dev/usb/xhci.c

1.62.2.2  pgoyette /*	$NetBSD: xhci.c,v 1.62.2.2 2017/03/20 06:57:39 pgoyette Exp $	*/
     1.1  jakllsch
     1.1  jakllsch /*
     1.1  jakllsch  * Copyright (c) 2013 Jonathan A. Kollasch
     1.1  jakllsch  * All rights reserved.
     1.1  jakllsch  *
     1.1  jakllsch  * Redistribution and use in source and binary forms, with or without
     1.1  jakllsch  * modification, are permitted provided that the following conditions
     1.1  jakllsch  * are met:
     1.1  jakllsch  * 1. Redistributions of source code must retain the above copyright
     1.1  jakllsch  *    notice, this list of conditions and the following disclaimer.
     1.1  jakllsch  * 2. Redistributions in binary form must reproduce the above copyright
     1.1  jakllsch  *    notice, this list of conditions and the following disclaimer in the
     1.1  jakllsch  *    documentation and/or other materials provided with the distribution.
     1.1  jakllsch  *
     1.1  jakllsch  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
     1.1  jakllsch  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
     1.1  jakllsch  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     1.1  jakllsch  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
     1.1  jakllsch  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
     1.1  jakllsch  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
     1.1  jakllsch  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
     1.1  jakllsch  * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
     1.1  jakllsch  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
     1.1  jakllsch  * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
     1.1  jakllsch  * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
     1.1  jakllsch  */
     1.1  jakllsch
    1.34     skrll /*
    1.41     skrll  * USB rev 2.0 and rev 3.1 specification
    1.41     skrll  *  http://www.usb.org/developers/docs/
    1.34     skrll  * xHCI rev 1.1 specification
    1.41     skrll  *  http://www.intel.com/technology/usb/spec.htm
    1.34     skrll  */
    1.34     skrll
     1.1  jakllsch #include <sys/cdefs.h>
1.62.2.2  pgoyette __KERNEL_RCSID(0, "$NetBSD: xhci.c,v 1.62.2.2 2017/03/20 06:57:39 pgoyette Exp $");
    1.27     skrll
    1.46     pooka #ifdef _KERNEL_OPT
    1.27     skrll #include "opt_usb.h"
    1.46     pooka #endif
     1.1  jakllsch
     1.1  jakllsch #include <sys/param.h>
     1.1  jakllsch #include <sys/systm.h>
     1.1  jakllsch #include <sys/kernel.h>
     1.1  jakllsch #include <sys/kmem.h>
     1.1  jakllsch #include <sys/device.h>
     1.1  jakllsch #include <sys/select.h>
     1.1  jakllsch #include <sys/proc.h>
     1.1  jakllsch #include <sys/queue.h>
     1.1  jakllsch #include <sys/mutex.h>
     1.1  jakllsch #include <sys/condvar.h>
     1.1  jakllsch #include <sys/bus.h>
     1.1  jakllsch #include <sys/cpu.h>
    1.27     skrll #include <sys/sysctl.h>
     1.1  jakllsch
     1.1  jakllsch #include <machine/endian.h>
     1.1  jakllsch
     1.1  jakllsch #include <dev/usb/usb.h>
     1.1  jakllsch #include <dev/usb/usbdi.h>
     1.1  jakllsch #include <dev/usb/usbdivar.h>
    1.34     skrll #include <dev/usb/usbdi_util.h>
    1.27     skrll #include <dev/usb/usbhist.h>
     1.1  jakllsch #include <dev/usb/usb_mem.h>
     1.1  jakllsch #include <dev/usb/usb_quirks.h>
     1.1  jakllsch
     1.1  jakllsch #include <dev/usb/xhcireg.h>
     1.1  jakllsch #include <dev/usb/xhcivar.h>
    1.34     skrll #include <dev/usb/usbroothub.h>
     1.1  jakllsch
    1.27     skrll
    1.27     skrll #ifdef USB_DEBUG
    1.27     skrll #ifndef XHCI_DEBUG
    1.27     skrll #define xhcidebug 0
    1.34     skrll #else /* !XHCI_DEBUG */
    1.27     skrll static int xhcidebug = 0;
    1.27     skrll
    1.27     skrll SYSCTL_SETUP(sysctl_hw_xhci_setup, "sysctl hw.xhci setup")
    1.27     skrll {
    1.27     skrll 	int err;
    1.27     skrll 	const struct sysctlnode *rnode;
    1.27     skrll 	const struct sysctlnode *cnode;
    1.27     skrll
    1.27     skrll 	err = sysctl_createv(clog, 0, NULL, &rnode,
    1.27     skrll 	    CTLFLAG_PERMANENT, CTLTYPE_NODE, "xhci",
    1.27     skrll 	    SYSCTL_DESCR("xhci global controls"),
    1.27     skrll 	    NULL, 0, NULL, 0, CTL_HW, CTL_CREATE, CTL_EOL);
    1.27     skrll
    1.27     skrll 	if (err)
    1.27     skrll 		goto fail;
    1.27     skrll
    1.27     skrll 	/* control debugging printfs */
    1.27     skrll 	err = sysctl_createv(clog, 0, &rnode, &cnode,
    1.27     skrll 	    CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
    1.27     skrll 	    "debug", SYSCTL_DESCR("Enable debugging output"),
    1.27     skrll 	    NULL, 0, &xhcidebug, sizeof(xhcidebug), CTL_CREATE, CTL_EOL);
    1.27     skrll 	if (err)
    1.27     skrll 		goto fail;
    1.27     skrll
    1.27     skrll 	return;
    1.27     skrll fail:
    1.27     skrll 	aprint_error("%s: sysctl_createv failed (err = %d)\n", __func__, err);
    1.27     skrll }
    1.27     skrll
    1.34     skrll #endif /* !XHCI_DEBUG */
    1.27     skrll #endif /* USB_DEBUG */
    1.27     skrll
    1.27     skrll #define DPRINTFN(N,FMT,A,B,C,D) USBHIST_LOGN(xhcidebug,N,FMT,A,B,C,D)
    1.27     skrll #define XHCIHIST_FUNC() USBHIST_FUNC()
    1.27     skrll #define XHCIHIST_CALLED(name) USBHIST_CALLED(xhcidebug)
     1.1  jakllsch
     1.1  jakllsch #define XHCI_DCI_SLOT 0
     1.1  jakllsch #define XHCI_DCI_EP_CONTROL 1
     1.1  jakllsch
     1.1  jakllsch #define XHCI_ICI_INPUT_CONTROL 0
     1.1  jakllsch
     1.1  jakllsch struct xhci_pipe {
     1.1  jakllsch 	struct usbd_pipe xp_pipe;
    1.34     skrll 	struct usb_task xp_async_task;
     1.1  jakllsch };
     1.1  jakllsch
     1.1  jakllsch #define XHCI_COMMAND_RING_TRBS 256
     1.1  jakllsch #define XHCI_EVENT_RING_TRBS 256
     1.1  jakllsch #define XHCI_EVENT_RING_SEGMENTS 1
     1.1  jakllsch #define XHCI_TRB_3_ED_BIT XHCI_TRB_3_ISP_BIT
     1.1  jakllsch
    1.34     skrll static usbd_status xhci_open(struct usbd_pipe *);
    1.34     skrll static void xhci_close_pipe(struct usbd_pipe *);
     1.1  jakllsch static int xhci_intr1(struct xhci_softc * const);
     1.1  jakllsch static void xhci_softintr(void *);
     1.1  jakllsch static void xhci_poll(struct usbd_bus *);
    1.34     skrll static struct usbd_xfer *xhci_allocx(struct usbd_bus *, unsigned int);
    1.34     skrll static void xhci_freex(struct usbd_bus *, struct usbd_xfer *);
     1.1  jakllsch static void xhci_get_lock(struct usbd_bus *, kmutex_t **);
    1.34     skrll static usbd_status xhci_new_device(device_t, struct usbd_bus *, int, int, int,
     1.1  jakllsch     struct usbd_port *);
    1.34     skrll static int xhci_roothub_ctrl(struct usbd_bus *, usb_device_request_t *,
    1.34     skrll     void *, int);
     1.1  jakllsch
    1.34     skrll static usbd_status xhci_configure_endpoint(struct usbd_pipe *);
    1.34     skrll //static usbd_status xhci_unconfigure_endpoint(struct usbd_pipe *);
    1.34     skrll static usbd_status xhci_reset_endpoint(struct usbd_pipe *);
    1.34     skrll static usbd_status xhci_stop_endpoint(struct usbd_pipe *);
     1.1  jakllsch
    1.55     skrll static void xhci_host_dequeue(struct xhci_ring * const);
    1.34     skrll static usbd_status xhci_set_dequeue(struct usbd_pipe *);
     1.1  jakllsch
     1.1  jakllsch static usbd_status xhci_do_command(struct xhci_softc * const,
     1.1  jakllsch     struct xhci_trb * const, int);
    1.34     skrll static usbd_status xhci_do_command_locked(struct xhci_softc * const,
    1.34     skrll     struct xhci_trb * const, int);
    1.48     skrll static usbd_status xhci_init_slot(struct usbd_device *, uint32_t);
    1.48     skrll static void xhci_free_slot(struct xhci_softc *, struct xhci_slot *, int, int);
    1.51     skrll static usbd_status xhci_set_address(struct usbd_device *, uint32_t, bool);
     1.1  jakllsch static usbd_status xhci_enable_slot(struct xhci_softc * const,
     1.1  jakllsch     uint8_t * const);
    1.34     skrll static usbd_status xhci_disable_slot(struct xhci_softc * const, uint8_t);
     1.1  jakllsch static usbd_status xhci_address_device(struct xhci_softc * const,
     1.1  jakllsch     uint64_t, uint8_t, bool);
    1.34     skrll static void xhci_set_dcba(struct xhci_softc * const, uint64_t, int);
     1.1  jakllsch static usbd_status xhci_update_ep0_mps(struct xhci_softc * const,
     1.1  jakllsch     struct xhci_slot * const, u_int);
     1.1  jakllsch static usbd_status xhci_ring_init(struct xhci_softc * const,
     1.1  jakllsch     struct xhci_ring * const, size_t, size_t);
     1.1  jakllsch static void xhci_ring_free(struct xhci_softc * const, struct xhci_ring * const);
     1.1  jakllsch
    1.51     skrll static void xhci_setup_ctx(struct usbd_pipe *);
    1.51     skrll static void xhci_setup_route(struct usbd_pipe *, uint32_t *);
    1.51     skrll static void xhci_setup_tthub(struct usbd_pipe *, uint32_t *);
    1.51     skrll static void xhci_setup_maxburst(struct usbd_pipe *, uint32_t *);
    1.51     skrll static uint32_t xhci_bival2ival(uint32_t, uint32_t);
    1.51     skrll
    1.34     skrll static void xhci_noop(struct usbd_pipe *);
     1.1  jakllsch
    1.34     skrll static usbd_status xhci_root_intr_transfer(struct usbd_xfer *);
    1.34     skrll static usbd_status xhci_root_intr_start(struct usbd_xfer *);
    1.34     skrll static void xhci_root_intr_abort(struct usbd_xfer *);
    1.34     skrll static void xhci_root_intr_close(struct usbd_pipe *);
    1.34     skrll static void xhci_root_intr_done(struct usbd_xfer *);
    1.34     skrll
    1.34     skrll static usbd_status xhci_device_ctrl_transfer(struct usbd_xfer *);
    1.34     skrll static usbd_status xhci_device_ctrl_start(struct usbd_xfer *);
    1.34     skrll static void xhci_device_ctrl_abort(struct usbd_xfer *);
    1.34     skrll static void xhci_device_ctrl_close(struct usbd_pipe *);
    1.34     skrll static void xhci_device_ctrl_done(struct usbd_xfer *);
    1.34     skrll
    1.34     skrll static usbd_status xhci_device_intr_transfer(struct usbd_xfer *);
    1.34     skrll static usbd_status xhci_device_intr_start(struct usbd_xfer *);
    1.34     skrll static void xhci_device_intr_abort(struct usbd_xfer *);
    1.34     skrll static void xhci_device_intr_close(struct usbd_pipe *);
    1.34     skrll static void xhci_device_intr_done(struct usbd_xfer *);
    1.34     skrll
    1.34     skrll static usbd_status xhci_device_bulk_transfer(struct usbd_xfer *);
    1.34     skrll static usbd_status xhci_device_bulk_start(struct usbd_xfer *);
    1.34     skrll static void xhci_device_bulk_abort(struct usbd_xfer *);
    1.34     skrll static void xhci_device_bulk_close(struct usbd_pipe *);
    1.34     skrll static void xhci_device_bulk_done(struct usbd_xfer *);
     1.1  jakllsch
     1.1  jakllsch static void xhci_timeout(void *);
     1.1  jakllsch static void xhci_timeout_task(void *);
     1.1  jakllsch
     1.1  jakllsch static const struct usbd_bus_methods xhci_bus_methods = {
    1.34     skrll 	.ubm_open = xhci_open,
    1.34     skrll 	.ubm_softint = xhci_softintr,
    1.34     skrll 	.ubm_dopoll = xhci_poll,
    1.34     skrll 	.ubm_allocx = xhci_allocx,
    1.34     skrll 	.ubm_freex = xhci_freex,
    1.34     skrll 	.ubm_getlock = xhci_get_lock,
    1.34     skrll 	.ubm_newdev = xhci_new_device,
    1.34     skrll 	.ubm_rhctrl = xhci_roothub_ctrl,
     1.1  jakllsch };
     1.1  jakllsch
     1.1  jakllsch static const struct usbd_pipe_methods xhci_root_intr_methods = {
    1.34     skrll 	.upm_transfer = xhci_root_intr_transfer,
    1.34     skrll 	.upm_start = xhci_root_intr_start,
    1.34     skrll 	.upm_abort = xhci_root_intr_abort,
    1.34     skrll 	.upm_close = xhci_root_intr_close,
    1.34     skrll 	.upm_cleartoggle = xhci_noop,
    1.34     skrll 	.upm_done = xhci_root_intr_done,
     1.1  jakllsch };
     1.1  jakllsch
     1.1  jakllsch
     1.1  jakllsch static const struct usbd_pipe_methods xhci_device_ctrl_methods = {
    1.34     skrll 	.upm_transfer = xhci_device_ctrl_transfer,
    1.34     skrll 	.upm_start = xhci_device_ctrl_start,
    1.34     skrll 	.upm_abort = xhci_device_ctrl_abort,
    1.34     skrll 	.upm_close = xhci_device_ctrl_close,
    1.34     skrll 	.upm_cleartoggle = xhci_noop,
    1.34     skrll 	.upm_done = xhci_device_ctrl_done,
     1.1  jakllsch };
     1.1  jakllsch
     1.1  jakllsch static const struct usbd_pipe_methods xhci_device_isoc_methods = {
    1.34     skrll 	.upm_cleartoggle = xhci_noop,
     1.1  jakllsch };
     1.1  jakllsch
     1.1  jakllsch static const struct usbd_pipe_methods xhci_device_bulk_methods = {
    1.34     skrll 	.upm_transfer = xhci_device_bulk_transfer,
    1.34     skrll 	.upm_start = xhci_device_bulk_start,
    1.34     skrll 	.upm_abort = xhci_device_bulk_abort,
    1.34     skrll 	.upm_close = xhci_device_bulk_close,
    1.34     skrll 	.upm_cleartoggle = xhci_noop,
    1.34     skrll 	.upm_done = xhci_device_bulk_done,
     1.1  jakllsch };
     1.1  jakllsch
     1.1  jakllsch static const struct usbd_pipe_methods xhci_device_intr_methods = {
    1.34     skrll 	.upm_transfer = xhci_device_intr_transfer,
    1.34     skrll 	.upm_start = xhci_device_intr_start,
    1.34     skrll 	.upm_abort = xhci_device_intr_abort,
    1.34     skrll 	.upm_close = xhci_device_intr_close,
    1.34     skrll 	.upm_cleartoggle = xhci_noop,
    1.34     skrll 	.upm_done = xhci_device_intr_done,
     1.1  jakllsch };
     1.1  jakllsch
     1.1  jakllsch static inline uint32_t
    1.34     skrll xhci_read_1(const struct xhci_softc * const sc, bus_size_t offset)
    1.34     skrll {
    1.34     skrll 	return bus_space_read_1(sc->sc_iot, sc->sc_ioh, offset);
    1.34     skrll }
    1.34     skrll
    1.34     skrll static inline uint32_t
     1.1  jakllsch xhci_read_4(const struct xhci_softc * const sc, bus_size_t offset)
     1.1  jakllsch {
     1.1  jakllsch 	return bus_space_read_4(sc->sc_iot, sc->sc_ioh, offset);
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll static inline void
    1.34     skrll xhci_write_1(const struct xhci_softc * const sc, bus_size_t offset,
    1.34     skrll     uint32_t value)
    1.34     skrll {
    1.34     skrll 	bus_space_write_1(sc->sc_iot, sc->sc_ioh, offset, value);
    1.34     skrll }
    1.34     skrll
     1.4       apb #if 0 /* unused */
     1.1  jakllsch static inline void
     1.1  jakllsch xhci_write_4(const struct xhci_softc * const sc, bus_size_t offset,
     1.1  jakllsch     uint32_t value)
     1.1  jakllsch {
     1.1  jakllsch 	bus_space_write_4(sc->sc_iot, sc->sc_ioh, offset, value);
     1.1  jakllsch }
     1.4       apb #endif /* unused */
     1.1  jakllsch
     1.1  jakllsch static inline uint32_t
     1.1  jakllsch xhci_cap_read_4(const struct xhci_softc * const sc, bus_size_t offset)
     1.1  jakllsch {
     1.1  jakllsch 	return bus_space_read_4(sc->sc_iot, sc->sc_cbh, offset);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline uint32_t
     1.1  jakllsch xhci_op_read_4(const struct xhci_softc * const sc, bus_size_t offset)
     1.1  jakllsch {
     1.1  jakllsch 	return bus_space_read_4(sc->sc_iot, sc->sc_obh, offset);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline void
     1.1  jakllsch xhci_op_write_4(const struct xhci_softc * const sc, bus_size_t offset,
     1.1  jakllsch     uint32_t value)
     1.1  jakllsch {
     1.1  jakllsch 	bus_space_write_4(sc->sc_iot, sc->sc_obh, offset, value);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline uint64_t
     1.1  jakllsch xhci_op_read_8(const struct xhci_softc * const sc, bus_size_t offset)
     1.1  jakllsch {
     1.1  jakllsch 	uint64_t value;
     1.1  jakllsch
     1.1  jakllsch 	if (sc->sc_ac64) {
     1.1  jakllsch #ifdef XHCI_USE_BUS_SPACE_8
     1.1  jakllsch 		value = bus_space_read_8(sc->sc_iot, sc->sc_obh, offset);
     1.1  jakllsch #else
     1.1  jakllsch 		value = bus_space_read_4(sc->sc_iot, sc->sc_obh, offset);
     1.1  jakllsch 		value |= (uint64_t)bus_space_read_4(sc->sc_iot, sc->sc_obh,
     1.1  jakllsch 		    offset + 4) << 32;
     1.1  jakllsch #endif
     1.1  jakllsch 	} else {
     1.1  jakllsch 		value = bus_space_read_4(sc->sc_iot, sc->sc_obh, offset);
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	return value;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline void
     1.1  jakllsch xhci_op_write_8(const struct xhci_softc * const sc, bus_size_t offset,
     1.1  jakllsch     uint64_t value)
     1.1  jakllsch {
     1.1  jakllsch 	if (sc->sc_ac64) {
     1.1  jakllsch #ifdef XHCI_USE_BUS_SPACE_8
     1.1  jakllsch 		bus_space_write_8(sc->sc_iot, sc->sc_obh, offset, value);
     1.1  jakllsch #else
     1.1  jakllsch 		bus_space_write_4(sc->sc_iot, sc->sc_obh, offset + 0,
     1.1  jakllsch 		    (value >> 0) & 0xffffffff);
     1.1  jakllsch 		bus_space_write_4(sc->sc_iot, sc->sc_obh, offset + 4,
     1.1  jakllsch 		    (value >> 32) & 0xffffffff);
     1.1  jakllsch #endif
     1.1  jakllsch 	} else {
     1.1  jakllsch 		bus_space_write_4(sc->sc_iot, sc->sc_obh, offset, value);
     1.1  jakllsch 	}
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline uint32_t
     1.1  jakllsch xhci_rt_read_4(const struct xhci_softc * const sc, bus_size_t offset)
     1.1  jakllsch {
     1.1  jakllsch 	return bus_space_read_4(sc->sc_iot, sc->sc_rbh, offset);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline void
     1.1  jakllsch xhci_rt_write_4(const struct xhci_softc * const sc, bus_size_t offset,
     1.1  jakllsch     uint32_t value)
     1.1  jakllsch {
     1.1  jakllsch 	bus_space_write_4(sc->sc_iot, sc->sc_rbh, offset, value);
     1.1  jakllsch }
     1.1  jakllsch
     1.4       apb #if 0 /* unused */
     1.1  jakllsch static inline uint64_t
     1.1  jakllsch xhci_rt_read_8(const struct xhci_softc * const sc, bus_size_t offset)
     1.1  jakllsch {
     1.1  jakllsch 	uint64_t value;
     1.1  jakllsch
     1.1  jakllsch 	if (sc->sc_ac64) {
     1.1  jakllsch #ifdef XHCI_USE_BUS_SPACE_8
     1.1  jakllsch 		value = bus_space_read_8(sc->sc_iot, sc->sc_rbh, offset);
     1.1  jakllsch #else
     1.1  jakllsch 		value = bus_space_read_4(sc->sc_iot, sc->sc_rbh, offset);
     1.1  jakllsch 		value |= (uint64_t)bus_space_read_4(sc->sc_iot, sc->sc_rbh,
     1.1  jakllsch 		    offset + 4) << 32;
     1.1  jakllsch #endif
     1.1  jakllsch 	} else {
     1.1  jakllsch 		value = bus_space_read_4(sc->sc_iot, sc->sc_rbh, offset);
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	return value;
     1.1  jakllsch }
     1.4       apb #endif /* unused */
     1.1  jakllsch
     1.1  jakllsch static inline void
     1.1  jakllsch xhci_rt_write_8(const struct xhci_softc * const sc, bus_size_t offset,
     1.1  jakllsch     uint64_t value)
     1.1  jakllsch {
     1.1  jakllsch 	if (sc->sc_ac64) {
     1.1  jakllsch #ifdef XHCI_USE_BUS_SPACE_8
     1.1  jakllsch 		bus_space_write_8(sc->sc_iot, sc->sc_rbh, offset, value);
     1.1  jakllsch #else
     1.1  jakllsch 		bus_space_write_4(sc->sc_iot, sc->sc_rbh, offset + 0,
     1.1  jakllsch 		    (value >> 0) & 0xffffffff);
     1.1  jakllsch 		bus_space_write_4(sc->sc_iot, sc->sc_rbh, offset + 4,
     1.1  jakllsch 		    (value >> 32) & 0xffffffff);
     1.1  jakllsch #endif
     1.1  jakllsch 	} else {
     1.1  jakllsch 		bus_space_write_4(sc->sc_iot, sc->sc_rbh, offset, value);
     1.1  jakllsch 	}
     1.1  jakllsch }
     1.1  jakllsch
     1.4       apb #if 0 /* unused */
     1.1  jakllsch static inline uint32_t
     1.1  jakllsch xhci_db_read_4(const struct xhci_softc * const sc, bus_size_t offset)
     1.1  jakllsch {
     1.1  jakllsch 	return bus_space_read_4(sc->sc_iot, sc->sc_dbh, offset);
     1.1  jakllsch }
     1.4       apb #endif /* unused */
     1.1  jakllsch
     1.1  jakllsch static inline void
     1.1  jakllsch xhci_db_write_4(const struct xhci_softc * const sc, bus_size_t offset,
     1.1  jakllsch     uint32_t value)
     1.1  jakllsch {
     1.1  jakllsch 	bus_space_write_4(sc->sc_iot, sc->sc_dbh, offset, value);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch /* --- */
     1.1  jakllsch
     1.1  jakllsch static inline uint8_t
     1.1  jakllsch xhci_ep_get_type(usb_endpoint_descriptor_t * const ed)
     1.1  jakllsch {
    1.34     skrll 	u_int eptype = 0;
     1.1  jakllsch
     1.1  jakllsch 	switch (UE_GET_XFERTYPE(ed->bmAttributes)) {
     1.1  jakllsch 	case UE_CONTROL:
     1.1  jakllsch 		eptype = 0x0;
     1.1  jakllsch 		break;
     1.1  jakllsch 	case UE_ISOCHRONOUS:
     1.1  jakllsch 		eptype = 0x1;
     1.1  jakllsch 		break;
     1.1  jakllsch 	case UE_BULK:
     1.1  jakllsch 		eptype = 0x2;
     1.1  jakllsch 		break;
     1.1  jakllsch 	case UE_INTERRUPT:
     1.1  jakllsch 		eptype = 0x3;
     1.1  jakllsch 		break;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	if ((UE_GET_XFERTYPE(ed->bmAttributes) == UE_CONTROL) ||
     1.1  jakllsch 	    (UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN))
     1.1  jakllsch 		return eptype | 0x4;
     1.1  jakllsch 	else
     1.1  jakllsch 		return eptype;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static u_int
     1.1  jakllsch xhci_ep_get_dci(usb_endpoint_descriptor_t * const ed)
     1.1  jakllsch {
     1.1  jakllsch 	/* xHCI 1.0 section 4.5.1 */
     1.1  jakllsch 	u_int epaddr = UE_GET_ADDR(ed->bEndpointAddress);
     1.1  jakllsch 	u_int in = 0;
     1.1  jakllsch
     1.1  jakllsch 	if ((UE_GET_XFERTYPE(ed->bmAttributes) == UE_CONTROL) ||
     1.1  jakllsch 	    (UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN))
     1.1  jakllsch 		in = 1;
     1.1  jakllsch
     1.1  jakllsch 	return epaddr * 2 + in;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline u_int
     1.1  jakllsch xhci_dci_to_ici(const u_int i)
     1.1  jakllsch {
     1.1  jakllsch 	return i + 1;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline void *
     1.1  jakllsch xhci_slot_get_dcv(struct xhci_softc * const sc, struct xhci_slot * const xs,
     1.1  jakllsch     const u_int dci)
     1.1  jakllsch {
     1.1  jakllsch 	return KERNADDR(&xs->xs_dc_dma, sc->sc_ctxsz * dci);
     1.1  jakllsch }
     1.1  jakllsch
     1.4       apb #if 0 /* unused */
     1.1  jakllsch static inline bus_addr_t
     1.1  jakllsch xhci_slot_get_dcp(struct xhci_softc * const sc, struct xhci_slot * const xs,
     1.1  jakllsch     const u_int dci)
     1.1  jakllsch {
     1.1  jakllsch 	return DMAADDR(&xs->xs_dc_dma, sc->sc_ctxsz * dci);
     1.1  jakllsch }
     1.4       apb #endif /* unused */
     1.1  jakllsch
     1.1  jakllsch static inline void *
     1.1  jakllsch xhci_slot_get_icv(struct xhci_softc * const sc, struct xhci_slot * const xs,
     1.1  jakllsch     const u_int ici)
     1.1  jakllsch {
     1.1  jakllsch 	return KERNADDR(&xs->xs_ic_dma, sc->sc_ctxsz * ici);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline bus_addr_t
     1.1  jakllsch xhci_slot_get_icp(struct xhci_softc * const sc, struct xhci_slot * const xs,
     1.1  jakllsch     const u_int ici)
     1.1  jakllsch {
     1.1  jakllsch 	return DMAADDR(&xs->xs_ic_dma, sc->sc_ctxsz * ici);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline struct xhci_trb *
     1.1  jakllsch xhci_ring_trbv(struct xhci_ring * const xr, u_int idx)
     1.1  jakllsch {
     1.1  jakllsch 	return KERNADDR(&xr->xr_dma, XHCI_TRB_SIZE * idx);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline bus_addr_t
     1.1  jakllsch xhci_ring_trbp(struct xhci_ring * const xr, u_int idx)
     1.1  jakllsch {
     1.1  jakllsch 	return DMAADDR(&xr->xr_dma, XHCI_TRB_SIZE * idx);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static inline void
     1.1  jakllsch xhci_trb_put(struct xhci_trb * const trb, uint64_t parameter, uint32_t status,
     1.1  jakllsch     uint32_t control)
     1.1  jakllsch {
    1.34     skrll 	trb->trb_0 = htole64(parameter);
    1.34     skrll 	trb->trb_2 = htole32(status);
    1.34     skrll 	trb->trb_3 = htole32(control);
     1.1  jakllsch }
     1.1  jakllsch
    1.40     skrll static int
    1.40     skrll xhci_trb_get_idx(struct xhci_ring *xr, uint64_t trb_0, int *idx)
    1.40     skrll {
    1.40     skrll 	/* base address of TRBs */
    1.40     skrll 	bus_addr_t trbp = xhci_ring_trbp(xr, 0);
    1.40     skrll
    1.40     skrll 	/* trb_0 range sanity check */
    1.40     skrll 	if (trb_0 == 0 || trb_0 < trbp ||
    1.40     skrll 	    (trb_0 - trbp) % sizeof(struct xhci_trb) != 0 ||
    1.40     skrll 	    (trb_0 - trbp) / sizeof(struct xhci_trb) >= xr->xr_ntrb) {
    1.40     skrll 		return 1;
    1.40     skrll 	}
    1.40     skrll 	*idx = (trb_0 - trbp) / sizeof(struct xhci_trb);
    1.40     skrll 	return 0;
    1.40     skrll }
    1.40     skrll
1.62.2.1  pgoyette static unsigned int
1.62.2.1  pgoyette xhci_get_epstate(struct xhci_softc * const sc, struct xhci_slot * const xs,
1.62.2.1  pgoyette     u_int dci)
1.62.2.1  pgoyette {
1.62.2.1  pgoyette 	uint32_t *cp;
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	usb_syncmem(&xs->xs_dc_dma, 0, sc->sc_pgsz, BUS_DMASYNC_POSTREAD);
1.62.2.1  pgoyette 	cp = xhci_slot_get_dcv(sc, xs, dci);
1.62.2.1  pgoyette 	return XHCI_EPCTX_0_EPSTATE_GET(le32toh(cp[0]));
1.62.2.1  pgoyette }
1.62.2.1  pgoyette
1.62.2.2  pgoyette static inline unsigned int
1.62.2.2  pgoyette xhci_ctlrport2bus(struct xhci_softc * const sc, unsigned int ctlrport)
1.62.2.2  pgoyette {
1.62.2.2  pgoyette 	const unsigned int port = ctlrport - 1;
1.62.2.2  pgoyette 	const uint8_t bit = __BIT(port % NBBY);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	return __SHIFTOUT(sc->sc_ctlrportbus[port / NBBY], bit);
1.62.2.2  pgoyette }
1.62.2.2  pgoyette
1.62.2.2  pgoyette /*
1.62.2.2  pgoyette  * Return the roothub port for a controller port.  Both are 1..n.
1.62.2.2  pgoyette  */
1.62.2.2  pgoyette static inline unsigned int
1.62.2.2  pgoyette xhci_ctlrport2rhport(struct xhci_softc * const sc, unsigned int ctrlport)
1.62.2.2  pgoyette {
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	return sc->sc_ctlrportmap[ctrlport - 1];
1.62.2.2  pgoyette }
1.62.2.2  pgoyette
1.62.2.2  pgoyette /*
1.62.2.2  pgoyette  * Return the controller port for a bus roothub port.  Both are 1..n.
1.62.2.2  pgoyette  */
1.62.2.2  pgoyette static inline unsigned int
1.62.2.2  pgoyette xhci_rhport2ctlrport(struct xhci_softc * const sc, unsigned int bn,
1.62.2.2  pgoyette     unsigned int rhport)
1.62.2.2  pgoyette {
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	return sc->sc_rhportmap[bn][rhport - 1];
1.62.2.2  pgoyette }
1.62.2.2  pgoyette
     1.1  jakllsch /* --- */
     1.1  jakllsch
     1.1  jakllsch void
     1.1  jakllsch xhci_childdet(device_t self, device_t child)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_softc * const sc = device_private(self);
     1.1  jakllsch
     1.1  jakllsch 	KASSERT(sc->sc_child == child);
     1.1  jakllsch 	if (child == sc->sc_child)
     1.1  jakllsch 		sc->sc_child = NULL;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch int
     1.1  jakllsch xhci_detach(struct xhci_softc *sc, int flags)
     1.1  jakllsch {
     1.1  jakllsch 	int rv = 0;
     1.1  jakllsch
1.62.2.2  pgoyette 	if (sc->sc_child2 != NULL) {
1.62.2.2  pgoyette 		rv = config_detach(sc->sc_child2, flags);
1.62.2.2  pgoyette 		if (rv != 0)
1.62.2.2  pgoyette 			return rv;
1.62.2.2  pgoyette 	}
     1.1  jakllsch
1.62.2.2  pgoyette 	if (sc->sc_child != NULL) {
1.62.2.2  pgoyette 		rv = config_detach(sc->sc_child, flags);
1.62.2.2  pgoyette 		if (rv != 0)
1.62.2.2  pgoyette 			return rv;
1.62.2.2  pgoyette 	}
     1.1  jakllsch
     1.1  jakllsch 	/* XXX unconfigure/free slots */
     1.1  jakllsch
     1.1  jakllsch 	/* verify: */
     1.1  jakllsch 	xhci_rt_write_4(sc, XHCI_IMAN(0), 0);
     1.1  jakllsch 	xhci_op_write_4(sc, XHCI_USBCMD, 0);
     1.1  jakllsch 	/* do we need to wait for stop? */
     1.1  jakllsch
     1.1  jakllsch 	xhci_op_write_8(sc, XHCI_CRCR, 0);
     1.1  jakllsch 	xhci_ring_free(sc, &sc->sc_cr);
     1.1  jakllsch 	cv_destroy(&sc->sc_command_cv);
1.62.2.2  pgoyette 	cv_destroy(&sc->sc_cmdbusy_cv);
     1.1  jakllsch
     1.1  jakllsch 	xhci_rt_write_4(sc, XHCI_ERSTSZ(0), 0);
     1.1  jakllsch 	xhci_rt_write_8(sc, XHCI_ERSTBA(0), 0);
     1.1  jakllsch 	xhci_rt_write_8(sc, XHCI_ERDP(0), 0|XHCI_ERDP_LO_BUSY);
     1.1  jakllsch 	xhci_ring_free(sc, &sc->sc_er);
     1.1  jakllsch
     1.1  jakllsch 	usb_freemem(&sc->sc_bus, &sc->sc_eventst_dma);
     1.1  jakllsch
     1.1  jakllsch 	xhci_op_write_8(sc, XHCI_DCBAAP, 0);
     1.1  jakllsch 	usb_freemem(&sc->sc_bus, &sc->sc_dcbaa_dma);
     1.1  jakllsch
     1.1  jakllsch 	kmem_free(sc->sc_slots, sizeof(*sc->sc_slots) * sc->sc_maxslots);
     1.1  jakllsch
1.62.2.2  pgoyette 	kmem_free(sc->sc_ctlrportbus,
1.62.2.2  pgoyette 	    howmany(sc->sc_maxports * sizeof(uint8_t), NBBY));
1.62.2.2  pgoyette 	kmem_free(sc->sc_ctlrportmap, sc->sc_maxports * sizeof(int));
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	for (size_t j = 0; j < __arraycount(sc->sc_rhportmap); j++) {
1.62.2.2  pgoyette 		kmem_free(sc->sc_rhportmap[j], sc->sc_maxports * sizeof(int));
1.62.2.2  pgoyette 	}
1.62.2.2  pgoyette
     1.1  jakllsch 	mutex_destroy(&sc->sc_lock);
     1.1  jakllsch 	mutex_destroy(&sc->sc_intr_lock);
     1.1  jakllsch
     1.1  jakllsch 	pool_cache_destroy(sc->sc_xferpool);
     1.1  jakllsch
     1.1  jakllsch 	return rv;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch int
     1.1  jakllsch xhci_activate(device_t self, enum devact act)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_softc * const sc = device_private(self);
     1.1  jakllsch
     1.1  jakllsch 	switch (act) {
     1.1  jakllsch 	case DVACT_DEACTIVATE:
     1.1  jakllsch 		sc->sc_dying = true;
     1.1  jakllsch 		return 0;
     1.1  jakllsch 	default:
     1.1  jakllsch 		return EOPNOTSUPP;
     1.1  jakllsch 	}
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch bool
     1.1  jakllsch xhci_suspend(device_t dv, const pmf_qual_t *qual)
     1.1  jakllsch {
     1.1  jakllsch 	return false;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch bool
     1.1  jakllsch xhci_resume(device_t dv, const pmf_qual_t *qual)
     1.1  jakllsch {
     1.1  jakllsch 	return false;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch bool
     1.1  jakllsch xhci_shutdown(device_t self, int flags)
     1.1  jakllsch {
     1.1  jakllsch 	return false;
     1.1  jakllsch }
     1.1  jakllsch
    1.40     skrll static int
    1.40     skrll xhci_hc_reset(struct xhci_softc * const sc)
    1.40     skrll {
    1.40     skrll 	uint32_t usbcmd, usbsts;
    1.40     skrll 	int i;
    1.40     skrll
    1.40     skrll 	/* Check controller not ready */
    1.42     skrll 	for (i = 0; i < XHCI_WAIT_CNR; i++) {
    1.40     skrll 		usbsts = xhci_op_read_4(sc, XHCI_USBSTS);
    1.40     skrll 		if ((usbsts & XHCI_STS_CNR) == 0)
    1.40     skrll 			break;
    1.40     skrll 		usb_delay_ms(&sc->sc_bus, 1);
    1.40     skrll 	}
    1.42     skrll 	if (i >= XHCI_WAIT_CNR) {
    1.40     skrll 		aprint_error_dev(sc->sc_dev, "controller not ready timeout\n");
    1.40     skrll 		return EIO;
    1.40     skrll 	}
    1.40     skrll
    1.40     skrll 	/* Halt controller */
    1.40     skrll 	usbcmd = 0;
    1.40     skrll 	xhci_op_write_4(sc, XHCI_USBCMD, usbcmd);
    1.40     skrll 	usb_delay_ms(&sc->sc_bus, 1);
    1.40     skrll
    1.40     skrll 	/* Reset controller */
    1.40     skrll 	usbcmd = XHCI_CMD_HCRST;
    1.40     skrll 	xhci_op_write_4(sc, XHCI_USBCMD, usbcmd);
    1.42     skrll 	for (i = 0; i < XHCI_WAIT_HCRST; i++) {
    1.40     skrll 		usbcmd = xhci_op_read_4(sc, XHCI_USBCMD);
    1.40     skrll 		if ((usbcmd & XHCI_CMD_HCRST) == 0)
    1.40     skrll 			break;
    1.40     skrll 		usb_delay_ms(&sc->sc_bus, 1);
    1.40     skrll 	}
    1.42     skrll 	if (i >= XHCI_WAIT_HCRST) {
    1.40     skrll 		aprint_error_dev(sc->sc_dev, "host controller reset timeout\n");
    1.40     skrll 		return EIO;
    1.40     skrll 	}
    1.40     skrll
    1.40     skrll 	/* Check controller not ready */
    1.42     skrll 	for (i = 0; i < XHCI_WAIT_CNR; i++) {
    1.40     skrll 		usbsts = xhci_op_read_4(sc, XHCI_USBSTS);
    1.40     skrll 		if ((usbsts & XHCI_STS_CNR) == 0)
    1.40     skrll 			break;
    1.40     skrll 		usb_delay_ms(&sc->sc_bus, 1);
    1.40     skrll 	}
    1.42     skrll 	if (i >= XHCI_WAIT_CNR) {
    1.40     skrll 		aprint_error_dev(sc->sc_dev,
    1.40     skrll 		    "controller not ready timeout after reset\n");
    1.40     skrll 		return EIO;
    1.40     skrll 	}
    1.40     skrll
    1.40     skrll 	return 0;
    1.40     skrll }
    1.40     skrll
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch hexdump(const char *msg, const void *base, size_t len)
     1.1  jakllsch {
     1.1  jakllsch #if 0
     1.1  jakllsch 	size_t cnt;
     1.1  jakllsch 	const uint32_t *p;
     1.1  jakllsch 	extern paddr_t vtophys(vaddr_t);
     1.1  jakllsch
     1.1  jakllsch 	p = base;
     1.1  jakllsch 	cnt = 0;
     1.1  jakllsch
     1.1  jakllsch 	printf("*** %s (%zu bytes @ %p %p)\n", msg, len, base,
     1.1  jakllsch 	    (void *)vtophys((vaddr_t)base));
     1.1  jakllsch
     1.1  jakllsch 	while (cnt < len) {
     1.1  jakllsch 		if (cnt % 16 == 0)
     1.1  jakllsch 			printf("%p: ", p);
     1.1  jakllsch 		else if (cnt % 8 == 0)
     1.1  jakllsch 			printf(" |");
     1.1  jakllsch 		printf(" %08x", *p++);
     1.1  jakllsch 		cnt += 4;
     1.1  jakllsch 		if (cnt % 16 == 0)
     1.1  jakllsch 			printf("\n");
     1.1  jakllsch 	}
    1.44     skrll 	if (cnt % 16 != 0)
    1.44     skrll 		printf("\n");
     1.1  jakllsch #endif
     1.1  jakllsch }
     1.1  jakllsch
1.62.2.2  pgoyette /* 7.2 xHCI Support Protocol Capability */
1.62.2.2  pgoyette static void
1.62.2.2  pgoyette xhci_id_protocols(struct xhci_softc *sc, bus_size_t ecp)
1.62.2.2  pgoyette {
1.62.2.2  pgoyette 	/* XXX Cache this lot */
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	const uint32_t w0 = xhci_read_4(sc, ecp);
1.62.2.2  pgoyette 	const uint32_t w4 = xhci_read_4(sc, ecp + 4);
1.62.2.2  pgoyette 	const uint32_t w8 = xhci_read_4(sc, ecp + 8);
1.62.2.2  pgoyette 	const uint32_t wc = xhci_read_4(sc, ecp + 0xc);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	aprint_debug_dev(sc->sc_dev,
1.62.2.2  pgoyette 	    " SP: %08x %08x %08x %08x\n", w0, w4, w8, wc);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	if (w4 != XHCI_XECP_USBID)
1.62.2.2  pgoyette 		return;
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	const int major = XHCI_XECP_SP_W0_MAJOR(w0);
1.62.2.2  pgoyette 	const int minor = XHCI_XECP_SP_W0_MINOR(w0);
1.62.2.2  pgoyette 	const uint8_t cpo = XHCI_XECP_SP_W8_CPO(w8);
1.62.2.2  pgoyette 	const uint8_t cpc = XHCI_XECP_SP_W8_CPC(w8);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	const uint16_t mm = __SHIFTOUT(w0, __BITS(31, 16));
1.62.2.2  pgoyette 	switch (mm) {
1.62.2.2  pgoyette 	case 0x0200:
1.62.2.2  pgoyette 	case 0x0300:
1.62.2.2  pgoyette 	case 0x0301:
1.62.2.2  pgoyette 		aprint_debug_dev(sc->sc_dev, " %s ports %d - %d\n",
1.62.2.2  pgoyette 		    major == 3 ? "ss" : "hs", cpo, cpo + cpc -1);
1.62.2.2  pgoyette 		break;
1.62.2.2  pgoyette 	default:
1.62.2.2  pgoyette 		aprint_debug_dev(sc->sc_dev, " unknown major/minor (%d/%d)\n",
1.62.2.2  pgoyette 		    major, minor);
1.62.2.2  pgoyette 		return;
1.62.2.2  pgoyette 	}
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	const size_t bus = (major == 3) ? 0 : 1;
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	/* Index arrays with 0..n-1 where ports are numbered 1..n */
1.62.2.2  pgoyette 	for (size_t cp = cpo - 1; cp < cpo + cpc - 1; cp++) {
1.62.2.2  pgoyette 		if (sc->sc_ctlrportmap[cp] != 0) {
1.62.2.2  pgoyette 			aprint_error_dev(sc->sc_dev, "contoller port %zu "
1.62.2.2  pgoyette 			    "already assigned", cp);
1.62.2.2  pgoyette 			continue;
1.62.2.2  pgoyette 		}
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		sc->sc_ctlrportbus[cp / NBBY] |=
1.62.2.2  pgoyette 		    bus == 0 ? 0 : __BIT(cp % NBBY);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		const size_t rhp = sc->sc_rhportcount[bus]++;
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		KASSERTMSG(sc->sc_rhportmap[bus][rhp] == 0,
1.62.2.2  pgoyette 		    "bus %zu rhp %zu is %d", bus, rhp,
1.62.2.2  pgoyette 		    sc->sc_rhportmap[bus][rhp]);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		sc->sc_rhportmap[bus][rhp] = cp + 1;
1.62.2.2  pgoyette 		sc->sc_ctlrportmap[cp] = rhp + 1;
1.62.2.2  pgoyette 	}
1.62.2.2  pgoyette }
1.62.2.2  pgoyette
    1.40     skrll /* Process extended capabilities */
    1.40     skrll static void
    1.40     skrll xhci_ecp(struct xhci_softc *sc, uint32_t hcc)
    1.40     skrll {
    1.40     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.40     skrll
1.62.2.2  pgoyette 	bus_size_t ecp = XHCI_HCC_XECP(hcc) * 4;
    1.40     skrll 	while (ecp != 0) {
1.62.2.2  pgoyette 		uint32_t ecr = xhci_read_4(sc, ecp);
1.62.2.2  pgoyette 		aprint_debug_dev(sc->sc_dev, "ECR: 0x%08x\n", ecr);
    1.40     skrll 		switch (XHCI_XECP_ID(ecr)) {
    1.40     skrll 		case XHCI_ID_PROTOCOLS: {
1.62.2.2  pgoyette 			xhci_id_protocols(sc, ecp);
    1.40     skrll 			break;
    1.40     skrll 		}
    1.40     skrll 		case XHCI_ID_USB_LEGACY: {
    1.40     skrll 			uint8_t bios_sem;
    1.40     skrll
    1.40     skrll 			/* Take host controller ownership from BIOS */
    1.40     skrll 			bios_sem = xhci_read_1(sc, ecp + XHCI_XECP_BIOS_SEM);
    1.40     skrll 			if (bios_sem) {
    1.40     skrll 				/* sets xHCI to be owned by OS */
    1.40     skrll 				xhci_write_1(sc, ecp + XHCI_XECP_OS_SEM, 1);
    1.40     skrll 				aprint_debug_dev(sc->sc_dev,
    1.40     skrll 				    "waiting for BIOS to give up control\n");
    1.40     skrll 				for (int i = 0; i < 5000; i++) {
    1.40     skrll 					bios_sem = xhci_read_1(sc, ecp +
    1.40     skrll 					    XHCI_XECP_BIOS_SEM);
    1.40     skrll 					if (bios_sem == 0)
    1.40     skrll 						break;
    1.40     skrll 					DELAY(1000);
    1.40     skrll 				}
    1.40     skrll 				if (bios_sem) {
    1.40     skrll 					aprint_error_dev(sc->sc_dev,
    1.40     skrll 					    "timed out waiting for BIOS\n");
    1.40     skrll 				}
    1.40     skrll 			}
    1.40     skrll 			break;
    1.40     skrll 		}
    1.40     skrll 		default:
    1.40     skrll 			break;
    1.40     skrll 		}
    1.40     skrll 		ecr = xhci_read_4(sc, ecp);
    1.40     skrll 		if (XHCI_XECP_NEXT(ecr) == 0) {
    1.40     skrll 			ecp = 0;
    1.40     skrll 		} else {
    1.40     skrll 			ecp += XHCI_XECP_NEXT(ecr) * 4;
    1.40     skrll 		}
    1.40     skrll 	}
    1.40     skrll }
    1.40     skrll
    1.34     skrll #define XHCI_HCCPREV1_BITS	\
    1.34     skrll 	"\177\020"	/* New bitmask */			\
    1.34     skrll 	"f\020\020XECP\0"					\
    1.34     skrll 	"f\014\4MAXPSA\0"					\
    1.34     skrll 	"b\013CFC\0"						\
    1.34     skrll 	"b\012SEC\0"						\
    1.34     skrll 	"b\011SBD\0"						\
    1.34     skrll 	"b\010FSE\0"						\
    1.34     skrll 	"b\7NSS\0"						\
    1.34     skrll 	"b\6LTC\0"						\
    1.34     skrll 	"b\5LHRC\0"						\
    1.34     skrll 	"b\4PIND\0"						\
    1.34     skrll 	"b\3PPC\0"						\
    1.34     skrll 	"b\2CZC\0"						\
    1.34     skrll 	"b\1BNC\0"						\
    1.34     skrll 	"b\0AC64\0"						\
    1.34     skrll 	"\0"
    1.34     skrll #define XHCI_HCCV1_x_BITS	\
    1.34     skrll 	"\177\020"	/* New bitmask */			\
    1.34     skrll 	"f\020\020XECP\0"					\
    1.34     skrll 	"f\014\4MAXPSA\0"					\
    1.34     skrll 	"b\013CFC\0"						\
    1.34     skrll 	"b\012SEC\0"						\
    1.34     skrll 	"b\011SPC\0"						\
    1.34     skrll 	"b\010PAE\0"						\
    1.34     skrll 	"b\7NSS\0"						\
    1.34     skrll 	"b\6LTC\0"						\
    1.34     skrll 	"b\5LHRC\0"						\
    1.34     skrll 	"b\4PIND\0"						\
    1.34     skrll 	"b\3PPC\0"						\
    1.34     skrll 	"b\2CSZ\0"						\
    1.34     skrll 	"b\1BNC\0"						\
    1.34     skrll 	"b\0AC64\0"						\
    1.34     skrll 	"\0"
     1.1  jakllsch
    1.15     skrll int
     1.1  jakllsch xhci_init(struct xhci_softc *sc)
     1.1  jakllsch {
     1.1  jakllsch 	bus_size_t bsz;
    1.34     skrll 	uint32_t cap, hcs1, hcs2, hcs3, hcc, dboff, rtsoff;
    1.40     skrll 	uint32_t pagesize, config;
    1.40     skrll 	int i = 0;
     1.1  jakllsch 	uint16_t hciversion;
     1.1  jakllsch 	uint8_t caplength;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch
1.62.2.2  pgoyette 	/* Set up the bus struct for the usb 3 and usb 2 buses */
1.62.2.2  pgoyette 	sc->sc_bus.ub_methods = &xhci_bus_methods;
1.62.2.2  pgoyette 	sc->sc_bus.ub_pipesize = sizeof(struct xhci_pipe);
    1.34     skrll 	sc->sc_bus.ub_revision = USBREV_3_0;
    1.34     skrll 	sc->sc_bus.ub_usedma = true;
1.62.2.2  pgoyette 	sc->sc_bus.ub_hcpriv = sc;
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	sc->sc_bus2.ub_methods = &xhci_bus_methods;
1.62.2.2  pgoyette 	sc->sc_bus2.ub_pipesize = sizeof(struct xhci_pipe);
1.62.2.2  pgoyette 	sc->sc_bus2.ub_revision = USBREV_2_0;
1.62.2.2  pgoyette 	sc->sc_bus2.ub_usedma = true;
1.62.2.2  pgoyette 	sc->sc_bus2.ub_hcpriv = sc;
1.62.2.2  pgoyette 	sc->sc_bus2.ub_dmatag = sc->sc_bus.ub_dmatag;
     1.1  jakllsch
     1.1  jakllsch 	cap = xhci_read_4(sc, XHCI_CAPLENGTH);
     1.1  jakllsch 	caplength = XHCI_CAP_CAPLENGTH(cap);
     1.1  jakllsch 	hciversion = XHCI_CAP_HCIVERSION(cap);
     1.1  jakllsch
    1.34     skrll 	if (hciversion < XHCI_HCIVERSION_0_96 ||
    1.34     skrll 	    hciversion > XHCI_HCIVERSION_1_0) {
     1.1  jakllsch 		aprint_normal_dev(sc->sc_dev,
     1.1  jakllsch 		    "xHCI version %x.%x not known to be supported\n",
     1.1  jakllsch 		    (hciversion >> 8) & 0xff, (hciversion >> 0) & 0xff);
     1.1  jakllsch 	} else {
     1.1  jakllsch 		aprint_verbose_dev(sc->sc_dev, "xHCI version %x.%x\n",
     1.1  jakllsch 		    (hciversion >> 8) & 0xff, (hciversion >> 0) & 0xff);
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	if (bus_space_subregion(sc->sc_iot, sc->sc_ioh, 0, caplength,
     1.1  jakllsch 	    &sc->sc_cbh) != 0) {
     1.1  jakllsch 		aprint_error_dev(sc->sc_dev, "capability subregion failure\n");
    1.15     skrll 		return ENOMEM;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	hcs1 = xhci_cap_read_4(sc, XHCI_HCSPARAMS1);
     1.1  jakllsch 	sc->sc_maxslots = XHCI_HCS1_MAXSLOTS(hcs1);
     1.1  jakllsch 	sc->sc_maxintrs = XHCI_HCS1_MAXINTRS(hcs1);
     1.1  jakllsch 	sc->sc_maxports = XHCI_HCS1_MAXPORTS(hcs1);
     1.1  jakllsch 	hcs2 = xhci_cap_read_4(sc, XHCI_HCSPARAMS2);
    1.34     skrll 	hcs3 = xhci_cap_read_4(sc, XHCI_HCSPARAMS3);
    1.34     skrll 	aprint_debug_dev(sc->sc_dev,
    1.34     skrll 	    "hcs1=%"PRIx32" hcs2=%"PRIx32" hcs3=%"PRIx32"\n", hcs1, hcs2, hcs3);
    1.34     skrll
     1.1  jakllsch 	hcc = xhci_cap_read_4(sc, XHCI_HCCPARAMS);
     1.1  jakllsch 	sc->sc_ac64 = XHCI_HCC_AC64(hcc);
     1.1  jakllsch 	sc->sc_ctxsz = XHCI_HCC_CSZ(hcc) ? 64 : 32;
     1.1  jakllsch
    1.34     skrll 	char sbuf[128];
    1.34     skrll 	if (hciversion < XHCI_HCIVERSION_1_0)
    1.34     skrll 		snprintb(sbuf, sizeof(sbuf), XHCI_HCCPREV1_BITS, hcc);
    1.34     skrll 	else
    1.34     skrll 		snprintb(sbuf, sizeof(sbuf), XHCI_HCCV1_x_BITS, hcc);
    1.34     skrll 	aprint_debug_dev(sc->sc_dev, "hcc=%s\n", sbuf);
    1.12  jakllsch 	aprint_debug_dev(sc->sc_dev, "xECP %x\n", XHCI_HCC_XECP(hcc) * 4);
    1.34     skrll
1.62.2.2  pgoyette 	/* default all ports to bus 0, i.e. usb 3 */
1.62.2.2  pgoyette 	sc->sc_ctlrportbus = kmem_zalloc(
1.62.2.2  pgoyette 	    howmany(sc->sc_maxports * sizeof(uint8_t), NBBY), KM_SLEEP);
1.62.2.2  pgoyette 	sc->sc_ctlrportmap = kmem_zalloc(sc->sc_maxports * sizeof(int), KM_SLEEP);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	/* controller port to bus roothub port map */
1.62.2.2  pgoyette 	for (size_t j = 0; j < __arraycount(sc->sc_rhportmap); j++) {
1.62.2.2  pgoyette 		sc->sc_rhportmap[j] = kmem_zalloc(sc->sc_maxports * sizeof(int), KM_SLEEP);
1.62.2.2  pgoyette 	}
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	/*
1.62.2.2  pgoyette 	 * Process all Extended Capabilities
1.62.2.2  pgoyette 	 */
    1.40     skrll 	xhci_ecp(sc, hcc);
     1.1  jakllsch
1.62.2.2  pgoyette 	bsz = XHCI_PORTSC(sc->sc_maxports);
     1.1  jakllsch 	if (bus_space_subregion(sc->sc_iot, sc->sc_ioh, caplength, bsz,
     1.1  jakllsch 	    &sc->sc_obh) != 0) {
     1.1  jakllsch 		aprint_error_dev(sc->sc_dev, "operational subregion failure\n");
    1.15     skrll 		return ENOMEM;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	dboff = xhci_cap_read_4(sc, XHCI_DBOFF);
     1.1  jakllsch 	if (bus_space_subregion(sc->sc_iot, sc->sc_ioh, dboff,
     1.1  jakllsch 	    sc->sc_maxslots * 4, &sc->sc_dbh) != 0) {
     1.1  jakllsch 		aprint_error_dev(sc->sc_dev, "doorbell subregion failure\n");
    1.15     skrll 		return ENOMEM;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	rtsoff = xhci_cap_read_4(sc, XHCI_RTSOFF);
     1.1  jakllsch 	if (bus_space_subregion(sc->sc_iot, sc->sc_ioh, rtsoff,
     1.1  jakllsch 	    sc->sc_maxintrs * 0x20, &sc->sc_rbh) != 0) {
     1.1  jakllsch 		aprint_error_dev(sc->sc_dev, "runtime subregion failure\n");
    1.15     skrll 		return ENOMEM;
     1.1  jakllsch 	}
     1.1  jakllsch
    1.40     skrll 	int rv;
    1.40     skrll 	rv = xhci_hc_reset(sc);
    1.40     skrll 	if (rv != 0) {
    1.40     skrll 		return rv;
    1.37     skrll 	}
     1.1  jakllsch
    1.34     skrll 	if (sc->sc_vendor_init)
    1.34     skrll 		sc->sc_vendor_init(sc);
    1.34     skrll
     1.1  jakllsch 	pagesize = xhci_op_read_4(sc, XHCI_PAGESIZE);
    1.12  jakllsch 	aprint_debug_dev(sc->sc_dev, "PAGESIZE 0x%08x\n", pagesize);
     1.1  jakllsch 	pagesize = ffs(pagesize);
    1.37     skrll 	if (pagesize == 0) {
    1.37     skrll 		aprint_error_dev(sc->sc_dev, "pagesize is 0\n");
    1.15     skrll 		return EIO;
    1.37     skrll 	}
     1.1  jakllsch 	sc->sc_pgsz = 1 << (12 + (pagesize - 1));
    1.12  jakllsch 	aprint_debug_dev(sc->sc_dev, "sc_pgsz 0x%08x\n", (uint32_t)sc->sc_pgsz);
    1.12  jakllsch 	aprint_debug_dev(sc->sc_dev, "sc_maxslots 0x%08x\n",
     1.1  jakllsch 	    (uint32_t)sc->sc_maxslots);
    1.34     skrll 	aprint_debug_dev(sc->sc_dev, "sc_maxports %d\n", sc->sc_maxports);
     1.1  jakllsch
     1.5      matt 	usbd_status err;
     1.5      matt
     1.5      matt 	sc->sc_maxspbuf = XHCI_HCS2_MAXSPBUF(hcs2);
    1.12  jakllsch 	aprint_debug_dev(sc->sc_dev, "sc_maxspbuf %d\n", sc->sc_maxspbuf);
     1.5      matt 	if (sc->sc_maxspbuf != 0) {
     1.5      matt 		err = usb_allocmem(&sc->sc_bus,
     1.5      matt 		    sizeof(uint64_t) * sc->sc_maxspbuf, sizeof(uint64_t),
     1.5      matt 		    &sc->sc_spbufarray_dma);
    1.37     skrll 		if (err) {
    1.37     skrll 			aprint_error_dev(sc->sc_dev,
    1.37     skrll 			    "spbufarray init fail, err %d\n", err);
    1.37     skrll 			return ENOMEM;
    1.37     skrll 		}
    1.30     skrll
    1.36     skrll 		sc->sc_spbuf_dma = kmem_zalloc(sizeof(*sc->sc_spbuf_dma) *
    1.36     skrll 		    sc->sc_maxspbuf, KM_SLEEP);
     1.5      matt 		uint64_t *spbufarray = KERNADDR(&sc->sc_spbufarray_dma, 0);
     1.5      matt 		for (i = 0; i < sc->sc_maxspbuf; i++) {
     1.5      matt 			usb_dma_t * const dma = &sc->sc_spbuf_dma[i];
     1.5      matt 			/* allocate contexts */
     1.5      matt 			err = usb_allocmem(&sc->sc_bus, sc->sc_pgsz,
     1.5      matt 			    sc->sc_pgsz, dma);
    1.37     skrll 			if (err) {
    1.37     skrll 				aprint_error_dev(sc->sc_dev,
    1.37     skrll 				    "spbufarray_dma init fail, err %d\n", err);
    1.37     skrll 				rv = ENOMEM;
    1.37     skrll 				goto bad1;
    1.37     skrll 			}
     1.5      matt 			spbufarray[i] = htole64(DMAADDR(dma, 0));
     1.5      matt 			usb_syncmem(dma, 0, sc->sc_pgsz,
     1.5      matt 			    BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE);
     1.5      matt 		}
     1.5      matt
    1.30     skrll 		usb_syncmem(&sc->sc_spbufarray_dma, 0,
     1.5      matt 		    sizeof(uint64_t) * sc->sc_maxspbuf, BUS_DMASYNC_PREWRITE);
     1.5      matt 	}
     1.5      matt
     1.1  jakllsch 	config = xhci_op_read_4(sc, XHCI_CONFIG);
     1.1  jakllsch 	config &= ~0xFF;
     1.1  jakllsch 	config |= sc->sc_maxslots & 0xFF;
     1.1  jakllsch 	xhci_op_write_4(sc, XHCI_CONFIG, config);
     1.1  jakllsch
     1.1  jakllsch 	err = xhci_ring_init(sc, &sc->sc_cr, XHCI_COMMAND_RING_TRBS,
     1.1  jakllsch 	    XHCI_COMMAND_RING_SEGMENTS_ALIGN);
     1.1  jakllsch 	if (err) {
    1.37     skrll 		aprint_error_dev(sc->sc_dev, "command ring init fail, err %d\n",
    1.37     skrll 		    err);
    1.37     skrll 		rv = ENOMEM;
    1.37     skrll 		goto bad1;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	err = xhci_ring_init(sc, &sc->sc_er, XHCI_EVENT_RING_TRBS,
     1.1  jakllsch 	    XHCI_EVENT_RING_SEGMENTS_ALIGN);
     1.1  jakllsch 	if (err) {
    1.37     skrll 		aprint_error_dev(sc->sc_dev, "event ring init fail, err %d\n",
    1.37     skrll 		    err);
    1.37     skrll 		rv = ENOMEM;
    1.37     skrll 		goto bad2;
     1.1  jakllsch 	}
     1.1  jakllsch
    1.16     skrll 	usb_dma_t *dma;
    1.16     skrll 	size_t size;
    1.16     skrll 	size_t align;
    1.16     skrll
    1.16     skrll 	dma = &sc->sc_eventst_dma;
    1.16     skrll 	size = roundup2(XHCI_EVENT_RING_SEGMENTS * XHCI_ERSTE_SIZE,
    1.16     skrll 	    XHCI_EVENT_RING_SEGMENT_TABLE_ALIGN);
    1.37     skrll 	KASSERTMSG(size <= (512 * 1024), "eventst size %zu too large", size);
    1.16     skrll 	align = XHCI_EVENT_RING_SEGMENT_TABLE_ALIGN;
    1.16     skrll 	err = usb_allocmem(&sc->sc_bus, size, align, dma);
    1.37     skrll 	if (err) {
    1.37     skrll 		aprint_error_dev(sc->sc_dev, "eventst init fail, err %d\n",
    1.37     skrll 		    err);
    1.37     skrll 		rv = ENOMEM;
    1.37     skrll 		goto bad3;
    1.37     skrll 	}
    1.16     skrll
    1.16     skrll 	memset(KERNADDR(dma, 0), 0, size);
    1.16     skrll 	usb_syncmem(dma, 0, size, BUS_DMASYNC_PREWRITE);
    1.37     skrll 	aprint_debug_dev(sc->sc_dev, "eventst: %016jx %p %zx\n",
    1.16     skrll 	    (uintmax_t)DMAADDR(&sc->sc_eventst_dma, 0),
    1.16     skrll 	    KERNADDR(&sc->sc_eventst_dma, 0),
    1.34     skrll 	    sc->sc_eventst_dma.udma_block->size);
    1.16     skrll
    1.16     skrll 	dma = &sc->sc_dcbaa_dma;
    1.16     skrll 	size = (1 + sc->sc_maxslots) * sizeof(uint64_t);
    1.37     skrll 	KASSERTMSG(size <= 2048, "dcbaa size %zu too large", size);
    1.16     skrll 	align = XHCI_DEVICE_CONTEXT_BASE_ADDRESS_ARRAY_ALIGN;
    1.16     skrll 	err = usb_allocmem(&sc->sc_bus, size, align, dma);
    1.37     skrll 	if (err) {
    1.37     skrll 		aprint_error_dev(sc->sc_dev, "dcbaa init fail, err %d\n", err);
    1.37     skrll 		rv = ENOMEM;
    1.37     skrll 		goto bad4;
    1.37     skrll 	}
    1.37     skrll 	aprint_debug_dev(sc->sc_dev, "dcbaa: %016jx %p %zx\n",
    1.37     skrll 	    (uintmax_t)DMAADDR(&sc->sc_dcbaa_dma, 0),
    1.37     skrll 	    KERNADDR(&sc->sc_dcbaa_dma, 0),
    1.37     skrll 	    sc->sc_dcbaa_dma.udma_block->size);
    1.16     skrll
    1.16     skrll 	memset(KERNADDR(dma, 0), 0, size);
    1.16     skrll 	if (sc->sc_maxspbuf != 0) {
    1.16     skrll 		/*
    1.16     skrll 		 * DCBA entry 0 hold the scratchbuf array pointer.
    1.16     skrll 		 */
    1.16     skrll 		*(uint64_t *)KERNADDR(dma, 0) =
    1.16     skrll 		    htole64(DMAADDR(&sc->sc_spbufarray_dma, 0));
     1.1  jakllsch 	}
    1.16     skrll 	usb_syncmem(dma, 0, size, BUS_DMASYNC_PREWRITE);
     1.1  jakllsch
     1.1  jakllsch 	sc->sc_slots = kmem_zalloc(sizeof(*sc->sc_slots) * sc->sc_maxslots,
     1.1  jakllsch 	    KM_SLEEP);
    1.37     skrll 	if (sc->sc_slots == NULL) {
    1.37     skrll 		aprint_error_dev(sc->sc_dev, "slots init fail, err %d\n", err);
    1.37     skrll 		rv = ENOMEM;
    1.37     skrll 		goto bad;
    1.37     skrll 	}
    1.37     skrll
    1.37     skrll 	sc->sc_xferpool = pool_cache_init(sizeof(struct xhci_xfer), 0, 0, 0,
    1.37     skrll 	    "xhcixfer", NULL, IPL_USB, NULL, NULL, NULL);
    1.37     skrll 	if (sc->sc_xferpool == NULL) {
    1.37     skrll 		aprint_error_dev(sc->sc_dev, "pool_cache init fail, err %d\n",
    1.37     skrll 		    err);
    1.37     skrll 		rv = ENOMEM;
    1.37     skrll 		goto bad;
    1.37     skrll 	}
     1.1  jakllsch
     1.1  jakllsch 	cv_init(&sc->sc_command_cv, "xhcicmd");
1.62.2.2  pgoyette 	cv_init(&sc->sc_cmdbusy_cv, "xhcicmdq");
    1.34     skrll 	mutex_init(&sc->sc_lock, MUTEX_DEFAULT, IPL_SOFTUSB);
    1.34     skrll 	mutex_init(&sc->sc_intr_lock, MUTEX_DEFAULT, IPL_USB);
    1.34     skrll
     1.1  jakllsch 	struct xhci_erste *erst;
     1.1  jakllsch 	erst = KERNADDR(&sc->sc_eventst_dma, 0);
     1.1  jakllsch 	erst[0].erste_0 = htole64(xhci_ring_trbp(&sc->sc_er, 0));
    1.52     skrll 	erst[0].erste_2 = htole32(sc->sc_er.xr_ntrb);
     1.1  jakllsch 	erst[0].erste_3 = htole32(0);
     1.1  jakllsch 	usb_syncmem(&sc->sc_eventst_dma, 0,
     1.1  jakllsch 	    XHCI_ERSTE_SIZE * XHCI_EVENT_RING_SEGMENTS, BUS_DMASYNC_PREWRITE);
     1.1  jakllsch
     1.1  jakllsch 	xhci_rt_write_4(sc, XHCI_ERSTSZ(0), XHCI_EVENT_RING_SEGMENTS);
     1.1  jakllsch 	xhci_rt_write_8(sc, XHCI_ERSTBA(0), DMAADDR(&sc->sc_eventst_dma, 0));
     1.1  jakllsch 	xhci_rt_write_8(sc, XHCI_ERDP(0), xhci_ring_trbp(&sc->sc_er, 0) |
     1.1  jakllsch 	    XHCI_ERDP_LO_BUSY);
     1.1  jakllsch 	xhci_op_write_8(sc, XHCI_DCBAAP, DMAADDR(&sc->sc_dcbaa_dma, 0));
     1.1  jakllsch 	xhci_op_write_8(sc, XHCI_CRCR, xhci_ring_trbp(&sc->sc_cr, 0) |
     1.1  jakllsch 	    sc->sc_cr.xr_cs);
     1.1  jakllsch
     1.1  jakllsch #if 0
     1.1  jakllsch 	hexdump("eventst", KERNADDR(&sc->sc_eventst_dma, 0),
     1.1  jakllsch 	    XHCI_ERSTE_SIZE * XHCI_EVENT_RING_SEGMENTS);
     1.1  jakllsch #endif
     1.1  jakllsch
     1.1  jakllsch 	xhci_rt_write_4(sc, XHCI_IMAN(0), XHCI_IMAN_INTR_ENA);
    1.34     skrll 	if ((sc->sc_quirks & XHCI_QUIRK_INTEL) != 0)
    1.34     skrll 		/* Intel xhci needs interrupt rate moderated. */
    1.34     skrll 		xhci_rt_write_4(sc, XHCI_IMOD(0), XHCI_IMOD_DEFAULT_LP);
    1.34     skrll 	else
    1.34     skrll 		xhci_rt_write_4(sc, XHCI_IMOD(0), 0);
    1.53     skrll 	aprint_debug_dev(sc->sc_dev, "current IMOD %u\n",
    1.34     skrll 	    xhci_rt_read_4(sc, XHCI_IMOD(0)));
     1.1  jakllsch
     1.1  jakllsch 	xhci_op_write_4(sc, XHCI_USBCMD, XHCI_CMD_INTE|XHCI_CMD_RS); /* Go! */
    1.12  jakllsch 	aprint_debug_dev(sc->sc_dev, "USBCMD %08"PRIx32"\n",
     1.1  jakllsch 	    xhci_op_read_4(sc, XHCI_USBCMD));
     1.1  jakllsch
    1.37     skrll 	return 0;
    1.37     skrll
    1.37     skrll  bad:
    1.37     skrll 	if (sc->sc_xferpool) {
    1.37     skrll 		pool_cache_destroy(sc->sc_xferpool);
    1.37     skrll 		sc->sc_xferpool = NULL;
    1.37     skrll 	}
    1.37     skrll
    1.37     skrll 	if (sc->sc_slots) {
    1.37     skrll 		kmem_free(sc->sc_slots, sizeof(*sc->sc_slots) *
    1.37     skrll 		    sc->sc_maxslots);
    1.37     skrll 		sc->sc_slots = NULL;
    1.37     skrll 	}
    1.37     skrll
    1.37     skrll 	usb_freemem(&sc->sc_bus, &sc->sc_dcbaa_dma);
    1.37     skrll  bad4:
    1.37     skrll 	usb_freemem(&sc->sc_bus, &sc->sc_eventst_dma);
    1.37     skrll  bad3:
    1.37     skrll 	xhci_ring_free(sc, &sc->sc_er);
    1.37     skrll  bad2:
    1.37     skrll 	xhci_ring_free(sc, &sc->sc_cr);
    1.37     skrll 	i = sc->sc_maxspbuf;
    1.37     skrll  bad1:
    1.37     skrll 	for (int j = 0; j < i; j++)
    1.37     skrll 		usb_freemem(&sc->sc_bus, &sc->sc_spbuf_dma[j]);
    1.37     skrll 	usb_freemem(&sc->sc_bus, &sc->sc_spbufarray_dma);
    1.37     skrll
    1.37     skrll 	return rv;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch int
     1.1  jakllsch xhci_intr(void *v)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_softc * const sc = v;
    1.25     skrll 	int ret = 0;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
    1.25     skrll 	if (sc == NULL)
     1.1  jakllsch 		return 0;
     1.1  jakllsch
    1.25     skrll 	mutex_spin_enter(&sc->sc_intr_lock);
    1.25     skrll
    1.25     skrll 	if (sc->sc_dying || !device_has_power(sc->sc_dev))
    1.25     skrll 		goto done;
    1.25     skrll
     1.1  jakllsch 	/* If we get an interrupt while polling, then just ignore it. */
    1.34     skrll 	if (sc->sc_bus.ub_usepolling) {
     1.1  jakllsch #ifdef DIAGNOSTIC
    1.27     skrll 		DPRINTFN(16, "ignored interrupt while polling", 0, 0, 0, 0);
     1.1  jakllsch #endif
    1.25     skrll 		goto done;
     1.1  jakllsch 	}
     1.1  jakllsch
    1.25     skrll 	ret = xhci_intr1(sc);
    1.25     skrll done:
    1.25     skrll 	mutex_spin_exit(&sc->sc_intr_lock);
    1.25     skrll 	return ret;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch int
     1.1  jakllsch xhci_intr1(struct xhci_softc * const sc)
     1.1  jakllsch {
     1.1  jakllsch 	uint32_t usbsts;
     1.1  jakllsch 	uint32_t iman;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	usbsts = xhci_op_read_4(sc, XHCI_USBSTS);
    1.27     skrll 	DPRINTFN(16, "USBSTS %08x", usbsts, 0, 0, 0);
     1.1  jakllsch #if 0
     1.1  jakllsch 	if ((usbsts & (XHCI_STS_EINT|XHCI_STS_PCD)) == 0) {
     1.1  jakllsch 		return 0;
     1.1  jakllsch 	}
     1.1  jakllsch #endif
     1.1  jakllsch 	xhci_op_write_4(sc, XHCI_USBSTS,
     1.1  jakllsch 	    usbsts & (2|XHCI_STS_EINT|XHCI_STS_PCD)); /* XXX */
     1.1  jakllsch 	usbsts = xhci_op_read_4(sc, XHCI_USBSTS);
    1.27     skrll 	DPRINTFN(16, "USBSTS %08x", usbsts, 0, 0, 0);
     1.1  jakllsch
     1.1  jakllsch 	iman = xhci_rt_read_4(sc, XHCI_IMAN(0));
    1.27     skrll 	DPRINTFN(16, "IMAN0 %08x", iman, 0, 0, 0);
    1.34     skrll 	iman |= XHCI_IMAN_INTR_PEND;
     1.1  jakllsch 	xhci_rt_write_4(sc, XHCI_IMAN(0), iman);
     1.1  jakllsch 	iman = xhci_rt_read_4(sc, XHCI_IMAN(0));
    1.27     skrll 	DPRINTFN(16, "IMAN0 %08x", iman, 0, 0, 0);
     1.1  jakllsch 	usbsts = xhci_op_read_4(sc, XHCI_USBSTS);
    1.27     skrll 	DPRINTFN(16, "USBSTS %08x", usbsts, 0, 0, 0);
     1.1  jakllsch
     1.1  jakllsch 	usb_schedsoftintr(&sc->sc_bus);
     1.1  jakllsch
     1.1  jakllsch 	return 1;
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /*
    1.34     skrll  * 3 port speed types used in USB stack
    1.34     skrll  *
    1.34     skrll  * usbdi speed
    1.34     skrll  *	definition: USB_SPEED_* in usb.h
    1.34     skrll  *	They are used in struct usbd_device in USB stack.
    1.34     skrll  *	ioctl interface uses these values too.
    1.34     skrll  * port_status speed
    1.34     skrll  *	definition: UPS_*_SPEED in usb.h
    1.34     skrll  *	They are used in usb_port_status_t and valid only for USB 2.0.
    1.34     skrll  *	Speed value is always 0 for Super Speed or more, and dwExtPortStatus
    1.34     skrll  *	of usb_port_status_ext_t indicates port speed.
    1.34     skrll  *	Note that some 3.0 values overlap with 2.0 values.
    1.34     skrll  *	(e.g. 0x200 means UPS_POER_POWER_SS in SS and
    1.34     skrll  *	            means UPS_LOW_SPEED in HS.)
    1.34     skrll  *	port status returned from hub also uses these values.
    1.34     skrll  *	On NetBSD UPS_OTHER_SPEED indicates port speed is super speed
    1.34     skrll  *	or more.
    1.34     skrll  * xspeed:
    1.34     skrll  *	definition: Protocol Speed ID (PSI) (xHCI 1.1 7.2.1)
    1.34     skrll  *	They are used in only slot context and PORTSC reg of xhci.
    1.34     skrll  *	The difference between usbdi speed and xspeed is
    1.34     skrll  *	that FS and LS values are swapped.
    1.34     skrll  */
    1.34     skrll
    1.34     skrll /* convert usbdi speed to xspeed */
    1.34     skrll static int
    1.34     skrll xhci_speed2xspeed(int speed)
    1.34     skrll {
    1.34     skrll 	switch (speed) {
    1.34     skrll 	case USB_SPEED_LOW:	return 2;
    1.34     skrll 	case USB_SPEED_FULL:	return 1;
    1.34     skrll 	default:		return speed;
    1.34     skrll 	}
    1.34     skrll }
    1.34     skrll
    1.34     skrll #if 0
    1.34     skrll /* convert xspeed to usbdi speed */
    1.34     skrll static int
    1.34     skrll xhci_xspeed2speed(int xspeed)
    1.34     skrll {
    1.34     skrll 	switch (xspeed) {
    1.34     skrll 	case 1: return USB_SPEED_FULL;
    1.34     skrll 	case 2: return USB_SPEED_LOW;
    1.34     skrll 	default: return xspeed;
    1.34     skrll 	}
    1.34     skrll }
    1.34     skrll #endif
    1.34     skrll
    1.34     skrll /* convert xspeed to port status speed */
    1.34     skrll static int
    1.34     skrll xhci_xspeed2psspeed(int xspeed)
    1.34     skrll {
    1.34     skrll 	switch (xspeed) {
    1.34     skrll 	case 0: return 0;
    1.34     skrll 	case 1: return UPS_FULL_SPEED;
    1.34     skrll 	case 2: return UPS_LOW_SPEED;
    1.34     skrll 	case 3: return UPS_HIGH_SPEED;
    1.34     skrll 	default: return UPS_OTHER_SPEED;
    1.34     skrll 	}
    1.34     skrll }
    1.34     skrll
    1.34     skrll /*
    1.54     skrll  * Construct input contexts and issue TRB to open pipe.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_configure_endpoint(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.34     skrll 	struct xhci_slot * const xs = pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(pipe->up_endpoint->ue_edesc);
     1.1  jakllsch 	struct xhci_trb trb;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	DPRINTFN(4, "slot %u dci %u epaddr 0x%02x attr 0x%02x",
    1.34     skrll 	    xs->xs_idx, dci, pipe->up_endpoint->ue_edesc->bEndpointAddress,
    1.34     skrll 	    pipe->up_endpoint->ue_edesc->bmAttributes);
     1.1  jakllsch
     1.1  jakllsch 	/* XXX ensure input context is available? */
     1.1  jakllsch
     1.1  jakllsch 	memset(xhci_slot_get_icv(sc, xs, 0), 0, sc->sc_pgsz);
     1.1  jakllsch
    1.51     skrll 	/* set up context */
    1.51     skrll 	xhci_setup_ctx(pipe);
     1.1  jakllsch
     1.1  jakllsch 	hexdump("input control context", xhci_slot_get_icv(sc, xs, 0),
     1.1  jakllsch 	    sc->sc_ctxsz * 1);
     1.1  jakllsch 	hexdump("input endpoint context", xhci_slot_get_icv(sc, xs,
     1.1  jakllsch 	    xhci_dci_to_ici(dci)), sc->sc_ctxsz * 1);
     1.1  jakllsch
     1.1  jakllsch 	trb.trb_0 = xhci_slot_get_icp(sc, xs, 0);
     1.1  jakllsch 	trb.trb_2 = 0;
     1.1  jakllsch 	trb.trb_3 = XHCI_TRB_3_SLOT_SET(xs->xs_idx) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_CONFIGURE_EP);
     1.1  jakllsch
     1.1  jakllsch 	err = xhci_do_command(sc, &trb, USBD_DEFAULT_TIMEOUT);
     1.1  jakllsch
     1.1  jakllsch 	usb_syncmem(&xs->xs_dc_dma, 0, sc->sc_pgsz, BUS_DMASYNC_POSTREAD);
     1.1  jakllsch 	hexdump("output context", xhci_slot_get_dcv(sc, xs, dci),
     1.1  jakllsch 	    sc->sc_ctxsz * 1);
     1.1  jakllsch
     1.1  jakllsch 	return err;
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll #if 0
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_unconfigure_endpoint(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.27     skrll #ifdef USB_DEBUG
    1.34     skrll 	struct xhci_slot * const xs = pipe->up_dev->ud_hcpriv;
    1.27     skrll #endif
    1.27     skrll
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll 	DPRINTFN(4, "slot %u", xs->xs_idx, 0, 0, 0);
    1.27     skrll
     1.1  jakllsch 	return USBD_NORMAL_COMPLETION;
     1.1  jakllsch }
    1.34     skrll #endif
     1.1  jakllsch
    1.34     skrll /* 4.6.8, 6.4.3.7 */
     1.1  jakllsch static usbd_status
1.62.2.1  pgoyette xhci_reset_endpoint_locked(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.34     skrll 	struct xhci_slot * const xs = pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(pipe->up_endpoint->ue_edesc);
     1.1  jakllsch 	struct xhci_trb trb;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	DPRINTFN(4, "slot %u dci %u", xs->xs_idx, dci, 0, 0);
    1.34     skrll
1.62.2.1  pgoyette 	KASSERT(mutex_owned(&sc->sc_lock));
1.62.2.1  pgoyette
     1.1  jakllsch 	trb.trb_0 = 0;
     1.1  jakllsch 	trb.trb_2 = 0;
     1.1  jakllsch 	trb.trb_3 = XHCI_TRB_3_SLOT_SET(xs->xs_idx) |
     1.1  jakllsch 	    XHCI_TRB_3_EP_SET(dci) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_RESET_EP);
     1.1  jakllsch
1.62.2.1  pgoyette 	err = xhci_do_command_locked(sc, &trb, USBD_DEFAULT_TIMEOUT);
     1.1  jakllsch
     1.1  jakllsch 	return err;
     1.1  jakllsch }
     1.1  jakllsch
1.62.2.1  pgoyette static usbd_status
1.62.2.1  pgoyette xhci_reset_endpoint(struct usbd_pipe *pipe)
1.62.2.1  pgoyette {
1.62.2.1  pgoyette 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	mutex_enter(&sc->sc_lock);
1.62.2.1  pgoyette 	usbd_status ret = xhci_reset_endpoint_locked(pipe);
1.62.2.1  pgoyette 	mutex_exit(&sc->sc_lock);
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	return ret;
1.62.2.1  pgoyette }
1.62.2.1  pgoyette
    1.34     skrll /*
    1.34     skrll  * 4.6.9, 6.4.3.8
    1.34     skrll  * Stop execution of TDs on xfer ring.
    1.34     skrll  * Should be called with sc_lock held.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_stop_endpoint(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.34     skrll 	struct xhci_slot * const xs = pipe->up_dev->ud_hcpriv;
     1.1  jakllsch 	struct xhci_trb trb;
     1.1  jakllsch 	usbd_status err;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(pipe->up_endpoint->ue_edesc);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	DPRINTFN(4, "slot %u dci %u", xs->xs_idx, dci, 0, 0);
    1.34     skrll
    1.34     skrll 	KASSERT(mutex_owned(&sc->sc_lock));
     1.1  jakllsch
     1.1  jakllsch 	trb.trb_0 = 0;
     1.1  jakllsch 	trb.trb_2 = 0;
     1.1  jakllsch 	trb.trb_3 = XHCI_TRB_3_SLOT_SET(xs->xs_idx) |
     1.1  jakllsch 	    XHCI_TRB_3_EP_SET(dci) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_STOP_EP);
     1.1  jakllsch
    1.34     skrll 	err = xhci_do_command_locked(sc, &trb, USBD_DEFAULT_TIMEOUT);
     1.1  jakllsch
     1.1  jakllsch 	return err;
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /*
    1.34     skrll  * Set TR Dequeue Pointer.
    1.54     skrll  * xHCI 1.1  4.6.10  6.4.3.9
    1.54     skrll  * Purge all of the TRBs on ring and reinitialize ring.
    1.54     skrll  * Set TR dequeue Pointr to 0 and Cycle State to 1.
    1.54     skrll  * EPSTATE of endpoint must be ERROR or STOPPED, otherwise CONTEXT_STATE
    1.54     skrll  * error will be generated.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
1.62.2.1  pgoyette xhci_set_dequeue_locked(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.34     skrll 	struct xhci_slot * const xs = pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(pipe->up_endpoint->ue_edesc);
     1.1  jakllsch 	struct xhci_ring * const xr = &xs->xs_ep[dci].xe_tr;
     1.1  jakllsch 	struct xhci_trb trb;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll 	DPRINTFN(4, "slot %u dci %u", xs->xs_idx, dci, 0, 0);
     1.1  jakllsch
1.62.2.1  pgoyette 	KASSERT(mutex_owned(&sc->sc_lock));
1.62.2.1  pgoyette
    1.56     skrll 	xhci_host_dequeue(xr);
     1.1  jakllsch
    1.34     skrll 	/* set DCS */
     1.1  jakllsch 	trb.trb_0 = xhci_ring_trbp(xr, 0) | 1; /* XXX */
     1.1  jakllsch 	trb.trb_2 = 0;
     1.1  jakllsch 	trb.trb_3 = XHCI_TRB_3_SLOT_SET(xs->xs_idx) |
     1.1  jakllsch 	    XHCI_TRB_3_EP_SET(dci) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_SET_TR_DEQUEUE);
     1.1  jakllsch
1.62.2.1  pgoyette 	err = xhci_do_command_locked(sc, &trb, USBD_DEFAULT_TIMEOUT);
     1.1  jakllsch
     1.1  jakllsch 	return err;
     1.1  jakllsch }
     1.1  jakllsch
1.62.2.1  pgoyette static usbd_status
1.62.2.1  pgoyette xhci_set_dequeue(struct usbd_pipe *pipe)
1.62.2.1  pgoyette {
1.62.2.1  pgoyette 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	mutex_enter(&sc->sc_lock);
1.62.2.1  pgoyette 	usbd_status ret = xhci_set_dequeue_locked(pipe);
1.62.2.1  pgoyette 	mutex_exit(&sc->sc_lock);
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	return ret;
1.62.2.1  pgoyette }
1.62.2.1  pgoyette
    1.34     skrll /*
    1.34     skrll  * Open new pipe: called from usbd_setup_pipe_flags.
    1.34     skrll  * Fills methods of pipe.
    1.34     skrll  * If pipe is not for ep0, calls configure_endpoint.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_open(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	struct usbd_device * const dev = pipe->up_dev;
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(dev->ud_bus);
    1.34     skrll 	usb_endpoint_descriptor_t * const ed = pipe->up_endpoint->ue_edesc;
     1.1  jakllsch 	const uint8_t xfertype = UE_GET_XFERTYPE(ed->bmAttributes);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.53     skrll 	DPRINTFN(1, "addr %d depth %d port %d speed %d", dev->ud_addr,
    1.53     skrll 	    dev->ud_depth, dev->ud_powersrc->up_portno, dev->ud_speed);
    1.53     skrll 	DPRINTFN(1, " dci %u type 0x%02x epaddr 0x%02x attr 0x%02x",
    1.53     skrll 	    xhci_ep_get_dci(ed), ed->bDescriptorType, ed->bEndpointAddress,
    1.53     skrll 	    ed->bmAttributes);
    1.53     skrll 	DPRINTFN(1, " mps %u ival %u", UGETW(ed->wMaxPacketSize), ed->bInterval,
    1.53     skrll 	    0, 0);
     1.1  jakllsch
     1.1  jakllsch 	if (sc->sc_dying)
     1.1  jakllsch 		return USBD_IOERROR;
     1.1  jakllsch
     1.1  jakllsch 	/* Root Hub */
    1.34     skrll 	if (dev->ud_depth == 0 && dev->ud_powersrc->up_portno == 0) {
     1.1  jakllsch 		switch (ed->bEndpointAddress) {
     1.1  jakllsch 		case USB_CONTROL_ENDPOINT:
    1.34     skrll 			pipe->up_methods = &roothub_ctrl_methods;
     1.1  jakllsch 			break;
    1.34     skrll 		case UE_DIR_IN | USBROOTHUB_INTR_ENDPT:
    1.34     skrll 			pipe->up_methods = &xhci_root_intr_methods;
     1.1  jakllsch 			break;
     1.1  jakllsch 		default:
    1.34     skrll 			pipe->up_methods = NULL;
    1.27     skrll 			DPRINTFN(0, "bad bEndpointAddress 0x%02x",
    1.27     skrll 			    ed->bEndpointAddress, 0, 0, 0);
     1.1  jakllsch 			return USBD_INVAL;
     1.1  jakllsch 		}
     1.1  jakllsch 		return USBD_NORMAL_COMPLETION;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	switch (xfertype) {
     1.1  jakllsch 	case UE_CONTROL:
    1.34     skrll 		pipe->up_methods = &xhci_device_ctrl_methods;
     1.1  jakllsch 		break;
     1.1  jakllsch 	case UE_ISOCHRONOUS:
    1.34     skrll 		pipe->up_methods = &xhci_device_isoc_methods;
     1.1  jakllsch 		return USBD_INVAL;
     1.1  jakllsch 		break;
     1.1  jakllsch 	case UE_BULK:
    1.34     skrll 		pipe->up_methods = &xhci_device_bulk_methods;
     1.1  jakllsch 		break;
     1.1  jakllsch 	case UE_INTERRUPT:
    1.34     skrll 		pipe->up_methods = &xhci_device_intr_methods;
     1.1  jakllsch 		break;
     1.1  jakllsch 	default:
     1.1  jakllsch 		return USBD_IOERROR;
     1.1  jakllsch 		break;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	if (ed->bEndpointAddress != USB_CONTROL_ENDPOINT)
    1.34     skrll 		return xhci_configure_endpoint(pipe);
     1.1  jakllsch
     1.1  jakllsch 	return USBD_NORMAL_COMPLETION;
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /*
    1.34     skrll  * Closes pipe, called from usbd_kill_pipe via close methods.
    1.34     skrll  * If the endpoint to be closed is ep0, disable_slot.
    1.34     skrll  * Should be called with sc_lock held.
    1.34     skrll  */
     1.1  jakllsch static void
    1.34     skrll xhci_close_pipe(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.34     skrll 	struct xhci_slot * const xs = pipe->up_dev->ud_hcpriv;
    1.34     skrll 	usb_endpoint_descriptor_t * const ed = pipe->up_endpoint->ue_edesc;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(ed);
    1.34     skrll 	struct xhci_trb trb;
    1.34     skrll 	uint32_t *cp;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch
    1.34     skrll 	if (sc->sc_dying)
     1.1  jakllsch 		return;
     1.1  jakllsch
    1.41     skrll 	/* xs is uninitialized before xhci_init_slot */
    1.34     skrll 	if (xs == NULL || xs->xs_idx == 0)
     1.1  jakllsch 		return;
     1.1  jakllsch
    1.34     skrll 	DPRINTFN(4, "pipe %p slot %u dci %u", pipe, xs->xs_idx, dci, 0);
     1.1  jakllsch
    1.34     skrll 	KASSERTMSG(!cpu_intr_p() && !cpu_softintr_p(), "called from intr ctx");
    1.34     skrll 	KASSERT(mutex_owned(&sc->sc_lock));
     1.1  jakllsch
    1.34     skrll 	if (pipe->up_dev->ud_depth == 0)
    1.34     skrll 		return;
     1.1  jakllsch
    1.34     skrll 	if (dci == XHCI_DCI_EP_CONTROL) {
    1.34     skrll 		DPRINTFN(4, "closing ep0", 0, 0, 0, 0);
    1.34     skrll 		xhci_disable_slot(sc, xs->xs_idx);
    1.34     skrll 		return;
    1.34     skrll 	}
     1.1  jakllsch
    1.34     skrll 	/*
    1.34     skrll 	 * This may fail in the case that xhci_close_pipe is called after
    1.34     skrll 	 * xhci_abort_xfer e.g. usbd_kill_pipe.
    1.34     skrll 	 */
    1.34     skrll 	(void)xhci_stop_endpoint(pipe);
     1.1  jakllsch
    1.34     skrll 	/*
    1.34     skrll 	 * set appropriate bit to be dropped.
    1.34     skrll 	 * don't set DC bit to 1, otherwise all endpoints
    1.34     skrll 	 * would be deconfigured.
    1.34     skrll 	 */
    1.34     skrll 	cp = xhci_slot_get_icv(sc, xs, XHCI_ICI_INPUT_CONTROL);
    1.34     skrll 	cp[0] = htole32(XHCI_INCTX_0_DROP_MASK(dci));
    1.34     skrll 	cp[1] = htole32(0);
     1.1  jakllsch
    1.34     skrll 	/* XXX should be most significant one, not dci? */
    1.34     skrll 	cp = xhci_slot_get_icv(sc, xs, xhci_dci_to_ici(XHCI_DCI_SLOT));
    1.34     skrll 	cp[0] = htole32(XHCI_SCTX_0_CTX_NUM_SET(dci));
     1.1  jakllsch
    1.55     skrll 	/* configure ep context performs an implicit dequeue */
    1.55     skrll 	xhci_host_dequeue(&xs->xs_ep[dci].xe_tr);
    1.55     skrll
    1.34     skrll 	/* sync input contexts before they are read from memory */
    1.34     skrll 	usb_syncmem(&xs->xs_ic_dma, 0, sc->sc_pgsz, BUS_DMASYNC_PREWRITE);
     1.1  jakllsch
    1.34     skrll 	trb.trb_0 = xhci_slot_get_icp(sc, xs, 0);
    1.34     skrll 	trb.trb_2 = 0;
    1.34     skrll 	trb.trb_3 = XHCI_TRB_3_SLOT_SET(xs->xs_idx) |
    1.34     skrll 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_CONFIGURE_EP);
     1.1  jakllsch
    1.34     skrll 	(void)xhci_do_command_locked(sc, &trb, USBD_DEFAULT_TIMEOUT);
    1.34     skrll 	usb_syncmem(&xs->xs_dc_dma, 0, sc->sc_pgsz, BUS_DMASYNC_POSTREAD);
    1.34     skrll }
     1.1  jakllsch
    1.34     skrll /*
    1.34     skrll  * Abort transfer.
1.62.2.1  pgoyette  * Should be called with sc_lock held.
    1.34     skrll  */
    1.34     skrll static void
    1.34     skrll xhci_abort_xfer(struct usbd_xfer *xfer, usbd_status status)
    1.34     skrll {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
1.62.2.1  pgoyette 	struct xhci_slot * const xs = xfer->ux_pipe->up_dev->ud_hcpriv;
1.62.2.1  pgoyette 	const u_int dci = xhci_ep_get_dci(xfer->ux_pipe->up_endpoint->ue_edesc);
     1.1  jakllsch
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	DPRINTFN(4, "xfer %p pipe %p status %d",
    1.34     skrll 	    xfer, xfer->ux_pipe, status, 0);
     1.1  jakllsch
    1.34     skrll 	KASSERT(mutex_owned(&sc->sc_lock));
     1.1  jakllsch
    1.34     skrll 	if (sc->sc_dying) {
    1.34     skrll 		/* If we're dying, just do the software part. */
    1.53     skrll 		DPRINTFN(4, "xfer %p dying %u", xfer, xfer->ux_status, 0, 0);
    1.54     skrll 		xfer->ux_status = status;
    1.34     skrll 		callout_stop(&xfer->ux_callout);
    1.34     skrll 		usb_transfer_complete(xfer);
    1.34     skrll 		return;
     1.1  jakllsch 	}
    1.34     skrll
1.62.2.1  pgoyette 	/*
1.62.2.1  pgoyette 	 * If an abort is already in progress then just wait for it to
1.62.2.1  pgoyette 	 * complete and return.
1.62.2.1  pgoyette 	 */
1.62.2.1  pgoyette 	if (xfer->ux_hcflags & UXFER_ABORTING) {
1.62.2.1  pgoyette 		DPRINTFN(4, "already aborting", 0, 0, 0, 0);
1.62.2.1  pgoyette #ifdef DIAGNOSTIC
1.62.2.1  pgoyette 		if (status == USBD_TIMEOUT)
1.62.2.1  pgoyette 			DPRINTFN(4, "TIMEOUT while aborting", 0, 0, 0, 0);
1.62.2.1  pgoyette #endif
1.62.2.1  pgoyette 		/* Override the status which might be USBD_TIMEOUT. */
1.62.2.1  pgoyette 		xfer->ux_status = status;
1.62.2.1  pgoyette 		DPRINTFN(4, "xfer %p waiting for abort to finish", xfer, 0, 0,
1.62.2.1  pgoyette 		    0);
1.62.2.1  pgoyette 		xfer->ux_hcflags |= UXFER_ABORTWAIT;
1.62.2.1  pgoyette 		while (xfer->ux_hcflags & UXFER_ABORTING)
1.62.2.1  pgoyette 			cv_wait(&xfer->ux_hccv, &sc->sc_lock);
1.62.2.1  pgoyette 		return;
1.62.2.1  pgoyette 	}
1.62.2.1  pgoyette 	xfer->ux_hcflags |= UXFER_ABORTING;
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	/*
1.62.2.1  pgoyette 	 * Step 1: Stop xfer timeout timer.
1.62.2.1  pgoyette 	 */
    1.34     skrll 	xfer->ux_status = status;
    1.34     skrll 	callout_stop(&xfer->ux_callout);
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	/*
1.62.2.1  pgoyette 	 * Step 2: Stop execution of TD on the ring.
1.62.2.1  pgoyette 	 */
1.62.2.1  pgoyette 	switch (xhci_get_epstate(sc, xs, dci)) {
1.62.2.1  pgoyette 	case XHCI_EPSTATE_HALTED:
1.62.2.1  pgoyette 		(void)xhci_reset_endpoint_locked(xfer->ux_pipe);
1.62.2.1  pgoyette 		break;
1.62.2.1  pgoyette 	case XHCI_EPSTATE_STOPPED:
1.62.2.1  pgoyette 		break;
1.62.2.1  pgoyette 	default:
1.62.2.1  pgoyette 		(void)xhci_stop_endpoint(xfer->ux_pipe);
1.62.2.1  pgoyette 		break;
1.62.2.1  pgoyette 	}
1.62.2.1  pgoyette #ifdef DIAGNOSTIC
1.62.2.1  pgoyette 	uint32_t epst = xhci_get_epstate(sc, xs, dci);
1.62.2.1  pgoyette 	if (epst != XHCI_EPSTATE_STOPPED)
1.62.2.1  pgoyette 		DPRINTFN(4, "dci %u not stopped %u", dci, epst, 0, 0);
1.62.2.1  pgoyette #endif
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	/*
1.62.2.1  pgoyette 	 * Step 3: Remove any vestiges of the xfer from the ring.
1.62.2.1  pgoyette 	 */
1.62.2.1  pgoyette 	xhci_set_dequeue_locked(xfer->ux_pipe);
1.62.2.1  pgoyette
1.62.2.1  pgoyette 	/*
1.62.2.1  pgoyette 	 * Step 4: Notify completion to waiting xfers.
1.62.2.1  pgoyette 	 */
1.62.2.1  pgoyette 	int wake = xfer->ux_hcflags & UXFER_ABORTWAIT;
1.62.2.1  pgoyette 	xfer->ux_hcflags &= ~(UXFER_ABORTING | UXFER_ABORTWAIT);
    1.34     skrll 	usb_transfer_complete(xfer);
1.62.2.1  pgoyette 	if (wake) {
1.62.2.1  pgoyette 		cv_broadcast(&xfer->ux_hccv);
1.62.2.1  pgoyette 	}
    1.34     skrll 	DPRINTFN(14, "end", 0, 0, 0, 0);
    1.34     skrll
    1.34     skrll 	KASSERT(mutex_owned(&sc->sc_lock));
     1.1  jakllsch }
     1.1  jakllsch
    1.55     skrll static void
    1.55     skrll xhci_host_dequeue(struct xhci_ring * const xr)
    1.55     skrll {
    1.55     skrll 	/* When dequeueing the controller, update our struct copy too */
    1.55     skrll 	memset(xr->xr_trb, 0, xr->xr_ntrb * XHCI_TRB_SIZE);
    1.55     skrll 	usb_syncmem(&xr->xr_dma, 0, xr->xr_ntrb * XHCI_TRB_SIZE,
    1.55     skrll 	    BUS_DMASYNC_PREWRITE);
    1.55     skrll 	memset(xr->xr_cookies, 0, xr->xr_ntrb * sizeof(*xr->xr_cookies));
    1.55     skrll
    1.55     skrll 	xr->xr_ep = 0;
    1.55     skrll 	xr->xr_cs = 1;
    1.55     skrll }
    1.55     skrll
    1.34     skrll /*
    1.34     skrll  * Recover STALLed endpoint.
    1.34     skrll  * xHCI 1.1 sect 4.10.2.1
    1.34     skrll  * Issue RESET_EP to recover halt condition and SET_TR_DEQUEUE to remove
    1.34     skrll  * all transfers on transfer ring.
    1.34     skrll  * These are done in thread context asynchronously.
    1.34     skrll  */
     1.1  jakllsch static void
    1.34     skrll xhci_clear_endpoint_stall_async_task(void *cookie)
     1.1  jakllsch {
    1.34     skrll 	struct usbd_xfer * const xfer = cookie;
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
    1.34     skrll 	struct xhci_slot * const xs = xfer->ux_pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(xfer->ux_pipe->up_endpoint->ue_edesc);
    1.34     skrll 	struct xhci_ring * const tr = &xs->xs_ep[dci].xe_tr;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	DPRINTFN(4, "xfer %p slot %u dci %u", xfer, xs->xs_idx, dci, 0);
     1.1  jakllsch
    1.34     skrll 	xhci_reset_endpoint(xfer->ux_pipe);
    1.34     skrll 	xhci_set_dequeue(xfer->ux_pipe);
    1.34     skrll
    1.34     skrll 	mutex_enter(&sc->sc_lock);
    1.34     skrll 	tr->is_halted = false;
    1.34     skrll 	usb_transfer_complete(xfer);
    1.34     skrll 	mutex_exit(&sc->sc_lock);
    1.34     skrll 	DPRINTFN(4, "ends", 0, 0, 0, 0);
    1.34     skrll }
    1.34     skrll
    1.34     skrll static usbd_status
    1.34     skrll xhci_clear_endpoint_stall_async(struct usbd_xfer *xfer)
    1.34     skrll {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
    1.34     skrll 	struct xhci_pipe * const xp = (struct xhci_pipe *)xfer->ux_pipe;
    1.34     skrll
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	DPRINTFN(4, "xfer %p", xfer, 0, 0, 0);
    1.34     skrll
    1.34     skrll 	if (sc->sc_dying) {
    1.34     skrll 		return USBD_IOERROR;
    1.34     skrll 	}
    1.34     skrll
    1.34     skrll 	usb_init_task(&xp->xp_async_task,
    1.34     skrll 	    xhci_clear_endpoint_stall_async_task, xfer, USB_TASKQ_MPSAFE);
    1.34     skrll 	usb_add_task(xfer->ux_pipe->up_dev, &xp->xp_async_task, USB_TASKQ_HC);
    1.34     skrll 	DPRINTFN(4, "ends", 0, 0, 0, 0);
    1.34     skrll
    1.34     skrll 	return USBD_NORMAL_COMPLETION;
    1.34     skrll }
    1.34     skrll
    1.34     skrll /* Process roothub port status/change events and notify to uhub_intr. */
    1.34     skrll static void
1.62.2.2  pgoyette xhci_rhpsc(struct xhci_softc * const sc, u_int ctlrport)
    1.34     skrll {
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	DPRINTFN(4, "xhci%d: port %u status change", device_unit(sc->sc_dev),
1.62.2.2  pgoyette 	   ctlrport, 0, 0);
    1.34     skrll
1.62.2.2  pgoyette 	if (ctlrport > sc->sc_maxports)
    1.34     skrll 		return;
    1.34     skrll
1.62.2.2  pgoyette 	const size_t bn = xhci_ctlrport2bus(sc, ctlrport);
1.62.2.2  pgoyette 	const size_t rhp = xhci_ctlrport2rhport(sc, ctlrport);
1.62.2.2  pgoyette 	struct usbd_xfer * const xfer = sc->sc_intrxfer[bn];
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	DPRINTFN(4, "xhci%d: bus %d bp %u xfer %p status change",
1.62.2.2  pgoyette 	    device_unit(sc->sc_dev), bn, rhp, xfer);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	if (xfer == NULL)
    1.34     skrll 		return;
    1.34     skrll
1.62.2.2  pgoyette 	uint8_t *p = xfer->ux_buf;
    1.34     skrll 	memset(p, 0, xfer->ux_length);
1.62.2.2  pgoyette 	p[rhp / NBBY] |= 1 << (rhp % NBBY);
    1.34     skrll 	xfer->ux_actlen = xfer->ux_length;
    1.34     skrll 	xfer->ux_status = USBD_NORMAL_COMPLETION;
    1.34     skrll 	usb_transfer_complete(xfer);
    1.34     skrll }
    1.34     skrll
    1.34     skrll /* Process Transfer Events */
    1.34     skrll static void
    1.34     skrll xhci_event_transfer(struct xhci_softc * const sc,
    1.34     skrll     const struct xhci_trb * const trb)
    1.34     skrll {
    1.34     skrll 	uint64_t trb_0;
    1.34     skrll 	uint32_t trb_2, trb_3;
    1.34     skrll 	uint8_t trbcode;
    1.34     skrll 	u_int slot, dci;
    1.34     skrll 	struct xhci_slot *xs;
    1.34     skrll 	struct xhci_ring *xr;
    1.34     skrll 	struct xhci_xfer *xx;
    1.34     skrll 	struct usbd_xfer *xfer;
    1.34     skrll 	usbd_status err;
    1.34     skrll
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	trb_0 = le64toh(trb->trb_0);
    1.34     skrll 	trb_2 = le32toh(trb->trb_2);
    1.34     skrll 	trb_3 = le32toh(trb->trb_3);
    1.34     skrll 	trbcode = XHCI_TRB_2_ERROR_GET(trb_2);
    1.34     skrll 	slot = XHCI_TRB_3_SLOT_GET(trb_3);
    1.34     skrll 	dci = XHCI_TRB_3_EP_GET(trb_3);
    1.34     skrll 	xs = &sc->sc_slots[slot];
    1.34     skrll 	xr = &xs->xs_ep[dci].xe_tr;
    1.34     skrll
    1.34     skrll 	/* sanity check */
    1.34     skrll 	KASSERTMSG(xs->xs_idx != 0 && xs->xs_idx <= sc->sc_maxslots,
    1.34     skrll 	    "invalid xs_idx %u slot %u", xs->xs_idx, slot);
    1.34     skrll
    1.40     skrll 	int idx = 0;
    1.34     skrll 	if ((trb_3 & XHCI_TRB_3_ED_BIT) == 0) {
    1.40     skrll 		if (xhci_trb_get_idx(xr, trb_0, &idx)) {
    1.40     skrll 			DPRINTFN(0, "invalid trb_0 0x%"PRIx64, trb_0, 0, 0, 0);
    1.34     skrll 			return;
    1.34     skrll 		}
    1.34     skrll 		xx = xr->xr_cookies[idx];
    1.34     skrll
1.62.2.1  pgoyette 		/* clear cookie of consumed TRB */
1.62.2.1  pgoyette 		xr->xr_cookies[idx] = NULL;
1.62.2.1  pgoyette
    1.34     skrll 		/*
1.62.2.1  pgoyette 		 * xx is NULL if pipe is opened but xfer is not started.
1.62.2.1  pgoyette 		 * It happens when stopping idle pipe.
    1.34     skrll 		 */
    1.34     skrll 		if (xx == NULL || trbcode == XHCI_TRB_ERROR_LENGTH) {
    1.53     skrll 			DPRINTFN(1, "Ignore #%u: cookie %p cc %u dci %u",
    1.53     skrll 			    idx, xx, trbcode, dci);
    1.53     skrll 			DPRINTFN(1, " orig TRB %"PRIx64" type %u", trb_0,
    1.53     skrll 			    XHCI_TRB_3_TYPE_GET(le32toh(xr->xr_trb[idx].trb_3)),
    1.53     skrll 			    0, 0);
1.62.2.1  pgoyette 			return;
    1.34     skrll 		}
    1.34     skrll 	} else {
    1.54     skrll 		/* When ED != 0, trb_0 is virtual addr of struct xhci_xfer. */
    1.34     skrll 		xx = (void *)(uintptr_t)(trb_0 & ~0x3);
    1.34     skrll 	}
    1.34     skrll 	/* XXX this may not happen */
    1.34     skrll 	if (xx == NULL) {
    1.34     skrll 		DPRINTFN(1, "xfer done: xx is NULL", 0, 0, 0, 0);
    1.34     skrll 		return;
    1.34     skrll 	}
    1.34     skrll 	xfer = &xx->xx_xfer;
    1.34     skrll 	/* XXX this may happen when detaching */
    1.34     skrll 	if (xfer == NULL) {
    1.34     skrll 		DPRINTFN(1, "xx(%p)->xx_xfer is NULL trb_0 %#"PRIx64,
    1.34     skrll 		    xx, trb_0, 0, 0);
    1.34     skrll 		return;
    1.34     skrll 	}
    1.34     skrll 	DPRINTFN(14, "xfer %p", xfer, 0, 0, 0);
    1.34     skrll 	/* XXX I dunno why this happens */
    1.34     skrll 	KASSERTMSG(xfer->ux_pipe != NULL, "xfer(%p)->ux_pipe is NULL", xfer);
    1.34     skrll
    1.34     skrll 	if (!xfer->ux_pipe->up_repeat &&
    1.34     skrll 	    SIMPLEQ_EMPTY(&xfer->ux_pipe->up_queue)) {
    1.34     skrll 		DPRINTFN(1, "xfer(%p)->pipe not queued", xfer, 0, 0, 0);
    1.34     skrll 		return;
    1.34     skrll 	}
    1.34     skrll
    1.34     skrll 	/* 4.11.5.2 Event Data TRB */
    1.34     skrll 	if ((trb_3 & XHCI_TRB_3_ED_BIT) != 0) {
    1.34     skrll 		DPRINTFN(14, "transfer Event Data: 0x%016"PRIx64" 0x%08"PRIx32
    1.34     skrll 		    " %02x", trb_0, XHCI_TRB_2_REM_GET(trb_2), trbcode, 0);
    1.34     skrll 		if ((trb_0 & 0x3) == 0x3) {
    1.34     skrll 			xfer->ux_actlen = XHCI_TRB_2_REM_GET(trb_2);
    1.34     skrll 		}
    1.34     skrll 	}
    1.34     skrll
    1.34     skrll 	switch (trbcode) {
    1.34     skrll 	case XHCI_TRB_ERROR_SHORT_PKT:
    1.34     skrll 	case XHCI_TRB_ERROR_SUCCESS:
    1.54     skrll 		/*
1.62.2.1  pgoyette 		 * A ctrl transfer can generate two events if it has a Data
1.62.2.1  pgoyette 		 * stage.  A short data stage can be OK and should not
1.62.2.1  pgoyette 		 * complete the transfer as the status stage needs to be
1.62.2.1  pgoyette 		 * performed.
    1.54     skrll 		 *
    1.54     skrll 		 * Note: Data and Status stage events point at same xfer.
    1.54     skrll 		 * ux_actlen and ux_dmabuf will be passed to
    1.54     skrll 		 * usb_transfer_complete after the Status stage event.
    1.54     skrll 		 *
    1.54     skrll 		 * It can be distingished which stage generates the event:
    1.54     skrll 		 * + by checking least 3 bits of trb_0 if ED==1.
    1.54     skrll 		 *   (see xhci_device_ctrl_start).
    1.54     skrll 		 * + by checking the type of original TRB if ED==0.
    1.54     skrll 		 *
    1.54     skrll 		 * In addition, intr, bulk, and isoc transfer currently
    1.54     skrll 		 * consists of single TD, so the "skip" is not needed.
    1.54     skrll 		 * ctrl xfer uses EVENT_DATA, and others do not.
    1.54     skrll 		 * Thus driver can switch the flow by checking ED bit.
    1.54     skrll 		 */
1.62.2.1  pgoyette 		if ((trb_3 & XHCI_TRB_3_ED_BIT) == 0) {
1.62.2.1  pgoyette 			if (xfer->ux_actlen == 0)
1.62.2.1  pgoyette 				xfer->ux_actlen = xfer->ux_length -
1.62.2.1  pgoyette 				    XHCI_TRB_2_REM_GET(trb_2);
1.62.2.1  pgoyette 			if (XHCI_TRB_3_TYPE_GET(le32toh(xr->xr_trb[idx].trb_3))
1.62.2.1  pgoyette 			    == XHCI_TRB_TYPE_DATA_STAGE) {
1.62.2.1  pgoyette 				return;
1.62.2.1  pgoyette 			}
1.62.2.1  pgoyette 		} else if ((trb_0 & 0x3) == 0x3) {
1.62.2.1  pgoyette 			return;
1.62.2.1  pgoyette 		}
    1.34     skrll 		err = USBD_NORMAL_COMPLETION;
    1.34     skrll 		break;
1.62.2.1  pgoyette 	case XHCI_TRB_ERROR_STOPPED:
1.62.2.1  pgoyette 	case XHCI_TRB_ERROR_LENGTH:
1.62.2.1  pgoyette 	case XHCI_TRB_ERROR_STOPPED_SHORT:
1.62.2.1  pgoyette 		/*
1.62.2.1  pgoyette 		 * don't complete the transfer being aborted
1.62.2.1  pgoyette 		 * as abort_xfer does instead.
1.62.2.1  pgoyette 		 */
1.62.2.1  pgoyette 		if (xfer->ux_hcflags & UXFER_ABORTING) {
1.62.2.1  pgoyette 			DPRINTFN(14, "ignore aborting xfer %p", xfer, 0, 0, 0);
1.62.2.1  pgoyette 			return;
1.62.2.1  pgoyette 		}
1.62.2.1  pgoyette 		err = USBD_CANCELLED;
1.62.2.1  pgoyette 		break;
    1.34     skrll 	case XHCI_TRB_ERROR_STALL:
    1.34     skrll 	case XHCI_TRB_ERROR_BABBLE:
    1.34     skrll 		DPRINTFN(1, "ERR %u slot %u dci %u", trbcode, slot, dci, 0);
    1.34     skrll 		xr->is_halted = true;
    1.34     skrll 		err = USBD_STALLED;
    1.34     skrll 		/*
    1.34     skrll 		 * Stalled endpoints can be recoverd by issuing
    1.34     skrll 		 * command TRB TYPE_RESET_EP on xHCI instead of
    1.34     skrll 		 * issuing request CLEAR_FEATURE UF_ENDPOINT_HALT
    1.34     skrll 		 * on the endpoint. However, this function may be
    1.34     skrll 		 * called from softint context (e.g. from umass),
    1.34     skrll 		 * in that case driver gets KASSERT in cv_timedwait
    1.34     skrll 		 * in xhci_do_command.
    1.34     skrll 		 * To avoid this, this runs reset_endpoint and
    1.34     skrll 		 * usb_transfer_complete in usb task thread
    1.34     skrll 		 * asynchronously (and then umass issues clear
    1.34     skrll 		 * UF_ENDPOINT_HALT).
    1.34     skrll 		 */
    1.34     skrll 		xfer->ux_status = err;
    1.57     skrll 		callout_stop(&xfer->ux_callout);
    1.34     skrll 		xhci_clear_endpoint_stall_async(xfer);
    1.34     skrll 		return;
    1.34     skrll 	default:
    1.34     skrll 		DPRINTFN(1, "ERR %u slot %u dci %u", trbcode, slot, dci, 0);
    1.34     skrll 		err = USBD_IOERROR;
    1.34     skrll 		break;
    1.34     skrll 	}
    1.34     skrll 	xfer->ux_status = err;
    1.34     skrll
    1.34     skrll 	if ((trb_3 & XHCI_TRB_3_ED_BIT) != 0) {
    1.34     skrll 		if ((trb_0 & 0x3) == 0x0) {
    1.34     skrll 			callout_stop(&xfer->ux_callout);
    1.34     skrll 			usb_transfer_complete(xfer);
    1.34     skrll 		}
    1.34     skrll 	} else {
    1.34     skrll 		callout_stop(&xfer->ux_callout);
    1.34     skrll 		usb_transfer_complete(xfer);
    1.34     skrll 	}
    1.34     skrll }
    1.34     skrll
    1.34     skrll /* Process Command complete events */
    1.34     skrll static void
    1.50     skrll xhci_event_cmd(struct xhci_softc * const sc, const struct xhci_trb * const trb)
    1.34     skrll {
    1.34     skrll 	uint64_t trb_0;
    1.34     skrll 	uint32_t trb_2, trb_3;
    1.34     skrll
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
1.62.2.2  pgoyette 	KASSERT(mutex_owned(&sc->sc_lock));
1.62.2.2  pgoyette
    1.34     skrll 	trb_0 = le64toh(trb->trb_0);
    1.34     skrll 	trb_2 = le32toh(trb->trb_2);
    1.34     skrll 	trb_3 = le32toh(trb->trb_3);
    1.34     skrll
    1.34     skrll 	if (trb_0 == sc->sc_command_addr) {
1.62.2.2  pgoyette 		sc->sc_resultpending = false;
1.62.2.2  pgoyette
    1.34     skrll 		sc->sc_result_trb.trb_0 = trb_0;
    1.34     skrll 		sc->sc_result_trb.trb_2 = trb_2;
    1.34     skrll 		sc->sc_result_trb.trb_3 = trb_3;
    1.34     skrll 		if (XHCI_TRB_2_ERROR_GET(trb_2) !=
    1.34     skrll 		    XHCI_TRB_ERROR_SUCCESS) {
    1.34     skrll 			DPRINTFN(1, "command completion "
    1.34     skrll 			    "failure: 0x%016"PRIx64" 0x%08"PRIx32" "
    1.34     skrll 			    "0x%08"PRIx32, trb_0, trb_2, trb_3, 0);
    1.34     skrll 		}
    1.34     skrll 		cv_signal(&sc->sc_command_cv);
    1.34     skrll 	} else {
    1.34     skrll 		DPRINTFN(1, "spurious event: %p 0x%016"PRIx64" "
    1.34     skrll 		    "0x%08"PRIx32" 0x%08"PRIx32, trb, trb_0,
    1.34     skrll 		    trb_2, trb_3);
    1.34     skrll 	}
    1.34     skrll }
    1.34     skrll
    1.34     skrll /*
    1.34     skrll  * Process events.
    1.34     skrll  * called from xhci_softintr
    1.34     skrll  */
    1.34     skrll static void
    1.34     skrll xhci_handle_event(struct xhci_softc * const sc,
    1.34     skrll     const struct xhci_trb * const trb)
    1.34     skrll {
    1.34     skrll 	uint64_t trb_0;
    1.34     skrll 	uint32_t trb_2, trb_3;
    1.34     skrll
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	trb_0 = le64toh(trb->trb_0);
    1.34     skrll 	trb_2 = le32toh(trb->trb_2);
    1.34     skrll 	trb_3 = le32toh(trb->trb_3);
    1.34     skrll
    1.34     skrll 	DPRINTFN(14, "event: %p 0x%016"PRIx64" 0x%08"PRIx32" 0x%08"PRIx32,
    1.34     skrll 	    trb, trb_0, trb_2, trb_3);
    1.34     skrll
    1.34     skrll 	/*
    1.34     skrll 	 * 4.11.3.1, 6.4.2.1
    1.34     skrll 	 * TRB Pointer is invalid for these completion codes.
    1.34     skrll 	 */
    1.34     skrll 	switch (XHCI_TRB_2_ERROR_GET(trb_2)) {
    1.34     skrll 	case XHCI_TRB_ERROR_RING_UNDERRUN:
    1.34     skrll 	case XHCI_TRB_ERROR_RING_OVERRUN:
    1.34     skrll 	case XHCI_TRB_ERROR_VF_RING_FULL:
    1.34     skrll 		return;
    1.34     skrll 	default:
    1.34     skrll 		if (trb_0 == 0) {
    1.34     skrll 			return;
    1.34     skrll 		}
    1.34     skrll 		break;
    1.34     skrll 	}
    1.34     skrll
    1.34     skrll 	switch (XHCI_TRB_3_TYPE_GET(trb_3)) {
    1.34     skrll 	case XHCI_TRB_EVENT_TRANSFER:
    1.34     skrll 		xhci_event_transfer(sc, trb);
    1.34     skrll 		break;
    1.34     skrll 	case XHCI_TRB_EVENT_CMD_COMPLETE:
    1.34     skrll 		xhci_event_cmd(sc, trb);
    1.34     skrll 		break;
    1.34     skrll 	case XHCI_TRB_EVENT_PORT_STS_CHANGE:
    1.34     skrll 		xhci_rhpsc(sc, (uint32_t)((trb_0 >> 24) & 0xff));
    1.34     skrll 		break;
    1.34     skrll 	default:
    1.34     skrll 		break;
    1.34     skrll 	}
    1.34     skrll }
    1.34     skrll
    1.34     skrll static void
    1.34     skrll xhci_softintr(void *v)
    1.34     skrll {
    1.34     skrll 	struct usbd_bus * const bus = v;
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(bus);
    1.34     skrll 	struct xhci_ring * const er = &sc->sc_er;
    1.34     skrll 	struct xhci_trb *trb;
    1.34     skrll 	int i, j, k;
    1.34     skrll
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	KASSERT(sc->sc_bus.ub_usepolling || mutex_owned(&sc->sc_lock));
    1.34     skrll
    1.34     skrll 	i = er->xr_ep;
    1.34     skrll 	j = er->xr_cs;
     1.1  jakllsch
    1.53     skrll 	DPRINTFN(16, "er: xr_ep %d xr_cs %d", i, j, 0, 0);
    1.27     skrll
     1.1  jakllsch 	while (1) {
     1.1  jakllsch 		usb_syncmem(&er->xr_dma, XHCI_TRB_SIZE * i, XHCI_TRB_SIZE,
     1.1  jakllsch 		    BUS_DMASYNC_POSTREAD);
     1.1  jakllsch 		trb = &er->xr_trb[i];
     1.1  jakllsch 		k = (le32toh(trb->trb_3) & XHCI_TRB_3_CYCLE_BIT) ? 1 : 0;
     1.1  jakllsch
     1.1  jakllsch 		if (j != k)
     1.1  jakllsch 			break;
     1.1  jakllsch
     1.1  jakllsch 		xhci_handle_event(sc, trb);
     1.1  jakllsch
     1.1  jakllsch 		i++;
    1.52     skrll 		if (i == er->xr_ntrb) {
     1.1  jakllsch 			i = 0;
     1.1  jakllsch 			j ^= 1;
     1.1  jakllsch 		}
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	er->xr_ep = i;
     1.1  jakllsch 	er->xr_cs = j;
     1.1  jakllsch
     1.1  jakllsch 	xhci_rt_write_8(sc, XHCI_ERDP(0), xhci_ring_trbp(er, er->xr_ep) |
     1.1  jakllsch 	    XHCI_ERDP_LO_BUSY);
     1.1  jakllsch
    1.27     skrll 	DPRINTFN(16, "ends", 0, 0, 0, 0);
     1.1  jakllsch
     1.1  jakllsch 	return;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch xhci_poll(struct usbd_bus *bus)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(bus);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch
    1.25     skrll 	mutex_spin_enter(&sc->sc_intr_lock);
     1.1  jakllsch 	xhci_intr1(sc);
    1.25     skrll 	mutex_spin_exit(&sc->sc_intr_lock);
     1.1  jakllsch
     1.1  jakllsch 	return;
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll static struct usbd_xfer *
    1.34     skrll xhci_allocx(struct usbd_bus *bus, unsigned int nframes)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(bus);
    1.34     skrll 	struct usbd_xfer *xfer;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch
     1.1  jakllsch 	xfer = pool_cache_get(sc->sc_xferpool, PR_NOWAIT);
     1.1  jakllsch 	if (xfer != NULL) {
     1.6     skrll 		memset(xfer, 0, sizeof(struct xhci_xfer));
     1.1  jakllsch #ifdef DIAGNOSTIC
    1.34     skrll 		xfer->ux_state = XFER_BUSY;
     1.1  jakllsch #endif
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	return xfer;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_freex(struct usbd_bus *bus, struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(bus);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch
     1.1  jakllsch #ifdef DIAGNOSTIC
    1.34     skrll 	if (xfer->ux_state != XFER_BUSY) {
    1.27     skrll 		DPRINTFN(0, "xfer=%p not busy, 0x%08x",
    1.34     skrll 		    xfer, xfer->ux_state, 0, 0);
     1.1  jakllsch 	}
    1.34     skrll 	xfer->ux_state = XFER_FREE;
     1.1  jakllsch #endif
     1.1  jakllsch 	pool_cache_put(sc->sc_xferpool, xfer);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch xhci_get_lock(struct usbd_bus *bus, kmutex_t **lock)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(bus);
     1.1  jakllsch
     1.1  jakllsch 	*lock = &sc->sc_lock;
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll extern uint32_t usb_cookie_no;
     1.1  jakllsch
    1.34     skrll /*
    1.41     skrll  * xHCI 4.3
    1.41     skrll  * Called when uhub_explore finds a new device (via usbd_new_device).
    1.41     skrll  * Port initialization and speed detection (4.3.1) are already done in uhub.c.
    1.41     skrll  * This function does:
    1.41     skrll  *   Allocate and construct dev structure of default endpoint (ep0).
    1.41     skrll  *   Allocate and open pipe of ep0.
    1.41     skrll  *   Enable slot and initialize slot context.
    1.41     skrll  *   Set Address.
    1.41     skrll  *   Read initial device descriptor.
    1.34     skrll  *   Determine initial MaxPacketSize (mps) by speed.
    1.41     skrll  *   Read full device descriptor.
    1.41     skrll  *   Register this device.
    1.54     skrll  * Finally state of device transitions ADDRESSED.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_new_device(device_t parent, struct usbd_bus *bus, int depth,
     1.1  jakllsch     int speed, int port, struct usbd_port *up)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(bus);
    1.34     skrll 	struct usbd_device *dev;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch 	usb_device_descriptor_t *dd;
     1.1  jakllsch 	struct xhci_slot *xs;
     1.1  jakllsch 	uint32_t *cp;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.51     skrll 	DPRINTFN(4, "port %u depth %u speed %u up %p", port, depth, speed, up);
    1.27     skrll
    1.34     skrll 	dev = kmem_zalloc(sizeof(*dev), KM_SLEEP);
     1.1  jakllsch 	if (dev == NULL)
     1.1  jakllsch 		return USBD_NOMEM;
     1.1  jakllsch
    1.34     skrll 	dev->ud_bus = bus;
    1.51     skrll 	dev->ud_quirks = &usbd_no_quirk;
    1.51     skrll 	dev->ud_addr = 0;
    1.51     skrll 	dev->ud_ddesc.bMaxPacketSize = 0;
    1.51     skrll 	dev->ud_depth = depth;
    1.51     skrll 	dev->ud_powersrc = up;
    1.51     skrll 	dev->ud_myhub = up->up_parent;
    1.51     skrll 	dev->ud_speed = speed;
    1.51     skrll 	dev->ud_langid = USBD_NOLANG;
    1.51     skrll 	dev->ud_cookie.cookie = ++usb_cookie_no;
     1.1  jakllsch
     1.1  jakllsch 	/* Set up default endpoint handle. */
    1.34     skrll 	dev->ud_ep0.ue_edesc = &dev->ud_ep0desc;
    1.51     skrll 	/* doesn't matter, just don't let it uninitialized */
    1.51     skrll 	dev->ud_ep0.ue_toggle = 0;
     1.1  jakllsch
     1.1  jakllsch 	/* Set up default endpoint descriptor. */
    1.34     skrll 	dev->ud_ep0desc.bLength = USB_ENDPOINT_DESCRIPTOR_SIZE;
    1.34     skrll 	dev->ud_ep0desc.bDescriptorType = UDESC_ENDPOINT;
    1.34     skrll 	dev->ud_ep0desc.bEndpointAddress = USB_CONTROL_ENDPOINT;
    1.34     skrll 	dev->ud_ep0desc.bmAttributes = UE_CONTROL;
    1.51     skrll 	dev->ud_ep0desc.bInterval = 0;
    1.50     skrll
    1.34     skrll 	/* 4.3,  4.8.2.1 */
    1.34     skrll 	switch (speed) {
    1.34     skrll 	case USB_SPEED_SUPER:
    1.34     skrll 	case USB_SPEED_SUPER_PLUS:
    1.34     skrll 		USETW(dev->ud_ep0desc.wMaxPacketSize, USB_3_MAX_CTRL_PACKET);
    1.34     skrll 		break;
    1.34     skrll 	case USB_SPEED_FULL:
    1.34     skrll 		/* XXX using 64 as initial mps of ep0 in FS */
    1.34     skrll 	case USB_SPEED_HIGH:
    1.34     skrll 		USETW(dev->ud_ep0desc.wMaxPacketSize, USB_2_MAX_CTRL_PACKET);
    1.34     skrll 		break;
    1.34     skrll 	case USB_SPEED_LOW:
    1.34     skrll 	default:
    1.34     skrll 		USETW(dev->ud_ep0desc.wMaxPacketSize, USB_MAX_IPACKET);
    1.34     skrll 		break;
    1.34     skrll 	}
     1.1  jakllsch
    1.51     skrll 	up->up_dev = dev;
    1.51     skrll
    1.51     skrll 	/* Establish the default pipe. */
    1.51     skrll 	err = usbd_setup_pipe(dev, 0, &dev->ud_ep0, USBD_DEFAULT_INTERVAL,
    1.51     skrll 	    &dev->ud_pipe0);
    1.51     skrll 	if (err) {
    1.51     skrll 		goto bad;
    1.51     skrll 	}
     1.1  jakllsch
    1.51     skrll 	dd = &dev->ud_ddesc;
     1.1  jakllsch
1.62.2.2  pgoyette 	if (depth == 0 && port == 0) {
1.62.2.2  pgoyette 		KASSERT(bus->ub_devices[USB_ROOTHUB_INDEX] == NULL);
1.62.2.2  pgoyette 		bus->ub_devices[USB_ROOTHUB_INDEX] = dev;
    1.51     skrll 		err = usbd_get_initial_ddesc(dev, dd);
    1.61     skrll 		if (err) {
    1.61     skrll 			DPRINTFN(1, "get_initial_ddesc %u", err, 0, 0, 0);
    1.34     skrll 			goto bad;
    1.61     skrll 		}
    1.61     skrll
     1.1  jakllsch 		err = usbd_reload_device_desc(dev);
    1.61     skrll 		if (err) {
    1.61     skrll 			DPRINTFN(1, "reload desc %u", err, 0, 0, 0);
    1.34     skrll 			goto bad;
    1.61     skrll 		}
     1.1  jakllsch 	} else {
    1.49     skrll 		uint8_t slot = 0;
    1.49     skrll
    1.48     skrll 		/* 4.3.2 */
     1.1  jakllsch 		err = xhci_enable_slot(sc, &slot);
1.62.2.1  pgoyette 		if (err) {
1.62.2.1  pgoyette 			DPRINTFN(1, "enable slot %u", err, 0, 0, 0);
    1.34     skrll 			goto bad;
1.62.2.1  pgoyette 		}
    1.50     skrll
     1.1  jakllsch 		xs = &sc->sc_slots[slot];
    1.34     skrll 		dev->ud_hcpriv = xs;
    1.50     skrll
    1.48     skrll 		/* 4.3.3 initialize slot structure */
    1.48     skrll 		err = xhci_init_slot(dev, slot);
    1.34     skrll 		if (err) {
1.62.2.1  pgoyette 			DPRINTFN(1, "init slot %u", err, 0, 0, 0);
    1.34     skrll 			dev->ud_hcpriv = NULL;
    1.34     skrll 			/*
    1.34     skrll 			 * We have to disable_slot here because
    1.34     skrll 			 * xs->xs_idx == 0 when xhci_init_slot fails,
    1.34     skrll 			 * in that case usbd_remove_dev won't work.
    1.34     skrll 			 */
    1.34     skrll 			mutex_enter(&sc->sc_lock);
    1.34     skrll 			xhci_disable_slot(sc, slot);
    1.34     skrll 			mutex_exit(&sc->sc_lock);
    1.34     skrll 			goto bad;
    1.34     skrll 		}
    1.34     skrll
    1.48     skrll 		/* 4.3.4 Address Assignment */
    1.51     skrll 		err = xhci_set_address(dev, slot, false);
    1.61     skrll 		if (err) {
    1.61     skrll 			DPRINTFN(1, "set address w/o bsr %u", err, 0, 0, 0);
    1.48     skrll 			goto bad;
    1.61     skrll 		}
    1.48     skrll
    1.34     skrll 		/* Allow device time to set new address */
    1.34     skrll 		usbd_delay_ms(dev, USB_SET_ADDRESS_SETTLE);
    1.50     skrll
     1.1  jakllsch 		cp = xhci_slot_get_dcv(sc, xs, XHCI_DCI_SLOT);
     1.1  jakllsch 		//hexdump("slot context", cp, sc->sc_ctxsz);
    1.49     skrll 		uint8_t addr = XHCI_SCTX_3_DEV_ADDR_GET(cp[3]);
    1.27     skrll 		DPRINTFN(4, "device address %u", addr, 0, 0, 0);
1.62.2.2  pgoyette 		/*
1.62.2.2  pgoyette 		 * XXX ensure we know when the hardware does something
1.62.2.2  pgoyette 		 * we can't yet cope with
1.62.2.2  pgoyette 		 */
    1.59      maya 		KASSERTMSG(addr >= 1 && addr <= 127, "addr %d", addr);
    1.34     skrll 		dev->ud_addr = addr;
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		KASSERTMSG(bus->ub_devices[usb_addr2dindex(dev->ud_addr)] == NULL,
1.62.2.2  pgoyette 		    "addr %d already allocated", dev->ud_addr);
1.62.2.2  pgoyette 		/*
1.62.2.2  pgoyette 		 * The root hub is given its own slot
1.62.2.2  pgoyette 		 */
1.62.2.2  pgoyette 		bus->ub_devices[usb_addr2dindex(dev->ud_addr)] = dev;
     1.1  jakllsch
     1.1  jakllsch 		err = usbd_get_initial_ddesc(dev, dd);
    1.61     skrll 		if (err) {
    1.61     skrll 			DPRINTFN(1, "get_initial_ddesc %u", err, 0, 0, 0);
    1.34     skrll 			goto bad;
    1.61     skrll 		}
    1.50     skrll
    1.24     skrll 		/* 4.8.2.1 */
    1.34     skrll 		if (USB_IS_SS(speed)) {
    1.34     skrll 			if (dd->bMaxPacketSize != 9) {
    1.34     skrll 				printf("%s: invalid mps 2^%u for SS ep0,"
    1.34     skrll 				    " using 512\n",
    1.34     skrll 				    device_xname(sc->sc_dev),
    1.34     skrll 				    dd->bMaxPacketSize);
    1.34     skrll 				dd->bMaxPacketSize = 9;
    1.34     skrll 			}
    1.34     skrll 			USETW(dev->ud_ep0desc.wMaxPacketSize,
    1.24     skrll 			    (1 << dd->bMaxPacketSize));
    1.34     skrll 		} else
    1.34     skrll 			USETW(dev->ud_ep0desc.wMaxPacketSize,
    1.24     skrll 			    dd->bMaxPacketSize);
    1.27     skrll 		DPRINTFN(4, "bMaxPacketSize %u", dd->bMaxPacketSize, 0, 0, 0);
    1.62     skrll 		err = xhci_update_ep0_mps(sc, xs,
    1.34     skrll 		    UGETW(dev->ud_ep0desc.wMaxPacketSize));
    1.62     skrll 		if (err) {
    1.62     skrll 			DPRINTFN(1, "update mps of ep0 %u", err, 0, 0, 0);
    1.62     skrll 			goto bad;
    1.62     skrll 		}
    1.50     skrll
     1.1  jakllsch 		err = usbd_reload_device_desc(dev);
    1.61     skrll 		if (err) {
    1.61     skrll 			DPRINTFN(1, "reload desc %u", err, 0, 0, 0);
    1.34     skrll 			goto bad;
    1.61     skrll 		}
     1.1  jakllsch 	}
     1.1  jakllsch
    1.27     skrll 	DPRINTFN(1, "adding unit addr=%d, rev=%02x,",
    1.34     skrll 		dev->ud_addr, UGETW(dd->bcdUSB), 0, 0);
    1.27     skrll 	DPRINTFN(1, " class=%d, subclass=%d, protocol=%d,",
    1.27     skrll 		dd->bDeviceClass, dd->bDeviceSubClass,
    1.27     skrll 		dd->bDeviceProtocol, 0);
    1.27     skrll 	DPRINTFN(1, " mps=%d, len=%d, noconf=%d, speed=%d",
    1.27     skrll 		dd->bMaxPacketSize, dd->bLength, dd->bNumConfigurations,
    1.34     skrll 		dev->ud_speed);
     1.1  jakllsch
    1.33     skrll 	usbd_get_device_strings(dev);
    1.33     skrll
     1.1  jakllsch 	usbd_add_dev_event(USB_EVENT_DEVICE_ATTACH, dev);
     1.1  jakllsch
1.62.2.2  pgoyette 	if (depth == 0 && port == 0) {
     1.1  jakllsch 		usbd_attach_roothub(parent, dev);
1.62.2.2  pgoyette 		DPRINTFN(1, "root hub %p", dev, 0, 0, 0);
     1.1  jakllsch 		return USBD_NORMAL_COMPLETION;
     1.1  jakllsch 	}
     1.1  jakllsch
    1.34     skrll 	err = usbd_probe_and_attach(parent, dev, port, dev->ud_addr);
    1.34     skrll  bad:
    1.34     skrll 	if (err != USBD_NORMAL_COMPLETION) {
     1.1  jakllsch 		usbd_remove_device(dev, up);
     1.1  jakllsch 	}
     1.1  jakllsch
    1.34     skrll 	return err;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static usbd_status
     1.1  jakllsch xhci_ring_init(struct xhci_softc * const sc, struct xhci_ring * const xr,
     1.1  jakllsch     size_t ntrb, size_t align)
     1.1  jakllsch {
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch 	size_t size = ntrb * XHCI_TRB_SIZE;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	err = usb_allocmem(&sc->sc_bus, size, align, &xr->xr_dma);
     1.1  jakllsch 	if (err)
     1.1  jakllsch 		return err;
     1.1  jakllsch 	mutex_init(&xr->xr_lock, MUTEX_DEFAULT, IPL_SOFTUSB);
     1.1  jakllsch 	xr->xr_cookies = kmem_zalloc(sizeof(*xr->xr_cookies) * ntrb, KM_SLEEP);
     1.1  jakllsch 	xr->xr_trb = xhci_ring_trbv(xr, 0);
     1.1  jakllsch 	xr->xr_ntrb = ntrb;
     1.1  jakllsch 	xr->is_halted = false;
    1.55     skrll 	xhci_host_dequeue(xr);
     1.1  jakllsch
     1.1  jakllsch 	return USBD_NORMAL_COMPLETION;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch xhci_ring_free(struct xhci_softc * const sc, struct xhci_ring * const xr)
     1.1  jakllsch {
     1.1  jakllsch 	usb_freemem(&sc->sc_bus, &xr->xr_dma);
     1.1  jakllsch 	mutex_destroy(&xr->xr_lock);
     1.1  jakllsch 	kmem_free(xr->xr_cookies, sizeof(*xr->xr_cookies) * xr->xr_ntrb);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch xhci_ring_put(struct xhci_softc * const sc, struct xhci_ring * const xr,
     1.1  jakllsch     void *cookie, struct xhci_trb * const trbs, size_t ntrbs)
     1.1  jakllsch {
     1.1  jakllsch 	size_t i;
     1.1  jakllsch 	u_int ri;
     1.1  jakllsch 	u_int cs;
     1.1  jakllsch 	uint64_t parameter;
     1.1  jakllsch 	uint32_t status;
     1.1  jakllsch 	uint32_t control;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
    1.59      maya 	KASSERTMSG(ntrbs <= XHCI_XFER_NTRB, "ntrbs %zu", ntrbs);
     1.1  jakllsch 	for (i = 0; i < ntrbs; i++) {
    1.27     skrll 		DPRINTFN(12, "xr %p trbs %p num %zu", xr, trbs, i, 0);
    1.27     skrll 		DPRINTFN(12, " %016"PRIx64" %08"PRIx32" %08"PRIx32,
    1.27     skrll 		    trbs[i].trb_0, trbs[i].trb_2, trbs[i].trb_3, 0);
    1.59      maya 		KASSERTMSG(XHCI_TRB_3_TYPE_GET(trbs[i].trb_3) !=
1.62.2.1  pgoyette 		    XHCI_TRB_TYPE_LINK, "trbs[%zu].trb3 %#x", i, trbs[i].trb_3);
     1.1  jakllsch 	}
     1.1  jakllsch
    1.27     skrll 	DPRINTFN(12, "%p xr_ep 0x%x xr_cs %u", xr, xr->xr_ep, xr->xr_cs, 0);
     1.1  jakllsch
     1.1  jakllsch 	ri = xr->xr_ep;
     1.1  jakllsch 	cs = xr->xr_cs;
     1.1  jakllsch
    1.11       dsl 	/*
    1.11       dsl 	 * Although the xhci hardware can do scatter/gather dma from
    1.11       dsl 	 * arbitrary sized buffers, there is a non-obvious restriction
    1.11       dsl 	 * that a LINK trb is only allowed at the end of a burst of
    1.11       dsl 	 * transfers - which might be 16kB.
    1.11       dsl 	 * Arbitrary aligned LINK trb definitely fail on Ivy bridge.
    1.11       dsl 	 * The simple solution is not to allow a LINK trb in the middle
    1.11       dsl 	 * of anything - as here.
    1.13       dsl 	 * XXX: (dsl) There are xhci controllers out there (eg some made by
    1.13       dsl 	 * ASMedia) that seem to lock up if they process a LINK trb but
    1.13       dsl 	 * cannot process the linked-to trb yet.
    1.13       dsl 	 * The code should write the 'cycle' bit on the link trb AFTER
    1.13       dsl 	 * adding the other trb.
    1.11       dsl 	 */
     1.1  jakllsch 	if (ri + ntrbs >= (xr->xr_ntrb - 1)) {
     1.1  jakllsch 		parameter = xhci_ring_trbp(xr, 0);
     1.1  jakllsch 		status = 0;
     1.1  jakllsch 		control = XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_LINK) |
     1.1  jakllsch 		    XHCI_TRB_3_TC_BIT | (cs ? XHCI_TRB_3_CYCLE_BIT : 0);
    1.34     skrll 		xhci_trb_put(&xr->xr_trb[ri], parameter, status, control);
     1.1  jakllsch 		usb_syncmem(&xr->xr_dma, XHCI_TRB_SIZE * ri, XHCI_TRB_SIZE * 1,
     1.1  jakllsch 		    BUS_DMASYNC_PREWRITE);
     1.1  jakllsch 		xr->xr_cookies[ri] = NULL;
     1.1  jakllsch 		xr->xr_ep = 0;
     1.1  jakllsch 		xr->xr_cs ^= 1;
     1.1  jakllsch 		ri = xr->xr_ep;
     1.1  jakllsch 		cs = xr->xr_cs;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	ri++;
     1.1  jakllsch
    1.11       dsl 	/* Write any subsequent TRB first */
     1.1  jakllsch 	for (i = 1; i < ntrbs; i++) {
     1.1  jakllsch 		parameter = trbs[i].trb_0;
     1.1  jakllsch 		status = trbs[i].trb_2;
     1.1  jakllsch 		control = trbs[i].trb_3;
     1.1  jakllsch
     1.1  jakllsch 		if (cs) {
     1.1  jakllsch 			control |= XHCI_TRB_3_CYCLE_BIT;
     1.1  jakllsch 		} else {
     1.1  jakllsch 			control &= ~XHCI_TRB_3_CYCLE_BIT;
     1.1  jakllsch 		}
     1.1  jakllsch
    1.34     skrll 		xhci_trb_put(&xr->xr_trb[ri], parameter, status, control);
     1.1  jakllsch 		usb_syncmem(&xr->xr_dma, XHCI_TRB_SIZE * ri, XHCI_TRB_SIZE * 1,
     1.1  jakllsch 		    BUS_DMASYNC_PREWRITE);
     1.1  jakllsch 		xr->xr_cookies[ri] = cookie;
     1.1  jakllsch 		ri++;
     1.1  jakllsch 	}
     1.1  jakllsch
    1.11       dsl 	/* Write the first TRB last */
     1.1  jakllsch 	i = 0;
    1.34     skrll 	parameter = trbs[i].trb_0;
    1.34     skrll 	status = trbs[i].trb_2;
    1.34     skrll 	control = trbs[i].trb_3;
     1.1  jakllsch
    1.34     skrll 	if (xr->xr_cs) {
    1.34     skrll 		control |= XHCI_TRB_3_CYCLE_BIT;
    1.34     skrll 	} else {
    1.34     skrll 		control &= ~XHCI_TRB_3_CYCLE_BIT;
    1.34     skrll 	}
     1.1  jakllsch
    1.34     skrll 	xhci_trb_put(&xr->xr_trb[xr->xr_ep], parameter, status, control);
    1.47   mlelstv 	usb_syncmem(&xr->xr_dma, XHCI_TRB_SIZE * xr->xr_ep, XHCI_TRB_SIZE * 1,
    1.34     skrll 	    BUS_DMASYNC_PREWRITE);
    1.34     skrll 	xr->xr_cookies[xr->xr_ep] = cookie;
     1.1  jakllsch
     1.1  jakllsch 	xr->xr_ep = ri;
     1.1  jakllsch 	xr->xr_cs = cs;
     1.1  jakllsch
    1.27     skrll 	DPRINTFN(12, "%p xr_ep 0x%x xr_cs %u", xr, xr->xr_ep, xr->xr_cs, 0);
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /*
    1.39     skrll  * Stop execution commands, purge all commands on command ring, and
    1.54     skrll  * rewind dequeue pointer.
    1.39     skrll  */
    1.39     skrll static void
    1.39     skrll xhci_abort_command(struct xhci_softc *sc)
    1.39     skrll {
    1.39     skrll 	struct xhci_ring * const cr = &sc->sc_cr;
    1.39     skrll 	uint64_t crcr;
    1.39     skrll 	int i;
    1.39     skrll
    1.39     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.39     skrll 	DPRINTFN(14, "command %#"PRIx64" timeout, aborting",
    1.39     skrll 	    sc->sc_command_addr, 0, 0, 0);
    1.39     skrll
    1.39     skrll 	mutex_enter(&cr->xr_lock);
    1.39     skrll
    1.39     skrll 	/* 4.6.1.2 Aborting a Command */
    1.39     skrll 	crcr = xhci_op_read_8(sc, XHCI_CRCR);
    1.39     skrll 	xhci_op_write_8(sc, XHCI_CRCR, crcr | XHCI_CRCR_LO_CA);
    1.39     skrll
    1.39     skrll 	for (i = 0; i < 500; i++) {
    1.39     skrll 		crcr = xhci_op_read_8(sc, XHCI_CRCR);
    1.39     skrll 		if ((crcr & XHCI_CRCR_LO_CRR) == 0)
    1.39     skrll 			break;
    1.39     skrll 		usb_delay_ms(&sc->sc_bus, 1);
    1.39     skrll 	}
    1.39     skrll 	if ((crcr & XHCI_CRCR_LO_CRR) != 0) {
    1.39     skrll 		DPRINTFN(1, "Command Abort timeout", 0, 0, 0, 0);
    1.39     skrll 		/* reset HC here? */
    1.39     skrll 	}
    1.39     skrll
    1.39     skrll 	/* reset command ring dequeue pointer */
    1.39     skrll 	cr->xr_ep = 0;
    1.39     skrll 	cr->xr_cs = 1;
    1.39     skrll 	xhci_op_write_8(sc, XHCI_CRCR, xhci_ring_trbp(cr, 0) | cr->xr_cs);
    1.39     skrll
    1.39     skrll 	mutex_exit(&cr->xr_lock);
    1.39     skrll }
    1.39     skrll
    1.39     skrll /*
    1.34     skrll  * Put a command on command ring, ring bell, set timer, and cv_timedwait.
    1.54     skrll  * Command completion is notified by cv_signal from xhci_event_cmd()
    1.54     skrll  * (called from xhci_softint), or timed-out.
    1.54     skrll  * The completion code is copied to sc->sc_result_trb in xhci_event_cmd(),
    1.54     skrll  * then do_command examines it.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
    1.50     skrll xhci_do_command_locked(struct xhci_softc * const sc,
    1.50     skrll     struct xhci_trb * const trb, int timeout)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_ring * const cr = &sc->sc_cr;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll 	DPRINTFN(12, "input: 0x%016"PRIx64" 0x%08"PRIx32" 0x%08"PRIx32,
    1.27     skrll 	    trb->trb_0, trb->trb_2, trb->trb_3, 0);
     1.1  jakllsch
    1.34     skrll 	KASSERTMSG(!cpu_intr_p() && !cpu_softintr_p(), "called from intr ctx");
    1.34     skrll 	KASSERT(mutex_owned(&sc->sc_lock));
     1.1  jakllsch
1.62.2.2  pgoyette 	while (sc->sc_command_addr != 0)
1.62.2.2  pgoyette 		cv_wait(&sc->sc_cmdbusy_cv, &sc->sc_lock);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	/*
1.62.2.2  pgoyette 	 * If enqueue pointer points at last of ring, it's Link TRB,
1.62.2.2  pgoyette 	 * command TRB will be stored in 0th TRB.
1.62.2.2  pgoyette 	 */
1.62.2.2  pgoyette 	if (cr->xr_ep == cr->xr_ntrb - 1)
1.62.2.2  pgoyette 		sc->sc_command_addr = xhci_ring_trbp(cr, 0);
1.62.2.2  pgoyette 	else
1.62.2.2  pgoyette 		sc->sc_command_addr = xhci_ring_trbp(cr, cr->xr_ep);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	sc->sc_resultpending = true;
     1.1  jakllsch
     1.1  jakllsch 	mutex_enter(&cr->xr_lock);
     1.1  jakllsch 	xhci_ring_put(sc, cr, NULL, trb, 1);
     1.1  jakllsch 	mutex_exit(&cr->xr_lock);
     1.1  jakllsch
     1.1  jakllsch 	xhci_db_write_4(sc, XHCI_DOORBELL(0), 0);
     1.1  jakllsch
1.62.2.2  pgoyette 	while (sc->sc_resultpending) {
1.62.2.2  pgoyette 		if (cv_timedwait(&sc->sc_command_cv, &sc->sc_lock,
1.62.2.2  pgoyette 		    MAX(1, mstohz(timeout))) == EWOULDBLOCK) {
1.62.2.2  pgoyette 			xhci_abort_command(sc);
1.62.2.2  pgoyette 			err = USBD_TIMEOUT;
1.62.2.2  pgoyette 			goto timedout;
1.62.2.2  pgoyette 		}
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	trb->trb_0 = sc->sc_result_trb.trb_0;
     1.1  jakllsch 	trb->trb_2 = sc->sc_result_trb.trb_2;
     1.1  jakllsch 	trb->trb_3 = sc->sc_result_trb.trb_3;
     1.1  jakllsch
    1.27     skrll 	DPRINTFN(12, "output: 0x%016"PRIx64" 0x%08"PRIx32" 0x%08"PRIx32"",
    1.27     skrll 	    trb->trb_0, trb->trb_2, trb->trb_3, 0);
     1.1  jakllsch
     1.1  jakllsch 	switch (XHCI_TRB_2_ERROR_GET(trb->trb_2)) {
     1.1  jakllsch 	case XHCI_TRB_ERROR_SUCCESS:
     1.1  jakllsch 		err = USBD_NORMAL_COMPLETION;
     1.1  jakllsch 		break;
     1.1  jakllsch 	default:
     1.1  jakllsch 	case 192 ... 223:
     1.1  jakllsch 		err = USBD_IOERROR;
     1.1  jakllsch 		break;
     1.1  jakllsch 	case 224 ... 255:
     1.1  jakllsch 		err = USBD_NORMAL_COMPLETION;
     1.1  jakllsch 		break;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch timedout:
1.62.2.2  pgoyette 	sc->sc_resultpending = false;
     1.1  jakllsch 	sc->sc_command_addr = 0;
1.62.2.2  pgoyette 	cv_broadcast(&sc->sc_cmdbusy_cv);
1.62.2.2  pgoyette
    1.34     skrll 	return err;
    1.34     skrll }
    1.34     skrll
    1.34     skrll static usbd_status
    1.34     skrll xhci_do_command(struct xhci_softc * const sc, struct xhci_trb * const trb,
    1.34     skrll     int timeout)
    1.34     skrll {
    1.34     skrll
    1.34     skrll 	mutex_enter(&sc->sc_lock);
    1.38     skrll 	usbd_status ret = xhci_do_command_locked(sc, trb, timeout);
     1.1  jakllsch 	mutex_exit(&sc->sc_lock);
    1.34     skrll
    1.34     skrll 	return ret;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static usbd_status
     1.1  jakllsch xhci_enable_slot(struct xhci_softc * const sc, uint8_t * const slotp)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_trb trb;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	trb.trb_0 = 0;
     1.1  jakllsch 	trb.trb_2 = 0;
     1.1  jakllsch 	trb.trb_3 = XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_ENABLE_SLOT);
     1.1  jakllsch
     1.1  jakllsch 	err = xhci_do_command(sc, &trb, USBD_DEFAULT_TIMEOUT);
     1.1  jakllsch 	if (err != USBD_NORMAL_COMPLETION) {
     1.1  jakllsch 		return err;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	*slotp = XHCI_TRB_3_SLOT_GET(trb.trb_3);
     1.1  jakllsch
     1.1  jakllsch 	return err;
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /*
    1.41     skrll  * xHCI 4.6.4
    1.41     skrll  * Deallocate ring and device/input context DMA buffers, and disable_slot.
    1.41     skrll  * All endpoints in the slot should be stopped.
    1.34     skrll  * Should be called with sc_lock held.
    1.34     skrll  */
    1.34     skrll static usbd_status
    1.34     skrll xhci_disable_slot(struct xhci_softc * const sc, uint8_t slot)
    1.34     skrll {
    1.34     skrll 	struct xhci_trb trb;
    1.34     skrll 	struct xhci_slot *xs;
    1.34     skrll 	usbd_status err;
    1.34     skrll
    1.34     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	if (sc->sc_dying)
    1.34     skrll 		return USBD_IOERROR;
    1.34     skrll
    1.34     skrll 	trb.trb_0 = 0;
    1.34     skrll 	trb.trb_2 = 0;
    1.34     skrll 	trb.trb_3 = htole32(
    1.34     skrll 		XHCI_TRB_3_SLOT_SET(slot) |
    1.34     skrll 		XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_DISABLE_SLOT));
    1.34     skrll
    1.34     skrll 	err = xhci_do_command_locked(sc, &trb, USBD_DEFAULT_TIMEOUT);
    1.34     skrll
    1.34     skrll 	if (!err) {
    1.34     skrll 		xs = &sc->sc_slots[slot];
    1.34     skrll 		if (xs->xs_idx != 0) {
    1.48     skrll 			xhci_free_slot(sc, xs, XHCI_DCI_SLOT + 1, 32);
    1.34     skrll 			xhci_set_dcba(sc, 0, slot);
    1.34     skrll 			memset(xs, 0, sizeof(*xs));
    1.34     skrll 		}
    1.34     skrll 	}
    1.34     skrll
    1.34     skrll 	return err;
    1.34     skrll }
    1.34     skrll
    1.34     skrll /*
    1.41     skrll  * Set address of device and transition slot state from ENABLED to ADDRESSED
    1.41     skrll  * if Block Setaddress Request (BSR) is false.
    1.41     skrll  * If BSR==true, transition slot state from ENABLED to DEFAULT.
    1.34     skrll  * see xHCI 1.1  4.5.3, 3.3.4
    1.41     skrll  * Should be called without sc_lock held.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
     1.1  jakllsch xhci_address_device(struct xhci_softc * const sc,
     1.1  jakllsch     uint64_t icp, uint8_t slot_id, bool bsr)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_trb trb;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	trb.trb_0 = icp;
     1.1  jakllsch 	trb.trb_2 = 0;
     1.1  jakllsch 	trb.trb_3 = XHCI_TRB_3_SLOT_SET(slot_id) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_ADDRESS_DEVICE) |
     1.1  jakllsch 	    (bsr ? XHCI_TRB_3_BSR_BIT : 0);
     1.1  jakllsch
     1.1  jakllsch 	err = xhci_do_command(sc, &trb, USBD_DEFAULT_TIMEOUT);
    1.34     skrll
    1.34     skrll 	if (XHCI_TRB_2_ERROR_GET(trb.trb_2) == XHCI_TRB_ERROR_NO_SLOTS)
    1.34     skrll 		err = USBD_NO_ADDR;
    1.34     skrll
     1.1  jakllsch 	return err;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static usbd_status
     1.1  jakllsch xhci_update_ep0_mps(struct xhci_softc * const sc,
     1.1  jakllsch     struct xhci_slot * const xs, u_int mps)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_trb trb;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch 	uint32_t * cp;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll 	DPRINTFN(4, "slot %u mps %u", xs->xs_idx, mps, 0, 0);
     1.1  jakllsch
     1.1  jakllsch 	cp = xhci_slot_get_icv(sc, xs, XHCI_ICI_INPUT_CONTROL);
     1.1  jakllsch 	cp[0] = htole32(0);
     1.1  jakllsch 	cp[1] = htole32(XHCI_INCTX_1_ADD_MASK(XHCI_DCI_EP_CONTROL));
     1.1  jakllsch
     1.1  jakllsch 	cp = xhci_slot_get_icv(sc, xs, xhci_dci_to_ici(XHCI_DCI_EP_CONTROL));
     1.1  jakllsch 	cp[1] = htole32(XHCI_EPCTX_1_MAXP_SIZE_SET(mps));
     1.1  jakllsch
     1.1  jakllsch 	/* sync input contexts before they are read from memory */
     1.1  jakllsch 	usb_syncmem(&xs->xs_ic_dma, 0, sc->sc_pgsz, BUS_DMASYNC_PREWRITE);
     1.1  jakllsch 	hexdump("input context", xhci_slot_get_icv(sc, xs, 0),
     1.1  jakllsch 	    sc->sc_ctxsz * 4);
     1.1  jakllsch
     1.1  jakllsch 	trb.trb_0 = xhci_slot_get_icp(sc, xs, 0);
     1.1  jakllsch 	trb.trb_2 = 0;
     1.1  jakllsch 	trb.trb_3 = XHCI_TRB_3_SLOT_SET(xs->xs_idx) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_EVALUATE_CTX);
     1.1  jakllsch
     1.1  jakllsch 	err = xhci_do_command(sc, &trb, USBD_DEFAULT_TIMEOUT);
     1.1  jakllsch 	return err;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch xhci_set_dcba(struct xhci_softc * const sc, uint64_t dcba, int si)
     1.1  jakllsch {
     1.1  jakllsch 	uint64_t * const dcbaa = KERNADDR(&sc->sc_dcbaa_dma, 0);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll 	DPRINTFN(4, "dcbaa %p dc %016"PRIx64" slot %d",
    1.27     skrll 	    &dcbaa[si], dcba, si, 0);
     1.1  jakllsch
     1.5      matt 	dcbaa[si] = htole64(dcba);
     1.1  jakllsch 	usb_syncmem(&sc->sc_dcbaa_dma, si * sizeof(uint64_t), sizeof(uint64_t),
     1.1  jakllsch 	    BUS_DMASYNC_PREWRITE);
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /*
    1.48     skrll  * Allocate device and input context DMA buffer, and
    1.48     skrll  * TRB DMA buffer for each endpoint.
    1.34     skrll  */
     1.1  jakllsch static usbd_status
    1.48     skrll xhci_init_slot(struct usbd_device *dev, uint32_t slot)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(dev->ud_bus);
     1.1  jakllsch 	struct xhci_slot *xs;
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch 	u_int dci;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.48     skrll 	DPRINTFN(4, "slot %u", slot, 0, 0, 0);
     1.1  jakllsch
     1.1  jakllsch 	xs = &sc->sc_slots[slot];
     1.1  jakllsch
     1.1  jakllsch 	/* allocate contexts */
     1.1  jakllsch 	err = usb_allocmem(&sc->sc_bus, sc->sc_pgsz, sc->sc_pgsz,
     1.1  jakllsch 	    &xs->xs_dc_dma);
     1.1  jakllsch 	if (err)
     1.1  jakllsch 		return err;
     1.1  jakllsch 	memset(KERNADDR(&xs->xs_dc_dma, 0), 0, sc->sc_pgsz);
     1.1  jakllsch
     1.1  jakllsch 	err = usb_allocmem(&sc->sc_bus, sc->sc_pgsz, sc->sc_pgsz,
     1.1  jakllsch 	    &xs->xs_ic_dma);
     1.1  jakllsch 	if (err)
    1.34     skrll 		goto bad1;
     1.1  jakllsch 	memset(KERNADDR(&xs->xs_ic_dma, 0), 0, sc->sc_pgsz);
     1.1  jakllsch
     1.1  jakllsch 	for (dci = 0; dci < 32; dci++) {
     1.1  jakllsch 		//CTASSERT(sizeof(xs->xs_ep[dci]) == sizeof(struct xhci_endpoint));
     1.1  jakllsch 		memset(&xs->xs_ep[dci], 0, sizeof(xs->xs_ep[dci]));
     1.1  jakllsch 		if (dci == XHCI_DCI_SLOT)
     1.1  jakllsch 			continue;
     1.1  jakllsch 		err = xhci_ring_init(sc, &xs->xs_ep[dci].xe_tr,
     1.1  jakllsch 		    XHCI_TRANSFER_RING_TRBS, XHCI_TRB_ALIGN);
     1.1  jakllsch 		if (err) {
    1.27     skrll 			DPRINTFN(0, "ring init failure", 0, 0, 0, 0);
    1.34     skrll 			goto bad2;
     1.1  jakllsch 		}
     1.1  jakllsch 	}
     1.1  jakllsch
    1.48     skrll  bad2:
    1.48     skrll 	if (err == USBD_NORMAL_COMPLETION) {
    1.48     skrll 		xs->xs_idx = slot;
    1.48     skrll 	} else {
    1.48     skrll 		xhci_free_slot(sc, xs, XHCI_DCI_SLOT + 1, dci);
    1.48     skrll 	}
    1.48     skrll
    1.48     skrll 	return err;
    1.48     skrll
    1.48     skrll  bad1:
    1.48     skrll 	usb_freemem(&sc->sc_bus, &xs->xs_dc_dma);
    1.48     skrll 	xs->xs_idx = 0;
    1.48     skrll 	return err;
    1.48     skrll }
    1.48     skrll
    1.48     skrll static void
    1.48     skrll xhci_free_slot(struct xhci_softc *sc, struct xhci_slot *xs, int start_dci,
    1.48     skrll     int end_dci)
    1.48     skrll {
    1.48     skrll 	u_int dci;
    1.48     skrll
    1.48     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.48     skrll 	DPRINTFN(4, "slot %u start %u end %u", xs->xs_idx, start_dci, end_dci,
    1.48     skrll 	    0);
    1.48     skrll
    1.48     skrll 	for (dci = start_dci; dci < end_dci; dci++) {
    1.48     skrll 		xhci_ring_free(sc, &xs->xs_ep[dci].xe_tr);
    1.48     skrll 		memset(&xs->xs_ep[dci], 0, sizeof(xs->xs_ep[dci]));
    1.48     skrll 	}
    1.48     skrll 	usb_freemem(&sc->sc_bus, &xs->xs_ic_dma);
    1.48     skrll 	usb_freemem(&sc->sc_bus, &xs->xs_dc_dma);
    1.48     skrll 	xs->xs_idx = 0;
    1.48     skrll }
    1.48     skrll
    1.48     skrll /*
    1.48     skrll  * Setup slot context, set Device Context Base Address, and issue
    1.48     skrll  * Set Address Device command.
    1.48     skrll  */
    1.48     skrll static usbd_status
    1.51     skrll xhci_set_address(struct usbd_device *dev, uint32_t slot, bool bsr)
    1.48     skrll {
    1.48     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(dev->ud_bus);
    1.48     skrll 	struct xhci_slot *xs;
    1.48     skrll 	usbd_status err;
    1.51     skrll
    1.51     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.51     skrll 	DPRINTFN(4, "slot %u bsr %u", slot, bsr, 0, 0);
    1.51     skrll
    1.51     skrll 	xs = &sc->sc_slots[slot];
    1.51     skrll
    1.51     skrll 	xhci_setup_ctx(dev->ud_pipe0);
    1.51     skrll
    1.51     skrll 	hexdump("input context", xhci_slot_get_icv(sc, xs, 0),
    1.51     skrll 	    sc->sc_ctxsz * 3);
    1.51     skrll
    1.51     skrll 	xhci_set_dcba(sc, DMAADDR(&xs->xs_dc_dma, 0), slot);
    1.51     skrll
    1.51     skrll 	err = xhci_address_device(sc, xhci_slot_get_icp(sc, xs, 0), slot, bsr);
    1.51     skrll
    1.51     skrll 	usb_syncmem(&xs->xs_dc_dma, 0, sc->sc_pgsz, BUS_DMASYNC_POSTREAD);
    1.51     skrll 	hexdump("output context", xhci_slot_get_dcv(sc, xs, 0),
    1.51     skrll 	    sc->sc_ctxsz * 2);
    1.51     skrll
    1.51     skrll 	return err;
    1.51     skrll }
    1.51     skrll
    1.51     skrll /*
    1.51     skrll  * 4.8.2, 6.2.3.2
    1.51     skrll  * construct slot/endpoint context parameters and do syncmem
    1.51     skrll  */
    1.51     skrll static void
    1.51     skrll xhci_setup_ctx(struct usbd_pipe *pipe)
    1.51     skrll {
    1.51     skrll 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.51     skrll 	struct usbd_device *dev = pipe->up_dev;
    1.51     skrll 	struct xhci_slot * const xs = dev->ud_hcpriv;
    1.51     skrll 	usb_endpoint_descriptor_t * const ed = pipe->up_endpoint->ue_edesc;
    1.51     skrll 	const u_int dci = xhci_ep_get_dci(ed);
    1.51     skrll 	const uint8_t xfertype = UE_GET_XFERTYPE(ed->bmAttributes);
    1.48     skrll 	uint32_t *cp;
    1.51     skrll 	uint16_t mps = UGETW(ed->wMaxPacketSize);
    1.51     skrll 	uint8_t speed = dev->ud_speed;
    1.51     skrll 	uint8_t ival = ed->bInterval;
    1.48     skrll
    1.51     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.51     skrll 	DPRINTFN(4, "pipe %p: slot %u dci %u speed %u", pipe, xs->xs_idx, dci,
    1.51     skrll 	    speed);
    1.48     skrll
     1.1  jakllsch 	/* set up initial input control context */
     1.1  jakllsch 	cp = xhci_slot_get_icv(sc, xs, XHCI_ICI_INPUT_CONTROL);
     1.1  jakllsch 	cp[0] = htole32(0);
    1.51     skrll 	cp[1] = htole32(XHCI_INCTX_1_ADD_MASK(dci));
    1.51     skrll 	if (dci == XHCI_DCI_EP_CONTROL)
    1.51     skrll 		cp[1] |= htole32(XHCI_INCTX_1_ADD_MASK(XHCI_DCI_SLOT));
    1.51     skrll 	cp[7] = htole32(0);
     1.1  jakllsch
     1.1  jakllsch 	/* set up input slot context */
     1.1  jakllsch 	cp = xhci_slot_get_icv(sc, xs, xhci_dci_to_ici(XHCI_DCI_SLOT));
    1.51     skrll 	cp[0] =
    1.51     skrll 	    XHCI_SCTX_0_CTX_NUM_SET(dci) |
    1.51     skrll 	    XHCI_SCTX_0_SPEED_SET(xhci_speed2xspeed(speed));
    1.51     skrll 	cp[1] = 0;
    1.51     skrll 	cp[2] = XHCI_SCTX_2_IRQ_TARGET_SET(0);
    1.51     skrll 	cp[3] = 0;
    1.51     skrll 	xhci_setup_route(pipe, cp);
    1.51     skrll 	xhci_setup_tthub(pipe, cp);
    1.51     skrll
    1.51     skrll 	cp[0] = htole32(cp[0]);
    1.51     skrll 	cp[1] = htole32(cp[1]);
    1.51     skrll 	cp[2] = htole32(cp[2]);
    1.51     skrll 	cp[3] = htole32(cp[3]);
    1.51     skrll
    1.51     skrll 	/* set up input endpoint context */
    1.51     skrll 	cp = xhci_slot_get_icv(sc, xs, xhci_dci_to_ici(dci));
    1.51     skrll 	cp[0] =
    1.51     skrll 	    XHCI_EPCTX_0_EPSTATE_SET(0) |
    1.51     skrll 	    XHCI_EPCTX_0_MULT_SET(0) |
    1.51     skrll 	    XHCI_EPCTX_0_MAXP_STREAMS_SET(0) |
    1.51     skrll 	    XHCI_EPCTX_0_LSA_SET(0) |
    1.51     skrll 	    XHCI_EPCTX_0_MAX_ESIT_PAYLOAD_HI_SET(0);
    1.51     skrll 	cp[1] =
    1.51     skrll 	    XHCI_EPCTX_1_EPTYPE_SET(xhci_ep_get_type(ed)) |
    1.51     skrll 	    XHCI_EPCTX_1_HID_SET(0) |
    1.51     skrll 	    XHCI_EPCTX_1_MAXB_SET(0);
    1.51     skrll
    1.51     skrll 	if (xfertype != UE_ISOCHRONOUS)
    1.51     skrll 		cp[1] |= XHCI_EPCTX_1_CERR_SET(3);
    1.51     skrll
    1.51     skrll 	if (xfertype == UE_CONTROL)
    1.51     skrll 		cp[4] = XHCI_EPCTX_4_AVG_TRB_LEN_SET(8); /* 6.2.3 */
    1.51     skrll 	else if (USB_IS_SS(speed))
    1.51     skrll 		cp[4] = XHCI_EPCTX_4_AVG_TRB_LEN_SET(mps);
    1.51     skrll 	else
    1.51     skrll 		cp[4] = XHCI_EPCTX_4_AVG_TRB_LEN_SET(UE_GET_SIZE(mps));
    1.51     skrll
    1.51     skrll 	xhci_setup_maxburst(pipe, cp);
    1.51     skrll
    1.51     skrll 	switch (xfertype) {
    1.51     skrll 	case UE_CONTROL:
    1.51     skrll 		break;
    1.51     skrll 	case UE_BULK:
    1.51     skrll 		/* XXX Set MaxPStreams, HID, and LSA if streams enabled */
    1.51     skrll 		break;
    1.51     skrll 	case UE_INTERRUPT:
    1.51     skrll 		if (pipe->up_interval != USBD_DEFAULT_INTERVAL)
    1.51     skrll 			ival = pipe->up_interval;
    1.51     skrll
    1.51     skrll 		ival = xhci_bival2ival(ival, speed);
    1.51     skrll 		cp[0] |= XHCI_EPCTX_0_IVAL_SET(ival);
    1.51     skrll 		break;
    1.51     skrll 	case UE_ISOCHRONOUS:
    1.51     skrll 		if (pipe->up_interval != USBD_DEFAULT_INTERVAL)
    1.51     skrll 			ival = pipe->up_interval;
    1.51     skrll
    1.51     skrll 		/* xHCI 6.2.3.6 Table 65, USB 2.0 9.6.6 */
    1.51     skrll 		if (speed == USB_SPEED_FULL)
    1.51     skrll 			ival += 3; /* 1ms -> 125us */
    1.51     skrll 		ival--;
    1.51     skrll 		cp[0] |= XHCI_EPCTX_0_IVAL_SET(ival);
    1.51     skrll 		break;
    1.51     skrll 	default:
    1.51     skrll 		break;
    1.51     skrll 	}
    1.53     skrll 	DPRINTFN(4, "setting ival %u MaxBurst %#x",
    1.53     skrll 	    XHCI_EPCTX_0_IVAL_GET(cp[0]), XHCI_EPCTX_1_MAXB_GET(cp[1]), 0, 0);
     1.1  jakllsch
    1.55     skrll 	/* rewind TR dequeue pointer in xHC */
     1.1  jakllsch 	/* can't use xhci_ep_get_dci() yet? */
     1.1  jakllsch 	*(uint64_t *)(&cp[2]) = htole64(
    1.51     skrll 	    xhci_ring_trbp(&xs->xs_ep[dci].xe_tr, 0) |
     1.1  jakllsch 	    XHCI_EPCTX_2_DCS_SET(1));
    1.51     skrll
    1.51     skrll 	cp[0] = htole32(cp[0]);
    1.51     skrll 	cp[1] = htole32(cp[1]);
    1.51     skrll 	cp[4] = htole32(cp[4]);
     1.1  jakllsch
    1.55     skrll 	/* rewind TR dequeue pointer in driver */
    1.55     skrll 	struct xhci_ring *xr = &xs->xs_ep[dci].xe_tr;
    1.55     skrll 	mutex_enter(&xr->xr_lock);
    1.55     skrll 	xhci_host_dequeue(xr);
    1.55     skrll 	mutex_exit(&xr->xr_lock);
    1.55     skrll
     1.1  jakllsch 	/* sync input contexts before they are read from memory */
     1.1  jakllsch 	usb_syncmem(&xs->xs_ic_dma, 0, sc->sc_pgsz, BUS_DMASYNC_PREWRITE);
    1.51     skrll }
    1.51     skrll
    1.51     skrll /*
    1.51     skrll  * Setup route string and roothub port of given device for slot context
    1.51     skrll  */
    1.51     skrll static void
    1.51     skrll xhci_setup_route(struct usbd_pipe *pipe, uint32_t *cp)
    1.51     skrll {
1.62.2.2  pgoyette 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.51     skrll 	struct usbd_device *dev = pipe->up_dev;
    1.51     skrll 	struct usbd_port *up = dev->ud_powersrc;
    1.51     skrll 	struct usbd_device *hub;
    1.51     skrll 	struct usbd_device *adev;
    1.51     skrll 	uint8_t rhport = 0;
    1.51     skrll 	uint32_t route = 0;
    1.51     skrll
    1.51     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.51     skrll
    1.51     skrll 	/* Locate root hub port and Determine route string */
    1.51     skrll 	/* 4.3.3 route string does not include roothub port */
    1.51     skrll 	for (hub = dev; hub != NULL; hub = hub->ud_myhub) {
    1.51     skrll 		uint32_t dep;
    1.51     skrll
    1.51     skrll 		DPRINTFN(4, "hub %p depth %d upport %p upportno %d",
    1.51     skrll 		    hub, hub->ud_depth, hub->ud_powersrc,
    1.51     skrll 		    hub->ud_powersrc ? hub->ud_powersrc->up_portno : -1);
    1.51     skrll
    1.51     skrll 		if (hub->ud_powersrc == NULL)
    1.51     skrll 			break;
    1.51     skrll 		dep = hub->ud_depth;
    1.51     skrll 		if (dep == 0)
    1.51     skrll 			break;
    1.51     skrll 		rhport = hub->ud_powersrc->up_portno;
    1.51     skrll 		if (dep > USB_HUB_MAX_DEPTH)
    1.51     skrll 			continue;
    1.51     skrll
    1.51     skrll 		route |=
    1.51     skrll 		    (rhport > UHD_SS_NPORTS_MAX ? UHD_SS_NPORTS_MAX : rhport)
    1.51     skrll 		    << ((dep - 1) * 4);
    1.51     skrll 	}
    1.51     skrll 	route = route >> 4;
1.62.2.2  pgoyette 	size_t bn = hub == sc->sc_bus.ub_roothub ? 0 : 1;
    1.51     skrll
    1.51     skrll 	/* Locate port on upstream high speed hub */
    1.51     skrll 	for (adev = dev, hub = up->up_parent;
    1.51     skrll 	     hub != NULL && hub->ud_speed != USB_SPEED_HIGH;
    1.51     skrll 	     adev = hub, hub = hub->ud_myhub)
    1.51     skrll 		;
    1.51     skrll 	if (hub) {
    1.51     skrll 		int p;
    1.51     skrll 		for (p = 0; p < hub->ud_hub->uh_hubdesc.bNbrPorts; p++) {
    1.51     skrll 			if (hub->ud_hub->uh_ports[p].up_dev == adev) {
    1.51     skrll 				dev->ud_myhsport = &hub->ud_hub->uh_ports[p];
    1.51     skrll 				goto found;
    1.51     skrll 			}
    1.51     skrll 		}
1.62.2.2  pgoyette 		panic("%s: cannot find HS port", __func__);
    1.51     skrll 	found:
    1.51     skrll 		DPRINTFN(4, "high speed port %d", p, 0, 0, 0);
    1.51     skrll 	} else {
    1.51     skrll 		dev->ud_myhsport = NULL;
    1.51     skrll 	}
    1.51     skrll
1.62.2.2  pgoyette 	const size_t ctlrport = xhci_rhport2ctlrport(sc, bn, rhport);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 	DPRINTFN(4, "rhport %u ctlrport %u Route %05x hub %p", rhport,
1.62.2.2  pgoyette 	    ctlrport, route, hub);
1.62.2.2  pgoyette
    1.51     skrll 	cp[0] |= XHCI_SCTX_0_ROUTE_SET(route);
1.62.2.2  pgoyette 	cp[1] |= XHCI_SCTX_1_RH_PORT_SET(ctlrport);
    1.51     skrll }
    1.51     skrll
    1.51     skrll /*
    1.51     skrll  * Setup whether device is hub, whether device uses MTT, and
    1.51     skrll  * TT informations if it uses MTT.
    1.51     skrll  */
    1.51     skrll static void
    1.51     skrll xhci_setup_tthub(struct usbd_pipe *pipe, uint32_t *cp)
    1.51     skrll {
    1.51     skrll 	struct usbd_device *dev = pipe->up_dev;
    1.51     skrll 	usb_device_descriptor_t * const dd = &dev->ud_ddesc;
    1.51     skrll 	uint32_t speed = dev->ud_speed;
    1.51     skrll 	uint8_t tthubslot, ttportnum;
    1.51     skrll 	bool ishub;
    1.51     skrll 	bool usemtt;
    1.51     skrll
    1.51     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.51     skrll
    1.51     skrll 	/*
    1.51     skrll 	 * 6.2.2, Table 57-60, 6.2.2.1, 6.2.2.2
    1.51     skrll 	 * tthubslot:
    1.51     skrll 	 *   This is the slot ID of parent HS hub
    1.51     skrll 	 *   if LS/FS device is connected && connected through HS hub.
    1.51     skrll 	 *   This is 0 if device is not LS/FS device ||
    1.51     skrll 	 *   parent hub is not HS hub ||
    1.51     skrll 	 *   attached to root hub.
    1.51     skrll 	 * ttportnum:
    1.51     skrll 	 *   This is the downstream facing port of parent HS hub
    1.51     skrll 	 *   if LS/FS device is connected.
    1.51     skrll 	 *   This is 0 if device is not LS/FS device ||
    1.51     skrll 	 *   parent hub is not HS hub ||
    1.51     skrll 	 *   attached to root hub.
    1.51     skrll 	 */
    1.51     skrll 	if (dev->ud_myhsport != NULL &&
    1.51     skrll 	    dev->ud_myhub != NULL && dev->ud_myhub->ud_depth != 0 &&
    1.51     skrll 	    (dev->ud_myhub != NULL &&
    1.51     skrll 	     dev->ud_myhub->ud_speed == USB_SPEED_HIGH) &&
    1.51     skrll 	    (speed == USB_SPEED_LOW || speed == USB_SPEED_FULL)) {
    1.51     skrll 		ttportnum = dev->ud_myhsport->up_portno;
    1.51     skrll 		tthubslot = dev->ud_myhsport->up_parent->ud_addr;
    1.51     skrll 	} else {
    1.51     skrll 		ttportnum = 0;
    1.51     skrll 		tthubslot = 0;
    1.51     skrll 	}
    1.51     skrll 	DPRINTFN(4, "myhsport %p ttportnum=%d tthubslot=%d",
    1.51     skrll 	    dev->ud_myhsport, ttportnum, tthubslot, 0);
    1.51     skrll
    1.51     skrll 	/* ishub is valid after reading UDESC_DEVICE */
    1.51     skrll 	ishub = (dd->bDeviceClass == UDCLASS_HUB);
    1.51     skrll
    1.51     skrll 	/* dev->ud_hub is valid after reading UDESC_HUB */
    1.51     skrll 	if (ishub && dev->ud_hub) {
    1.51     skrll 		usb_hub_descriptor_t *hd = &dev->ud_hub->uh_hubdesc;
    1.51     skrll 		uint8_t ttt =
    1.51     skrll 		    __SHIFTOUT(UGETW(hd->wHubCharacteristics), UHD_TT_THINK);
    1.51     skrll
    1.51     skrll 		cp[1] |= XHCI_SCTX_1_NUM_PORTS_SET(hd->bNbrPorts);
    1.51     skrll 		cp[2] |= XHCI_SCTX_2_TT_THINK_TIME_SET(ttt);
    1.51     skrll 		DPRINTFN(4, "nports=%d ttt=%d", hd->bNbrPorts, ttt, 0, 0);
    1.51     skrll 	}
    1.51     skrll
    1.51     skrll #define IS_TTHUB(dd) \
    1.51     skrll     ((dd)->bDeviceProtocol == UDPROTO_HSHUBSTT || \
    1.51     skrll      (dd)->bDeviceProtocol == UDPROTO_HSHUBMTT)
    1.51     skrll
    1.51     skrll 	/*
    1.51     skrll 	 * MTT flag is set if
    1.51     skrll 	 * 1. this is HS hub && MTT is enabled
    1.51     skrll 	 *  or
    1.51     skrll 	 * 2. this is not hub && this is LS or FS device &&
    1.51     skrll 	 *    MTT of parent HS hub (and its parent, too) is enabled
    1.51     skrll 	 */
    1.51     skrll 	if (ishub && speed == USB_SPEED_HIGH && IS_TTHUB(dd))
    1.51     skrll 		usemtt = true;
    1.51     skrll 	else if (!ishub &&
    1.51     skrll 	     (speed == USB_SPEED_LOW || speed == USB_SPEED_FULL) &&
    1.51     skrll 	     dev->ud_myhub != NULL && dev->ud_myhub->ud_depth != 0 &&
    1.51     skrll 	     (dev->ud_myhub != NULL &&
    1.51     skrll 	      dev->ud_myhub->ud_speed == USB_SPEED_HIGH) &&
    1.51     skrll 	     dev->ud_myhsport != NULL &&
    1.51     skrll 	     IS_TTHUB(&dev->ud_myhsport->up_parent->ud_ddesc))
    1.51     skrll 		usemtt = true;
    1.51     skrll 	else
    1.51     skrll 		usemtt = false;
    1.51     skrll 	DPRINTFN(4, "class %u proto %u ishub %d usemtt %d",
    1.51     skrll 	    dd->bDeviceClass, dd->bDeviceProtocol, ishub, usemtt);
    1.51     skrll
    1.51     skrll #undef IS_TTHUB
    1.51     skrll
    1.51     skrll 	cp[0] |=
    1.51     skrll 	    XHCI_SCTX_0_HUB_SET(ishub ? 1 : 0) |
    1.51     skrll 	    XHCI_SCTX_0_MTT_SET(usemtt ? 1 : 0);
    1.51     skrll 	cp[2] |=
    1.51     skrll 	    XHCI_SCTX_2_TT_HUB_SID_SET(tthubslot) |
    1.51     skrll 	    XHCI_SCTX_2_TT_PORT_NUM_SET(ttportnum);
    1.51     skrll }
    1.51     skrll
    1.51     skrll /* set up params for periodic endpoint */
    1.51     skrll static void
    1.51     skrll xhci_setup_maxburst(struct usbd_pipe *pipe, uint32_t *cp)
    1.51     skrll {
    1.51     skrll 	struct usbd_device *dev = pipe->up_dev;
    1.51     skrll 	usb_endpoint_descriptor_t * const ed = pipe->up_endpoint->ue_edesc;
    1.51     skrll 	const uint8_t xfertype = UE_GET_XFERTYPE(ed->bmAttributes);
    1.51     skrll 	usbd_desc_iter_t iter;
    1.51     skrll 	const usb_cdc_descriptor_t *cdcd;
    1.51     skrll 	uint32_t maxb = 0;
    1.51     skrll 	uint16_t mps = UGETW(ed->wMaxPacketSize);
    1.51     skrll 	uint8_t speed = dev->ud_speed;
    1.51     skrll 	uint8_t ep;
    1.51     skrll
    1.51     skrll 	/* config desc is NULL when opening ep0 */
    1.51     skrll 	if (dev == NULL || dev->ud_cdesc == NULL)
    1.51     skrll 		goto no_cdcd;
    1.51     skrll 	cdcd = (const usb_cdc_descriptor_t *)usb_find_desc(dev,
    1.51     skrll 	    UDESC_INTERFACE, USBD_CDCSUBTYPE_ANY);
    1.51     skrll 	if (cdcd == NULL)
    1.51     skrll 		goto no_cdcd;
    1.51     skrll 	usb_desc_iter_init(dev, &iter);
    1.51     skrll 	iter.cur = (const void *)cdcd;
    1.51     skrll
    1.51     skrll 	/* find endpoint_ss_comp desc for ep of this pipe */
    1.51     skrll 	for (ep = 0;;) {
    1.51     skrll 		cdcd = (const usb_cdc_descriptor_t *)usb_desc_iter_next(&iter);
    1.51     skrll 		if (cdcd == NULL)
    1.51     skrll 			break;
    1.51     skrll 		if (ep == 0 && cdcd->bDescriptorType == UDESC_ENDPOINT) {
    1.51     skrll 			ep = ((const usb_endpoint_descriptor_t *)cdcd)->
    1.51     skrll 			    bEndpointAddress;
    1.51     skrll 			if (UE_GET_ADDR(ep) ==
    1.51     skrll 			    UE_GET_ADDR(ed->bEndpointAddress)) {
    1.51     skrll 				cdcd = (const usb_cdc_descriptor_t *)
    1.51     skrll 				    usb_desc_iter_next(&iter);
    1.51     skrll 				break;
    1.51     skrll 			}
    1.51     skrll 			ep = 0;
    1.51     skrll 		}
    1.51     skrll 	}
    1.51     skrll 	if (cdcd != NULL && cdcd->bDescriptorType == UDESC_ENDPOINT_SS_COMP) {
    1.51     skrll 		const usb_endpoint_ss_comp_descriptor_t * esscd =
    1.51     skrll 		    (const usb_endpoint_ss_comp_descriptor_t *)cdcd;
    1.51     skrll 		maxb = esscd->bMaxBurst;
    1.51     skrll 	}
    1.51     skrll
    1.51     skrll  no_cdcd:
    1.51     skrll 	/* 6.2.3.4,  4.8.2.4 */
    1.51     skrll 	if (USB_IS_SS(speed)) {
    1.60     skrll 		/* USB 3.1  9.6.6 */
    1.51     skrll 		cp[1] |= XHCI_EPCTX_1_MAXP_SIZE_SET(mps);
    1.60     skrll 		/* USB 3.1  9.6.7 */
    1.51     skrll 		cp[1] |= XHCI_EPCTX_1_MAXB_SET(maxb);
    1.51     skrll #ifdef notyet
    1.51     skrll 		if (xfertype == UE_ISOCHRONOUS) {
    1.51     skrll 		}
    1.51     skrll 		if (XHCI_HCC2_LEC(sc->sc_hcc2) != 0) {
    1.51     skrll 			/* use ESIT */
    1.51     skrll 			cp[4] |= XHCI_EPCTX_4_MAX_ESIT_PAYLOAD_SET(x);
    1.51     skrll 			cp[0] |= XHCI_EPCTX_0_MAX_ESIT_PAYLOAD_HI_SET(x);
    1.51     skrll
    1.51     skrll 			/* XXX if LEC = 1, set ESIT instead */
    1.51     skrll 			cp[0] |= XHCI_EPCTX_0_MULT_SET(0);
    1.51     skrll 		} else {
    1.51     skrll 			/* use ival */
    1.51     skrll 		}
    1.51     skrll #endif
    1.51     skrll 	} else {
    1.60     skrll 		/* USB 2.0  9.6.6 */
    1.51     skrll 		cp[1] |= XHCI_EPCTX_1_MAXP_SIZE_SET(UE_GET_SIZE(mps));
     1.1  jakllsch
    1.51     skrll 		/* 6.2.3.4 */
    1.51     skrll 		if (speed == USB_SPEED_HIGH &&
    1.51     skrll 		   (xfertype == UE_ISOCHRONOUS || xfertype == UE_INTERRUPT)) {
    1.51     skrll 			maxb = UE_GET_TRANS(mps);
    1.51     skrll 		} else {
    1.51     skrll 			/* LS/FS or HS CTRL or HS BULK */
    1.51     skrll 			maxb = 0;
    1.51     skrll 		}
    1.51     skrll 		cp[1] |= XHCI_EPCTX_1_MAXB_SET(maxb);
    1.51     skrll 	}
    1.51     skrll }
     1.1  jakllsch
    1.51     skrll /*
    1.51     skrll  * Convert endpoint bInterval value to endpoint context interval value
    1.51     skrll  * for Interrupt pipe.
    1.51     skrll  * xHCI 6.2.3.6 Table 65, USB 2.0 9.6.6
    1.51     skrll  */
    1.51     skrll static uint32_t
    1.51     skrll xhci_bival2ival(uint32_t ival, uint32_t speed)
    1.51     skrll {
    1.51     skrll 	if (speed == USB_SPEED_LOW || speed == USB_SPEED_FULL) {
    1.51     skrll 		int i;
     1.1  jakllsch
    1.51     skrll 		/*
    1.51     skrll 		 * round ival down to "the nearest base 2 multiple of
    1.51     skrll 		 * bInterval * 8".
    1.51     skrll 		 * bInterval is at most 255 as its type is uByte.
    1.51     skrll 		 * 255(ms) = 2040(x 125us) < 2^11, so start with 10.
    1.51     skrll 		 */
    1.51     skrll 		for (i = 10; i > 0; i--) {
    1.51     skrll 			if ((ival * 8) >= (1 << i))
    1.51     skrll 				break;
    1.51     skrll 		}
    1.51     skrll 		ival = i;
    1.51     skrll 	} else {
    1.51     skrll 		/* Interval = bInterval-1 for SS/HS */
    1.51     skrll 		ival--;
    1.51     skrll 	}
     1.1  jakllsch
    1.51     skrll 	return ival;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch /* ----- */
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_noop(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /*
    1.34     skrll  * Process root hub request.
    1.34     skrll  */
    1.34     skrll static int
    1.34     skrll xhci_roothub_ctrl(struct usbd_bus *bus, usb_device_request_t *req,
    1.34     skrll     void *buf, int buflen)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_BUS2SC(bus);
     1.1  jakllsch 	usb_port_status_t ps;
     1.1  jakllsch 	int l, totlen = 0;
    1.34     skrll 	uint16_t len, value, index;
     1.1  jakllsch 	int port, i;
     1.1  jakllsch 	uint32_t v;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch
     1.1  jakllsch 	if (sc->sc_dying)
    1.34     skrll 		return -1;
     1.1  jakllsch
1.62.2.2  pgoyette 	size_t bn = bus == &sc->sc_bus ? 0 : 1;
1.62.2.2  pgoyette
    1.34     skrll 	len = UGETW(req->wLength);
     1.1  jakllsch 	value = UGETW(req->wValue);
     1.1  jakllsch 	index = UGETW(req->wIndex);
     1.1  jakllsch
    1.27     skrll 	DPRINTFN(12, "rhreq: %04x %04x %04x %04x",
    1.27     skrll 	    req->bmRequestType | (req->bRequest << 8), value, index, len);
     1.1  jakllsch
     1.1  jakllsch #define C(x,y) ((x) | ((y) << 8))
    1.34     skrll 	switch (C(req->bRequest, req->bmRequestType)) {
     1.1  jakllsch 	case C(UR_GET_DESCRIPTOR, UT_READ_DEVICE):
    1.27     skrll 		DPRINTFN(8, "getdesc: wValue=0x%04x", value, 0, 0, 0);
     1.1  jakllsch 		if (len == 0)
     1.1  jakllsch 			break;
    1.34     skrll 		switch (value) {
    1.34     skrll 		case C(0, UDESC_DEVICE): {
    1.34     skrll 			usb_device_descriptor_t devd;
    1.34     skrll 			totlen = min(buflen, sizeof(devd));
    1.34     skrll 			memcpy(&devd, buf, totlen);
    1.34     skrll 			USETW(devd.idVendor, sc->sc_id_vendor);
    1.34     skrll 			memcpy(buf, &devd, totlen);
     1.1  jakllsch 			break;
    1.34     skrll 		}
    1.34     skrll #define sd ((usb_string_descriptor_t *)buf)
    1.34     skrll 		case C(1, UDESC_STRING):
    1.34     skrll 			/* Vendor */
    1.34     skrll 			totlen = usb_makestrdesc(sd, len, sc->sc_vendor);
    1.34     skrll 			break;
    1.34     skrll 		case C(2, UDESC_STRING):
    1.34     skrll 			/* Product */
    1.34     skrll 			totlen = usb_makestrdesc(sd, len, "xHCI Root Hub");
     1.1  jakllsch 			break;
     1.1  jakllsch #undef sd
     1.1  jakllsch 		default:
    1.34     skrll 			/* default from usbroothub */
    1.34     skrll 			return buflen;
     1.1  jakllsch 		}
     1.1  jakllsch 		break;
    1.34     skrll
     1.1  jakllsch 	/* Hub requests */
     1.1  jakllsch 	case C(UR_CLEAR_FEATURE, UT_WRITE_CLASS_DEVICE):
     1.1  jakllsch 		break;
    1.34     skrll 	/* Clear Port Feature request */
1.62.2.2  pgoyette 	case C(UR_CLEAR_FEATURE, UT_WRITE_CLASS_OTHER): {
1.62.2.2  pgoyette 		const size_t cp = xhci_rhport2ctlrport(sc, bn, index);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		DPRINTFN(4, "UR_CLEAR_PORT_FEAT bp=%d feat=%d bus=%d cp=%d",
1.62.2.2  pgoyette 		    index, value, bn, cp);
1.62.2.2  pgoyette 		if (index < 1 || index > sc->sc_rhportcount[bn]) {
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
1.62.2.2  pgoyette 		port = XHCI_PORTSC(cp);
     1.1  jakllsch 		v = xhci_op_read_4(sc, port);
    1.27     skrll 		DPRINTFN(4, "portsc=0x%08x", v, 0, 0, 0);
     1.1  jakllsch 		v &= ~XHCI_PS_CLEAR;
     1.1  jakllsch 		switch (value) {
     1.1  jakllsch 		case UHF_PORT_ENABLE:
    1.34     skrll 			xhci_op_write_4(sc, port, v & ~XHCI_PS_PED);
     1.1  jakllsch 			break;
     1.1  jakllsch 		case UHF_PORT_SUSPEND:
    1.34     skrll 			return -1;
     1.1  jakllsch 		case UHF_PORT_POWER:
     1.1  jakllsch 			break;
     1.1  jakllsch 		case UHF_PORT_TEST:
     1.1  jakllsch 		case UHF_PORT_INDICATOR:
    1.34     skrll 			return -1;
     1.1  jakllsch 		case UHF_C_PORT_CONNECTION:
     1.1  jakllsch 			xhci_op_write_4(sc, port, v | XHCI_PS_CSC);
     1.1  jakllsch 			break;
     1.1  jakllsch 		case UHF_C_PORT_ENABLE:
     1.1  jakllsch 		case UHF_C_PORT_SUSPEND:
     1.1  jakllsch 		case UHF_C_PORT_OVER_CURRENT:
    1.34     skrll 			return -1;
    1.34     skrll 		case UHF_C_BH_PORT_RESET:
    1.34     skrll 			xhci_op_write_4(sc, port, v | XHCI_PS_WRC);
    1.34     skrll 			break;
     1.1  jakllsch 		case UHF_C_PORT_RESET:
     1.1  jakllsch 			xhci_op_write_4(sc, port, v | XHCI_PS_PRC);
     1.1  jakllsch 			break;
    1.34     skrll 		case UHF_C_PORT_LINK_STATE:
    1.34     skrll 			xhci_op_write_4(sc, port, v | XHCI_PS_PLC);
    1.34     skrll 			break;
    1.34     skrll 		case UHF_C_PORT_CONFIG_ERROR:
    1.34     skrll 			xhci_op_write_4(sc, port, v | XHCI_PS_CEC);
    1.34     skrll 			break;
     1.1  jakllsch 		default:
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
     1.1  jakllsch 		break;
1.62.2.2  pgoyette 	}
     1.1  jakllsch 	case C(UR_GET_DESCRIPTOR, UT_READ_CLASS_DEVICE):
     1.1  jakllsch 		if (len == 0)
     1.1  jakllsch 			break;
     1.1  jakllsch 		if ((value & 0xff) != 0) {
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
    1.34     skrll 		usb_hub_descriptor_t hubd;
    1.34     skrll
    1.34     skrll 		totlen = min(buflen, sizeof(hubd));
    1.34     skrll 		memcpy(&hubd, buf, totlen);
1.62.2.2  pgoyette 		hubd.bNbrPorts = sc->sc_rhportcount[bn];
     1.1  jakllsch 		USETW(hubd.wHubCharacteristics, UHD_PWR_NO_SWITCH);
     1.1  jakllsch 		hubd.bPwrOn2PwrGood = 200;
1.62.2.2  pgoyette 		for (i = 0, l = sc->sc_rhportcount[bn]; l > 0; i++, l -= 8) {
1.62.2.2  pgoyette 			/* XXX can't find out? */
1.62.2.2  pgoyette 			hubd.DeviceRemovable[i++] = 0;
1.62.2.2  pgoyette 		}
     1.3     skrll 		hubd.bDescLength = USB_HUB_DESCRIPTOR_SIZE + i;
    1.34     skrll 		totlen = min(totlen, hubd.bDescLength);
    1.34     skrll 		memcpy(buf, &hubd, totlen);
     1.1  jakllsch 		break;
     1.1  jakllsch 	case C(UR_GET_STATUS, UT_READ_CLASS_DEVICE):
     1.1  jakllsch 		if (len != 4) {
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
     1.1  jakllsch 		memset(buf, 0, len); /* ? XXX */
     1.1  jakllsch 		totlen = len;
     1.1  jakllsch 		break;
    1.34     skrll 	/* Get Port Status request */
1.62.2.2  pgoyette 	case C(UR_GET_STATUS, UT_READ_CLASS_OTHER): {
1.62.2.2  pgoyette 		const size_t cp = xhci_rhport2ctlrport(sc, bn, index);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		DPRINTFN(8, "get port status bn=%d i=%d cp=%zu", bn, index, cp,
1.62.2.2  pgoyette 		    0);
1.62.2.2  pgoyette 		if (index < 1 || index > sc->sc_rhportcount[bn]) {
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
     1.1  jakllsch 		if (len != 4) {
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
1.62.2.2  pgoyette 		v = xhci_op_read_4(sc, XHCI_PORTSC(cp));
1.62.2.2  pgoyette 		DPRINTFN(4, "getrhportsc %d %08x", cp, v, 0, 0);
    1.34     skrll 		i = xhci_xspeed2psspeed(XHCI_PS_SPEED_GET(v));
     1.1  jakllsch 		if (v & XHCI_PS_CCS)	i |= UPS_CURRENT_CONNECT_STATUS;
     1.1  jakllsch 		if (v & XHCI_PS_PED)	i |= UPS_PORT_ENABLED;
     1.1  jakllsch 		if (v & XHCI_PS_OCA)	i |= UPS_OVERCURRENT_INDICATOR;
     1.1  jakllsch 		//if (v & XHCI_PS_SUSP)	i |= UPS_SUSPEND;
     1.1  jakllsch 		if (v & XHCI_PS_PR)	i |= UPS_RESET;
    1.34     skrll 		if (v & XHCI_PS_PP) {
    1.34     skrll 			if (i & UPS_OTHER_SPEED)
    1.34     skrll 					i |= UPS_PORT_POWER_SS;
    1.34     skrll 			else
    1.34     skrll 					i |= UPS_PORT_POWER;
    1.34     skrll 		}
    1.34     skrll 		if (i & UPS_OTHER_SPEED)
    1.34     skrll 			i |= UPS_PORT_LS_SET(XHCI_PS_PLS_GET(v));
    1.34     skrll 		if (sc->sc_vendor_port_status)
    1.34     skrll 			i = sc->sc_vendor_port_status(sc, v, i);
     1.1  jakllsch 		USETW(ps.wPortStatus, i);
     1.1  jakllsch 		i = 0;
     1.1  jakllsch 		if (v & XHCI_PS_CSC)    i |= UPS_C_CONNECT_STATUS;
     1.1  jakllsch 		if (v & XHCI_PS_PEC)    i |= UPS_C_PORT_ENABLED;
     1.1  jakllsch 		if (v & XHCI_PS_OCC)    i |= UPS_C_OVERCURRENT_INDICATOR;
     1.1  jakllsch 		if (v & XHCI_PS_PRC)	i |= UPS_C_PORT_RESET;
    1.34     skrll 		if (v & XHCI_PS_WRC)	i |= UPS_C_BH_PORT_RESET;
    1.34     skrll 		if (v & XHCI_PS_PLC)	i |= UPS_C_PORT_LINK_STATE;
    1.34     skrll 		if (v & XHCI_PS_CEC)	i |= UPS_C_PORT_CONFIG_ERROR;
     1.1  jakllsch 		USETW(ps.wPortChange, i);
    1.34     skrll 		totlen = min(len, sizeof(ps));
    1.34     skrll 		memcpy(buf, &ps, totlen);
     1.1  jakllsch 		break;
1.62.2.2  pgoyette 	}
     1.1  jakllsch 	case C(UR_SET_DESCRIPTOR, UT_WRITE_CLASS_DEVICE):
    1.34     skrll 		return -1;
    1.34     skrll 	case C(UR_SET_HUB_DEPTH, UT_WRITE_CLASS_DEVICE):
    1.34     skrll 		break;
     1.1  jakllsch 	case C(UR_SET_FEATURE, UT_WRITE_CLASS_DEVICE):
     1.1  jakllsch 		break;
    1.34     skrll 	/* Set Port Feature request */
    1.34     skrll 	case C(UR_SET_FEATURE, UT_WRITE_CLASS_OTHER): {
    1.34     skrll 		int optval = (index >> 8) & 0xff;
    1.34     skrll 		index &= 0xff;
1.62.2.2  pgoyette 		if (index < 1 || index > sc->sc_rhportcount[bn]) {
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		const size_t cp = xhci_rhport2ctlrport(sc, bn, index);
1.62.2.2  pgoyette
1.62.2.2  pgoyette 		port = XHCI_PORTSC(cp);
     1.1  jakllsch 		v = xhci_op_read_4(sc, port);
1.62.2.2  pgoyette 		DPRINTFN(4, "index %d cp %d portsc=0x%08x", index, cp, v, 0);
     1.1  jakllsch 		v &= ~XHCI_PS_CLEAR;
     1.1  jakllsch 		switch (value) {
     1.1  jakllsch 		case UHF_PORT_ENABLE:
     1.1  jakllsch 			xhci_op_write_4(sc, port, v | XHCI_PS_PED);
     1.1  jakllsch 			break;
     1.1  jakllsch 		case UHF_PORT_SUSPEND:
     1.1  jakllsch 			/* XXX suspend */
     1.1  jakllsch 			break;
     1.1  jakllsch 		case UHF_PORT_RESET:
    1.34     skrll 			v &= ~(XHCI_PS_PED | XHCI_PS_PR);
     1.1  jakllsch 			xhci_op_write_4(sc, port, v | XHCI_PS_PR);
     1.1  jakllsch 			/* Wait for reset to complete. */
     1.1  jakllsch 			usb_delay_ms(&sc->sc_bus, USB_PORT_ROOT_RESET_DELAY);
     1.1  jakllsch 			if (sc->sc_dying) {
    1.34     skrll 				return -1;
     1.1  jakllsch 			}
     1.1  jakllsch 			v = xhci_op_read_4(sc, port);
     1.1  jakllsch 			if (v & XHCI_PS_PR) {
     1.1  jakllsch 				xhci_op_write_4(sc, port, v & ~XHCI_PS_PR);
     1.1  jakllsch 				usb_delay_ms(&sc->sc_bus, 10);
     1.1  jakllsch 				/* XXX */
     1.1  jakllsch 			}
     1.1  jakllsch 			break;
     1.1  jakllsch 		case UHF_PORT_POWER:
     1.1  jakllsch 			/* XXX power control */
     1.1  jakllsch 			break;
     1.1  jakllsch 		/* XXX more */
     1.1  jakllsch 		case UHF_C_PORT_RESET:
     1.1  jakllsch 			xhci_op_write_4(sc, port, v | XHCI_PS_PRC);
     1.1  jakllsch 			break;
    1.34     skrll 		case UHF_PORT_U1_TIMEOUT:
    1.34     skrll 			if (XHCI_PS_SPEED_GET(v) < XHCI_PS_SPEED_SS) {
    1.34     skrll 				return -1;
    1.34     skrll 			}
1.62.2.2  pgoyette 			port = XHCI_PORTPMSC(cp);
    1.34     skrll 			v = xhci_op_read_4(sc, port);
1.62.2.2  pgoyette 			DPRINTFN(4, "index %d cp %d portpmsc=0x%08x", index, cp, v, 0);
    1.34     skrll 			v &= ~XHCI_PM3_U1TO_SET(0xff);
    1.34     skrll 			v |= XHCI_PM3_U1TO_SET(optval);
    1.34     skrll 			xhci_op_write_4(sc, port, v);
    1.34     skrll 			break;
    1.34     skrll 		case UHF_PORT_U2_TIMEOUT:
    1.34     skrll 			if (XHCI_PS_SPEED_GET(v) < XHCI_PS_SPEED_SS) {
    1.34     skrll 				return -1;
    1.34     skrll 			}
1.62.2.2  pgoyette 			port = XHCI_PORTPMSC(cp);
    1.34     skrll 			v = xhci_op_read_4(sc, port);
1.62.2.2  pgoyette 			DPRINTFN(4, "index %d cp %d portpmsc=0x%08x", index, cp, v, 0);
    1.34     skrll 			v &= ~XHCI_PM3_U2TO_SET(0xff);
    1.34     skrll 			v |= XHCI_PM3_U2TO_SET(optval);
    1.34     skrll 			xhci_op_write_4(sc, port, v);
    1.34     skrll 			break;
     1.1  jakllsch 		default:
    1.34     skrll 			return -1;
     1.1  jakllsch 		}
    1.34     skrll 	}
     1.1  jakllsch 		break;
     1.1  jakllsch 	case C(UR_CLEAR_TT_BUFFER, UT_WRITE_CLASS_OTHER):
     1.1  jakllsch 	case C(UR_RESET_TT, UT_WRITE_CLASS_OTHER):
     1.1  jakllsch 	case C(UR_GET_TT_STATE, UT_READ_CLASS_OTHER):
     1.1  jakllsch 	case C(UR_STOP_TT, UT_WRITE_CLASS_OTHER):
     1.1  jakllsch 		break;
     1.1  jakllsch 	default:
    1.34     skrll 		/* default from usbroothub */
    1.34     skrll 		return buflen;
     1.1  jakllsch 	}
    1.27     skrll
    1.34     skrll 	return totlen;
     1.1  jakllsch }
     1.1  jakllsch
    1.28     skrll /* root hub interrupt */
     1.1  jakllsch
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_root_intr_transfer(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	/* Insert last in queue. */
     1.1  jakllsch 	mutex_enter(&sc->sc_lock);
     1.1  jakllsch 	err = usb_insert_transfer(xfer);
     1.1  jakllsch 	mutex_exit(&sc->sc_lock);
     1.1  jakllsch 	if (err)
     1.1  jakllsch 		return err;
     1.1  jakllsch
     1.1  jakllsch 	/* Pipe isn't running, start first */
    1.34     skrll 	return xhci_root_intr_start(SIMPLEQ_FIRST(&xfer->ux_pipe->up_queue));
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /* Wait for roothub port status/change */
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_root_intr_start(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
1.62.2.2  pgoyette 	const size_t bn = XHCI_XFER2BUS(xfer) == &sc->sc_bus ? 0 : 1;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	if (sc->sc_dying)
     1.1  jakllsch 		return USBD_IOERROR;
     1.1  jakllsch
     1.1  jakllsch 	mutex_enter(&sc->sc_lock);
1.62.2.2  pgoyette 	sc->sc_intrxfer[bn] = xfer;
     1.1  jakllsch 	mutex_exit(&sc->sc_lock);
     1.1  jakllsch
     1.1  jakllsch 	return USBD_IN_PROGRESS;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_root_intr_abort(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
1.62.2.2  pgoyette 	const size_t bn = XHCI_XFER2BUS(xfer) == &sc->sc_bus ? 0 : 1;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	KASSERT(mutex_owned(&sc->sc_lock));
    1.34     skrll 	KASSERT(xfer->ux_pipe->up_intrxfer == xfer);
    1.21     skrll
1.62.2.2  pgoyette 	sc->sc_intrxfer[bn] = NULL;
    1.22     skrll
    1.34     skrll 	xfer->ux_status = USBD_CANCELLED;
     1.1  jakllsch 	usb_transfer_complete(xfer);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_root_intr_close(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
1.62.2.2  pgoyette 	const struct usbd_xfer *xfer = pipe->up_intrxfer;
1.62.2.2  pgoyette 	const size_t bn = XHCI_XFER2BUS(xfer) == &sc->sc_bus ? 0 : 1;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	KASSERT(mutex_owned(&sc->sc_lock));
     1.1  jakllsch
1.62.2.2  pgoyette 	sc->sc_intrxfer[bn] = NULL;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_root_intr_done(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch /* -------------- */
     1.1  jakllsch /* device control */
     1.1  jakllsch
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_device_ctrl_transfer(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	/* Insert last in queue. */
     1.1  jakllsch 	mutex_enter(&sc->sc_lock);
     1.1  jakllsch 	err = usb_insert_transfer(xfer);
     1.1  jakllsch 	mutex_exit(&sc->sc_lock);
     1.1  jakllsch 	if (err)
    1.34     skrll 		return err;
     1.1  jakllsch
     1.1  jakllsch 	/* Pipe isn't running, start first */
    1.34     skrll 	return xhci_device_ctrl_start(SIMPLEQ_FIRST(&xfer->ux_pipe->up_queue));
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_device_ctrl_start(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
    1.34     skrll 	struct xhci_slot * const xs = xfer->ux_pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(xfer->ux_pipe->up_endpoint->ue_edesc);
     1.1  jakllsch 	struct xhci_ring * const tr = &xs->xs_ep[dci].xe_tr;
    1.35     skrll 	struct xhci_xfer * const xx = XHCI_XFER2XXFER(xfer);
    1.34     skrll 	usb_device_request_t * const req = &xfer->ux_request;
    1.34     skrll 	const int isread = usbd_xfer_isread(xfer);
     1.1  jakllsch 	const uint32_t len = UGETW(req->wLength);
    1.34     skrll 	usb_dma_t * const dma = &xfer->ux_dmabuf;
     1.1  jakllsch 	uint64_t parameter;
     1.1  jakllsch 	uint32_t status;
     1.1  jakllsch 	uint32_t control;
     1.1  jakllsch 	u_int i;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll 	DPRINTFN(12, "req: %04x %04x %04x %04x",
    1.27     skrll 	    req->bmRequestType | (req->bRequest << 8), UGETW(req->wValue),
    1.27     skrll 	    UGETW(req->wIndex), UGETW(req->wLength));
     1.1  jakllsch
     1.1  jakllsch 	/* we rely on the bottom bits for extra info */
    1.59      maya 	KASSERTMSG(((uintptr_t)xfer & 0x3) == 0x0, "xfer %zx",
    1.59      maya 	    (uintptr_t) xfer);
     1.1  jakllsch
    1.34     skrll 	KASSERT((xfer->ux_rqflags & URQ_REQUEST) != 0);
     1.1  jakllsch
     1.1  jakllsch 	i = 0;
     1.1  jakllsch
     1.1  jakllsch 	/* setup phase */
1.62.2.1  pgoyette 	memcpy(&parameter, req, sizeof(parameter));
     1.1  jakllsch 	status = XHCI_TRB_2_IRQ_SET(0) | XHCI_TRB_2_BYTES_SET(sizeof(*req));
     1.1  jakllsch 	control = ((len == 0) ? XHCI_TRB_3_TRT_NONE :
     1.1  jakllsch 	     (isread ? XHCI_TRB_3_TRT_IN : XHCI_TRB_3_TRT_OUT)) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_SETUP_STAGE) |
     1.1  jakllsch 	    XHCI_TRB_3_IDT_BIT;
     1.1  jakllsch 	xhci_trb_put(&xx->xx_trb[i++], parameter, status, control);
     1.1  jakllsch
    1.34     skrll 	if (len != 0) {
    1.34     skrll 		/* data phase */
    1.34     skrll 		parameter = DMAADDR(dma, 0);
    1.59      maya 		KASSERTMSG(len <= 0x10000, "len %d", len);
    1.34     skrll 		status = XHCI_TRB_2_IRQ_SET(0) |
    1.34     skrll 		    XHCI_TRB_2_TDSZ_SET(1) |
    1.34     skrll 		    XHCI_TRB_2_BYTES_SET(len);
    1.34     skrll 		control = (isread ? XHCI_TRB_3_DIR_IN : 0) |
    1.34     skrll 		    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_DATA_STAGE) |
1.62.2.1  pgoyette 		    (usbd_xfer_isread(xfer) ? XHCI_TRB_3_ISP_BIT : 0) |
    1.34     skrll 		    XHCI_TRB_3_IOC_BIT;
    1.34     skrll 		xhci_trb_put(&xx->xx_trb[i++], parameter, status, control);
    1.34     skrll 	}
     1.1  jakllsch
     1.1  jakllsch 	parameter = 0;
    1.28     skrll 	status = XHCI_TRB_2_IRQ_SET(0);
     1.1  jakllsch 	/* the status stage has inverted direction */
    1.28     skrll 	control = ((isread && (len > 0)) ? 0 : XHCI_TRB_3_DIR_IN) |
     1.1  jakllsch 	    XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_STATUS_STAGE) |
     1.1  jakllsch 	    XHCI_TRB_3_IOC_BIT;
     1.1  jakllsch 	xhci_trb_put(&xx->xx_trb[i++], parameter, status, control);
     1.1  jakllsch
     1.1  jakllsch 	mutex_enter(&tr->xr_lock);
     1.1  jakllsch 	xhci_ring_put(sc, tr, xfer, xx->xx_trb, i);
     1.1  jakllsch 	mutex_exit(&tr->xr_lock);
     1.1  jakllsch
     1.1  jakllsch 	xhci_db_write_4(sc, XHCI_DOORBELL(xs->xs_idx), dci);
     1.1  jakllsch
    1.34     skrll 	if (xfer->ux_timeout && !sc->sc_bus.ub_usepolling) {
    1.34     skrll 		callout_reset(&xfer->ux_callout, mstohz(xfer->ux_timeout),
     1.1  jakllsch 		    xhci_timeout, xfer);
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	return USBD_IN_PROGRESS;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_ctrl_done(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll 	usb_device_request_t *req = &xfer->ux_request;
    1.34     skrll 	int len = UGETW(req->wLength);
    1.34     skrll 	int rd = req->bmRequestType & UT_READ;
     1.1  jakllsch
    1.34     skrll 	if (len)
    1.34     skrll 		usb_syncmem(&xfer->ux_dmabuf, 0, len,
    1.34     skrll 		    rd ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_ctrl_abort(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	xhci_abort_xfer(xfer, USBD_CANCELLED);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_ctrl_close(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	xhci_close_pipe(pipe);
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /* ------------------ */
    1.34     skrll /* device isochronous */
     1.1  jakllsch
     1.1  jakllsch /* ----------- */
     1.1  jakllsch /* device bulk */
     1.1  jakllsch
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_device_bulk_transfer(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	/* Insert last in queue. */
     1.1  jakllsch 	mutex_enter(&sc->sc_lock);
     1.1  jakllsch 	err = usb_insert_transfer(xfer);
     1.1  jakllsch 	mutex_exit(&sc->sc_lock);
     1.1  jakllsch 	if (err)
     1.1  jakllsch 		return err;
     1.1  jakllsch
     1.1  jakllsch 	/*
     1.1  jakllsch 	 * Pipe isn't running (otherwise err would be USBD_INPROG),
     1.1  jakllsch 	 * so start it first.
     1.1  jakllsch 	 */
    1.34     skrll 	return xhci_device_bulk_start(SIMPLEQ_FIRST(&xfer->ux_pipe->up_queue));
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_device_bulk_start(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
    1.34     skrll 	struct xhci_slot * const xs = xfer->ux_pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(xfer->ux_pipe->up_endpoint->ue_edesc);
     1.1  jakllsch 	struct xhci_ring * const tr = &xs->xs_ep[dci].xe_tr;
    1.35     skrll 	struct xhci_xfer * const xx = XHCI_XFER2XXFER(xfer);
    1.34     skrll 	const uint32_t len = xfer->ux_length;
    1.34     skrll 	usb_dma_t * const dma = &xfer->ux_dmabuf;
     1.1  jakllsch 	uint64_t parameter;
     1.1  jakllsch 	uint32_t status;
     1.1  jakllsch 	uint32_t control;
     1.1  jakllsch 	u_int i = 0;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
    1.27     skrll 	DPRINTFN(15, "%p slot %u dci %u", xfer, xs->xs_idx, dci, 0);
     1.1  jakllsch
     1.1  jakllsch 	if (sc->sc_dying)
     1.1  jakllsch 		return USBD_IOERROR;
     1.1  jakllsch
    1.34     skrll 	KASSERT((xfer->ux_rqflags & URQ_REQUEST) == 0);
     1.1  jakllsch
     1.1  jakllsch 	parameter = DMAADDR(dma, 0);
    1.11       dsl 	/*
    1.13       dsl 	 * XXX: (dsl) The physical buffer must not cross a 64k boundary.
    1.11       dsl 	 * If the user supplied buffer crosses such a boundary then 2
    1.11       dsl 	 * (or more) TRB should be used.
    1.11       dsl 	 * If multiple TRB are used the td_size field must be set correctly.
    1.11       dsl 	 * For v1.0 devices (like ivy bridge) this is the number of usb data
    1.11       dsl 	 * blocks needed to complete the transfer.
    1.11       dsl 	 * Setting it to 1 in the last TRB causes an extra zero-length
    1.11       dsl 	 * data block be sent.
    1.11       dsl 	 * The earlier documentation differs, I don't know how it behaves.
    1.11       dsl 	 */
    1.59      maya 	KASSERTMSG(len <= 0x10000, "len %d", len);
     1.1  jakllsch 	status = XHCI_TRB_2_IRQ_SET(0) |
     1.1  jakllsch 	    XHCI_TRB_2_TDSZ_SET(1) |
     1.1  jakllsch 	    XHCI_TRB_2_BYTES_SET(len);
     1.1  jakllsch 	control = XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_NORMAL) |
1.62.2.1  pgoyette 	    (usbd_xfer_isread(xfer) ? XHCI_TRB_3_ISP_BIT : 0) |
1.62.2.1  pgoyette 	    XHCI_TRB_3_IOC_BIT;
     1.1  jakllsch 	xhci_trb_put(&xx->xx_trb[i++], parameter, status, control);
     1.1  jakllsch
     1.1  jakllsch 	mutex_enter(&tr->xr_lock);
     1.1  jakllsch 	xhci_ring_put(sc, tr, xfer, xx->xx_trb, i);
     1.1  jakllsch 	mutex_exit(&tr->xr_lock);
     1.1  jakllsch
     1.1  jakllsch 	xhci_db_write_4(sc, XHCI_DOORBELL(xs->xs_idx), dci);
     1.1  jakllsch
    1.34     skrll 	if (xfer->ux_timeout && !sc->sc_bus.ub_usepolling) {
    1.34     skrll 		callout_reset(&xfer->ux_callout, mstohz(xfer->ux_timeout),
    1.34     skrll 		    xhci_timeout, xfer);
    1.34     skrll 	}
    1.34     skrll
     1.1  jakllsch 	return USBD_IN_PROGRESS;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_bulk_done(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.27     skrll #ifdef USB_DEBUG
    1.34     skrll 	struct xhci_slot * const xs = xfer->ux_pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(xfer->ux_pipe->up_endpoint->ue_edesc);
    1.27     skrll #endif
    1.34     skrll 	const int isread = usbd_xfer_isread(xfer);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
     1.1  jakllsch
    1.27     skrll 	DPRINTFN(15, "%p slot %u dci %u", xfer, xs->xs_idx, dci, 0);
     1.1  jakllsch
    1.34     skrll 	usb_syncmem(&xfer->ux_dmabuf, 0, xfer->ux_length,
     1.1  jakllsch 	    isread ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_bulk_abort(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	xhci_abort_xfer(xfer, USBD_CANCELLED);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_bulk_close(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.34     skrll
    1.34     skrll 	xhci_close_pipe(pipe);
     1.1  jakllsch }
     1.1  jakllsch
    1.34     skrll /* ---------------- */
    1.34     skrll /* device interrupt */
     1.1  jakllsch
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_device_intr_transfer(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
     1.1  jakllsch 	usbd_status err;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	/* Insert last in queue. */
     1.1  jakllsch 	mutex_enter(&sc->sc_lock);
     1.1  jakllsch 	err = usb_insert_transfer(xfer);
     1.1  jakllsch 	mutex_exit(&sc->sc_lock);
     1.1  jakllsch 	if (err)
     1.1  jakllsch 		return err;
     1.1  jakllsch
     1.1  jakllsch 	/*
     1.1  jakllsch 	 * Pipe isn't running (otherwise err would be USBD_INPROG),
     1.1  jakllsch 	 * so start it first.
     1.1  jakllsch 	 */
    1.34     skrll 	return xhci_device_intr_start(SIMPLEQ_FIRST(&xfer->ux_pipe->up_queue));
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static usbd_status
    1.34     skrll xhci_device_intr_start(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
    1.34     skrll 	struct xhci_slot * const xs = xfer->ux_pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(xfer->ux_pipe->up_endpoint->ue_edesc);
     1.1  jakllsch 	struct xhci_ring * const tr = &xs->xs_ep[dci].xe_tr;
    1.35     skrll 	struct xhci_xfer * const xx = XHCI_XFER2XXFER(xfer);
    1.34     skrll 	const uint32_t len = xfer->ux_length;
    1.34     skrll 	usb_dma_t * const dma = &xfer->ux_dmabuf;
     1.1  jakllsch 	uint64_t parameter;
     1.1  jakllsch 	uint32_t status;
     1.1  jakllsch 	uint32_t control;
     1.1  jakllsch 	u_int i = 0;
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
    1.27     skrll 	DPRINTFN(15, "%p slot %u dci %u", xfer, xs->xs_idx, dci, 0);
     1.1  jakllsch
     1.1  jakllsch 	if (sc->sc_dying)
     1.1  jakllsch 		return USBD_IOERROR;
     1.1  jakllsch
    1.34     skrll 	KASSERT((xfer->ux_rqflags & URQ_REQUEST) == 0);
     1.1  jakllsch
     1.1  jakllsch 	parameter = DMAADDR(dma, 0);
    1.59      maya 	KASSERTMSG(len <= 0x10000, "len %d", len);
     1.1  jakllsch 	status = XHCI_TRB_2_IRQ_SET(0) |
     1.1  jakllsch 	    XHCI_TRB_2_TDSZ_SET(1) |
     1.1  jakllsch 	    XHCI_TRB_2_BYTES_SET(len);
     1.1  jakllsch 	control = XHCI_TRB_3_TYPE_SET(XHCI_TRB_TYPE_NORMAL) |
1.62.2.1  pgoyette 	    (usbd_xfer_isread(xfer) ? XHCI_TRB_3_ISP_BIT : 0) |
1.62.2.1  pgoyette 	    XHCI_TRB_3_IOC_BIT;
     1.1  jakllsch 	xhci_trb_put(&xx->xx_trb[i++], parameter, status, control);
     1.1  jakllsch
     1.1  jakllsch 	mutex_enter(&tr->xr_lock);
     1.1  jakllsch 	xhci_ring_put(sc, tr, xfer, xx->xx_trb, i);
     1.1  jakllsch 	mutex_exit(&tr->xr_lock);
     1.1  jakllsch
     1.1  jakllsch 	xhci_db_write_4(sc, XHCI_DOORBELL(xs->xs_idx), dci);
     1.1  jakllsch
    1.34     skrll 	if (xfer->ux_timeout && !sc->sc_bus.ub_usepolling) {
    1.34     skrll 		callout_reset(&xfer->ux_callout, mstohz(xfer->ux_timeout),
    1.34     skrll 		    xhci_timeout, xfer);
    1.34     skrll 	}
    1.34     skrll
     1.1  jakllsch 	return USBD_IN_PROGRESS;
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_intr_done(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc __diagused = XHCI_XFER2SC(xfer);
    1.27     skrll #ifdef USB_DEBUG
    1.34     skrll 	struct xhci_slot * const xs = xfer->ux_pipe->up_dev->ud_hcpriv;
    1.34     skrll 	const u_int dci = xhci_ep_get_dci(xfer->ux_pipe->up_endpoint->ue_edesc);
    1.19     ozaki #endif
    1.34     skrll 	const int isread = usbd_xfer_isread(xfer);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
    1.27     skrll 	DPRINTFN(15, "%p slot %u dci %u", xfer, xs->xs_idx, dci, 0);
     1.1  jakllsch
    1.34     skrll 	KASSERT(sc->sc_bus.ub_usepolling || mutex_owned(&sc->sc_lock));
     1.1  jakllsch
    1.34     skrll 	usb_syncmem(&xfer->ux_dmabuf, 0, xfer->ux_length,
     1.1  jakllsch 	    isread ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_intr_abort(struct usbd_xfer *xfer)
     1.1  jakllsch {
    1.34     skrll 	struct xhci_softc * const sc __diagused = XHCI_XFER2SC(xfer);
    1.27     skrll
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.10     skrll
    1.10     skrll 	KASSERT(mutex_owned(&sc->sc_lock));
    1.27     skrll 	DPRINTFN(15, "%p", xfer, 0, 0, 0);
    1.34     skrll 	KASSERT(xfer->ux_pipe->up_intrxfer == xfer);
    1.34     skrll 	xhci_abort_xfer(xfer, USBD_CANCELLED);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
    1.34     skrll xhci_device_intr_close(struct usbd_pipe *pipe)
     1.1  jakllsch {
    1.34     skrll 	//struct xhci_softc * const sc = XHCI_PIPE2SC(pipe);
    1.27     skrll
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll 	DPRINTFN(15, "%p", pipe, 0, 0, 0);
    1.27     skrll
    1.34     skrll 	xhci_close_pipe(pipe);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch /* ------------ */
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch xhci_timeout(void *addr)
     1.1  jakllsch {
     1.1  jakllsch 	struct xhci_xfer * const xx = addr;
    1.34     skrll 	struct usbd_xfer * const xfer = &xx->xx_xfer;
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	if (sc->sc_dying) {
     1.1  jakllsch 		return;
     1.1  jakllsch 	}
     1.1  jakllsch
     1.1  jakllsch 	usb_init_task(&xx->xx_abort_task, xhci_timeout_task, addr,
     1.1  jakllsch 	    USB_TASKQ_MPSAFE);
    1.34     skrll 	usb_add_task(xx->xx_xfer.ux_pipe->up_dev, &xx->xx_abort_task,
     1.1  jakllsch 	    USB_TASKQ_HC);
     1.1  jakllsch }
     1.1  jakllsch
     1.1  jakllsch static void
     1.1  jakllsch xhci_timeout_task(void *addr)
     1.1  jakllsch {
    1.34     skrll 	struct usbd_xfer * const xfer = addr;
    1.34     skrll 	struct xhci_softc * const sc = XHCI_XFER2SC(xfer);
     1.1  jakllsch
    1.27     skrll 	XHCIHIST_FUNC(); XHCIHIST_CALLED();
    1.27     skrll
     1.1  jakllsch 	mutex_enter(&sc->sc_lock);
     1.1  jakllsch 	xhci_abort_xfer(xfer, USBD_TIMEOUT);
     1.1  jakllsch 	mutex_exit(&sc->sc_lock);
     1.1  jakllsch }