = trb;
type = XHCI_TRB_3_TYPE_GET(trb->dwTrb3);
if ((trb->dwTrb3 & XHCI_TRB_3_CYCLE_BIT) !=
(ccs & XHCI_TRB_3_CYCLE_BIT))
break;
DPRINTF(("pci_xhci: cmd type 0x%x, Trb0 x%016lx dwTrb2 x%08x"
" dwTrb3 x%08x, TRB_CYCLE %u/ccs %u",
type, trb->qwTrb0, trb->dwTrb2, trb->dwTrb3,
trb->dwTrb3 & XHCI_TRB_3_CYCLE_BIT, ccs));
cmderr = XHCI_TRB_ERROR_SUCCESS;
evtrb.dwTrb2 = 0;
evtrb.dwTrb3 = (ccs & XHCI_TRB_3_CYCLE_BIT) |
XHCI_TRB_3_TYPE_SET(XHCI_TRB_EVENT_CMD_COMPLETE);
slot = 0;
switch (type) {
case XHCI_TRB_TYPE_LINK: /* 0x06 */
if (trb->dwTrb3 & XHCI_TRB_3_TC_BIT)
ccs ^= XHCI_CRCR_LO_RCS;
break;
case XHCI_TRB_TYPE_ENABLE_SLOT: /* 0x09 */
cmderr = pci_xhci_cmd_enable_slot(sc, &slot);
break;
case XHCI_TRB_TYPE_DISABLE_SLOT: /* 0x0A */
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_disable_slot(sc, slot);
break;
case XHCI_TRB_TYPE_ADDRESS_DEVICE: /* 0x0B */
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_address_device(sc, slot, trb);
break;
case XHCI_TRB_TYPE_CONFIGURE_EP: /* 0x0C */
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_config_ep(sc, slot, trb);
break;
case XHCI_TRB_TYPE_EVALUATE_CTX: /* 0x0D */
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_eval_ctx(sc, slot, trb);
break;
case XHCI_TRB_TYPE_RESET_EP: /* 0x0E */
DPRINTF(("Reset Endpoint on slot %d", slot));
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_reset_ep(sc, slot, trb);
break;
case XHCI_TRB_TYPE_STOP_EP: /* 0x0F */
DPRINTF(("Stop Endpoint on slot %d", slot));
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_reset_ep(sc, slot, trb);
break;
case XHCI_TRB_TYPE_SET_TR_DEQUEUE: /* 0x10 */
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_set_tr(sc, slot, trb);
break;
case XHCI_TRB_TYPE_RESET_DEVICE: /* 0x11 */
slot = XHCI_TRB_3_SLOT_GET(trb->dwTrb3);
cmderr = pci_xhci_cmd_reset_device(sc, slot);
break;
case XHCI_TRB_TYPE_FORCE_EVENT: /* 0x12 */
/* TODO: */
break;
case XHCI_TRB_TYPE_NEGOTIATE_BW: /* 0x13 */
break;
case XHCI_TRB_TYPE_SET_LATENCY_TOL: /* 0x14 */
break;
case XHCI_TRB_TYPE_GET_PORT_BW: /* 0x15 */
break;
case XHCI_TRB_TYPE_FORCE_HEADER: /* 0x16 */
break;
case XHCI_TRB_TYPE_NOOP_CMD: /* 0x17 */
break;
default:
DPRINTF(("pci_xhci: unsupported cmd %x", type));
break;
}
if (type != XHCI_TRB_TYPE_LINK) {
/*
* insert command completion event and assert intr
*/
evtrb.qwTrb0 = crcr;
evtrb.dwTrb2 |= XHCI_TRB_2_ERROR_SET(cmderr);
evtrb.dwTrb3 |= XHCI_TRB_3_SLOT_SET(slot);
DPRINTF(("pci_xhci: command 0x%x result: 0x%x",
type, cmderr));
pci_xhci_insert_event(sc, &evtrb, 1);
}
trb = pci_xhci_trb_next(sc, trb, &crcr);
}
sc->opregs.crcr = crcr | (sc->opregs.crcr & XHCI_CRCR_LO_CA) | ccs;
sc->opregs.crcr &= ~XHCI_CRCR_LO_CRR;
return (error);
}
static void
pci_xhci_dump_trb(struct xhci_trb *trb)
{
static const char *trbtypes[] = {
"RESERVED",
"NORMAL",
"SETUP_STAGE",
"DATA_STAGE",
"STATUS_STAGE",
"ISOCH",
"LINK",
"EVENT_DATA",
"NOOP",
"ENABLE_SLOT",
"DISABLE_SLOT",
"ADDRESS_DEVICE",
"CONFIGURE_EP",
"EVALUATE_CTX",
"RESET_EP",
"STOP_EP",
"SET_TR_DEQUEUE",
"RESET_DEVICE",
"FORCE_EVENT",
"NEGOTIATE_BW",
"SET_LATENCY_TOL",
"GET_PORT_BW",
"FORCE_HEADER",
"NOOP_CMD"
};
uint32_t type;
type = XHCI_TRB_3_TYPE_GET(trb->dwTrb3);
DPRINTF(("pci_xhci: trb[@%p] type x%02x %s 0:x%016lx 2:x%08x 3:x%08x",
trb, type,
type <= XHCI_TRB_TYPE_NOOP_CMD ? trbtypes[type] : "INVALID",
trb->qwTrb0, trb->dwTrb2, trb->dwTrb3));
}
static int
pci_xhci_xfer_complete(struct pci_xhci_softc *sc, struct usb_data_xfer *xfer,
uint32_t slot, uint32_t epid, int *do_intr)
{
struct pci_xhci_dev_emu *dev;
struct pci_xhci_dev_ep *devep;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep_ctx;
struct xhci_trb *trb;
struct xhci_trb evtrb;
uint32_t trbflags;
uint32_t edtla;
int i, err;
dev = XHCI_SLOTDEV_PTR(sc, slot);
devep = &dev->eps[epid];
dev_ctx = pci_xhci_get_dev_ctx(sc, slot);
assert(dev_ctx != NULL);
ep_ctx = &dev_ctx->ctx_ep[epid];
err = XHCI_TRB_ERROR_SUCCESS;
*do_intr = 0;
edtla = 0;
/* go through list of TRBs and insert event(s) */
for (i = xfer->head; xfer->ndata > 0; ) {
evtrb.qwTrb0 = (uint64_t)xfer->data[i].hci_data;
trb = XHCI_GADDR(sc, evtrb.qwTrb0);
trbflags = trb->dwTrb3;
DPRINTF(("pci_xhci: xfer[%d] done?%u:%d trb %x %016lx %x "
"(err %d) IOC?%d",
i, xfer->data[i].processed, xfer->data[i].blen,
XHCI_TRB_3_TYPE_GET(trbflags), evtrb.qwTrb0,
trbflags, err,
trb->dwTrb3 & XHCI_TRB_3_IOC_BIT ? 1 : 0));
if (!xfer->data[i].processed) {
xfer->head = i;
break;
}
xfer->ndata--;
edtla += xfer->data[i].bdone;
trb->dwTrb3 = (trb->dwTrb3 & ~0x1) | (xfer->data[i].ccs);
pci_xhci_update_ep_ring(sc, dev, devep, ep_ctx,
xfer->data[i].streamid, xfer->data[i].trbnext,
xfer->data[i].ccs);
/* Only interrupt if IOC or short packet */
if (!(trb->dwTrb3 & XHCI_TRB_3_IOC_BIT) &&
!((err == XHCI_TRB_ERROR_SHORT_PKT) &&
(trb->dwTrb3 & XHCI_TRB_3_ISP_BIT))) {
i = (i + 1) % USB_MAX_XFER_BLOCKS;
continue;
}
evtrb.dwTrb2 = XHCI_TRB_2_ERROR_SET(err) |
XHCI_TRB_2_REM_SET(xfer->data[i].blen);
evtrb.dwTrb3 = XHCI_TRB_3_TYPE_SET(XHCI_TRB_EVENT_TRANSFER) |
XHCI_TRB_3_SLOT_SET(slot) | XHCI_TRB_3_EP_SET(epid);
if (XHCI_TRB_3_TYPE_GET(trbflags) == XHCI_TRB_TYPE_EVENT_DATA) {
DPRINTF(("pci_xhci EVENT_DATA edtla %u", edtla));
evtrb.qwTrb0 = trb->qwTrb0;
evtrb.dwTrb2 = (edtla & 0xFFFFF) |
XHCI_TRB_2_ERROR_SET(err);
evtrb.dwTrb3 |= XHCI_TRB_3_ED_BIT;
edtla = 0;
}
*do_intr = 1;
err = pci_xhci_insert_event(sc, &evtrb, 0);
if (err != XHCI_TRB_ERROR_SUCCESS) {
break;
}
i = (i + 1) % USB_MAX_XFER_BLOCKS;
}
return (err);
}
static void
pci_xhci_update_ep_ring(struct pci_xhci_softc *sc,
struct pci_xhci_dev_emu *dev __unused, struct pci_xhci_dev_ep *devep,
struct xhci_endp_ctx *ep_ctx, uint32_t streamid, uint64_t ringaddr, int ccs)
{
if (devep->ep_MaxPStreams != 0) {
devep->ep_sctx[streamid].qwSctx0 = (ringaddr & ~0xFUL) |
(ccs & 0x1);
devep->ep_sctx_trbs[streamid].ringaddr = ringaddr & ~0xFUL;
devep->ep_sctx_trbs[streamid].ccs = ccs & 0x1;
ep_ctx->qwEpCtx2 = (ep_ctx->qwEpCtx2 & ~0x1) | (ccs & 0x1);
DPRINTF(("xhci update ep-ring stream %d, addr %lx",
streamid, devep->ep_sctx[streamid].qwSctx0));
} else {
devep->ep_ringaddr = ringaddr & ~0xFUL;
devep->ep_ccs = ccs & 0x1;
devep->ep_tr = XHCI_GADDR(sc, ringaddr & ~0xFUL);
ep_ctx->qwEpCtx2 = (ringaddr & ~0xFUL) | (ccs & 0x1);
DPRINTF(("xhci update ep-ring, addr %lx",
(devep->ep_ringaddr | devep->ep_ccs)));
}
}
/*
* Outstanding transfer still in progress (device NAK'd earlier) so retry
* the transfer again to see if it succeeds.
*/
static int
pci_xhci_try_usb_xfer(struct pci_xhci_softc *sc,
struct pci_xhci_dev_emu *dev, struct pci_xhci_dev_ep *devep,
struct xhci_endp_ctx *ep_ctx, uint32_t slot, uint32_t epid)
{
struct usb_data_xfer *xfer;
int err;
int do_intr;
ep_ctx->dwEpCtx0 = FIELD_REPLACE(
ep_ctx->dwEpCtx0, XHCI_ST_EPCTX_RUNNING, 0x7, 0);
err = 0;
do_intr = 0;
xfer = devep->ep_xfer;
USB_DATA_XFER_LOCK(xfer);
/* outstanding requests queued up */
if (dev->dev_ue->ue_data != NULL) {
err = dev->dev_ue->ue_data(dev->dev_sc, xfer,
epid & 0x1 ? USB_XFER_IN : USB_XFER_OUT, epid/2);
if (err == USB_ERR_CANCELLED) {
if (USB_DATA_GET_ERRCODE(&xfer->data[xfer->head]) ==
USB_NAK)
err = XHCI_TRB_ERROR_SUCCESS;
} else {
err = pci_xhci_xfer_complete(sc, xfer, slot, epid,
&do_intr);
if (err == XHCI_TRB_ERROR_SUCCESS && do_intr) {
pci_xhci_assert_interrupt(sc);
}
/* XXX should not do it if error? */
USB_DATA_XFER_RESET(xfer);
}
}
USB_DATA_XFER_UNLOCK(xfer);
return (err);
}
static int
pci_xhci_handle_transfer(struct pci_xhci_softc *sc,
struct pci_xhci_dev_emu *dev, struct pci_xhci_dev_ep *devep,
struct xhci_endp_ctx *ep_ctx, struct xhci_trb *trb, uint32_t slot,
uint32_t epid, uint64_t addr, uint32_t ccs, uint32_t streamid)
{
struct xhci_trb *setup_trb;
struct usb_data_xfer *xfer;
struct usb_data_xfer_block *xfer_block;
uint64_t val;
uint32_t trbflags;
int do_intr, err;
int do_retry;
ep_ctx->dwEpCtx0 = FIELD_REPLACE(ep_ctx->dwEpCtx0,
XHCI_ST_EPCTX_RUNNING, 0x7, 0);
xfer = devep->ep_xfer;
USB_DATA_XFER_LOCK(xfer);
DPRINTF(("pci_xhci handle_transfer slot %u", slot));
retry:
err = XHCI_TRB_ERROR_INVALID;
do_retry = 0;
do_intr = 0;
setup_trb = NULL;
while (1) {
pci_xhci_dump_trb(trb);
trbflags = trb->dwTrb3;
if (XHCI_TRB_3_TYPE_GET(trbflags) != XHCI_TRB_TYPE_LINK &&
(trbflags & XHCI_TRB_3_CYCLE_BIT) !=
(ccs & XHCI_TRB_3_CYCLE_BIT)) {
DPRINTF(("Cycle-bit changed trbflags %x, ccs %x",
trbflags & XHCI_TRB_3_CYCLE_BIT, ccs));
break;
}
xfer_block = NULL;
switch (XHCI_TRB_3_TYPE_GET(trbflags)) {
case XHCI_TRB_TYPE_LINK:
if (trb->dwTrb3 & XHCI_TRB_3_TC_BIT)
ccs ^= 0x1;
xfer_block = usb_data_xfer_append(xfer, NULL, 0,
(void *)addr, ccs);
xfer_block->processed = 1;
break;
case XHCI_TRB_TYPE_SETUP_STAGE:
if ((trbflags & XHCI_TRB_3_IDT_BIT) == 0 ||
XHCI_TRB_2_BYTES_GET(trb->dwTrb2) != 8) {
DPRINTF(("pci_xhci: invalid setup trb"));
err = XHCI_TRB_ERROR_TRB;
goto errout;
}
setup_trb = trb;
val = trb->qwTrb0;
if (!xfer->ureq)
xfer->ureq = malloc(
sizeof(struct usb_device_request));
memcpy(xfer->ureq, &val,
sizeof(struct usb_device_request));
xfer_block = usb_data_xfer_append(xfer, NULL, 0,
(void *)addr, ccs);
xfer_block->processed = 1;
break;
case XHCI_TRB_TYPE_NORMAL:
case XHCI_TRB_TYPE_ISOCH:
if (setup_trb != NULL) {
DPRINTF(("pci_xhci: trb not supposed to be in "
"ctl scope"));
err = XHCI_TRB_ERROR_TRB;
goto errout;
}
/* fall through */
case XHCI_TRB_TYPE_DATA_STAGE:
xfer_block = usb_data_xfer_append(xfer,
(void *)(trbflags & XHCI_TRB_3_IDT_BIT ?
&trb->qwTrb0 : XHCI_GADDR(sc, trb->qwTrb0)),
trb->dwTrb2 & 0x1FFFF, (void *)addr, ccs);
break;
case XHCI_TRB_TYPE_STATUS_STAGE:
xfer_block = usb_data_xfer_append(xfer, NULL, 0,
(void *)addr, ccs);
break;
case XHCI_TRB_TYPE_NOOP:
xfer_block = usb_data_xfer_append(xfer, NULL, 0,
(void *)addr, ccs);
xfer_block->processed = 1;
break;
case XHCI_TRB_TYPE_EVENT_DATA:
xfer_block = usb_data_xfer_append(xfer, NULL, 0,
(void *)addr, ccs);
if ((epid > 1) && (trbflags & XHCI_TRB_3_IOC_BIT)) {
xfer_block->processed = 1;
}
break;
default:
DPRINTF(("pci_xhci: handle xfer unexpected trb type "
"0x%x",
XHCI_TRB_3_TYPE_GET(trbflags)));
err = XHCI_TRB_ERROR_TRB;
goto errout;
}
trb = pci_xhci_trb_next(sc, trb, &addr);
DPRINTF(("pci_xhci: next trb: 0x%lx", (uint64_t)trb));
if (xfer_block) {
xfer_block->trbnext = addr;
xfer_block->streamid = streamid;
}
if (!setup_trb && !(trbflags & XHCI_TRB_3_CHAIN_BIT) &&
XHCI_TRB_3_TYPE_GET(trbflags) != XHCI_TRB_TYPE_LINK) {
break;
}
/* handle current batch that requires interrupt on complete */
if (trbflags & XHCI_TRB_3_IOC_BIT) {
DPRINTF(("pci_xhci: trb IOC bit set"));
if (epid == 1)
do_retry = 1;
break;
}
}
DPRINTF(("pci_xhci[%d]: xfer->ndata %u", __LINE__, xfer->ndata));
if (xfer->ndata <= 0)
goto errout;
if (epid == 1) {
int usberr;
if (dev->dev_ue->ue_request != NULL)
usberr = dev->dev_ue->ue_request(dev->dev_sc, xfer);
else
usberr = USB_ERR_NOT_STARTED;
err = USB_TO_XHCI_ERR(usberr);
if (err == XHCI_TRB_ERROR_SUCCESS ||
err == XHCI_TRB_ERROR_STALL ||
err == XHCI_TRB_ERROR_SHORT_PKT) {
err = pci_xhci_xfer_complete(sc, xfer, slot, epid,
&do_intr);
if (err != XHCI_TRB_ERROR_SUCCESS)
do_retry = 0;
}
} else {
/* handle data transfer */
pci_xhci_try_usb_xfer(sc, dev, devep, ep_ctx, slot, epid);
err = XHCI_TRB_ERROR_SUCCESS;
}
errout:
if (err == XHCI_TRB_ERROR_EV_RING_FULL)
DPRINTF(("pci_xhci[%d]: event ring full", __LINE__));
if (!do_retry)
USB_DATA_XFER_UNLOCK(xfer);
if (do_intr)
pci_xhci_assert_interrupt(sc);
if (do_retry) {
USB_DATA_XFER_RESET(xfer);
DPRINTF(("pci_xhci[%d]: retry:continuing with next TRBs",
__LINE__));
goto retry;
}
if (epid == 1)
USB_DATA_XFER_RESET(xfer);
return (err);
}
static void
pci_xhci_device_doorbell(struct pci_xhci_softc *sc, uint32_t slot,
uint32_t epid, uint32_t streamid)
{
struct pci_xhci_dev_emu *dev;
struct pci_xhci_dev_ep *devep;
struct xhci_dev_ctx *dev_ctx;
struct xhci_endp_ctx *ep_ctx;
struct pci_xhci_trb_ring *sctx_tr;
struct xhci_trb *trb;
uint64_t ringaddr;
uint32_t ccs;
int error;
DPRINTF(("pci_xhci doorbell slot %u epid %u stream %u",
slot, epid, streamid));
if (slot == 0 || slot > XHCI_MAX_SLOTS) {
DPRINTF(("pci_xhci: invalid doorbell slot %u", slot));
return;
}
if (epid == 0 || epid >= XHCI_MAX_ENDPOINTS) {
DPRINTF(("pci_xhci: invalid endpoint %u", epid));
return;
}
dev = XHCI_SLOTDEV_PTR(sc, slot);
devep = &dev->eps[epid];
dev_ctx = pci_xhci_get_dev_ctx(sc, slot);
if (!dev_ctx) {
return;
}
ep_ctx = &dev_ctx->ctx_ep[epid];
sctx_tr = NULL;
DPRINTF(("pci_xhci: device doorbell ep[%u] %08x %08x %016lx %08x",
epid, ep_ctx->dwEpCtx0, ep_ctx->dwEpCtx1, ep_ctx->qwEpCtx2,
ep_ctx->dwEpCtx4));
if (ep_ctx->qwEpCtx2 == 0)
return;
/* handle pending transfers */
if (devep->ep_xfer->ndata > 0) {
pci_xhci_try_usb_xfer(sc, dev, devep, ep_ctx, slot, epid);
return;
}
/* get next trb work item */
if (devep->ep_MaxPStreams != 0) {
/*
* Stream IDs of 0, 65535 (any stream), and 65534
* (prime) are invalid.
*/
if (streamid == 0 || streamid == 65534 || streamid == 65535) {
DPRINTF(("pci_xhci: invalid stream %u", streamid));
return;
}
error = pci_xhci_find_stream(sc, ep_ctx, devep, streamid);
if (error != XHCI_TRB_ERROR_SUCCESS) {
DPRINTF(("pci_xhci: invalid stream %u: %d",
streamid, error));
return;
}
sctx_tr = &devep->ep_sctx_trbs[streamid];
ringaddr = sctx_tr->ringaddr;
ccs = sctx_tr->ccs;
trb = XHCI_GADDR(sc, sctx_tr->ringaddr & ~0xFUL);
DPRINTF(("doorbell, stream %u, ccs %lx, trb ccs %x",
streamid, ep_ctx->qwEpCtx2 & XHCI_TRB_3_CYCLE_BIT,
trb->dwTrb3 & XHCI_TRB_3_CYCLE_BIT));
} else {
if (streamid != 0) {
DPRINTF(("pci_xhci: invalid stream %u", streamid));
return;
}
ringaddr = devep->ep_ringaddr;
ccs = devep->ep_ccs;
trb = devep->ep_tr;
DPRINTF(("doorbell, ccs %lx, trb ccs %x",
ep_ctx->qwEpCtx2 & XHCI_TRB_3_CYCLE_BIT,
trb->dwTrb3 & XHCI_TRB_3_CYCLE_BIT));
}
if (XHCI_TRB_3_TYPE_GET(trb->dwTrb3) == 0) {
DPRINTF(("pci_xhci: ring %lx trb[%lx] EP %u is RESERVED?",
ep_ctx->qwEpCtx2, devep->ep_ringaddr, epid));
return;
}
pci_xhci_handle_transfer(sc, dev, devep, ep_ctx, trb, slot, epid,
ringaddr, ccs, streamid);
}
static void
pci_xhci_dbregs_write(struct pci_xhci_softc *sc, uint64_t offset,
uint64_t value)
{
offset = (offset - sc->dboff) / sizeof(uint32_t);
DPRINTF(("pci_xhci: doorbell write offset 0x%lx: 0x%lx",
offset, value));
if (XHCI_HALTED(sc)) {
DPRINTF(("pci_xhci: controller halted"));
return;
}
if (offset == 0)
pci_xhci_complete_commands(sc);
else if (sc->portregs != NULL)
pci_xhci_device_doorbell(sc, offset,
XHCI_DB_TARGET_GET(value), XHCI_DB_SID_GET(value));
}
static void
pci_xhci_rtsregs_write(struct pci_xhci_softc *sc, uint64_t offset,
uint64_t value)
{
struct pci_xhci_rtsregs *rts;
offset -= sc->rtsoff;
if (offset == 0) {
DPRINTF(("pci_xhci attempted write to MFINDEX"));
return;
}
DPRINTF(("pci_xhci: runtime regs write offset 0x%lx: 0x%lx",
offset, value));
offset -= 0x20; /* start of intrreg */
rts = &sc->rtsregs;
switch (offset) {
case 0x00:
if (value & XHCI_IMAN_INTR_PEND)
rts->intrreg.iman &= ~XHCI_IMAN_INTR_PEND;
rts->intrreg.iman = (value & XHCI_IMAN_INTR_ENA) |
(rts->intrreg.iman & XHCI_IMAN_INTR_PEND);
if (!(value & XHCI_IMAN_INTR_ENA))
pci_xhci_deassert_interrupt(sc);
break;
case 0x04:
rts->intrreg.imod = value;
break;
case 0x08:
rts->intrreg.erstsz = value & 0xFFFF;
break;
case 0x10:
/* ERSTBA low bits */
rts->intrreg.erstba = MASK_64_HI(sc->rtsregs.intrreg.erstba) |
(value & ~0x3F);
break;
case 0x14:
/* ERSTBA high bits */
rts->intrreg.erstba = (value << 32) |
MASK_64_LO(sc->rtsregs.intrreg.erstba);
rts->erstba_p = XHCI_GADDR(sc,
sc->rtsregs.intrreg.erstba & ~0x3FUL);
rts->erst_p = XHCI_GADDR(sc,
sc->rtsregs.erstba_p->qwEvrsTablePtr & ~0x3FUL);
rts->er_enq_idx = 0;
rts->er_events_cnt = 0;
DPRINTF(("pci_xhci: wr erstba erst (%p) ptr 0x%lx, sz %u",
rts->erstba_p,
rts->erstba_p->qwEvrsTablePtr,
rts->erstba_p->dwEvrsTableSize));
break;
case 0x18:
/* ERDP low bits */
rts->intrreg.erdp =
MASK_64_HI(sc->rtsregs.intrreg.erdp) |
(rts->intrreg.erdp & XHCI_ERDP_LO_BUSY) |
(value & ~0xF);
if (value & XHCI_ERDP_LO_BUSY) {
rts->intrreg.erdp &= ~XHCI_ERDP_LO_BUSY;
rts->intrreg.iman &= ~XHCI_IMAN_INTR_PEND;
}
rts->er_deq_seg = XHCI_ERDP_LO_SINDEX(value);
break;
case 0x1C:
/* ERDP high bits */
rts->intrreg.erdp = (value << 32) |
MASK_64_LO(sc->rtsregs.intrreg.erdp);
if (rts->er_events_cnt > 0) {
uint64_t erdp;
int erdp_i;
erdp = rts->intrreg.erdp & ~0xF;
erdp_i = (erdp - rts->erstba_p->qwEvrsTablePtr) /
sizeof(struct xhci_trb);
if (erdp_i <= rts->er_enq_idx)
rts->er_events_cnt = rts->er_enq_idx - erdp_i;
else
rts->er_events_cnt =
rts->erstba_p->dwEvrsTableSize -
(erdp_i - rts->er_enq_idx);
DPRINTF(("pci_xhci: erdp 0x%lx, events cnt %u",
erdp, rts->er_events_cnt));
}
break;
default:
DPRINTF(("pci_xhci attempted write to RTS offset 0x%lx",
offset));
break;
}
}
static uint64_t
pci_xhci_portregs_read(struct pci_xhci_softc *sc, uint64_t offset)
{
struct pci_xhci_portregs *portregs;
int port;
uint32_t reg;
if (sc->portregs == NULL)
return (0);
port = (offset - XHCI_PORTREGS_PORT0) / XHCI_PORTREGS_SETSZ;
offset = (offset - XHCI_PORTREGS_PORT0) % XHCI_PORTREGS_SETSZ;
if (port > XHCI_MAX_DEVS) {
DPRINTF(("pci_xhci: portregs_read port %d >= XHCI_MAX_DEVS",
port));
/* return default value for unused port */
return (XHCI_PS_SPEED_SET(3));
}
portregs = XHCI_PORTREG_PTR(sc, port);
switch (offset) {
case 0:
reg = portregs->portsc;
break;
case 4:
reg = portregs->portpmsc;
break;
case 8:
reg = portregs->portli;
break;
case 12:
reg = portregs->porthlpmc;
break;
default:
DPRINTF(("pci_xhci: unaligned portregs read offset %#lx",
offset));
reg = 0xffffffff;
break;
}
DPRINTF(("pci_xhci: portregs read offset 0x%lx port %u -> 0x%x",
offset, port, reg));
return (reg);
}
static void
pci_xhci_hostop_write(struct pci_xhci_softc *sc, uint64_t offset,
uint64_t value)
{
offset -= XHCI_CAPLEN;
if (offset < 0x400)
DPRINTF(("pci_xhci: hostop write offset 0x%lx: 0x%lx",
offset, value));
switch (offset) {
case XHCI_USBCMD:
sc->opregs.usbcmd = pci_xhci_usbcmd_write(sc, value & 0x3F0F);
break;
case XHCI_USBSTS:
/* clear bits on write */
sc->opregs.usbsts &= ~(value &
(XHCI_STS_HSE|XHCI_STS_EINT|XHCI_STS_PCD|XHCI_STS_SSS|
XHCI_STS_RSS|XHCI_STS_SRE|XHCI_STS_CNR));
break;
case XHCI_PAGESIZE:
/* read only */
break;
case XHCI_DNCTRL:
sc->opregs.dnctrl = value & 0xFFFF;
break;
case XHCI_CRCR_LO:
if (sc->opregs.crcr & XHCI_CRCR_LO_CRR) {
sc->opregs.crcr &= ~(XHCI_CRCR_LO_CS|XHCI_CRCR_LO_CA);
sc->opregs.crcr |= value &
(XHCI_CRCR_LO_CS|XHCI_CRCR_LO_CA);
} else {
sc->opregs.crcr = MASK_64_HI(sc->opregs.crcr) |
(value & (0xFFFFFFC0 | XHCI_CRCR_LO_RCS));
}
break;
case XHCI_CRCR_HI:
if (!(sc->opregs.crcr & XHCI_CRCR_LO_CRR)) {
sc->opregs.crcr = MASK_64_LO(sc->opregs.crcr) |
(value << 32);
sc->opregs.cr_p = XHCI_GADDR(sc,
sc->opregs.crcr & ~0xF);
}
if (sc->opregs.crcr & XHCI_CRCR_LO_CS) {
/* Stop operation of Command Ring */
}
if (sc->opregs.crcr & XHCI_CRCR_LO_CA) {
/* Abort command */
}
break;
case XHCI_DCBAAP_LO:
sc->opregs.dcbaap = MASK_64_HI(sc->opregs.dcbaap) |
(value & 0xFFFFFFC0);
break;
case XHCI_DCBAAP_HI:
sc->opregs.dcbaap = MASK_64_LO(sc->opregs.dcbaap) |
(value << 32);
sc->opregs.dcbaa_p = XHCI_GADDR(sc, sc->opregs.dcbaap & ~0x3FUL);
DPRINTF(("pci_xhci: opregs dcbaap = 0x%lx (vaddr 0x%lx)",
sc->opregs.dcbaap, (uint64_t)sc->opregs.dcbaa_p));
break;
case XHCI_CONFIG:
sc->opregs.config = value & 0x03FF;
break;
default:
if (offset >= 0x400)
pci_xhci_portregs_write(sc, offset, value);
break;
}
}
static void
pci_xhci_write(struct pci_devinst *pi, int baridx, uint64_t offset,
int size __unused, uint64_t value)
{
struct pci_xhci_softc *sc;
sc = pi->pi_arg;
assert(baridx == 0);
pthread_mutex_lock(&sc->mtx);
if (offset < XHCI_CAPLEN) /* read only registers */
WPRINTF(("pci_xhci: write RO-CAPs offset %ld", offset));
else if (offset < sc->dboff)
pci_xhci_hostop_write(sc, offset, value);
else if (offset < sc->rtsoff)
pci_xhci_dbregs_write(sc, offset, value);
else if (offset < sc->regsend)
pci_xhci_rtsregs_write(sc, offset, value);
else
WPRINTF(("pci_xhci: write invalid offset %ld", offset));
pthread_mutex_unlock(&sc->mtx);
}
static uint64_t
pci_xhci_hostcap_read(struct pci_xhci_softc *sc, uint64_t offset)
{
uint64_t value;
switch (offset) {
case XHCI_CAPLENGTH: /* 0x00 */
value = sc->caplength;
break;
case XHCI_HCSPARAMS1: /* 0x04 */
value = sc->hcsparams1;
break;
case XHCI_HCSPARAMS2: /* 0x08 */
value = sc->hcsparams2;
break;
case XHCI_HCSPARAMS3: /* 0x0C */
value = sc->hcsparams3;
break;
case XHCI_HCSPARAMS0: /* 0x10 */
value = sc->hccparams1;
break;
case XHCI_DBOFF: /* 0x14 */
value = sc->dboff;
break;
case XHCI_RTSOFF: /* 0x18 */
value = sc->rtsoff;
break;
case XHCI_HCCPRAMS2: /* 0x1C */
value = sc->hccparams2;
break;
default:
value = 0;
break;
}
DPRINTF(("pci_xhci: hostcap read offset 0x%lx -> 0x%lx",
offset, value));
return (value);
}
static uint64_t
pci_xhci_hostop_read(struct pci_xhci_softc *sc, uint64_t offset)
{
uint64_t value;
offset = (offset - XHCI_CAPLEN);
switch (offset) {
case XHCI_USBCMD: /* 0x00 */
value = sc->opregs.usbcmd;
break;
case XHCI_USBSTS: /* 0x04 */
value = sc->opregs.usbsts;
break;
case XHCI_PAGESIZE: /* 0x08 */
value = sc->opregs.pgsz;
break;
case XHCI_DNCTRL: /* 0x14 */
value = sc->opregs.dnctrl;
break;
case XHCI_CRCR_LO: /* 0x18 */
value = sc->opregs.crcr & XHCI_CRCR_LO_CRR;
break;
case XHCI_CRCR_HI: /* 0x1C */
value = 0;
break;
case XHCI_DCBAAP_LO: /* 0x30 */
value = sc->opregs.dcbaap & 0xFFFFFFFF;
break;
case XHCI_DCBAAP_HI: /* 0x34 */
value = (sc->opregs.dcbaap >> 32) & 0xFFFFFFFF;
break;
case XHCI_CONFIG: /* 0x38 */
value = sc->opregs.config;
break;
default:
if (offset >= 0x400)
value = pci_xhci_portregs_read(sc, offset);
else
value = 0;
break;
}
if (offset < 0x400)
DPRINTF(("pci_xhci: hostop read offset 0x%lx -> 0x%lx",
offset, value));
return (value);
}
static uint64_t
pci_xhci_dbregs_read(struct pci_xhci_softc *sc __unused,
uint64_t offset __unused)
{
/* read doorbell always returns 0 */
return (0);
}
static uint64_t
pci_xhci_rtsregs_read(struct pci_xhci_softc *sc, uint64_t offset)
{
uint32_t value;
offset -= sc->rtsoff;
value = 0;
if (offset == XHCI_MFINDEX) {
value = sc->rtsregs.mfindex;
} else if (offset >= 0x20) {
int item;
uint32_t *p;
offset -= 0x20;
item = offset % 32;
assert(offset < sizeof(sc->rtsregs.intrreg));
p = &sc->rtsregs.intrreg.iman;
p += item / sizeof(uint32_t);
value = *p;
}
DPRINTF(("pci_xhci: rtsregs read offset 0x%lx -> 0x%x",
offset, value));
return (value);
}
static uint64_t
pci_xhci_xecp_read(struct pci_xhci_softc *sc, uint64_t offset)
{
uint32_t value;
offset -= sc->regsend;
value = 0;
switch (offset) {
case 0:
/* rev major | rev minor | next-cap | cap-id */
value = (0x02 << 24) | (4 << 8) | XHCI_ID_PROTOCOLS;
break;
case 4:
/* name string = "USB" */
value = 0x20425355;
break;
case 8:
/* psic | proto-defined | compat # | compat offset */
value = ((XHCI_MAX_DEVS/2) << 8) | sc->usb2_port_start;
break;
case 12:
break;
case 16:
/* rev major | rev minor | next-cap | cap-id */
value = (0x03 << 24) | XHCI_ID_PROTOCOLS;
break;
case 20:
/* name string = "USB" */
value = 0x20425355;
break;
case 24:
/* psic | proto-defined | compat # | compat offset */
value = ((XHCI_MAX_DEVS/2) << 8) | sc->usb3_port_start;
break;
case 28:
break;
default:
DPRINTF(("pci_xhci: xecp invalid offset 0x%lx", offset));
break;
}
DPRINTF(("pci_xhci: xecp read offset 0x%lx -> 0x%x",
offset, value));
return (value);
}
static uint64_t
pci_xhci_read(struct pci_devinst *pi, int baridx, uint64_t offset, int size)
{
struct pci_xhci_softc *sc;
uint32_t value;
sc = pi->pi_arg;
assert(baridx == 0);
pthread_mutex_lock(&sc->mtx);
if (offset < XHCI_CAPLEN)
value = pci_xhci_hostcap_read(sc, offset);
else if (offset < sc->dboff)
value = pci_xhci_hostop_read(sc, offset);
else if (offset < sc->rtsoff)
value = pci_xhci_dbregs_read(sc, offset);
else if (offset < sc->regsend)
value = pci_xhci_rtsregs_read(sc, offset);
else if (offset < (sc->regsend + 4*32))
value = pci_xhci_xecp_read(sc, offset);
else {
value = 0;
WPRINTF(("pci_xhci: read invalid offset %ld", offset));
}
pthread_mutex_unlock(&sc->mtx);
switch (size) {
case 1:
value &= 0xFF;
break;
case 2:
value &= 0xFFFF;
break;
case 4:
value &= 0xFFFFFFFF;
break;
}
return (value);
}
static void
pci_xhci_reset_port(struct pci_xhci_softc *sc, int portn, int warm)
{
struct pci_xhci_portregs *port;
struct pci_xhci_dev_emu *dev;
struct xhci_trb evtrb;
int error;
assert(portn <= XHCI_MAX_DEVS);
DPRINTF(("xhci reset port %d", portn));
port = XHCI_PORTREG_PTR(sc, portn);
dev = XHCI_DEVINST_PTR(sc, portn);
if (dev) {
port->portsc &= ~(XHCI_PS_PLS_MASK | XHCI_PS_PR | XHCI_PS_PRC);
port->portsc |= XHCI_PS_PED |
XHCI_PS_SPEED_SET(dev->dev_ue->ue_usbspeed);
if (warm && dev->dev_ue->ue_usbver == 3) {
port->portsc |= XHCI_PS_WRC;
}
if ((port->portsc & XHCI_PS_PRC) == 0) {
port->portsc |= XHCI_PS_PRC;
pci_xhci_set_evtrb(&evtrb, portn,
XHCI_TRB_ERROR_SUCCESS,
XHCI_TRB_EVENT_PORT_STS_CHANGE);
error = pci_xhci_insert_event(sc, &evtrb, 1);
if (error != XHCI_TRB_ERROR_SUCCESS)
DPRINTF(("xhci reset port insert event "
"failed"));
}
}
}
static void
pci_xhci_init_port(struct pci_xhci_softc *sc, int portn)
{
struct pci_xhci_portregs *port;
struct pci_xhci_dev_emu *dev;
port = XHCI_PORTREG_PTR(sc, portn);
dev = XHCI_DEVINST_PTR(sc, portn);
if (dev) {
port->portsc = XHCI_PS_CCS | /* connected */
XHCI_PS_PP; /* port power */
if (dev->dev_ue->ue_usbver == 2) {
port->portsc |= XHCI_PS_PLS_SET(UPS_PORT_LS_POLL) |
XHCI_PS_SPEED_SET(dev->dev_ue->ue_usbspeed);
} else {
port->portsc |= XHCI_PS_PLS_SET(UPS_PORT_LS_U0) |
XHCI_PS_PED | /* enabled */
XHCI_PS_SPEED_SET(dev->dev_ue->ue_usbspeed);
}
DPRINTF(("Init port %d 0x%x", portn, port->portsc));
} else {
port->portsc = XHCI_PS_PLS_SET(UPS_PORT_LS_RX_DET) | XHCI_PS_PP;
DPRINTF(("Init empty port %d 0x%x", portn, port->portsc));
}
}
static int
pci_xhci_dev_intr(struct usb_hci *hci, int epctx)
{
struct pci_xhci_dev_emu *dev;
struct xhci_dev_ctx *dev_ctx;
struct xhci_trb evtrb;
struct pci_xhci_softc *sc;
struct pci_xhci_portregs *p;
struct xhci_endp_ctx *ep_ctx;
int error = 0;
int dir_in;
int epid;
dir_in = epctx & 0x80;
epid = epctx & ~0x80;
/* HW endpoint contexts are 0-15; convert to epid based on dir */
epid = (epid * 2) + (dir_in ? 1 : 0);
assert(epid >= 1 && epid <= 31);
dev = hci->hci_sc;
sc = dev->xsc;
/* check if device is ready; OS has to initialise it */
if (sc->rtsregs.erstba_p == NULL ||
(sc->opregs.usbcmd & XHCI_CMD_RS) == 0 ||
dev->dev_ctx == NULL)
return (0);
p = XHCI_PORTREG_PTR(sc, hci->hci_port);
/* raise event if link U3 (suspended) state */
if (XHCI_PS_PLS_GET(p->portsc) == 3) {
p->portsc &= ~XHCI_PS_PLS_MASK;
p->portsc |= XHCI_PS_PLS_SET(UPS_PORT_LS_RESUME);
if ((p->portsc & XHCI_PS_PLC) != 0)
return (0);
p->portsc |= XHCI_PS_PLC;
pci_xhci_set_evtrb(&evtrb, hci->hci_port,
XHCI_TRB_ERROR_SUCCESS, XHCI_TRB_EVENT_PORT_STS_CHANGE);
error = pci_xhci_insert_event(sc, &evtrb, 0);
if (error != XHCI_TRB_ERROR_SUCCESS)
goto done;
}
dev_ctx = dev->dev_ctx;
ep_ctx = &dev_ctx->ctx_ep[epid];
if ((ep_ctx->dwEpCtx0 & 0x7) == XHCI_ST_EPCTX_DISABLED) {
DPRINTF(("xhci device interrupt on disabled endpoint %d",
epid));
return (0);
}
DPRINTF(("xhci device interrupt on endpoint %d", epid));
pci_xhci_device_doorbell(sc, hci->hci_port, epid, 0);
done:
return (error);
}
static int
pci_xhci_dev_event(struct usb_hci *hci, enum hci_usbev evid __unused,
void *param __unused)
{
DPRINTF(("xhci device event port %d", hci->hci_port));
return (0);
}
/*
* Each controller contains a "slot" node which contains a list of
* child nodes each of which is a device. Each slot node's name
* corresponds to a specific controller slot. These nodes
* contain a "device" variable identifying the device model of the
* USB device. For example:
*
* pci.0.1.0
* .device="xhci"
* .slot
* .1
* .device="tablet"
*/
static int
pci_xhci_legacy_config(nvlist_t *nvl, const char *opts)
{
char node_name[16];
nvlist_t *slots_nvl, *slot_nvl;
char *cp, *opt, *str, *tofree;
int slot;
if (opts == NULL)
return (0);
slots_nvl = create_relative_config_node(nvl, "slot");
slot = 1;
tofree = str = strdup(opts);
while ((opt = strsep(&str, ",")) != NULL) {
/* device[=<config>] */
cp = strchr(opt, '=');
if (cp != NULL) {
*cp = '\0';
cp++;
}
snprintf(node_name, sizeof(node_name), "%d", slot);
slot++;
slot_nvl = create_relative_config_node(slots_nvl, node_name);
set_config_value_node(slot_nvl, "device", opt);
/*
* NB: Given that we split on commas above, the legacy
* format only supports a single option.
*/
if (cp != NULL && *cp != '\0')
pci_parse_legacy_config(slot_nvl, cp);
}
free(tofree);
return (0);
}
static int
pci_xhci_parse_devices(struct pci_xhci_softc *sc, nvlist_t *nvl)
{
struct pci_xhci_dev_emu *dev;
struct usb_devemu *ue;
const nvlist_t *slots_nvl, *slot_nvl;
const char *name, *device;
char *cp;
void *devsc, *cookie;
long slot;
int type, usb3_port, usb2_port, i, ndevices;
usb3_port = sc->usb3_port_start;
usb2_port = sc->usb2_port_start;
sc->devices = calloc(XHCI_MAX_DEVS, sizeof(struct pci_xhci_dev_emu *));
sc->slots = calloc(XHCI_MAX_SLOTS, sizeof(struct pci_xhci_dev_emu *));
ndevices = 0;
slots_nvl = find_relative_config_node(nvl, "slot");
if (slots_nvl == NULL)
goto portsfinal;
cookie = NULL;
while ((name = nvlist_next(slots_nvl, &type, &cookie)) != NULL) {
if (usb2_port == ((sc->usb2_port_start) + XHCI_MAX_DEVS/2) ||
usb3_port == ((sc->usb3_port_start) + XHCI_MAX_DEVS/2)) {
WPRINTF(("pci_xhci max number of USB 2 or 3 "
"devices reached, max %d", XHCI_MAX_DEVS/2));
goto bad;
}
if (type != NV_TYPE_NVLIST) {
EPRINTLN(
"pci_xhci: config variable '%s' under slot node",
name);
goto bad;
}
slot = strtol(name, &cp, 0);
if (*cp != '\0' || slot <= 0 || slot > XHCI_MAX_SLOTS) {
EPRINTLN("pci_xhci: invalid slot '%s'", name);
goto bad;
}
if (XHCI_SLOTDEV_PTR(sc, slot) != NULL) {
EPRINTLN("pci_xhci: duplicate slot '%s'", name);
goto bad;
}
slot_nvl = nvlist_get_nvlist(slots_nvl, name);
device = get_config_value_node(slot_nvl, "device");
if (device == NULL) {
EPRINTLN(
"pci_xhci: missing \"device\" value for slot '%s'",
name);
goto bad;
}
ue = usb_emu_finddev(device);
if (ue == NULL) {
EPRINTLN("pci_xhci: unknown device model \"%s\"",
device);
goto bad;
}
DPRINTF(("pci_xhci adding device %s", device));
dev = calloc(1, sizeof(struct pci_xhci_dev_emu));
dev->xsc = sc;
dev->hci.hci_sc = dev;
dev->hci.hci_intr = pci_xhci_dev_intr;
dev->hci.hci_event = pci_xhci_dev_event;
if (ue->ue_usbver == 2) {
if (usb2_port == sc->usb2_port_start +
XHCI_MAX_DEVS / 2) {
WPRINTF(("pci_xhci max number of USB 2 devices "
"reached, max %d", XHCI_MAX_DEVS / 2));
goto bad;
}
dev->hci.hci_port = usb2_port;
usb2_port++;
} else {
if (usb3_port == sc->usb3_port_start +
XHCI_MAX_DEVS / 2) {
WPRINTF(("pci_xhci max number of USB 3 devices "
"reached, max %d", XHCI_MAX_DEVS / 2));
goto bad;
}
dev->hci.hci_port = usb3_port;
usb3_port++;
}
XHCI_DEVINST_PTR(sc, dev->hci.hci_port) = dev;
dev->hci.hci_address = 0;
devsc = ue->ue_init(&dev->hci, nvl);
if (devsc == NULL) {
goto bad;
}
dev->dev_ue = ue;
dev->dev_sc = devsc;
XHCI_SLOTDEV_PTR(sc, slot) = dev;
ndevices++;
}
portsfinal:
sc->portregs = calloc(XHCI_MAX_DEVS, sizeof(struct pci_xhci_portregs));
if (ndevices > 0) {
for (i = 1; i <= XHCI_MAX_DEVS; i++) {
pci_xhci_init_port(sc, i);
}
} else {
WPRINTF(("pci_xhci no USB devices configured"));
}
return (0);
bad:
for (i = 1; i <= XHCI_MAX_DEVS; i++) {
free(XHCI_DEVINST_PTR(sc, i));
}
free(sc->devices);
free(sc->slots);
return (-1);
}
static int
pci_xhci_init(struct pci_devinst *pi, nvlist_t *nvl)
{
struct pci_xhci_softc *sc;
int error;
if (xhci_in_use) {
WPRINTF(("pci_xhci controller already defined"));
return (-1);
}
xhci_in_use = 1;
sc = calloc(1, sizeof(struct pci_xhci_softc));
pi->pi_arg = sc;
sc->xsc_pi = pi;
sc->usb2_port_start = (XHCI_MAX_DEVS/2) + 1;
sc->usb3_port_start = 1;
/* discover devices */
error = pci_xhci_parse_devices(sc, nvl);
if (error < 0)
goto done;
else
error = 0;
sc->caplength = XHCI_SET_CAPLEN(XHCI_CAPLEN) |
XHCI_SET_HCIVERSION(0x0100);
sc->hcsparams1 = XHCI_SET_HCSP1_MAXPORTS(XHCI_MAX_DEVS) |
XHCI_SET_HCSP1_MAXINTR(1) | /* interrupters */
XHCI_SET_HCSP1_MAXSLOTS(XHCI_MAX_SLOTS);
sc->hcsparams2 = XHCI_SET_HCSP2_ERSTMAX(XHCI_ERST_MAX) |
XHCI_SET_HCSP2_IST(0x04);
sc->hcsparams3 = 0; /* no latency */
sc->hccparams1 = XHCI_SET_HCCP1_AC64(1) | /* 64-bit addrs */
XHCI_SET_HCCP1_NSS(1) | /* no 2nd-streams */
XHCI_SET_HCCP1_SPC(1) | /* short packet */
XHCI_SET_HCCP1_MAXPSA(XHCI_STREAMS_MAX);
sc->hccparams2 = XHCI_SET_HCCP2_LEC(1) |
XHCI_SET_HCCP2_U3C(1);
sc->dboff = XHCI_SET_DOORBELL(XHCI_CAPLEN + XHCI_PORTREGS_START +
XHCI_MAX_DEVS * sizeof(struct pci_xhci_portregs));
/* dboff must be 32-bit aligned */
if (sc->dboff & 0x3)
sc->dboff = (sc->dboff + 0x3) & ~0x3;
/* rtsoff must be 32-bytes aligned */
sc->rtsoff = XHCI_SET_RTSOFFSET(sc->dboff + (XHCI_MAX_SLOTS+1) * 32);
if (sc->rtsoff & 0x1F)
sc->rtsoff = (sc->rtsoff + 0x1F) & ~0x1F;
DPRINTF(("pci_xhci dboff: 0x%x, rtsoff: 0x%x", sc->dboff,
sc->rtsoff));
sc->opregs.usbsts = XHCI_STS_HCH;
sc->opregs.pgsz = XHCI_PAGESIZE_4K;
pci_xhci_reset(sc);
sc->regsend = sc->rtsoff + 0x20 + 32; /* only 1 intrpter */
/*
* Set extended capabilities pointer to be after regsend;
* value of xecp field is 32-bit offset.
*/
sc->hccparams1 |= XHCI_SET_HCCP1_XECP(sc->regsend/4);
pci_set_cfgdata16(pi, PCIR_DEVICE, 0x1E31);
pci_set_cfgdata16(pi, PCIR_VENDOR, 0x8086);
pci_set_cfgdata8(pi, PCIR_CLASS, PCIC_SERIALBUS);
pci_set_cfgdata8(pi, PCIR_SUBCLASS, PCIS_SERIALBUS_USB);
pci_set_cfgdata8(pi, PCIR_PROGIF,PCIP_SERIALBUS_USB_XHCI);
pci_set_cfgdata8(pi, PCI_USBREV, PCI_USB_REV_3_0);
pci_emul_add_msicap(pi, 1);
/* regsend + xecp registers */
pci_emul_alloc_bar(pi, 0, PCIBAR_MEM32, sc->regsend + 4*32);
DPRINTF(("pci_xhci pci_emu_alloc: %d", sc->regsend + 4*32));
pci_lintr_request(pi);
pthread_mutex_init(&sc->mtx, NULL);
done:
if (error) {
free(sc);
}
return (error);
}
#ifdef BHYVE_SNAPSHOT
static void
pci_xhci_map_devs_slots(struct pci_xhci_softc *sc, int maps[])
{
int i, j;
struct pci_xhci_dev_emu *dev, *slot;
memset(maps, 0, sizeof(maps[0]) * XHCI_MAX_SLOTS);
for (i = 1; i <= XHCI_MAX_SLOTS; i++) {
for (j = 1; j <= XHCI_MAX_DEVS; j++) {
slot = XHCI_SLOTDEV_PTR(sc, i);
dev = XHCI_DEVINST_PTR(sc, j);
if (slot == dev)
maps[i] = j;
}
}
}
static int
pci_xhci_snapshot_ep(struct pci_xhci_softc *sc __unused,
struct pci_xhci_dev_emu *dev, int idx, struct vm_snapshot_meta *meta)
{
int k;
int ret;
struct usb_data_xfer *xfer;
struct usb_data_xfer_block *xfer_block;
/* some sanity checks */
if (meta->op == VM_SNAPSHOT_SAVE)
xfer = dev->eps[idx].ep_xfer;
SNAPSHOT_VAR_OR_LEAVE(xfer, meta, ret, done);
if (xfer == NULL) {
ret = 0;
goto done;
}
if (meta->op == VM_SNAPSHOT_RESTORE) {
pci_xhci_init_ep(dev, idx);
xfer = dev->eps[idx].ep_xfer;
}
/* save / restore proper */
for (k = 0; k < USB_MAX_XFER_BLOCKS; k++) {
xfer_block = &xfer->data[k];
SNAPSHOT_GUEST2HOST_ADDR_OR_LEAVE(xfer_block->buf,
XHCI_GADDR_SIZE(xfer_block->buf), true, meta, ret,
done);
SNAPSHOT_VAR_OR_LEAVE(xfer_block->blen, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer_block->bdone, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer_block->processed, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer_block->hci_data, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer_block->ccs, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer_block->streamid, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer_block->trbnext, meta, ret, done);
}
SNAPSHOT_VAR_OR_LEAVE(xfer->ureq, meta, ret, done);
if (xfer->ureq) {
/* xfer->ureq is not allocated at restore time */
if (meta->op == VM_SNAPSHOT_RESTORE)
xfer->ureq = malloc(sizeof(struct usb_device_request));
SNAPSHOT_BUF_OR_LEAVE(xfer->ureq,
sizeof(struct usb_device_request),
meta, ret, done);
}
SNAPSHOT_VAR_OR_LEAVE(xfer->ndata, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer->head, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(xfer->tail, meta, ret, done);
done:
return (ret);
}
static int
pci_xhci_snapshot(struct vm_snapshot_meta *meta)
{
int i, j;
int ret;
int restore_idx;
struct pci_devinst *pi;
struct pci_xhci_softc *sc;
struct pci_xhci_portregs *port;
struct pci_xhci_dev_emu *dev;
char dname[SNAP_DEV_NAME_LEN];
int maps[XHCI_MAX_SLOTS + 1];
pi = meta->dev_data;
sc = pi->pi_arg;
SNAPSHOT_VAR_OR_LEAVE(sc->caplength, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->hcsparams1, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->hcsparams2, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->hcsparams3, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->hccparams1, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->dboff, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsoff, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->hccparams2, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->regsend, meta, ret, done);
/* opregs */
SNAPSHOT_VAR_OR_LEAVE(sc->opregs.usbcmd, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->opregs.usbsts, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->opregs.pgsz, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->opregs.dnctrl, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->opregs.crcr, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->opregs.dcbaap, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->opregs.config, meta, ret, done);
/* opregs.cr_p */
SNAPSHOT_GUEST2HOST_ADDR_OR_LEAVE(sc->opregs.cr_p,
XHCI_GADDR_SIZE(sc->opregs.cr_p), true, meta, ret, done);
/* opregs.dcbaa_p */
SNAPSHOT_GUEST2HOST_ADDR_OR_LEAVE(sc->opregs.dcbaa_p,
XHCI_GADDR_SIZE(sc->opregs.dcbaa_p), true, meta, ret, done);
/* rtsregs */
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.mfindex, meta, ret, done);
/* rtsregs.intrreg */
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.intrreg.iman, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.intrreg.imod, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.intrreg.erstsz, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.intrreg.rsvd, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.intrreg.erstba, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.intrreg.erdp, meta, ret, done);
/* rtsregs.erstba_p */
SNAPSHOT_GUEST2HOST_ADDR_OR_LEAVE(sc->rtsregs.erstba_p,
XHCI_GADDR_SIZE(sc->rtsregs.erstba_p), true, meta, ret, done);
/* rtsregs.erst_p */
SNAPSHOT_GUEST2HOST_ADDR_OR_LEAVE(sc->rtsregs.erst_p,
XHCI_GADDR_SIZE(sc->rtsregs.erst_p), true, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.er_deq_seg, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.er_enq_idx, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.er_enq_seg, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.er_events_cnt, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->rtsregs.event_pcs, meta, ret, done);
/* sanity checking */
for (i = 1; i <= XHCI_MAX_DEVS; i++) {
dev = XHCI_DEVINST_PTR(sc, i);
if (dev == NULL)
continue;
if (meta->op == VM_SNAPSHOT_SAVE)
restore_idx = i;
SNAPSHOT_VAR_OR_LEAVE(restore_idx, meta, ret, done);
/* check if the restored device (when restoring) is sane */
if (restore_idx != i) {
fprintf(stderr, "%s: idx not matching: actual: %d, "
"expected: %d\r\n", __func__, restore_idx, i);
ret = EINVAL;
goto done;
}
if (meta->op == VM_SNAPSHOT_SAVE) {
memset(dname, 0, sizeof(dname));
strncpy(dname, dev->dev_ue->ue_emu, sizeof(dname) - 1);
}
SNAPSHOT_BUF_OR_LEAVE(dname, sizeof(dname), meta, ret, done);
if (meta->op == VM_SNAPSHOT_RESTORE) {
dname[sizeof(dname) - 1] = '\0';
if (strcmp(dev->dev_ue->ue_emu, dname)) {
fprintf(stderr, "%s: device names mismatch: "
"actual: %s, expected: %s\r\n",
__func__, dname, dev->dev_ue->ue_emu);
ret = EINVAL;
goto done;
}
}
}
/* portregs */
for (i = 1; i <= XHCI_MAX_DEVS; i++) {
port = XHCI_PORTREG_PTR(sc, i);
dev = XHCI_DEVINST_PTR(sc, i);
if (dev == NULL)
continue;
SNAPSHOT_VAR_OR_LEAVE(port->portsc, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(port->portpmsc, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(port->portli, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(port->porthlpmc, meta, ret, done);
}
/* slots */
if (meta->op == VM_SNAPSHOT_SAVE)
pci_xhci_map_devs_slots(sc, maps);
for (i = 1; i <= XHCI_MAX_SLOTS; i++) {
SNAPSHOT_VAR_OR_LEAVE(maps[i], meta, ret, done);
if (meta->op == VM_SNAPSHOT_SAVE) {
dev = XHCI_SLOTDEV_PTR(sc, i);
} else if (meta->op == VM_SNAPSHOT_RESTORE) {
if (maps[i] != 0)
dev = XHCI_DEVINST_PTR(sc, maps[i]);
else
dev = NULL;
XHCI_SLOTDEV_PTR(sc, i) = dev;
} else {
/* error */
ret = EINVAL;
goto done;
}
if (dev == NULL)
continue;
SNAPSHOT_GUEST2HOST_ADDR_OR_LEAVE(dev->dev_ctx,
XHCI_GADDR_SIZE(dev->dev_ctx), true, meta, ret, done);
if (dev->dev_ctx != NULL) {
for (j = 1; j < XHCI_MAX_ENDPOINTS; j++) {
ret = pci_xhci_snapshot_ep(sc, dev, j, meta);
if (ret != 0)
goto done;
}
}
SNAPSHOT_VAR_OR_LEAVE(dev->dev_slotstate, meta, ret, done);
/* devices[i]->dev_sc */
dev->dev_ue->ue_snapshot(dev->dev_sc, meta);
/* devices[i]->hci */
SNAPSHOT_VAR_OR_LEAVE(dev->hci.hci_address, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(dev->hci.hci_port, meta, ret, done);
}
SNAPSHOT_VAR_OR_LEAVE(sc->usb2_port_start, meta, ret, done);
SNAPSHOT_VAR_OR_LEAVE(sc->usb3_port_start, meta, ret, done);
done:
return (ret);
}
#endif
static const struct pci_devemu pci_de_xhci = {
.pe_emu = "xhci",
.pe_init = pci_xhci_init,
.pe_legacy_config = pci_xhci_legacy_config,
.pe_barwrite = pci_xhci_write,
.pe_barread = pci_xhci_read,
#ifdef BHYVE_SNAPSHOT
.pe_snapshot = pci_xhci_snapshot,
#endif
};
PCI_EMUL_SET(pci_de_xhci);