dev/usb/motg.c

1.9  jmcneill /*	$NetBSD: motg.c,v 1.9 2014/09/13 14:46:50 jmcneill Exp $	*/
1.1    bouyer
1.1    bouyer /*
1.1    bouyer  * Copyright (c) 1998, 2004, 2011, 2012, 2014 The NetBSD Foundation, Inc.
1.1    bouyer  * All rights reserved.
1.1    bouyer  *
1.1    bouyer  * This code is derived from software contributed to The NetBSD Foundation
1.1    bouyer  * by Lennart Augustsson (lennart (at) augustsson.net) at
1.1    bouyer  * Carlstedt Research & Technology, Jared D. McNeill (jmcneill (at) invisible.ca),
1.1    bouyer  * Matthew R. Green (mrg (at) eterna.com.au), and Manuel Bouyer (bouyer (at) netbsd.org).
1.1    bouyer  *
1.1    bouyer  * Redistribution and use in source and binary forms, with or without
1.1    bouyer  * modification, are permitted provided that the following conditions
1.1    bouyer  * are met:
1.1    bouyer  * 1. Redistributions of source code must retain the above copyright
1.1    bouyer  *    notice, this list of conditions and the following disclaimer.
1.1    bouyer  * 2. Redistributions in binary form must reproduce the above copyright
1.1    bouyer  *    notice, this list of conditions and the following disclaimer in the
1.1    bouyer  *    documentation and/or other materials provided with the distribution.
1.1    bouyer  *
1.1    bouyer  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1    bouyer  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1    bouyer  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1    bouyer  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1    bouyer  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1    bouyer  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1    bouyer  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1    bouyer  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1    bouyer  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1    bouyer  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1    bouyer  * POSSIBILITY OF SUCH DAMAGE.
1.1    bouyer  */
1.1    bouyer
1.1    bouyer
1.1    bouyer /*
1.1    bouyer  * This file contains the driver for the Mentor Graphics Inventra USB
1.1    bouyer  * 2.0 High Speed Dual-Role controller.
1.1    bouyer  *
1.1    bouyer  * NOTE: The current implementation only supports Device Side Mode!
1.1    bouyer  */
1.1    bouyer
1.1    bouyer #include <sys/cdefs.h>
1.9  jmcneill __KERNEL_RCSID(0, "$NetBSD: motg.c,v 1.9 2014/09/13 14:46:50 jmcneill Exp $");
1.1    bouyer
1.1    bouyer #include <sys/param.h>
1.1    bouyer #include <sys/systm.h>
1.1    bouyer #include <sys/kernel.h>
1.1    bouyer #include <sys/kmem.h>
1.1    bouyer #include <sys/device.h>
1.1    bouyer #include <sys/select.h>
1.1    bouyer #include <sys/extent.h>
1.1    bouyer #include <sys/proc.h>
1.1    bouyer #include <sys/queue.h>
1.1    bouyer #include <sys/bus.h>
1.1    bouyer #include <sys/cpu.h>
1.1    bouyer
1.1    bouyer #include <machine/endian.h>
1.1    bouyer
1.1    bouyer #include <dev/usb/usb.h>
1.1    bouyer #include <dev/usb/usbdi.h>
1.1    bouyer #include <dev/usb/usbdivar.h>
1.1    bouyer #include <dev/usb/usb_mem.h>
1.1    bouyer #include <dev/usb/usb_quirks.h>
1.1    bouyer
1.1    bouyer #include <dev/usb/motgreg.h>
1.1    bouyer #include <dev/usb/motgvar.h>
1.1    bouyer #include <dev/usb/usbroothub_subr.h>
1.1    bouyer
1.1    bouyer #define MOTG_DEBUG
1.1    bouyer #ifdef MOTG_DEBUG
1.1    bouyer #define DPRINTF(x)	if (motgdebug) printf x
1.1    bouyer #define DPRINTFN(n,x)	if (motgdebug & (n)) printf x
1.1    bouyer #define MD_ROOT 0x0002
1.1    bouyer #define MD_CTRL 0x0004
1.1    bouyer #define MD_BULK 0x0008
1.1    bouyer // int motgdebug = MD_ROOT | MD_CTRL | MD_BULK;
1.1    bouyer int motgdebug = 0;
1.1    bouyer #else
1.1    bouyer #define DPRINTF(x)
1.1    bouyer #define DPRINTFN(n,x)
1.1    bouyer #endif
1.1    bouyer
1.1    bouyer /* various timeouts, for various speeds */
1.1    bouyer /* control NAK timeouts */
1.1    bouyer #define NAK_TO_CTRL	10	/* 1024 frames, about 1s */
1.1    bouyer #define NAK_TO_CTRL_HIGH 13	/* 8k microframes, about 0.8s */
1.1    bouyer
1.1    bouyer /* intr/iso polling intervals */
1.1    bouyer #define POLL_TO		100	/* 100 frames, about 0.1s */
1.1    bouyer #define POLL_TO_HIGH	10	/* 100 microframes, about 0.12s */
1.1    bouyer
1.1    bouyer /* bulk NAK timeouts */
1.3    bouyer #define NAK_TO_BULK	0 /* disabled */
1.3    bouyer #define NAK_TO_BULK_HIGH 0
1.1    bouyer
1.1    bouyer static void 		motg_hub_change(struct motg_softc *);
1.1    bouyer static usbd_status	motg_root_ctrl_transfer(usbd_xfer_handle);
1.1    bouyer static usbd_status	motg_root_ctrl_start(usbd_xfer_handle);
1.1    bouyer static void		motg_root_ctrl_abort(usbd_xfer_handle);
1.1    bouyer static void		motg_root_ctrl_close(usbd_pipe_handle);
1.1    bouyer static void		motg_root_ctrl_done(usbd_xfer_handle);
1.1    bouyer
1.1    bouyer static usbd_status	motg_root_intr_transfer(usbd_xfer_handle);
1.1    bouyer static usbd_status	motg_root_intr_start(usbd_xfer_handle);
1.1    bouyer static void		motg_root_intr_abort(usbd_xfer_handle);
1.1    bouyer static void		motg_root_intr_close(usbd_pipe_handle);
1.1    bouyer static void		motg_root_intr_done(usbd_xfer_handle);
1.1    bouyer
1.1    bouyer static usbd_status	motg_open(usbd_pipe_handle);
1.1    bouyer static void		motg_poll(struct usbd_bus *);
1.1    bouyer static void		motg_softintr(void *);
1.1    bouyer static usbd_status	motg_allocm(struct usbd_bus *, usb_dma_t *, u_int32_t);
1.1    bouyer static void		motg_freem(struct usbd_bus *, usb_dma_t *);
1.1    bouyer static usbd_xfer_handle	motg_allocx(struct usbd_bus *);
1.1    bouyer static void		motg_freex(struct usbd_bus *, usbd_xfer_handle);
1.1    bouyer static void		motg_get_lock(struct usbd_bus *, kmutex_t **);
1.1    bouyer static void		motg_noop(usbd_pipe_handle pipe);
1.1    bouyer static usbd_status	motg_portreset(struct motg_softc*);
1.1    bouyer
1.1    bouyer static usbd_status	motg_device_ctrl_transfer(usbd_xfer_handle);
1.1    bouyer static usbd_status	motg_device_ctrl_start(usbd_xfer_handle);
1.1    bouyer static void		motg_device_ctrl_abort(usbd_xfer_handle);
1.1    bouyer static void		motg_device_ctrl_close(usbd_pipe_handle);
1.1    bouyer static void		motg_device_ctrl_done(usbd_xfer_handle);
1.1    bouyer static usbd_status	motg_device_ctrl_start1(struct motg_softc *);
1.1    bouyer static void		motg_device_ctrl_read(usbd_xfer_handle);
1.1    bouyer static void		motg_device_ctrl_intr_rx(struct motg_softc *);
1.1    bouyer static void		motg_device_ctrl_intr_tx(struct motg_softc *);
1.1    bouyer
1.1    bouyer static usbd_status	motg_device_data_transfer(usbd_xfer_handle);
1.1    bouyer static usbd_status	motg_device_data_start(usbd_xfer_handle);
1.1    bouyer static usbd_status	motg_device_data_start1(struct motg_softc *,
1.1    bouyer 			    struct motg_hw_ep *);
1.1    bouyer static void		motg_device_data_abort(usbd_xfer_handle);
1.1    bouyer static void		motg_device_data_close(usbd_pipe_handle);
1.1    bouyer static void		motg_device_data_done(usbd_xfer_handle);
1.1    bouyer static void		motg_device_intr_rx(struct motg_softc *, int);
1.1    bouyer static void		motg_device_intr_tx(struct motg_softc *, int);
1.1    bouyer static void		motg_device_data_read(usbd_xfer_handle);
1.1    bouyer static void		motg_device_data_write(usbd_xfer_handle);
1.1    bouyer
1.1    bouyer static void		motg_waitintr(struct motg_softc *, usbd_xfer_handle);
1.3    bouyer static void		motg_device_clear_toggle(usbd_pipe_handle);
1.3    bouyer static void		motg_device_xfer_abort(usbd_xfer_handle);
1.1    bouyer
1.1    bouyer #define MOTG_INTR_ENDPT 1
1.1    bouyer #define UBARR(sc) bus_space_barrier((sc)->sc_iot, (sc)->sc_ioh, 0, (sc)->sc_size, \
1.1    bouyer 			BUS_SPACE_BARRIER_READ|BUS_SPACE_BARRIER_WRITE)
1.1    bouyer #define UWRITE1(sc, r, x) \
1.1    bouyer  do { UBARR(sc); bus_space_write_1((sc)->sc_iot, (sc)->sc_ioh, (r), (x)); \
1.1    bouyer  } while (/*CONSTCOND*/0)
1.1    bouyer #define UWRITE2(sc, r, x) \
1.1    bouyer  do { UBARR(sc); bus_space_write_2((sc)->sc_iot, (sc)->sc_ioh, (r), (x)); \
1.1    bouyer  } while (/*CONSTCOND*/0)
1.1    bouyer #define UWRITE4(sc, r, x) \
1.1    bouyer  do { UBARR(sc); bus_space_write_4((sc)->sc_iot, (sc)->sc_ioh, (r), (x)); \
1.1    bouyer  } while (/*CONSTCOND*/0)
1.1    bouyer
1.1    bouyer static __inline uint32_t
1.1    bouyer UREAD1(struct motg_softc *sc, bus_size_t r)
1.1    bouyer {
1.1    bouyer
1.1    bouyer 	UBARR(sc);
1.1    bouyer 	return bus_space_read_1(sc->sc_iot, sc->sc_ioh, r);
1.1    bouyer }
1.1    bouyer static __inline uint32_t
1.1    bouyer UREAD2(struct motg_softc *sc, bus_size_t r)
1.1    bouyer {
1.1    bouyer
1.1    bouyer 	UBARR(sc);
1.1    bouyer 	return bus_space_read_2(sc->sc_iot, sc->sc_ioh, r);
1.1    bouyer }
1.4     joerg
1.4     joerg #if 0
1.1    bouyer static __inline uint32_t
1.1    bouyer UREAD4(struct motg_softc *sc, bus_size_t r)
1.1    bouyer {
1.1    bouyer
1.1    bouyer 	UBARR(sc);
1.1    bouyer 	return bus_space_read_4(sc->sc_iot, sc->sc_ioh, r);
1.1    bouyer }
1.4     joerg #endif
1.1    bouyer
1.1    bouyer static void
1.7     skrll musbotg_pull_common(struct motg_softc *sc, uint8_t on)
1.1    bouyer {
1.1    bouyer         uint8_t val;
1.1    bouyer
1.1    bouyer         val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer         if (on)
1.1    bouyer                 val |= MUSB2_MASK_SOFTC;
1.1    bouyer         else
1.1    bouyer                 val &= ~MUSB2_MASK_SOFTC;
1.1    bouyer
1.1    bouyer         UWRITE1(sc, MUSB2_REG_POWER, val);
1.1    bouyer }
1.1    bouyer
1.1    bouyer const struct usbd_bus_methods motg_bus_methods = {
1.1    bouyer 	.open_pipe =	motg_open,
1.1    bouyer 	.soft_intr =	motg_softintr,
1.1    bouyer 	.do_poll =	motg_poll,
1.1    bouyer 	.allocm =	motg_allocm,
1.1    bouyer 	.freem =	motg_freem,
1.1    bouyer 	.allocx =	motg_allocx,
1.1    bouyer 	.freex =	motg_freex,
1.1    bouyer 	.get_lock =	motg_get_lock,
1.1    bouyer 	.new_device =	NULL,
1.1    bouyer };
1.1    bouyer
1.1    bouyer const struct usbd_pipe_methods motg_root_ctrl_methods = {
1.1    bouyer 	.transfer =	motg_root_ctrl_transfer,
1.1    bouyer 	.start =	motg_root_ctrl_start,
1.1    bouyer 	.abort =	motg_root_ctrl_abort,
1.1    bouyer 	.close =	motg_root_ctrl_close,
1.1    bouyer 	.cleartoggle =	motg_noop,
1.1    bouyer 	.done =		motg_root_ctrl_done,
1.1    bouyer };
1.1    bouyer
1.1    bouyer const struct usbd_pipe_methods motg_root_intr_methods = {
1.1    bouyer 	.transfer =	motg_root_intr_transfer,
1.1    bouyer 	.start =	motg_root_intr_start,
1.1    bouyer 	.abort =	motg_root_intr_abort,
1.1    bouyer 	.close =	motg_root_intr_close,
1.1    bouyer 	.cleartoggle =	motg_noop,
1.1    bouyer 	.done =		motg_root_intr_done,
1.1    bouyer };
1.1    bouyer
1.1    bouyer const struct usbd_pipe_methods motg_device_ctrl_methods = {
1.1    bouyer 	.transfer =	motg_device_ctrl_transfer,
1.1    bouyer 	.start =	motg_device_ctrl_start,
1.1    bouyer 	.abort =	motg_device_ctrl_abort,
1.1    bouyer 	.close =	motg_device_ctrl_close,
1.1    bouyer 	.cleartoggle =	motg_noop,
1.1    bouyer 	.done =		motg_device_ctrl_done,
1.1    bouyer };
1.1    bouyer
1.1    bouyer const struct usbd_pipe_methods motg_device_data_methods = {
1.1    bouyer 	.transfer =	motg_device_data_transfer,
1.1    bouyer 	.start =	motg_device_data_start,
1.1    bouyer 	.abort =	motg_device_data_abort,
1.1    bouyer 	.close =	motg_device_data_close,
1.1    bouyer 	.cleartoggle =	motg_device_clear_toggle,
1.1    bouyer 	.done =		motg_device_data_done,
1.1    bouyer };
1.1    bouyer
1.1    bouyer usbd_status
1.1    bouyer motg_init(struct motg_softc *sc)
1.1    bouyer {
1.1    bouyer 	uint32_t nrx, ntx, val;
1.1    bouyer 	int dynfifo;
1.1    bouyer 	int offset, i;
1.1    bouyer
1.1    bouyer 	if (sc->sc_mode == MOTG_MODE_DEVICE)
1.1    bouyer 		return USBD_NORMAL_COMPLETION; /* not supported */
1.1    bouyer
1.1    bouyer 	/* disable all interrupts */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_INTUSBE, 0);
1.1    bouyer 	UWRITE2(sc, MUSB2_REG_INTTXE, 0);
1.1    bouyer 	UWRITE2(sc, MUSB2_REG_INTRXE, 0);
1.1    bouyer 	/* disable pullup */
1.1    bouyer
1.7     skrll 	musbotg_pull_common(sc, 0);
1.1    bouyer
1.1    bouyer 	/* disable double packet buffering XXX what's this ? */
1.1    bouyer 	UWRITE2(sc, MUSB2_REG_RXDBDIS, 0xFFFF);
1.1    bouyer 	UWRITE2(sc, MUSB2_REG_TXDBDIS, 0xFFFF);
1.1    bouyer
1.1    bouyer 	/* enable HighSpeed and ISO Update flags */
1.1    bouyer
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_POWER,
1.1    bouyer 	    MUSB2_MASK_HSENAB | MUSB2_MASK_ISOUPD);
1.1    bouyer
1.1    bouyer 	if (sc->sc_mode == MOTG_MODE_DEVICE) {
1.1    bouyer 		/* clear Session bit, if set */
1.1    bouyer 		val = UREAD1(sc, MUSB2_REG_DEVCTL);
1.1    bouyer 		val &= ~MUSB2_MASK_SESS;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_DEVCTL, val);
1.1    bouyer 	} else {
1.1    bouyer 		/* Enter session for Host mode */
1.1    bouyer 		val = UREAD1(sc, MUSB2_REG_DEVCTL);
1.1    bouyer 		val |= MUSB2_MASK_SESS;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_DEVCTL, val);
1.1    bouyer 	}
1.1    bouyer 	delay(1000);
1.1    bouyer 	DPRINTF(("DEVCTL 0x%x\n", UREAD1(sc, MUSB2_REG_DEVCTL)));
1.1    bouyer
1.1    bouyer 	/* disable testmode */
1.1    bouyer
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TESTMODE, 0);
1.1    bouyer
1.7     skrll 	/* set default value */
1.1    bouyer
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_MISC, 0);
1.1    bouyer
1.7     skrll 	/* select endpoint index 0 */
1.1    bouyer
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_EPINDEX, 0);
1.1    bouyer
1.9  jmcneill 	if (sc->sc_ep_max == 0) {
1.9  jmcneill 		/* read out number of endpoints */
1.9  jmcneill 		nrx = (UREAD1(sc, MUSB2_REG_EPINFO) / 16);
1.1    bouyer
1.9  jmcneill 		ntx = (UREAD1(sc, MUSB2_REG_EPINFO) % 16);
1.1    bouyer
1.9  jmcneill 		/* these numbers exclude the control endpoint */
1.1    bouyer
1.9  jmcneill 		DPRINTF(("RX/TX endpoints: %u/%u\n", nrx, ntx));
1.1    bouyer
1.9  jmcneill 		sc->sc_ep_max = MAX(nrx, ntx);
1.9  jmcneill 	} else {
1.9  jmcneill 		nrx = ntx = sc->sc_ep_max;
1.9  jmcneill 	}
1.1    bouyer 	if (sc->sc_ep_max == 0) {
1.1    bouyer 		aprint_error_dev(sc->sc_dev, " no endpoints\n");
1.1    bouyer 		return USBD_INVAL;
1.1    bouyer 	}
1.1    bouyer 	KASSERT(sc->sc_ep_max <= MOTG_MAX_HW_EP);
1.1    bouyer 	/* read out configuration data */
1.1    bouyer 	val = UREAD1(sc, MUSB2_REG_CONFDATA);
1.1    bouyer
1.1    bouyer 	DPRINTF(("Config Data: 0x%02x\n", val));
1.1    bouyer
1.1    bouyer 	dynfifo = (val & MUSB2_MASK_CD_DYNFIFOSZ) ? 1 : 0;
1.1    bouyer
1.7     skrll 	if (dynfifo) {
1.1    bouyer 		aprint_normal_dev(sc->sc_dev, "Dynamic FIFO sizing detected, "
1.1    bouyer 		    "assuming 16Kbytes of FIFO RAM\n");
1.7     skrll 	}
1.7     skrll
1.1    bouyer 	DPRINTF(("HW version: 0x%04x\n", UREAD1(sc, MUSB2_REG_HWVERS)));
1.1    bouyer
1.1    bouyer 	/* initialise endpoint profiles */
1.1    bouyer 	sc->sc_in_ep[0].ep_fifo_size = 64;
1.1    bouyer 	sc->sc_out_ep[0].ep_fifo_size = 0; /* not used */
1.1    bouyer 	sc->sc_out_ep[0].ep_number = sc->sc_in_ep[0].ep_number = 0;
1.1    bouyer 	SIMPLEQ_INIT(&sc->sc_in_ep[0].ep_pipes);
1.1    bouyer 	offset = 64;
1.1    bouyer
1.1    bouyer 	for (i = 1; i <= sc->sc_ep_max; i++) {
1.1    bouyer 		int fiforx_size, fifotx_size, fifo_size;
1.1    bouyer
1.7     skrll 		/* select endpoint */
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_EPINDEX, i);
1.1    bouyer
1.1    bouyer 		val = UREAD1(sc, MUSB2_REG_FSIZE);
1.1    bouyer 		fiforx_size = (val & MUSB2_MASK_RX_FSIZE) >> 4;
1.1    bouyer 		fifotx_size = (val & MUSB2_MASK_TX_FSIZE);
1.1    bouyer
1.1    bouyer 		DPRINTF(("Endpoint %u FIFO size: IN=%u, OUT=%u, DYN=%d\n",
1.1    bouyer 		    i, fifotx_size, fiforx_size, dynfifo));
1.1    bouyer
1.1    bouyer 		if (dynfifo) {
1.1    bouyer 			if (i < 3) {
1.1    bouyer 				fifo_size = 12;       /* 4K */
1.1    bouyer 			} else if (i < 10) {
1.1    bouyer 				fifo_size = 10;       /* 1K */
1.1    bouyer 			} else {
1.7     skrll 				fifo_size = 7;        /* 128 bytes */
1.7     skrll 			}
1.1    bouyer 			if (fiforx_size && (i <= nrx)) {
1.1    bouyer 				fiforx_size = fifo_size;
1.1    bouyer 				if (fifo_size > 7) {
1.3    bouyer #if 0
1.7     skrll 					UWRITE1(sc, MUSB2_REG_RXFIFOSZ,
1.1    bouyer 					    MUSB2_VAL_FIFOSZ(fifo_size) |
1.1    bouyer 					    MUSB2_MASK_FIFODB);
1.3    bouyer #else
1.7     skrll 					UWRITE1(sc, MUSB2_REG_RXFIFOSZ,
1.3    bouyer 					    MUSB2_VAL_FIFOSZ(fifo_size));
1.3    bouyer #endif
1.1    bouyer 				} else {
1.7     skrll 					UWRITE1(sc, MUSB2_REG_RXFIFOSZ,
1.3    bouyer 					    MUSB2_VAL_FIFOSZ(fifo_size));
1.1    bouyer 				}
1.7     skrll 				UWRITE2(sc, MUSB2_REG_RXFIFOADD,
1.1    bouyer 				    offset >> 3);
1.1    bouyer 				offset += (1 << fiforx_size);
1.1    bouyer 			}
1.1    bouyer 			if (fifotx_size && (i <= ntx)) {
1.1    bouyer 				fifotx_size = fifo_size;
1.1    bouyer 				if (fifo_size > 7) {
1.3    bouyer #if 0
1.7     skrll 					UWRITE1(sc, MUSB2_REG_TXFIFOSZ,
1.7     skrll 					    MUSB2_VAL_FIFOSZ(fifo_size) |
1.1    bouyer 					    MUSB2_MASK_FIFODB);
1.3    bouyer #else
1.7     skrll 					UWRITE1(sc, MUSB2_REG_TXFIFOSZ,
1.7     skrll 					    MUSB2_VAL_FIFOSZ(fifo_size));
1.3    bouyer #endif
1.1    bouyer 				} else {
1.7     skrll 					UWRITE1(sc, MUSB2_REG_TXFIFOSZ,
1.7     skrll 					    MUSB2_VAL_FIFOSZ(fifo_size));
1.7     skrll 				}
1.7     skrll
1.7     skrll 				UWRITE2(sc, MUSB2_REG_TXFIFOADD,
1.1    bouyer 				    offset >> 3);
1.7     skrll
1.1    bouyer 				offset += (1 << fifotx_size);
1.1    bouyer 			}
1.1    bouyer 		}
1.1    bouyer 		if (fiforx_size && (i <= nrx)) {
1.1    bouyer 			sc->sc_in_ep[i].ep_fifo_size = (1 << fiforx_size);
1.1    bouyer 			SIMPLEQ_INIT(&sc->sc_in_ep[i].ep_pipes);
1.1    bouyer 		}
1.1    bouyer 		if (fifotx_size && (i <= ntx)) {
1.1    bouyer 			sc->sc_out_ep[i].ep_fifo_size = (1 << fifotx_size);
1.1    bouyer 			SIMPLEQ_INIT(&sc->sc_out_ep[i].ep_pipes);
1.1    bouyer 		}
1.1    bouyer 		sc->sc_out_ep[i].ep_number = sc->sc_in_ep[i].ep_number = i;
1.1    bouyer 	}
1.1    bouyer
1.7     skrll
1.1    bouyer 	DPRINTF(("Dynamic FIFO size = %d bytes\n", offset));
1.1    bouyer
1.1    bouyer 	/* turn on default interrupts */
1.1    bouyer
1.1    bouyer 	if (sc->sc_mode == MOTG_MODE_HOST) {
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_INTUSBE, 0xff);
1.1    bouyer 		UWRITE2(sc, MUSB2_REG_INTTXE, 0xffff);
1.1    bouyer 		UWRITE2(sc, MUSB2_REG_INTRXE, 0xffff);
1.1    bouyer 	} else
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_INTUSBE, MUSB2_MASK_IRESET);
1.1    bouyer
1.1    bouyer 	sc->sc_xferpool = pool_cache_init(sizeof(struct motg_xfer), 0, 0, 0,
1.1    bouyer 	    "motgxfer", NULL, IPL_USB, NULL, NULL, NULL);
1.1    bouyer
1.1    bouyer 	mutex_init(&sc->sc_lock, MUTEX_DEFAULT, IPL_SOFTUSB);
1.1    bouyer 	mutex_init(&sc->sc_intr_lock, MUTEX_DEFAULT, IPL_SCHED);
1.1    bouyer
1.1    bouyer 	/* Set up the bus struct. */
1.1    bouyer 	sc->sc_bus.methods = &motg_bus_methods;
1.1    bouyer 	sc->sc_bus.pipe_size = sizeof(struct motg_pipe);
1.1    bouyer 	sc->sc_bus.usbrev = USBREV_2_0;
1.1    bouyer 	sc->sc_bus.hci_private = sc;
1.1    bouyer 	snprintf(sc->sc_vendor, sizeof(sc->sc_vendor),
1.1    bouyer 	    "Mentor Graphics");
1.1    bouyer 	sc->sc_child = config_found(sc->sc_dev, &sc->sc_bus, usbctlprint);
1.1    bouyer 	return USBD_NORMAL_COMPLETION;
1.1    bouyer }
1.1    bouyer
1.1    bouyer static int
1.1    bouyer motg_select_ep(struct motg_softc *sc, usbd_pipe_handle pipe)
1.1    bouyer {
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)pipe;
1.1    bouyer 	usb_endpoint_descriptor_t *ed = pipe->endpoint->edesc;
1.1    bouyer 	struct motg_hw_ep *ep;
1.1    bouyer 	int i, size;
1.1    bouyer
1.1    bouyer 	ep = (UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN) ?
1.1    bouyer 	    sc->sc_in_ep : sc->sc_out_ep;
1.1    bouyer 	size = UE_GET_SIZE(UGETW(pipe->endpoint->edesc->wMaxPacketSize));
1.1    bouyer
1.1    bouyer 	for (i = sc->sc_ep_max; i >= 1; i--) {
1.1    bouyer 		DPRINTF(("%s_ep[%d].ep_fifo_size %d size %d ref %d\n",
1.1    bouyer 		    (UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN) ?
1.1    bouyer 		    "in" : "out", i, ep[i].ep_fifo_size, size, ep[i].refcount));
1.1    bouyer 		if (ep[i].ep_fifo_size >= size) {
1.1    bouyer 			/* found a suitable endpoint */
1.1    bouyer 			otgpipe->hw_ep = &ep[i];
1.1    bouyer 			mutex_enter(&sc->sc_lock);
1.1    bouyer 			if (otgpipe->hw_ep->refcount > 0) {
1.1    bouyer 				/* no luck, try next */
1.1    bouyer 				mutex_exit(&sc->sc_lock);
1.1    bouyer 				otgpipe->hw_ep = NULL;
1.1    bouyer 			} else {
1.1    bouyer 				otgpipe->hw_ep->refcount++;
1.1    bouyer 				SIMPLEQ_INSERT_TAIL(&otgpipe->hw_ep->ep_pipes,
1.1    bouyer 				    otgpipe, ep_pipe_list);
1.1    bouyer 				mutex_exit(&sc->sc_lock);
1.1    bouyer 				return 0;
1.1    bouyer 			}
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	return -1;
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Open a new pipe. */
1.1    bouyer usbd_status
1.1    bouyer motg_open(usbd_pipe_handle pipe)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)pipe;
1.1    bouyer 	usb_endpoint_descriptor_t *ed = pipe->endpoint->edesc;
1.1    bouyer
1.1    bouyer 	DPRINTF(("motg_open: pipe=%p, addr=%d, endpt=%d (%d)\n",
1.1    bouyer 		     pipe, pipe->device->address,
1.1    bouyer 		     ed->bEndpointAddress, sc->sc_root_addr));
1.1    bouyer
1.1    bouyer 	if (sc->sc_dying)
1.1    bouyer 		return USBD_IOERROR;
1.1    bouyer
1.1    bouyer 	/* toggle state needed for bulk endpoints */
1.1    bouyer 	otgpipe->nexttoggle = pipe->endpoint->datatoggle;
1.1    bouyer
1.1    bouyer 	if (pipe->device->address == sc->sc_root_addr) {
1.1    bouyer 		switch (ed->bEndpointAddress) {
1.1    bouyer 		case USB_CONTROL_ENDPOINT:
1.1    bouyer 			pipe->methods = &motg_root_ctrl_methods;
1.1    bouyer 			break;
1.1    bouyer 		case UE_DIR_IN | MOTG_INTR_ENDPT:
1.1    bouyer 			pipe->methods = &motg_root_intr_methods;
1.1    bouyer 			break;
1.1    bouyer 		default:
1.1    bouyer 			return (USBD_INVAL);
1.1    bouyer 		}
1.1    bouyer 	} else {
1.1    bouyer 		switch (ed->bmAttributes & UE_XFERTYPE) {
1.1    bouyer 		case UE_CONTROL:
1.1    bouyer 			pipe->methods = &motg_device_ctrl_methods;
1.1    bouyer 			/* always use sc_in_ep[0] for in and out */
1.1    bouyer 			otgpipe->hw_ep = &sc->sc_in_ep[0];
1.1    bouyer 			mutex_enter(&sc->sc_lock);
1.1    bouyer 			otgpipe->hw_ep->refcount++;
1.1    bouyer 			SIMPLEQ_INSERT_TAIL(&otgpipe->hw_ep->ep_pipes,
1.1    bouyer 			    otgpipe, ep_pipe_list);
1.1    bouyer 			mutex_exit(&sc->sc_lock);
1.1    bouyer 			break;
1.1    bouyer 		case UE_BULK:
1.1    bouyer 		case UE_INTERRUPT:
1.7     skrll 			DPRINTFN(MD_BULK,
1.1    bouyer 			    ("new %s %s pipe wMaxPacketSize %d\n",
1.1    bouyer 			    (ed->bmAttributes & UE_XFERTYPE) == UE_BULK ?
1.1    bouyer 			    "bulk" : "interrupt",
1.1    bouyer 			    (UE_GET_DIR(pipe->endpoint->edesc->bEndpointAddress) == UE_DIR_IN) ? "read" : "write",
1.1    bouyer 			    UGETW(pipe->endpoint->edesc->wMaxPacketSize)));
1.1    bouyer 			if (motg_select_ep(sc, pipe) != 0)
1.1    bouyer 				goto bad;
1.1    bouyer 			KASSERT(otgpipe->hw_ep != NULL);
1.1    bouyer 			pipe->methods = &motg_device_data_methods;
1.1    bouyer 			otgpipe->nexttoggle = pipe->endpoint->datatoggle;
1.1    bouyer 			break;
1.1    bouyer 		default:
1.1    bouyer 			goto bad;
1.1    bouyer #ifdef notyet
1.1    bouyer 		case UE_ISOCHRONOUS:
1.1    bouyer 			...
1.1    bouyer 			break;
1.1    bouyer #endif /* notyet */
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	return (USBD_NORMAL_COMPLETION);
1.1    bouyer
1.1    bouyer  bad:
1.1    bouyer 	return (USBD_NOMEM);
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_softintr(void *v)
1.1    bouyer {
1.1    bouyer 	struct usbd_bus *bus = v;
1.1    bouyer 	struct motg_softc *sc = bus->hci_private;
1.1    bouyer 	uint16_t rx_status, tx_status;
1.1    bouyer 	uint8_t ctrl_status;
1.1    bouyer 	uint32_t val;
1.1    bouyer 	int i;
1.1    bouyer
1.1    bouyer 	KASSERT(sc->sc_bus.use_polling || mutex_owned(&sc->sc_lock));
1.1    bouyer
1.1    bouyer 	DPRINTFN(MD_ROOT | MD_CTRL,
1.1    bouyer 	    ("%s: motg_softintr\n", device_xname(sc->sc_dev)));
1.1    bouyer
1.1    bouyer 	mutex_spin_enter(&sc->sc_intr_lock);
1.1    bouyer 	rx_status = sc->sc_intr_rx_ep;
1.1    bouyer 	sc->sc_intr_rx_ep = 0;
1.1    bouyer 	tx_status = sc->sc_intr_tx_ep;
1.1    bouyer 	sc->sc_intr_tx_ep = 0;
1.1    bouyer 	ctrl_status = sc->sc_intr_ctrl;
1.1    bouyer 	sc->sc_intr_ctrl = 0;
1.1    bouyer 	mutex_spin_exit(&sc->sc_intr_lock);
1.1    bouyer
1.1    bouyer 	ctrl_status |= UREAD1(sc, MUSB2_REG_INTUSB);
1.1    bouyer
1.1    bouyer 	if (ctrl_status & (MUSB2_MASK_IRESET |
1.1    bouyer 	    MUSB2_MASK_IRESUME | MUSB2_MASK_ISUSP |
1.1    bouyer 	    MUSB2_MASK_ICONN | MUSB2_MASK_IDISC)) {
1.1    bouyer 		DPRINTFN(MD_ROOT | MD_CTRL, ("motg_softintr bus 0x%x\n",
1.1    bouyer 		    ctrl_status));
1.1    bouyer
1.1    bouyer 		if (ctrl_status & MUSB2_MASK_IRESET) {
1.1    bouyer 			sc->sc_isreset = 1;
1.1    bouyer 			sc->sc_port_suspended = 0;
1.1    bouyer 			sc->sc_port_suspended_change = 1;
1.1    bouyer 			sc->sc_connected_changed = 1;
1.1    bouyer 			sc->sc_port_enabled = 1;
1.1    bouyer
1.1    bouyer 			val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer 			if (val & MUSB2_MASK_HSMODE)
1.1    bouyer 				sc->sc_high_speed = 1;
1.1    bouyer 			else
1.1    bouyer 				sc->sc_high_speed = 0;
1.1    bouyer 			DPRINTFN(MD_ROOT | MD_CTRL, ("motg_softintr speed %d\n",
1.1    bouyer 			    sc->sc_high_speed));
1.1    bouyer
1.1    bouyer 			/* turn off interrupts */
1.1    bouyer 			val = MUSB2_MASK_IRESET;
1.1    bouyer 			val &= ~MUSB2_MASK_IRESUME;
1.1    bouyer 			val |= MUSB2_MASK_ISUSP;
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_INTUSBE, val);
1.1    bouyer 			UWRITE2(sc, MUSB2_REG_INTTXE, 0);
1.1    bouyer 			UWRITE2(sc, MUSB2_REG_INTRXE, 0);
1.1    bouyer 		}
1.1    bouyer 		if (ctrl_status & MUSB2_MASK_IRESUME) {
1.1    bouyer 			if (sc->sc_port_suspended) {
1.1    bouyer 				sc->sc_port_suspended = 0;
1.1    bouyer 				sc->sc_port_suspended_change = 1;
1.1    bouyer 				val = UREAD1(sc, MUSB2_REG_INTUSBE);
1.1    bouyer 				/* disable resume interrupt */
1.1    bouyer 				val &= ~MUSB2_MASK_IRESUME;
1.1    bouyer 				/* enable suspend interrupt */
1.1    bouyer 				val |= MUSB2_MASK_ISUSP;
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_INTUSBE, val);
1.1    bouyer 			}
1.1    bouyer 		} else if (ctrl_status & MUSB2_MASK_ISUSP) {
1.1    bouyer 			if (!sc->sc_port_suspended) {
1.1    bouyer 				sc->sc_port_suspended = 1;
1.1    bouyer 				sc->sc_port_suspended_change = 1;
1.1    bouyer
1.1    bouyer 				val = UREAD1(sc, MUSB2_REG_INTUSBE);
1.1    bouyer 				/* disable suspend interrupt */
1.1    bouyer 				val &= ~MUSB2_MASK_ISUSP;
1.1    bouyer 				/* enable resume interrupt */
1.1    bouyer 				val |= MUSB2_MASK_IRESUME;
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_INTUSBE, val);
1.1    bouyer 			}
1.1    bouyer 		}
1.1    bouyer 		if (ctrl_status & MUSB2_MASK_ICONN) {
1.1    bouyer 			sc->sc_connected = 1;
1.1    bouyer 			sc->sc_connected_changed = 1;
1.1    bouyer 			sc->sc_isreset = 1;
1.1    bouyer 			sc->sc_port_enabled = 1;
1.1    bouyer 		} else if (ctrl_status & MUSB2_MASK_IDISC) {
1.1    bouyer 			sc->sc_connected = 0;
1.1    bouyer 			sc->sc_connected_changed = 1;
1.1    bouyer 			sc->sc_isreset = 0;
1.1    bouyer 			sc->sc_port_enabled = 0;
1.1    bouyer 		}
1.1    bouyer
1.1    bouyer 		/* complete root HUB interrupt endpoint */
1.1    bouyer
1.1    bouyer 		motg_hub_change(sc);
1.1    bouyer 	}
1.1    bouyer 	/*
1.1    bouyer 	 * read in interrupt status and mix with the status we
1.1    bouyer 	 * got from the wrapper
1.1    bouyer 	 */
1.1    bouyer 	rx_status |= UREAD2(sc, MUSB2_REG_INTRX);
1.1    bouyer 	tx_status |= UREAD2(sc, MUSB2_REG_INTTX);
1.1    bouyer
1.1    bouyer 	if (rx_status & 0x01)
1.1    bouyer 		panic("ctrl_rx");
1.1    bouyer 	if (tx_status & 0x01)
1.1    bouyer 		motg_device_ctrl_intr_tx(sc);
1.1    bouyer 	for (i = 1; i <= sc->sc_ep_max; i++) {
1.1    bouyer 		if (rx_status & (0x01 << i))
1.1    bouyer 			motg_device_intr_rx(sc, i);
1.1    bouyer 		if (tx_status & (0x01 << i))
1.1    bouyer 			motg_device_intr_tx(sc, i);
1.1    bouyer 	}
1.1    bouyer 	return;
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_poll(struct usbd_bus *bus)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = bus->hci_private;
1.1    bouyer
1.1    bouyer 	sc->sc_intr_poll(sc->sc_intr_poll_arg);
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.1    bouyer 	motg_softintr(bus);
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer }
1.1    bouyer
1.1    bouyer int
1.1    bouyer motg_intr(struct motg_softc *sc, uint16_t rx_ep, uint16_t tx_ep,
1.2    bouyer     uint8_t ctrl)
1.1    bouyer {
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_intr_lock));
1.1    bouyer 	sc->sc_intr_tx_ep = tx_ep;
1.1    bouyer 	sc->sc_intr_rx_ep = rx_ep;
1.1    bouyer 	sc->sc_intr_ctrl = ctrl;
1.1    bouyer
1.1    bouyer 	if (!sc->sc_bus.use_polling) {
1.1    bouyer 		sc->sc_bus.no_intrs++;
1.1    bouyer 		usb_schedsoftintr(&sc->sc_bus);
1.1    bouyer 	}
1.1    bouyer 	return 1;
1.1    bouyer }
1.1    bouyer
1.2    bouyer int
1.2    bouyer motg_intr_vbus(struct motg_softc *sc, int vbus)
1.2    bouyer {
1.2    bouyer 	uint8_t val;
1.2    bouyer 	if (sc->sc_mode == MOTG_MODE_HOST && vbus == 0) {
1.2    bouyer 		DPRINTF(("motg_intr_vbus: vbus down, try to re-enable\n"));
1.2    bouyer 		/* try to re-enter session for Host mode */
1.2    bouyer 		val = UREAD1(sc, MUSB2_REG_DEVCTL);
1.2    bouyer 		val |= MUSB2_MASK_SESS;
1.2    bouyer 		UWRITE1(sc, MUSB2_REG_DEVCTL, val);
1.2    bouyer 	}
1.2    bouyer 	return 1;
1.2    bouyer }
1.2    bouyer
1.1    bouyer usbd_status
1.1    bouyer motg_allocm(struct usbd_bus *bus, usb_dma_t *dma, u_int32_t size)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = bus->hci_private;
1.1    bouyer 	usbd_status status;
1.1    bouyer
1.1    bouyer 	status = usb_allocmem(&sc->sc_bus, size, 0, dma);
1.1    bouyer 	if (status == USBD_NOMEM)
1.1    bouyer 		status = usb_reserve_allocm(&sc->sc_dma_reserve, dma, size);
1.1    bouyer 	return status;
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_freem(struct usbd_bus *bus, usb_dma_t *dma)
1.1    bouyer {
1.1    bouyer 	if (dma->block->flags & USB_DMA_RESERVE) {
1.1    bouyer 		usb_reserve_freem(&((struct motg_softc *)bus)->sc_dma_reserve,
1.1    bouyer 		    dma);
1.1    bouyer 		return;
1.1    bouyer 	}
1.1    bouyer 	usb_freemem(&((struct motg_softc *)bus)->sc_bus, dma);
1.1    bouyer }
1.1    bouyer
1.1    bouyer usbd_xfer_handle
1.1    bouyer motg_allocx(struct usbd_bus *bus)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = bus->hci_private;
1.1    bouyer 	usbd_xfer_handle xfer;
1.1    bouyer
1.1    bouyer 	xfer = pool_cache_get(sc->sc_xferpool, PR_NOWAIT);
1.1    bouyer 	if (xfer != NULL) {
1.1    bouyer 		memset(xfer, 0, sizeof(struct motg_xfer));
1.1    bouyer 		UXFER(xfer)->sc = sc;
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 		// XXX UXFER(xfer)->iinfo.isdone = 1;
1.1    bouyer 		xfer->busy_free = XFER_BUSY;
1.1    bouyer #endif
1.1    bouyer 	}
1.1    bouyer 	return (xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_freex(struct usbd_bus *bus, usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = bus->hci_private;
1.1    bouyer
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (xfer->busy_free != XFER_BUSY) {
1.1    bouyer 		printf("motg_freex: xfer=%p not busy, 0x%08x\n", xfer,
1.1    bouyer 		       xfer->busy_free);
1.1    bouyer 	}
1.1    bouyer 	xfer->busy_free = XFER_FREE;
1.1    bouyer #endif
1.1    bouyer 	pool_cache_put(sc->sc_xferpool, xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_get_lock(struct usbd_bus *bus, kmutex_t **lock)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = bus->hci_private;
1.1    bouyer
1.1    bouyer 	*lock = &sc->sc_lock;
1.1    bouyer }
1.1    bouyer
1.1    bouyer /*
1.1    bouyer  * Data structures and routines to emulate the root hub.
1.1    bouyer  */
1.1    bouyer usb_device_descriptor_t motg_devd = {
1.1    bouyer 	USB_DEVICE_DESCRIPTOR_SIZE,
1.1    bouyer 	UDESC_DEVICE,		/* type */
1.1    bouyer 	{0x00, 0x01},		/* USB version */
1.1    bouyer 	UDCLASS_HUB,		/* class */
1.1    bouyer 	UDSUBCLASS_HUB,		/* subclass */
1.1    bouyer 	UDPROTO_FSHUB,		/* protocol */
1.1    bouyer 	64,			/* max packet */
1.1    bouyer 	{0},{0},{0x00,0x01},	/* device id */
1.1    bouyer 	1,2,0,			/* string indicies */
1.1    bouyer 	1			/* # of configurations */
1.1    bouyer };
1.1    bouyer
1.1    bouyer const usb_config_descriptor_t motg_confd = {
1.1    bouyer 	USB_CONFIG_DESCRIPTOR_SIZE,
1.1    bouyer 	UDESC_CONFIG,
1.1    bouyer 	{USB_CONFIG_DESCRIPTOR_SIZE +
1.1    bouyer 	 USB_INTERFACE_DESCRIPTOR_SIZE +
1.1    bouyer 	 USB_ENDPOINT_DESCRIPTOR_SIZE},
1.1    bouyer 	1,
1.1    bouyer 	1,
1.1    bouyer 	0,
1.1    bouyer 	UC_ATTR_MBO | UC_SELF_POWERED,
1.1    bouyer 	0			/* max power */
1.1    bouyer };
1.1    bouyer
1.1    bouyer const usb_interface_descriptor_t motg_ifcd = {
1.1    bouyer 	USB_INTERFACE_DESCRIPTOR_SIZE,
1.1    bouyer 	UDESC_INTERFACE,
1.1    bouyer 	0,
1.1    bouyer 	0,
1.1    bouyer 	1,
1.1    bouyer 	UICLASS_HUB,
1.1    bouyer 	UISUBCLASS_HUB,
1.1    bouyer 	UIPROTO_FSHUB,
1.1    bouyer 	0
1.1    bouyer };
1.1    bouyer
1.1    bouyer const usb_endpoint_descriptor_t motg_endpd = {
1.1    bouyer 	USB_ENDPOINT_DESCRIPTOR_SIZE,
1.1    bouyer 	UDESC_ENDPOINT,
1.1    bouyer 	UE_DIR_IN | MOTG_INTR_ENDPT,
1.1    bouyer 	UE_INTERRUPT,
1.1    bouyer 	{8},
1.1    bouyer 	255
1.1    bouyer };
1.1    bouyer
1.1    bouyer const usb_hub_descriptor_t motg_hubd = {
1.1    bouyer 	USB_HUB_DESCRIPTOR_SIZE,
1.1    bouyer 	UDESC_HUB,
1.1    bouyer 	1,
1.1    bouyer 	{ UHD_PWR_NO_SWITCH | UHD_OC_INDIVIDUAL, 0 },
1.1    bouyer 	50,			/* power on to power good */
1.1    bouyer 	0,
1.1    bouyer 	{ 0x00 },		/* port is removable */
1.1    bouyer 	{ 0 },
1.1    bouyer };
1.1    bouyer
1.1    bouyer /*
1.1    bouyer  * Simulate a hardware hub by handling all the necessary requests.
1.1    bouyer  */
1.1    bouyer usbd_status
1.1    bouyer motg_root_ctrl_transfer(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	usbd_status err;
1.1    bouyer
1.1    bouyer 	/* Insert last in queue. */
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.1    bouyer 	err = usb_insert_transfer(xfer);
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer 	if (err)
1.1    bouyer 		return (err);
1.1    bouyer
1.1    bouyer 	/*
1.1    bouyer 	 * Pipe isn't running (otherwise err would be USBD_INPROG),
1.1    bouyer 	 * so start it first.
1.1    bouyer 	 */
1.1    bouyer 	return (motg_root_ctrl_start(SIMPLEQ_FIRST(&xfer->pipe->queue)));
1.1    bouyer }
1.1    bouyer
1.1    bouyer usbd_status
1.1    bouyer motg_root_ctrl_start(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	usb_device_request_t *req;
1.1    bouyer 	void *buf = NULL;
1.1    bouyer 	int len, value, index, status, change, l, totlen = 0;
1.1    bouyer 	usb_port_status_t ps;
1.1    bouyer 	usbd_status err;
1.1    bouyer 	uint32_t val;
1.1    bouyer
1.1    bouyer 	if (sc->sc_dying)
1.1    bouyer 		return (USBD_IOERROR);
1.1    bouyer
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (!(xfer->rqflags & URQ_REQUEST))
1.1    bouyer 		panic("motg_root_ctrl_start: not a request");
1.1    bouyer #endif
1.1    bouyer 	req = &xfer->request;
1.1    bouyer
1.1    bouyer 	DPRINTFN(MD_ROOT,("motg_root_ctrl_control type=0x%02x request=%02x\n",
1.1    bouyer 		    req->bmRequestType, req->bRequest));
1.1    bouyer
1.1    bouyer 	len = UGETW(req->wLength);
1.1    bouyer 	value = UGETW(req->wValue);
1.1    bouyer 	index = UGETW(req->wIndex);
1.1    bouyer
1.1    bouyer 	if (len != 0)
1.1    bouyer 		buf = KERNADDR(&xfer->dmabuf, 0);
1.1    bouyer
1.1    bouyer #define C(x,y) ((x) | ((y) << 8))
1.1    bouyer 	switch(C(req->bRequest, req->bmRequestType)) {
1.1    bouyer 	case C(UR_CLEAR_FEATURE, UT_WRITE_DEVICE):
1.1    bouyer 	case C(UR_CLEAR_FEATURE, UT_WRITE_INTERFACE):
1.1    bouyer 	case C(UR_CLEAR_FEATURE, UT_WRITE_ENDPOINT):
1.1    bouyer 		/*
1.1    bouyer 		 * DEVICE_REMOTE_WAKEUP and ENDPOINT_HALT are no-ops
1.1    bouyer 		 * for the integrated root hub.
1.1    bouyer 		 */
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_CONFIG, UT_READ_DEVICE):
1.1    bouyer 		if (len > 0) {
1.1    bouyer 			*(u_int8_t *)buf = sc->sc_root_conf;
1.1    bouyer 			totlen = 1;
1.1    bouyer 		}
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_DESCRIPTOR, UT_READ_DEVICE):
1.1    bouyer 		DPRINTFN(MD_ROOT,("motg_root_ctrl_control wValue=0x%04x\n", value));
1.1    bouyer 		if (len == 0)
1.1    bouyer 			break;
1.1    bouyer 		switch(value >> 8) {
1.1    bouyer 		case UDESC_DEVICE:
1.1    bouyer 			if ((value & 0xff) != 0) {
1.1    bouyer 				err = USBD_IOERROR;
1.1    bouyer 				goto ret;
1.1    bouyer 			}
1.1    bouyer 			totlen = l = min(len, USB_DEVICE_DESCRIPTOR_SIZE);
1.1    bouyer 			USETW(motg_devd.idVendor, sc->sc_id_vendor);
1.1    bouyer 			memcpy(buf, &motg_devd, l);
1.1    bouyer 			break;
1.1    bouyer 		case UDESC_CONFIG:
1.1    bouyer 			if ((value & 0xff) != 0) {
1.1    bouyer 				err = USBD_IOERROR;
1.1    bouyer 				goto ret;
1.1    bouyer 			}
1.1    bouyer 			totlen = l = min(len, USB_CONFIG_DESCRIPTOR_SIZE);
1.1    bouyer 			memcpy(buf, &motg_confd, l);
1.1    bouyer 			buf = (char *)buf + l;
1.1    bouyer 			len -= l;
1.1    bouyer 			l = min(len, USB_INTERFACE_DESCRIPTOR_SIZE);
1.1    bouyer 			totlen += l;
1.1    bouyer 			memcpy(buf, &motg_ifcd, l);
1.1    bouyer 			buf = (char *)buf + l;
1.1    bouyer 			len -= l;
1.1    bouyer 			l = min(len, USB_ENDPOINT_DESCRIPTOR_SIZE);
1.1    bouyer 			totlen += l;
1.1    bouyer 			memcpy(buf, &motg_endpd, l);
1.1    bouyer 			break;
1.1    bouyer 		case UDESC_STRING:
1.1    bouyer #define sd ((usb_string_descriptor_t *)buf)
1.1    bouyer 			switch (value & 0xff) {
1.1    bouyer 			case 0: /* Language table */
1.1    bouyer 				totlen = usb_makelangtbl(sd, len);
1.1    bouyer 				break;
1.1    bouyer 			case 1: /* Vendor */
1.1    bouyer 				totlen = usb_makestrdesc(sd, len,
1.1    bouyer 							 sc->sc_vendor);
1.1    bouyer 				break;
1.1    bouyer 			case 2: /* Product */
1.1    bouyer 				totlen = usb_makestrdesc(sd, len,
1.1    bouyer 							 "MOTG root hub");
1.1    bouyer 				break;
1.1    bouyer 			}
1.1    bouyer #undef sd
1.1    bouyer 			break;
1.1    bouyer 		default:
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_INTERFACE, UT_READ_INTERFACE):
1.1    bouyer 		if (len > 0) {
1.1    bouyer 			*(u_int8_t *)buf = 0;
1.1    bouyer 			totlen = 1;
1.1    bouyer 		}
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_STATUS, UT_READ_DEVICE):
1.1    bouyer 		if (len > 1) {
1.1    bouyer 			USETW(((usb_status_t *)buf)->wStatus,UDS_SELF_POWERED);
1.1    bouyer 			totlen = 2;
1.1    bouyer 		}
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_STATUS, UT_READ_INTERFACE):
1.1    bouyer 	case C(UR_GET_STATUS, UT_READ_ENDPOINT):
1.1    bouyer 		if (len > 1) {
1.1    bouyer 			USETW(((usb_status_t *)buf)->wStatus, 0);
1.1    bouyer 			totlen = 2;
1.1    bouyer 		}
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_SET_ADDRESS, UT_WRITE_DEVICE):
1.1    bouyer 		if (value >= USB_MAX_DEVICES) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		sc->sc_root_addr = value;
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_SET_CONFIG, UT_WRITE_DEVICE):
1.1    bouyer 		if (value != 0 && value != 1) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		sc->sc_root_conf = value;
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_SET_DESCRIPTOR, UT_WRITE_DEVICE):
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_SET_FEATURE, UT_WRITE_DEVICE):
1.1    bouyer 	case C(UR_SET_FEATURE, UT_WRITE_INTERFACE):
1.1    bouyer 	case C(UR_SET_FEATURE, UT_WRITE_ENDPOINT):
1.1    bouyer 		err = USBD_IOERROR;
1.1    bouyer 		goto ret;
1.1    bouyer 	case C(UR_SET_INTERFACE, UT_WRITE_INTERFACE):
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_SYNCH_FRAME, UT_WRITE_ENDPOINT):
1.1    bouyer 		break;
1.1    bouyer 	/* Hub requests */
1.1    bouyer 	case C(UR_CLEAR_FEATURE, UT_WRITE_CLASS_DEVICE):
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_CLEAR_FEATURE, UT_WRITE_CLASS_OTHER):
1.1    bouyer 		DPRINTFN(MD_ROOT,
1.1    bouyer 		    ("motg_root_ctrl_control: UR_CLEAR_PORT_FEATURE "
1.1    bouyer 			     "port=%d feature=%d\n",
1.1    bouyer 			     index, value));
1.1    bouyer 		if (index != 1) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		switch(value) {
1.1    bouyer 		case UHF_PORT_ENABLE:
1.1    bouyer 			sc->sc_port_enabled = 0;
1.1    bouyer 			break;
1.1    bouyer 		case UHF_PORT_SUSPEND:
1.1    bouyer 			if (sc->sc_port_suspended != 0) {
1.1    bouyer 				val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer 				val &= ~MUSB2_MASK_SUSPMODE;
1.1    bouyer 				val |= MUSB2_MASK_RESUME;
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_POWER, val);
1.1    bouyer 				/* wait 20 milliseconds */
1.1    bouyer 				usb_delay_ms(&sc->sc_bus, 20);
1.1    bouyer 				val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer 				val &= ~MUSB2_MASK_RESUME;
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_POWER, val);
1.1    bouyer 				sc->sc_port_suspended = 0;
1.1    bouyer 				sc->sc_port_suspended_change = 1;
1.1    bouyer 			}
1.1    bouyer 			break;
1.1    bouyer 		case UHF_PORT_RESET:
1.1    bouyer 			break;
1.1    bouyer 		case UHF_C_PORT_CONNECTION:
1.1    bouyer 			break;
1.1    bouyer 		case UHF_C_PORT_ENABLE:
1.1    bouyer 			break;
1.1    bouyer 		case UHF_C_PORT_OVER_CURRENT:
1.1    bouyer 			break;
1.1    bouyer 		case UHF_C_PORT_RESET:
1.1    bouyer 			sc->sc_isreset = 0;
1.1    bouyer 			err = USBD_NORMAL_COMPLETION;
1.1    bouyer 			goto ret;
1.1    bouyer 		case UHF_PORT_POWER:
1.1    bouyer 			/* XXX todo */
1.1    bouyer 			break;
1.1    bouyer 		case UHF_PORT_CONNECTION:
1.1    bouyer 		case UHF_PORT_OVER_CURRENT:
1.1    bouyer 		case UHF_PORT_LOW_SPEED:
1.1    bouyer 		case UHF_C_PORT_SUSPEND:
1.1    bouyer 		default:
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_BUS_STATE, UT_READ_CLASS_OTHER):
1.1    bouyer 		err = USBD_IOERROR;
1.1    bouyer 		goto ret;
1.1    bouyer 	case C(UR_GET_DESCRIPTOR, UT_READ_CLASS_DEVICE):
1.1    bouyer 		if (len == 0)
1.1    bouyer 			break;
1.1    bouyer 		if ((value & 0xff) != 0) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		l = min(len, USB_HUB_DESCRIPTOR_SIZE);
1.1    bouyer 		totlen = l;
1.1    bouyer 		memcpy(buf, &motg_hubd, l);
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_STATUS, UT_READ_CLASS_DEVICE):
1.1    bouyer 		if (len != 4) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		memset(buf, 0, len);
1.1    bouyer 		totlen = len;
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_GET_STATUS, UT_READ_CLASS_OTHER):
1.1    bouyer 		if (index != 1) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		if (len != 4) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		status = change = 0;
1.1    bouyer 		if (sc->sc_connected)
1.1    bouyer 			status |= UPS_CURRENT_CONNECT_STATUS;
1.1    bouyer 		if (sc->sc_connected_changed) {
1.1    bouyer 			change |= UPS_C_CONNECT_STATUS;
1.1    bouyer 			sc->sc_connected_changed = 0;
1.1    bouyer 		}
1.1    bouyer 		if (sc->sc_port_enabled)
1.1    bouyer 			status |= UPS_PORT_ENABLED;
1.1    bouyer 		if (sc->sc_port_enabled_changed) {
1.1    bouyer 			change |= UPS_C_PORT_ENABLED;
1.1    bouyer 			sc->sc_port_enabled_changed = 0;
1.1    bouyer 		}
1.1    bouyer 		if (sc->sc_port_suspended)
1.1    bouyer 			status |= UPS_SUSPEND;
1.1    bouyer 		if (sc->sc_high_speed)
1.1    bouyer 			status |= UPS_HIGH_SPEED;
1.1    bouyer 		status |= UPS_PORT_POWER; /* XXX */
1.1    bouyer 		if (sc->sc_isreset)
1.1    bouyer 			change |= UPS_C_PORT_RESET;
1.1    bouyer 		USETW(ps.wPortStatus, status);
1.1    bouyer 		USETW(ps.wPortChange, change);
1.1    bouyer 		l = min(len, sizeof ps);
1.1    bouyer 		memcpy(buf, &ps, l);
1.1    bouyer 		totlen = l;
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_SET_DESCRIPTOR, UT_WRITE_CLASS_DEVICE):
1.1    bouyer 		err = USBD_IOERROR;
1.1    bouyer 		goto ret;
1.1    bouyer 	case C(UR_SET_FEATURE, UT_WRITE_CLASS_DEVICE):
1.1    bouyer 		break;
1.1    bouyer 	case C(UR_SET_FEATURE, UT_WRITE_CLASS_OTHER):
1.1    bouyer 		if (index != 1) {
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		switch(value) {
1.1    bouyer 		case UHF_PORT_ENABLE:
1.1    bouyer 			sc->sc_port_enabled = 1;
1.1    bouyer 			break;
1.1    bouyer 		case UHF_PORT_SUSPEND:
1.1    bouyer 			if (sc->sc_port_suspended == 0) {
1.1    bouyer 				val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer 				val |= MUSB2_MASK_SUSPMODE;
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_POWER, val);
1.1    bouyer 				/* wait 20 milliseconds */
1.1    bouyer 				usb_delay_ms(&sc->sc_bus, 20);
1.1    bouyer 				sc->sc_port_suspended = 1;
1.1    bouyer 				sc->sc_port_suspended_change = 1;
1.1    bouyer 			}
1.1    bouyer 			break;
1.1    bouyer 		case UHF_PORT_RESET:
1.1    bouyer 			err = motg_portreset(sc);
1.1    bouyer 			goto ret;
1.1    bouyer 		case UHF_PORT_POWER:
1.1    bouyer 			/* XXX todo */
1.1    bouyer 			err = USBD_NORMAL_COMPLETION;
1.1    bouyer 			goto ret;
1.1    bouyer 		case UHF_C_PORT_CONNECTION:
1.1    bouyer 		case UHF_C_PORT_ENABLE:
1.1    bouyer 		case UHF_C_PORT_OVER_CURRENT:
1.1    bouyer 		case UHF_PORT_CONNECTION:
1.1    bouyer 		case UHF_PORT_OVER_CURRENT:
1.1    bouyer 		case UHF_PORT_LOW_SPEED:
1.1    bouyer 		case UHF_C_PORT_SUSPEND:
1.1    bouyer 		case UHF_C_PORT_RESET:
1.1    bouyer 		default:
1.1    bouyer 			err = USBD_IOERROR;
1.1    bouyer 			goto ret;
1.1    bouyer 		}
1.1    bouyer 		break;
1.1    bouyer 	default:
1.1    bouyer 		err = USBD_IOERROR;
1.1    bouyer 		goto ret;
1.1    bouyer 	}
1.1    bouyer 	xfer->actlen = totlen;
1.1    bouyer 	err = USBD_NORMAL_COMPLETION;
1.1    bouyer  ret:
1.1    bouyer 	xfer->status = err;
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.1    bouyer 	usb_transfer_complete(xfer);
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer 	return (USBD_IN_PROGRESS);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Abort a root control request. */
1.1    bouyer void
1.1    bouyer motg_root_ctrl_abort(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	/* Nothing to do, all transfers are synchronous. */
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Close the root pipe. */
1.1    bouyer void
1.1    bouyer motg_root_ctrl_close(usbd_pipe_handle pipe)
1.1    bouyer {
1.1    bouyer 	DPRINTFN(MD_ROOT, ("motg_root_ctrl_close\n"));
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_root_ctrl_done(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Abort a root interrupt request. */
1.1    bouyer void
1.1    bouyer motg_root_intr_abort(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.5     skrll 	KASSERT(xfer->pipe->intrxfer == xfer);
1.1    bouyer
1.1    bouyer 	sc->sc_intr_xfer = NULL;
1.1    bouyer
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	// XXX UXFER(xfer)->iinfo.isdone = 1;
1.1    bouyer #endif
1.5     skrll 	xfer->status = USBD_CANCELLED;
1.1    bouyer 	usb_transfer_complete(xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer usbd_status
1.1    bouyer motg_root_intr_transfer(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	usbd_status err;
1.1    bouyer
1.1    bouyer 	/* Insert last in queue. */
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.1    bouyer 	err = usb_insert_transfer(xfer);
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer 	if (err)
1.1    bouyer 		return (err);
1.1    bouyer
1.1    bouyer 	/*
1.1    bouyer 	 * Pipe isn't running (otherwise err would be USBD_INPROG),
1.1    bouyer 	 * start first
1.1    bouyer 	 */
1.1    bouyer 	return (motg_root_intr_start(SIMPLEQ_FIRST(&xfer->pipe->queue)));
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Start a transfer on the root interrupt pipe */
1.1    bouyer usbd_status
1.1    bouyer motg_root_intr_start(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	usbd_pipe_handle pipe = xfer->pipe;
1.1    bouyer 	struct motg_softc *sc = pipe->device->bus->hci_private;
1.1    bouyer
1.1    bouyer 	DPRINTFN(MD_ROOT, ("motg_root_intr_start: xfer=%p len=%d flags=%d\n",
1.1    bouyer 		     xfer, xfer->length, xfer->flags));
1.1    bouyer
1.1    bouyer 	if (sc->sc_dying)
1.1    bouyer 		return (USBD_IOERROR);
1.1    bouyer
1.1    bouyer 	sc->sc_intr_xfer = xfer;
1.1    bouyer 	return (USBD_IN_PROGRESS);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Close the root interrupt pipe. */
1.1    bouyer void
1.1    bouyer motg_root_intr_close(usbd_pipe_handle pipe)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = pipe->device->bus->hci_private;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer
1.1    bouyer 	sc->sc_intr_xfer = NULL;
1.1    bouyer 	DPRINTFN(MD_ROOT, ("motg_root_intr_close\n"));
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_root_intr_done(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_noop(usbd_pipe_handle pipe)
1.1    bouyer {
1.1    bouyer }
1.1    bouyer
1.1    bouyer static usbd_status
1.1    bouyer motg_portreset(struct motg_softc *sc)
1.1    bouyer {
1.1    bouyer 	uint32_t val;
1.1    bouyer
1.1    bouyer 	val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer 	val |= MUSB2_MASK_RESET;
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_POWER, val);
1.1    bouyer 	/* Wait for 20 msec */
1.1    bouyer 	usb_delay_ms(&sc->sc_bus, 20);
1.1    bouyer
1.1    bouyer 	val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer 	val &= ~MUSB2_MASK_RESET;
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_POWER, val);
1.1    bouyer
1.1    bouyer 	/* determine line speed */
1.1    bouyer 	val = UREAD1(sc, MUSB2_REG_POWER);
1.1    bouyer 	if (val & MUSB2_MASK_HSMODE)
1.1    bouyer 		sc->sc_high_speed = 1;
1.1    bouyer 	else
1.1    bouyer 		sc->sc_high_speed = 0;
1.1    bouyer 	DPRINTFN(MD_ROOT | MD_CTRL, ("motg_portreset speed %d\n",
1.1    bouyer 	    sc->sc_high_speed));
1.1    bouyer
1.1    bouyer 	sc->sc_isreset = 1;
1.1    bouyer 	sc->sc_port_enabled = 1;
1.1    bouyer 	return (USBD_NORMAL_COMPLETION);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /*
1.1    bouyer  * This routine is executed when an interrupt on the root hub is detected
1.1    bouyer  */
1.1    bouyer static void
1.1    bouyer motg_hub_change(struct motg_softc *sc)
1.1    bouyer {
1.1    bouyer 	usbd_xfer_handle xfer = sc->sc_intr_xfer;
1.1    bouyer 	usbd_pipe_handle pipe;
1.1    bouyer 	u_char *p;
1.1    bouyer
1.1    bouyer 	DPRINTFN(MD_ROOT, ("motg_hub_change\n"));
1.1    bouyer
1.1    bouyer 	if (xfer == NULL)
1.1    bouyer 		return; /* the interrupt pipe is not open */
1.1    bouyer
1.1    bouyer 	pipe = xfer->pipe;
1.1    bouyer 	if (pipe->device == NULL || pipe->device->bus == NULL)
1.1    bouyer 		return;	/* device has detached */
1.1    bouyer
1.1    bouyer 	p = KERNADDR(&xfer->dmabuf, 0);
1.1    bouyer 	p[0] = 1<<1;
1.1    bouyer 	xfer->actlen = 1;
1.1    bouyer 	xfer->status = USBD_NORMAL_COMPLETION;
1.1    bouyer 	usb_transfer_complete(xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static uint8_t
1.1    bouyer motg_speed(u_int8_t speed)
1.1    bouyer {
1.1    bouyer 	switch(speed) {
1.1    bouyer 	case USB_SPEED_LOW:
1.1    bouyer 		return MUSB2_MASK_TI_SPEED_LO;
1.1    bouyer 	case USB_SPEED_FULL:
1.1    bouyer 		return MUSB2_MASK_TI_SPEED_FS;
1.1    bouyer 	case USB_SPEED_HIGH:
1.1    bouyer 		return MUSB2_MASK_TI_SPEED_HS;
1.1    bouyer 	default:
1.1    bouyer 		panic("motg: unknown speed %d", speed);
1.1    bouyer 		/* NOTREACHED */
1.1    bouyer 	}
1.1    bouyer }
1.1    bouyer
1.1    bouyer static uint8_t
1.1    bouyer motg_type(u_int8_t type)
1.1    bouyer {
1.1    bouyer 	switch(type) {
1.1    bouyer 	case UE_CONTROL:
1.1    bouyer 		return MUSB2_MASK_TI_PROTO_CTRL;
1.1    bouyer 	case UE_ISOCHRONOUS:
1.1    bouyer 		return MUSB2_MASK_TI_PROTO_ISOC;
1.1    bouyer 	case UE_BULK:
1.1    bouyer 		return MUSB2_MASK_TI_PROTO_BULK;
1.1    bouyer 	case UE_INTERRUPT:
1.1    bouyer 		return MUSB2_MASK_TI_PROTO_INTR;
1.1    bouyer 	default:
1.1    bouyer 		panic("motg: unknown type %d", type);
1.1    bouyer 		/* NOTREACHED */
1.1    bouyer 	}
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_setup_endpoint_tx(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	usbd_device_handle dev = otgpipe->pipe.device;
1.1    bouyer 	int epnumber = otgpipe->hw_ep->ep_number;
1.1    bouyer
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXFADDR(epnumber), dev->address);
1.1    bouyer 	if (dev->myhsport) {
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXHADDR(epnumber),
1.1    bouyer 		    dev->myhsport->parent->address);
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXHUBPORT(epnumber),
1.1    bouyer 		    dev->myhsport->portno);
1.1    bouyer 	} else {
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXHADDR(epnumber), 0);
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXHUBPORT(epnumber), 0);
1.1    bouyer 	}
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXTI,
1.1    bouyer 	    motg_speed(dev->speed) |
1.1    bouyer 	    UE_GET_ADDR(xfer->pipe->endpoint->edesc->bEndpointAddress) |
1.1    bouyer 	    motg_type(UE_GET_XFERTYPE(xfer->pipe->endpoint->edesc->bmAttributes))
1.1    bouyer 	    );
1.1    bouyer 	if (epnumber == 0) {
1.1    bouyer 		if (sc->sc_high_speed) {
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXNAKLIMIT,
1.1    bouyer 			    NAK_TO_CTRL_HIGH);
1.1    bouyer 		} else {
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, NAK_TO_CTRL);
1.1    bouyer 		}
1.1    bouyer 	} else {
1.1    bouyer 		if ((xfer->pipe->endpoint->edesc->bmAttributes & UE_XFERTYPE)
1.1    bouyer 		    == UE_BULK) {
1.1    bouyer 			if (sc->sc_high_speed) {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_TXNAKLIMIT,
1.1    bouyer 				    NAK_TO_BULK_HIGH);
1.1    bouyer 			} else {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, NAK_TO_BULK);
1.1    bouyer 			}
1.1    bouyer 		} else {
1.1    bouyer 			if (sc->sc_high_speed) {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, POLL_TO_HIGH);
1.1    bouyer 			} else {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, POLL_TO);
1.1    bouyer 			}
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_setup_endpoint_rx(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	usbd_device_handle dev = xfer->pipe->device;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	int epnumber = otgpipe->hw_ep->ep_number;
1.1    bouyer
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_RXFADDR(epnumber), dev->address);
1.1    bouyer 	if (dev->myhsport) {
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXHADDR(epnumber),
1.1    bouyer 		    dev->myhsport->parent->address);
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXHUBPORT(epnumber),
1.1    bouyer 		    dev->myhsport->portno);
1.1    bouyer 	} else {
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXHADDR(epnumber), 0);
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXHUBPORT(epnumber), 0);
1.1    bouyer 	}
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_RXTI,
1.1    bouyer 	    motg_speed(dev->speed) |
1.1    bouyer 	    UE_GET_ADDR(xfer->pipe->endpoint->edesc->bEndpointAddress) |
1.1    bouyer 	    motg_type(UE_GET_XFERTYPE(xfer->pipe->endpoint->edesc->bmAttributes))
1.1    bouyer 	    );
1.1    bouyer 	if (epnumber == 0) {
1.1    bouyer 		if (sc->sc_high_speed) {
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXNAKLIMIT,
1.1    bouyer 			    NAK_TO_CTRL_HIGH);
1.1    bouyer 		} else {
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, NAK_TO_CTRL);
1.1    bouyer 		}
1.1    bouyer 	} else {
1.1    bouyer 		if ((xfer->pipe->endpoint->edesc->bmAttributes & UE_XFERTYPE)
1.1    bouyer 		    == UE_BULK) {
1.1    bouyer 			if (sc->sc_high_speed) {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_RXNAKLIMIT,
1.1    bouyer 				    NAK_TO_BULK_HIGH);
1.1    bouyer 			} else {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_RXNAKLIMIT, NAK_TO_BULK);
1.1    bouyer 			}
1.1    bouyer 		} else {
1.1    bouyer 			if (sc->sc_high_speed) {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_RXNAKLIMIT, POLL_TO_HIGH);
1.1    bouyer 			} else {
1.1    bouyer 				UWRITE1(sc, MUSB2_REG_RXNAKLIMIT, POLL_TO);
1.1    bouyer 			}
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer }
1.1    bouyer
1.1    bouyer static usbd_status
1.1    bouyer motg_device_ctrl_transfer(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	usbd_status err;
1.1    bouyer
1.1    bouyer 	/* Insert last in queue. */
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.1    bouyer 	err = usb_insert_transfer(xfer);
1.3    bouyer 	xfer->status = USBD_NOT_STARTED;
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer 	if (err)
1.1    bouyer 		return (err);
1.1    bouyer
1.1    bouyer 	/*
1.1    bouyer 	 * Pipe isn't running (otherwise err would be USBD_INPROG),
1.1    bouyer 	 * so start it first.
1.1    bouyer 	 */
1.1    bouyer 	return (motg_device_ctrl_start(SIMPLEQ_FIRST(&xfer->pipe->queue)));
1.1    bouyer }
1.1    bouyer
1.1    bouyer static usbd_status
1.1    bouyer motg_device_ctrl_start(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	usbd_status err;
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.1    bouyer 	err = motg_device_ctrl_start1(sc);
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer 	if (err != USBD_IN_PROGRESS)
1.1    bouyer 		return err;
1.1    bouyer 	if (sc->sc_bus.use_polling)
1.1    bouyer 		motg_waitintr(sc, xfer);
1.1    bouyer 	return USBD_IN_PROGRESS;
1.1    bouyer }
1.1    bouyer
1.1    bouyer static usbd_status
1.1    bouyer motg_device_ctrl_start1(struct motg_softc *sc)
1.1    bouyer {
1.1    bouyer 	struct motg_hw_ep *ep = &sc->sc_in_ep[0];
1.3    bouyer 	usbd_xfer_handle xfer = NULL;
1.1    bouyer 	struct motg_pipe *otgpipe;
1.1    bouyer 	usbd_status err = 0;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	if (sc->sc_dying)
1.1    bouyer 		return (USBD_IOERROR);
1.1    bouyer
1.1    bouyer 	if (!sc->sc_connected)
1.1    bouyer 		return (USBD_IOERROR);
1.1    bouyer
1.1    bouyer 	if (ep->xfer != NULL) {
1.1    bouyer 		err = USBD_IN_PROGRESS;
1.1    bouyer 		goto end;
1.1    bouyer 	}
1.1    bouyer 	/* locate the first pipe with work to do */
1.1    bouyer 	SIMPLEQ_FOREACH(otgpipe, &ep->ep_pipes, ep_pipe_list) {
1.1    bouyer 		xfer = SIMPLEQ_FIRST(&otgpipe->pipe.queue);
1.3    bouyer 		DPRINTFN(MD_CTRL,
1.3    bouyer 		    ("motg_device_ctrl_start1 pipe %p xfer %p status %d\n",
1.3    bouyer 		    otgpipe, xfer, (xfer != NULL) ? xfer->status : 0));
1.7     skrll
1.1    bouyer 		if (xfer != NULL) {
1.1    bouyer 			/* move this pipe to the end of the list */
1.1    bouyer 			SIMPLEQ_REMOVE(&ep->ep_pipes, otgpipe,
1.1    bouyer 			    motg_pipe, ep_pipe_list);
1.1    bouyer 			SIMPLEQ_INSERT_TAIL(&ep->ep_pipes,
1.1    bouyer 			    otgpipe, ep_pipe_list);
1.1    bouyer 			break;
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	if (xfer == NULL) {
1.1    bouyer 		err = USBD_NOT_STARTED;
1.1    bouyer 		goto end;
1.1    bouyer 	}
1.3    bouyer 	xfer->status = USBD_IN_PROGRESS;
1.1    bouyer 	KASSERT(otgpipe == (struct motg_pipe *)xfer->pipe);
1.1    bouyer 	KASSERT(otgpipe->hw_ep == ep);
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (!(xfer->rqflags & URQ_REQUEST))
1.1    bouyer 		panic("motg_device_ctrl_transfer: not a request");
1.1    bouyer #endif
1.1    bouyer 	// KASSERT(xfer->actlen == 0);
1.1    bouyer 	xfer->actlen = 0;
1.1    bouyer
1.1    bouyer 	ep->xfer = xfer;
1.1    bouyer 	ep->datalen = xfer->length;
1.1    bouyer 	if (ep->datalen > 0)
1.1    bouyer 		ep->data = KERNADDR(&xfer->dmabuf, 0);
1.1    bouyer 	else
1.1    bouyer 		ep->data = NULL;
1.1    bouyer 	if ((xfer->flags & USBD_FORCE_SHORT_XFER) &&
1.1    bouyer 	    (ep->datalen % 64) == 0)
1.1    bouyer 		ep->need_short_xfer = 1;
1.1    bouyer 	else
1.1    bouyer 		ep->need_short_xfer = 0;
1.1    bouyer 	/* now we need send this request */
1.7     skrll 	DPRINTFN(MD_CTRL,
1.1    bouyer 	    ("motg_device_ctrl_start1(%p) send data %p len %d short %d speed %d to %d\n",
1.1    bouyer 	    xfer, ep->data, ep->datalen, ep->need_short_xfer, xfer->pipe->device->speed,
1.1    bouyer 	    xfer->pipe->device->address));
1.1    bouyer 	KASSERT(ep->phase == IDLE);
1.1    bouyer 	ep->phase = SETUP;
1.1    bouyer 	/* select endpoint 0 */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_EPINDEX, 0);
1.1    bouyer 	/* fifo should be empty at this point */
1.1    bouyer 	KASSERT((UREAD1(sc, MUSB2_REG_TXCSRL) & MUSB2_MASK_CSR0L_TXPKTRDY) == 0);
1.1    bouyer 	/* send data */
1.1    bouyer 	// KASSERT(((vaddr_t)(&xfer->request) & 3) == 0);
1.1    bouyer 	KASSERT(sizeof(xfer->request) == 8);
1.1    bouyer 	bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh, MUSB2_REG_EPFIFO(0),
1.1    bouyer 	    (void *)&xfer->request, sizeof(xfer->request));
1.1    bouyer
1.1    bouyer 	motg_setup_endpoint_tx(xfer);
1.1    bouyer 	/* start transaction */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXCSRL,
1.1    bouyer 	    MUSB2_MASK_CSR0L_TXPKTRDY | MUSB2_MASK_CSR0L_SETUPPKT);
1.1    bouyer
1.1    bouyer end:
1.1    bouyer 	if (err)
1.1    bouyer 		return (err);
1.1    bouyer
1.1    bouyer 	return (USBD_IN_PROGRESS);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_device_ctrl_read(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	/* assume endpoint already selected */
1.1    bouyer 	motg_setup_endpoint_rx(xfer);
1.1    bouyer 	/* start transaction */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXCSRL, MUSB2_MASK_CSR0L_REQPKT);
1.1    bouyer 	otgpipe->hw_ep->phase = DATA_IN;
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_device_ctrl_intr_rx(struct motg_softc *sc)
1.1    bouyer {
1.1    bouyer 	struct motg_hw_ep *ep = &sc->sc_in_ep[0];
1.1    bouyer 	usbd_xfer_handle xfer = ep->xfer;
1.1    bouyer 	uint8_t csr;
1.1    bouyer 	int datalen, max_datalen;
1.1    bouyer 	char *data;
1.1    bouyer 	bool got_short;
1.3    bouyer 	usbd_status new_status = USBD_IN_PROGRESS;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (ep->phase != DATA_IN &&
1.1    bouyer 	    ep->phase != STATUS_IN)
1.1    bouyer 		panic("motg_device_ctrl_intr_rx: bad phase %d", ep->phase);
1.1    bouyer #endif
1.7     skrll         /* select endpoint 0 */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_EPINDEX, 0);
1.1    bouyer
1.1    bouyer 	/* read out FIFO status */
1.1    bouyer 	csr = UREAD1(sc, MUSB2_REG_TXCSRL);
1.7     skrll 	DPRINTFN(MD_CTRL,
1.7     skrll 	    ("motg_device_ctrl_intr_rx phase %d csr 0x%x xfer %p status %d\n",
1.3    bouyer 	    ep->phase, csr, xfer, (xfer != NULL) ? xfer->status : 0));
1.1    bouyer
1.1    bouyer 	if (csr & MUSB2_MASK_CSR0L_NAKTIMO) {
1.1    bouyer 		csr &= ~MUSB2_MASK_CSR0L_REQPKT;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, csr);
1.1    bouyer
1.1    bouyer 		csr &= ~MUSB2_MASK_CSR0L_NAKTIMO;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, csr);
1.3    bouyer 		new_status = USBD_TIMEOUT; /* XXX */
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (csr & (MUSB2_MASK_CSR0L_RXSTALL | MUSB2_MASK_CSR0L_ERROR)) {
1.3    bouyer 		if (csr & MUSB2_MASK_CSR0L_RXSTALL)
1.3    bouyer 			new_status = USBD_STALLED;
1.3    bouyer 		else
1.3    bouyer 			new_status = USBD_IOERROR;
1.1    bouyer 		/* clear status */
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if ((csr & MUSB2_MASK_CSR0L_RXPKTRDY) == 0)
1.1    bouyer 		return; /* no data yet */
1.1    bouyer
1.3    bouyer 	if (xfer == NULL || xfer->status != USBD_IN_PROGRESS)
1.1    bouyer 		goto complete;
1.1    bouyer
1.1    bouyer 	if (ep->phase == STATUS_IN) {
1.3    bouyer 		new_status = USBD_NORMAL_COMPLETION;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	datalen = UREAD2(sc, MUSB2_REG_RXCOUNT);
1.7     skrll 	DPRINTFN(MD_CTRL,
1.7     skrll 	    ("motg_device_ctrl_intr_rx phase %d datalen %d\n",
1.1    bouyer 	    ep->phase, datalen));
1.1    bouyer 	KASSERT(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize) > 0);
1.1    bouyer 	max_datalen = min(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize),
1.1    bouyer 	    ep->datalen);
1.1    bouyer 	if (datalen > max_datalen) {
1.3    bouyer 		new_status = USBD_IOERROR;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	got_short = (datalen < max_datalen);
1.1    bouyer 	if (datalen > 0) {
1.1    bouyer 		KASSERT(ep->phase == DATA_IN);
1.1    bouyer 		data = ep->data;
1.1    bouyer 		ep->data += datalen;
1.1    bouyer 		ep->datalen -= datalen;
1.1    bouyer 		xfer->actlen += datalen;
1.1    bouyer 		if (((vaddr_t)data & 0x3) == 0 &&
1.1    bouyer 		    (datalen >> 2) > 0) {
1.7     skrll 			DPRINTFN(MD_CTRL,
1.1    bouyer 			    ("motg_device_ctrl_intr_rx r4 data %p len %d\n",
1.1    bouyer 			    data, datalen));
1.1    bouyer 			bus_space_read_multi_4(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 			    MUSB2_REG_EPFIFO(0), (void *)data, datalen >> 2);
1.1    bouyer 			data += (datalen & ~0x3);
1.1    bouyer 			datalen -= (datalen & ~0x3);
1.1    bouyer 		}
1.7     skrll 		DPRINTFN(MD_CTRL,
1.1    bouyer 		    ("motg_device_ctrl_intr_rx r1 data %p len %d\n",
1.1    bouyer 		    data, datalen));
1.1    bouyer 		if (datalen) {
1.1    bouyer 			bus_space_read_multi_1(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 			    MUSB2_REG_EPFIFO(0), data, datalen);
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXCSRL, csr & ~MUSB2_MASK_CSR0L_RXPKTRDY);
1.1    bouyer 	KASSERT(ep->phase == DATA_IN);
1.1    bouyer 	if (got_short || (ep->datalen == 0)) {
1.1    bouyer 		if (ep->need_short_xfer == 0) {
1.1    bouyer 			ep->phase = STATUS_OUT;
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXCSRH,
1.1    bouyer 			    UREAD1(sc, MUSB2_REG_TXCSRH) |
1.1    bouyer 			    MUSB2_MASK_CSR0H_PING_DIS);
1.1    bouyer 			motg_setup_endpoint_tx(xfer);
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXCSRL,
1.1    bouyer 			    MUSB2_MASK_CSR0L_STATUSPKT |
1.1    bouyer 			    MUSB2_MASK_CSR0L_TXPKTRDY);
1.1    bouyer 			return;
1.1    bouyer 		}
1.1    bouyer 		ep->need_short_xfer = 0;
1.1    bouyer 	}
1.1    bouyer 	motg_device_ctrl_read(xfer);
1.1    bouyer 	return;
1.1    bouyer complete:
1.1    bouyer 	ep->phase = IDLE;
1.1    bouyer 	ep->xfer = NULL;
1.3    bouyer 	if (xfer && xfer->status == USBD_IN_PROGRESS) {
1.3    bouyer 		KASSERT(new_status != USBD_IN_PROGRESS);
1.3    bouyer 		xfer->status = new_status;
1.1    bouyer 		usb_transfer_complete(xfer);
1.3    bouyer 	}
1.1    bouyer 	motg_device_ctrl_start1(sc);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_device_ctrl_intr_tx(struct motg_softc *sc)
1.1    bouyer {
1.1    bouyer 	struct motg_hw_ep *ep = &sc->sc_in_ep[0];
1.1    bouyer 	usbd_xfer_handle xfer = ep->xfer;
1.1    bouyer 	uint8_t csr;
1.1    bouyer 	int datalen;
1.1    bouyer 	char *data;
1.3    bouyer 	usbd_status new_status = USBD_IN_PROGRESS;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	if (ep->phase == DATA_IN || ep->phase == STATUS_IN) {
1.1    bouyer 		motg_device_ctrl_intr_rx(sc);
1.1    bouyer 		return;
1.1    bouyer 	}
1.1    bouyer
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (ep->phase != SETUP && ep->phase != DATA_OUT &&
1.1    bouyer 	    ep->phase != STATUS_OUT)
1.1    bouyer 		panic("motg_device_ctrl_intr_tx: bad phase %d", ep->phase);
1.1    bouyer #endif
1.7     skrll         /* select endpoint 0 */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_EPINDEX, 0);
1.1    bouyer
1.1    bouyer 	csr = UREAD1(sc, MUSB2_REG_TXCSRL);
1.7     skrll 	DPRINTFN(MD_CTRL,
1.7     skrll 	    ("motg_device_ctrl_intr_tx phase %d csr 0x%x xfer %p status %d\n",
1.3    bouyer 	    ep->phase, csr, xfer, (xfer != NULL) ? xfer->status : 0));
1.1    bouyer
1.1    bouyer 	if (csr & MUSB2_MASK_CSR0L_RXSTALL) {
1.1    bouyer 		/* command not accepted */
1.3    bouyer 		new_status = USBD_STALLED;
1.1    bouyer 		/* clear status */
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (csr & MUSB2_MASK_CSR0L_NAKTIMO) {
1.3    bouyer 		new_status = USBD_TIMEOUT; /* XXX */
1.1    bouyer 		/* flush fifo */
1.1    bouyer 		while (csr & MUSB2_MASK_CSR0L_TXFIFONEMPTY) {
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXCSRH,
1.7     skrll 			    UREAD1(sc, MUSB2_REG_TXCSRH) |
1.1    bouyer 				MUSB2_MASK_CSR0H_FFLUSH);
1.1    bouyer 			csr = UREAD1(sc, MUSB2_REG_TXCSRL);
1.1    bouyer 		}
1.1    bouyer 		csr &= ~MUSB2_MASK_CSR0L_NAKTIMO;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, csr);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (csr & MUSB2_MASK_CSR0L_ERROR) {
1.3    bouyer 		new_status = USBD_IOERROR;
1.1    bouyer 		/* clear status */
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (csr & MUSB2_MASK_CSR0L_TXFIFONEMPTY) {
1.1    bouyer 		/* data still not sent */
1.1    bouyer 		return;
1.1    bouyer 	}
1.1    bouyer 	if (xfer == NULL)
1.1    bouyer 		goto complete;
1.1    bouyer 	if (ep->phase == STATUS_OUT) {
1.1    bouyer 		/*
1.1    bouyer 		 * we have sent status and got no error;
1.1    bouyer 		 * declare transfer complete
1.1    bouyer 		 */
1.7     skrll 		DPRINTFN(MD_CTRL,
1.3    bouyer 		    ("motg_device_ctrl_intr_tx %p status %d complete\n",
1.3    bouyer 			xfer, xfer->status));
1.3    bouyer 		new_status = USBD_NORMAL_COMPLETION;
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (ep->datalen == 0) {
1.1    bouyer 		if (ep->need_short_xfer) {
1.1    bouyer 			ep->need_short_xfer = 0;
1.1    bouyer 			/* one more data phase */
1.1    bouyer 			if (xfer->request.bmRequestType & UT_READ) {
1.7     skrll 				DPRINTFN(MD_CTRL,
1.1    bouyer 				    ("motg_device_ctrl_intr_tx %p to DATA_IN\n", xfer));
1.1    bouyer 				motg_device_ctrl_read(xfer);
1.1    bouyer 				return;
1.1    bouyer 			} /*  else fall back to DATA_OUT */
1.1    bouyer 		} else {
1.7     skrll 			DPRINTFN(MD_CTRL,
1.1    bouyer 			    ("motg_device_ctrl_intr_tx %p to STATUS_IN, csrh 0x%x\n",
1.1    bouyer 			    xfer, UREAD1(sc, MUSB2_REG_TXCSRH)));
1.1    bouyer 			ep->phase = STATUS_IN;
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_RXCSRH,
1.1    bouyer 			    UREAD1(sc, MUSB2_REG_RXCSRH) |
1.1    bouyer 			    MUSB2_MASK_CSR0H_PING_DIS);
1.1    bouyer 			motg_setup_endpoint_rx(xfer);
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXCSRL,
1.1    bouyer 			    MUSB2_MASK_CSR0L_STATUSPKT |
1.1    bouyer 			    MUSB2_MASK_CSR0L_REQPKT);
1.1    bouyer 			return;
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	if (xfer->request.bmRequestType & UT_READ) {
1.1    bouyer 		motg_device_ctrl_read(xfer);
1.1    bouyer 		return;
1.1    bouyer 	}
1.1    bouyer 	/* setup a dataout phase */
1.1    bouyer 	datalen = min(ep->datalen,
1.1    bouyer 	    UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize));
1.1    bouyer 	ep->phase = DATA_OUT;
1.7     skrll 	DPRINTFN(MD_CTRL,
1.1    bouyer 	    ("motg_device_ctrl_intr_tx %p to DATA_OUT, csrh 0x%x\n", xfer,
1.1    bouyer 	    UREAD1(sc, MUSB2_REG_TXCSRH)));
1.1    bouyer 	if (datalen) {
1.1    bouyer 		data = ep->data;
1.1    bouyer 		ep->data += datalen;
1.1    bouyer 		ep->datalen -= datalen;
1.1    bouyer 		xfer->actlen += datalen;
1.1    bouyer 		if (((vaddr_t)data & 0x3) == 0 &&
1.1    bouyer 		    (datalen >> 2) > 0) {
1.1    bouyer 			bus_space_write_multi_4(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 			    MUSB2_REG_EPFIFO(0), (void *)data, datalen >> 2);
1.1    bouyer 			data += (datalen & ~0x3);
1.1    bouyer 			datalen -= (datalen & ~0x3);
1.1    bouyer 		}
1.1    bouyer 		if (datalen) {
1.1    bouyer 			bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 			    MUSB2_REG_EPFIFO(0), data, datalen);
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	/* send data */
1.1    bouyer 	motg_setup_endpoint_tx(xfer);
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXCSRL, MUSB2_MASK_CSR0L_TXPKTRDY);
1.1    bouyer 	return;
1.1    bouyer
1.1    bouyer complete:
1.1    bouyer 	ep->phase = IDLE;
1.1    bouyer 	ep->xfer = NULL;
1.3    bouyer 	if (xfer && xfer->status == USBD_IN_PROGRESS) {
1.3    bouyer 		KASSERT(new_status != USBD_IN_PROGRESS);
1.3    bouyer 		xfer->status = new_status;
1.1    bouyer 		usb_transfer_complete(xfer);
1.3    bouyer 	}
1.1    bouyer 	motg_device_ctrl_start1(sc);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Abort a device control request. */
1.1    bouyer void
1.1    bouyer motg_device_ctrl_abort(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	DPRINTFN(MD_CTRL, ("motg_device_ctrl_abort:\n"));
1.3    bouyer 	motg_device_xfer_abort(xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Close a device control pipe */
1.1    bouyer void
1.1    bouyer motg_device_ctrl_close(usbd_pipe_handle pipe)
1.1    bouyer {
1.8     skrll 	struct motg_softc *sc __diagused = pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)pipe;
1.1    bouyer 	struct motg_pipe *otgpipeiter;
1.1    bouyer
1.1    bouyer 	DPRINTFN(MD_CTRL, ("motg_device_ctrl_close:\n"));
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	KASSERT(otgpipe->hw_ep->xfer == NULL ||
1.1    bouyer 	    otgpipe->hw_ep->xfer->pipe != pipe);
1.1    bouyer
1.1    bouyer 	SIMPLEQ_FOREACH(otgpipeiter, &otgpipe->hw_ep->ep_pipes, ep_pipe_list) {
1.1    bouyer 		if (otgpipeiter == otgpipe) {
1.1    bouyer 			/* remove from list */
1.1    bouyer 			SIMPLEQ_REMOVE(&otgpipe->hw_ep->ep_pipes, otgpipe,
1.1    bouyer 			    motg_pipe, ep_pipe_list);
1.1    bouyer 			otgpipe->hw_ep->refcount--;
1.1    bouyer 			/* we're done */
1.1    bouyer 			return;
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	panic("motg_device_ctrl_close: not found");
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_device_ctrl_done(usbd_xfer_handle xfer)
1.1    bouyer {
1.8     skrll 	struct motg_pipe *otgpipe __diagused = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	DPRINTFN(MD_CTRL, ("motg_device_ctrl_done:\n"));
1.1    bouyer 	KASSERT(otgpipe->hw_ep->xfer != xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static usbd_status
1.1    bouyer motg_device_data_transfer(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	usbd_status err;
1.1    bouyer
1.1    bouyer 	/* Insert last in queue. */
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.3    bouyer 	DPRINTF(("motg_device_data_transfer(%p) status %d\n",
1.3    bouyer 	    xfer, xfer->status));
1.1    bouyer 	err = usb_insert_transfer(xfer);
1.3    bouyer 	xfer->status = USBD_NOT_STARTED;
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer 	if (err)
1.1    bouyer 		return (err);
1.1    bouyer
1.1    bouyer 	/*
1.1    bouyer 	 * Pipe isn't running (otherwise err would be USBD_INPROG),
1.1    bouyer 	 * so start it first.
1.1    bouyer 	 */
1.1    bouyer 	return (motg_device_data_start(SIMPLEQ_FIRST(&xfer->pipe->queue)));
1.1    bouyer }
1.1    bouyer
1.1    bouyer static usbd_status
1.1    bouyer motg_device_data_start(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	usbd_status err;
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.3    bouyer 	DPRINTF(("motg_device_data_start(%p) status %d\n",
1.3    bouyer 	    xfer, xfer->status));
1.1    bouyer 	err = motg_device_data_start1(sc, otgpipe->hw_ep);
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer 	if (err != USBD_IN_PROGRESS)
1.1    bouyer 		return err;
1.1    bouyer 	if (sc->sc_bus.use_polling)
1.1    bouyer 		motg_waitintr(sc, xfer);
1.1    bouyer 	return USBD_IN_PROGRESS;
1.1    bouyer }
1.1    bouyer
1.1    bouyer static usbd_status
1.1    bouyer motg_device_data_start1(struct motg_softc *sc, struct motg_hw_ep *ep)
1.1    bouyer {
1.3    bouyer 	usbd_xfer_handle xfer = NULL;
1.1    bouyer 	struct motg_pipe *otgpipe;
1.1    bouyer 	usbd_status err = 0;
1.8     skrll 	uint32_t val __diagused;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	if (sc->sc_dying)
1.1    bouyer 		return (USBD_IOERROR);
1.1    bouyer
1.1    bouyer 	if (!sc->sc_connected)
1.1    bouyer 		return (USBD_IOERROR);
1.1    bouyer
1.1    bouyer 	if (ep->xfer != NULL) {
1.1    bouyer 		err = USBD_IN_PROGRESS;
1.1    bouyer 		goto end;
1.1    bouyer 	}
1.1    bouyer 	/* locate the first pipe with work to do */
1.1    bouyer 	SIMPLEQ_FOREACH(otgpipe, &ep->ep_pipes, ep_pipe_list) {
1.1    bouyer 		xfer = SIMPLEQ_FIRST(&otgpipe->pipe.queue);
1.3    bouyer 		DPRINTFN(MD_BULK,
1.3    bouyer 		    ("motg_device_data_start1 pipe %p xfer %p status %d\n",
1.3    bouyer 		    otgpipe, xfer, (xfer != NULL) ? xfer->status : 0));
1.1    bouyer 		if (xfer != NULL) {
1.1    bouyer 			/* move this pipe to the end of the list */
1.1    bouyer 			SIMPLEQ_REMOVE(&ep->ep_pipes, otgpipe,
1.1    bouyer 			    motg_pipe, ep_pipe_list);
1.1    bouyer 			SIMPLEQ_INSERT_TAIL(&ep->ep_pipes,
1.1    bouyer 			    otgpipe, ep_pipe_list);
1.1    bouyer 			break;
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	if (xfer == NULL) {
1.1    bouyer 		err = USBD_NOT_STARTED;
1.1    bouyer 		goto end;
1.1    bouyer 	}
1.3    bouyer 	xfer->status = USBD_IN_PROGRESS;
1.1    bouyer 	KASSERT(otgpipe == (struct motg_pipe *)xfer->pipe);
1.1    bouyer 	KASSERT(otgpipe->hw_ep == ep);
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (xfer->rqflags & URQ_REQUEST)
1.1    bouyer 		panic("motg_device_data_transfer: a request");
1.1    bouyer #endif
1.1    bouyer 	// KASSERT(xfer->actlen == 0);
1.1    bouyer 	xfer->actlen = 0;
1.1    bouyer
1.1    bouyer 	ep->xfer = xfer;
1.1    bouyer 	ep->datalen = xfer->length;
1.1    bouyer 	KASSERT(ep->datalen > 0);
1.1    bouyer 	ep->data = KERNADDR(&xfer->dmabuf, 0);
1.1    bouyer 	if ((xfer->flags & USBD_FORCE_SHORT_XFER) &&
1.1    bouyer 	    (ep->datalen % 64) == 0)
1.1    bouyer 		ep->need_short_xfer = 1;
1.1    bouyer 	else
1.1    bouyer 		ep->need_short_xfer = 0;
1.1    bouyer 	/* now we need send this request */
1.7     skrll 	DPRINTFN(MD_BULK,
1.1    bouyer 	    ("motg_device_data_start1(%p) %s data %p len %d short %d speed %d to %d\n",
1.7     skrll 	    xfer,
1.1    bouyer 	    UE_GET_DIR(xfer->pipe->endpoint->edesc->bEndpointAddress) == UE_DIR_IN ? "read" : "write",
1.1    bouyer 	    ep->data, ep->datalen, ep->need_short_xfer, xfer->pipe->device->speed,
1.1    bouyer 	    xfer->pipe->device->address));
1.1    bouyer 	KASSERT(ep->phase == IDLE);
1.1    bouyer 	/* select endpoint */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_EPINDEX, ep->ep_number);
1.1    bouyer 	if (UE_GET_DIR(xfer->pipe->endpoint->edesc->bEndpointAddress)
1.1    bouyer 	    == UE_DIR_IN) {
1.1    bouyer 		val = UREAD1(sc, MUSB2_REG_RXCSRL);
1.1    bouyer 		KASSERT((val & MUSB2_MASK_CSRL_RXPKTRDY) == 0);
1.1    bouyer 		motg_device_data_read(xfer);
1.1    bouyer 	} else {
1.1    bouyer 		ep->phase = DATA_OUT;
1.1    bouyer 		val = UREAD1(sc, MUSB2_REG_TXCSRL);
1.1    bouyer 		KASSERT((val & MUSB2_MASK_CSRL_TXPKTRDY) == 0);
1.1    bouyer 		motg_device_data_write(xfer);
1.1    bouyer 	}
1.1    bouyer end:
1.1    bouyer 	if (err)
1.1    bouyer 		return (err);
1.1    bouyer
1.1    bouyer 	return (USBD_IN_PROGRESS);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_device_data_read(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	uint32_t val;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	/* assume endpoint already selected */
1.1    bouyer 	motg_setup_endpoint_rx(xfer);
1.1    bouyer 	/* Max packet size */
1.1    bouyer 	UWRITE2(sc, MUSB2_REG_RXMAXP,
1.1    bouyer 	    UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize));
1.1    bouyer 	/* Data Toggle */
1.1    bouyer 	val = UREAD1(sc, MUSB2_REG_RXCSRH);
1.1    bouyer 	val |= MUSB2_MASK_CSRH_RXDT_WREN;
1.1    bouyer 	if (otgpipe->nexttoggle)
1.1    bouyer 		val |= MUSB2_MASK_CSRH_RXDT_VAL;
1.1    bouyer 	else
1.1    bouyer 		val &= ~MUSB2_MASK_CSRH_RXDT_VAL;
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_RXCSRH, val);
1.1    bouyer
1.7     skrll 	DPRINTFN(MD_BULK,
1.1    bouyer 	    ("motg_device_data_read %p to DATA_IN on ep %d, csrh 0x%x\n",
1.1    bouyer 	    xfer, otgpipe->hw_ep->ep_number, UREAD1(sc, MUSB2_REG_RXCSRH)));
1.1    bouyer 	/* start transaction */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_RXCSRL, MUSB2_MASK_CSRL_RXREQPKT);
1.1    bouyer 	otgpipe->hw_ep->phase = DATA_IN;
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_device_data_write(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	struct motg_hw_ep *ep = otgpipe->hw_ep;
1.1    bouyer 	int datalen;
1.1    bouyer 	char *data;
1.1    bouyer 	uint32_t val;
1.1    bouyer
1.1    bouyer 	KASSERT(xfer!=NULL);
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer
1.1    bouyer 	datalen = min(ep->datalen,
1.1    bouyer 	    UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize));
1.1    bouyer 	ep->phase = DATA_OUT;
1.7     skrll 	DPRINTFN(MD_BULK,
1.1    bouyer 	    ("motg_device_data_write %p to DATA_OUT on ep %d, len %d csrh 0x%x\n",
1.1    bouyer 	    xfer, ep->ep_number, datalen, UREAD1(sc, MUSB2_REG_TXCSRH)));
1.1    bouyer
1.1    bouyer 	/* assume endpoint already selected */
1.1    bouyer 	/* write data to fifo */
1.1    bouyer 	data = ep->data;
1.1    bouyer 	ep->data += datalen;
1.1    bouyer 	ep->datalen -= datalen;
1.1    bouyer 	xfer->actlen += datalen;
1.1    bouyer 	if (((vaddr_t)data & 0x3) == 0 &&
1.1    bouyer 	    (datalen >> 2) > 0) {
1.1    bouyer 		bus_space_write_multi_4(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 		    MUSB2_REG_EPFIFO(ep->ep_number),
1.1    bouyer 		    (void *)data, datalen >> 2);
1.1    bouyer 		data += (datalen & ~0x3);
1.1    bouyer 		datalen -= (datalen & ~0x3);
1.1    bouyer 	}
1.1    bouyer 	if (datalen) {
1.1    bouyer 		bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 		    MUSB2_REG_EPFIFO(ep->ep_number), data, datalen);
1.1    bouyer 	}
1.1    bouyer
1.1    bouyer 	motg_setup_endpoint_tx(xfer);
1.1    bouyer 	/* Max packet size */
1.1    bouyer 	UWRITE2(sc, MUSB2_REG_TXMAXP,
1.1    bouyer 	    UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize));
1.1    bouyer 	/* Data Toggle */
1.1    bouyer 	val = UREAD1(sc, MUSB2_REG_TXCSRH);
1.1    bouyer 	val |= MUSB2_MASK_CSRH_TXDT_WREN;
1.1    bouyer 	if (otgpipe->nexttoggle)
1.1    bouyer 		val |= MUSB2_MASK_CSRH_TXDT_VAL;
1.1    bouyer 	else
1.1    bouyer 		val &= ~MUSB2_MASK_CSRH_TXDT_VAL;
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXCSRH, val);
1.1    bouyer
1.1    bouyer 	/* start transaction */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_TXCSRL, MUSB2_MASK_CSRL_TXPKTRDY);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_device_intr_rx(struct motg_softc *sc, int epnumber)
1.1    bouyer {
1.1    bouyer 	struct motg_hw_ep *ep = &sc->sc_in_ep[epnumber];
1.1    bouyer 	usbd_xfer_handle xfer = ep->xfer;
1.1    bouyer 	uint8_t csr;
1.1    bouyer 	int datalen, max_datalen;
1.1    bouyer 	char *data;
1.1    bouyer 	bool got_short;
1.3    bouyer 	usbd_status new_status = USBD_IN_PROGRESS;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	KASSERT(ep->ep_number == epnumber);
1.1    bouyer
1.7     skrll 	DPRINTFN(MD_BULK,
1.1    bouyer 	    ("motg_device_intr_rx on ep %d\n", epnumber));
1.7     skrll         /* select endpoint */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_EPINDEX, epnumber);
1.1    bouyer
1.1    bouyer 	/* read out FIFO status */
1.1    bouyer 	csr = UREAD1(sc, MUSB2_REG_RXCSRL);
1.7     skrll 	DPRINTFN(MD_BULK,
1.7     skrll 	    ("motg_device_intr_rx phase %d csr 0x%x\n",
1.1    bouyer 	    ep->phase, csr));
1.1    bouyer
1.1    bouyer 	if ((csr & (MUSB2_MASK_CSRL_RXNAKTO | MUSB2_MASK_CSRL_RXSTALL |
1.1    bouyer 	    MUSB2_MASK_CSRL_RXERROR | MUSB2_MASK_CSRL_RXPKTRDY)) == 0)
1.1    bouyer 		return;
1.1    bouyer
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (ep->phase != DATA_IN)
1.1    bouyer 		panic("motg_device_intr_rx: bad phase %d", ep->phase);
1.1    bouyer #endif
1.1    bouyer 	if (csr & MUSB2_MASK_CSRL_RXNAKTO) {
1.1    bouyer 		csr &= ~MUSB2_MASK_CSRL_RXREQPKT;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXCSRL, csr);
1.1    bouyer
1.1    bouyer 		csr &= ~MUSB2_MASK_CSRL_RXNAKTO;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXCSRL, csr);
1.3    bouyer 		new_status = USBD_TIMEOUT; /* XXX */
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (csr & (MUSB2_MASK_CSRL_RXSTALL | MUSB2_MASK_CSRL_RXERROR)) {
1.7     skrll 		if (csr & MUSB2_MASK_CSRL_RXSTALL)
1.3    bouyer 			new_status = USBD_STALLED;
1.3    bouyer 		else
1.3    bouyer 			new_status = USBD_IOERROR;
1.1    bouyer 		/* clear status */
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	KASSERT(csr & MUSB2_MASK_CSRL_RXPKTRDY);
1.1    bouyer
1.3    bouyer 	if (xfer == NULL || xfer->status != USBD_IN_PROGRESS) {
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	otgpipe->nexttoggle = otgpipe->nexttoggle ^ 1;
1.1    bouyer
1.1    bouyer 	datalen = UREAD2(sc, MUSB2_REG_RXCOUNT);
1.7     skrll 	DPRINTFN(MD_BULK,
1.7     skrll 	    ("motg_device_intr_rx phase %d datalen %d\n",
1.1    bouyer 	    ep->phase, datalen));
1.1    bouyer 	KASSERT(UE_GET_SIZE(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)) > 0);
1.1    bouyer 	max_datalen = min(
1.1    bouyer 	    UE_GET_SIZE(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)),
1.1    bouyer 	    ep->datalen);
1.1    bouyer 	if (datalen > max_datalen) {
1.3    bouyer 		new_status = USBD_IOERROR;
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_RXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	got_short = (datalen < max_datalen);
1.1    bouyer 	if (datalen > 0) {
1.1    bouyer 		KASSERT(ep->phase == DATA_IN);
1.1    bouyer 		data = ep->data;
1.1    bouyer 		ep->data += datalen;
1.1    bouyer 		ep->datalen -= datalen;
1.1    bouyer 		xfer->actlen += datalen;
1.1    bouyer 		if (((vaddr_t)data & 0x3) == 0 &&
1.1    bouyer 		    (datalen >> 2) > 0) {
1.7     skrll 			DPRINTFN(MD_BULK,
1.1    bouyer 			    ("motg_device_intr_rx r4 data %p len %d\n",
1.1    bouyer 			    data, datalen));
1.1    bouyer 			bus_space_read_multi_4(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 			    MUSB2_REG_EPFIFO(ep->ep_number),
1.1    bouyer 			    (void *)data, datalen >> 2);
1.1    bouyer 			data += (datalen & ~0x3);
1.1    bouyer 			datalen -= (datalen & ~0x3);
1.1    bouyer 		}
1.7     skrll 		DPRINTFN(MD_BULK,
1.1    bouyer 		    ("motg_device_intr_rx r1 data %p len %d\n",
1.1    bouyer 		    data, datalen));
1.1    bouyer 		if (datalen) {
1.1    bouyer 			bus_space_read_multi_1(sc->sc_iot, sc->sc_ioh,
1.1    bouyer 			    MUSB2_REG_EPFIFO(ep->ep_number), data, datalen);
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_RXCSRL, 0);
1.1    bouyer 	KASSERT(ep->phase == DATA_IN);
1.1    bouyer 	if (got_short || (ep->datalen == 0)) {
1.1    bouyer 		if (ep->need_short_xfer == 0) {
1.3    bouyer 			new_status = USBD_NORMAL_COMPLETION;
1.1    bouyer 			goto complete;
1.1    bouyer 		}
1.1    bouyer 		ep->need_short_xfer = 0;
1.1    bouyer 	}
1.1    bouyer 	motg_device_data_read(xfer);
1.1    bouyer 	return;
1.1    bouyer complete:
1.7     skrll 	DPRINTFN(MD_BULK,
1.1    bouyer 	    ("motg_device_intr_rx xfer %p complete, status %d\n", xfer,
1.1    bouyer 	    (xfer != NULL) ? xfer->status : 0));
1.1    bouyer 	ep->phase = IDLE;
1.1    bouyer 	ep->xfer = NULL;
1.3    bouyer 	if (xfer && xfer->status == USBD_IN_PROGRESS) {
1.3    bouyer 		KASSERT(new_status != USBD_IN_PROGRESS);
1.3    bouyer 		xfer->status = new_status;
1.1    bouyer 		usb_transfer_complete(xfer);
1.3    bouyer 	}
1.1    bouyer 	motg_device_data_start1(sc, ep);
1.1    bouyer }
1.1    bouyer
1.1    bouyer static void
1.1    bouyer motg_device_intr_tx(struct motg_softc *sc, int epnumber)
1.1    bouyer {
1.1    bouyer 	struct motg_hw_ep *ep = &sc->sc_out_ep[epnumber];
1.1    bouyer 	usbd_xfer_handle xfer = ep->xfer;
1.1    bouyer 	uint8_t csr;
1.1    bouyer 	struct motg_pipe *otgpipe;
1.3    bouyer 	usbd_status new_status = USBD_IN_PROGRESS;
1.1    bouyer
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	KASSERT(ep->ep_number == epnumber);
1.1    bouyer
1.7     skrll 	DPRINTFN(MD_BULK,
1.1    bouyer 	    ("motg_device_intr_tx on ep %d\n", epnumber));
1.7     skrll         /* select endpoint */
1.1    bouyer 	UWRITE1(sc, MUSB2_REG_EPINDEX, epnumber);
1.1    bouyer
1.1    bouyer 	csr = UREAD1(sc, MUSB2_REG_TXCSRL);
1.7     skrll 	DPRINTFN(MD_BULK,
1.7     skrll 	    ("motg_device_intr_tx phase %d csr 0x%x\n",
1.1    bouyer 	    ep->phase, csr));
1.1    bouyer
1.1    bouyer 	if (csr & (MUSB2_MASK_CSRL_TXSTALLED|MUSB2_MASK_CSRL_TXERROR)) {
1.1    bouyer 		/* command not accepted */
1.7     skrll 		if (csr & MUSB2_MASK_CSRL_TXSTALLED)
1.3    bouyer 			new_status = USBD_STALLED;
1.3    bouyer 		else
1.3    bouyer 			new_status = USBD_IOERROR;
1.1    bouyer 		/* clear status */
1.1    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, 0);
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (csr & MUSB2_MASK_CSRL_TXNAKTO) {
1.3    bouyer 		new_status = USBD_TIMEOUT; /* XXX */
1.3    bouyer 		csr &= ~MUSB2_MASK_CSRL_TXNAKTO;
1.3    bouyer 		UWRITE1(sc, MUSB2_REG_TXCSRL, csr);
1.1    bouyer 		/* flush fifo */
1.1    bouyer 		while (csr & MUSB2_MASK_CSRL_TXFIFONEMPTY) {
1.1    bouyer 			csr |= MUSB2_MASK_CSRL_TXFFLUSH;
1.3    bouyer 			csr &= ~MUSB2_MASK_CSRL_TXNAKTO;
1.1    bouyer 			UWRITE1(sc, MUSB2_REG_TXCSRL, csr);
1.3    bouyer 			delay(1000);
1.1    bouyer 			csr = UREAD1(sc, MUSB2_REG_TXCSRL);
1.3    bouyer 			DPRINTFN(MD_BULK, ("TX fifo flush ep %d CSR 0x%x\n",
1.3    bouyer 			    epnumber, csr));
1.1    bouyer 		}
1.1    bouyer 		goto complete;
1.1    bouyer 	}
1.1    bouyer 	if (csr & (MUSB2_MASK_CSRL_TXFIFONEMPTY|MUSB2_MASK_CSRL_TXPKTRDY)) {
1.1    bouyer 		/* data still not sent */
1.1    bouyer 		return;
1.1    bouyer 	}
1.3    bouyer 	if (xfer == NULL || xfer->status != USBD_IN_PROGRESS)
1.1    bouyer 		goto complete;
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	if (ep->phase != DATA_OUT)
1.1    bouyer 		panic("motg_device_intr_tx: bad phase %d", ep->phase);
1.1    bouyer #endif
1.7     skrll
1.1    bouyer 	otgpipe = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	otgpipe->nexttoggle = otgpipe->nexttoggle ^ 1;
1.1    bouyer
1.1    bouyer 	if (ep->datalen == 0) {
1.1    bouyer 		if (ep->need_short_xfer) {
1.1    bouyer 			ep->need_short_xfer = 0;
1.1    bouyer 			/* one more data phase */
1.1    bouyer 		} else {
1.3    bouyer 			new_status = USBD_NORMAL_COMPLETION;
1.1    bouyer 			goto complete;
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	motg_device_data_write(xfer);
1.1    bouyer 	return;
1.1    bouyer
1.1    bouyer complete:
1.7     skrll 	DPRINTFN(MD_BULK,
1.1    bouyer 	    ("motg_device_intr_tx xfer %p complete, status %d\n", xfer,
1.1    bouyer 	    (xfer != NULL) ? xfer->status : 0));
1.1    bouyer #ifdef DIAGNOSTIC
1.3    bouyer 	if (xfer && xfer->status == USBD_IN_PROGRESS && ep->phase != DATA_OUT)
1.1    bouyer 		panic("motg_device_intr_tx: bad phase %d", ep->phase);
1.1    bouyer #endif
1.1    bouyer 	ep->phase = IDLE;
1.1    bouyer 	ep->xfer = NULL;
1.3    bouyer 	if (xfer && xfer->status == USBD_IN_PROGRESS) {
1.3    bouyer 		KASSERT(new_status != USBD_IN_PROGRESS);
1.3    bouyer 		xfer->status = new_status;
1.1    bouyer 		usb_transfer_complete(xfer);
1.3    bouyer 	}
1.1    bouyer 	motg_device_data_start1(sc, ep);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Abort a device control request. */
1.1    bouyer void
1.1    bouyer motg_device_data_abort(usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer #ifdef DIAGNOSTIC
1.1    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.1    bouyer #endif
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer
1.3    bouyer 	DPRINTFN(MD_BULK, ("motg_device_data_abort:\n"));
1.3    bouyer 	motg_device_xfer_abort(xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /* Close a device control pipe */
1.1    bouyer void
1.1    bouyer motg_device_data_close(usbd_pipe_handle pipe)
1.1    bouyer {
1.8     skrll 	struct motg_softc *sc __diagused = pipe->device->bus->hci_private;
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)pipe;
1.1    bouyer 	struct motg_pipe *otgpipeiter;
1.1    bouyer
1.1    bouyer 	DPRINTFN(MD_CTRL, ("motg_device_data_close:\n"));
1.1    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.1    bouyer 	KASSERT(otgpipe->hw_ep->xfer == NULL ||
1.1    bouyer 	    otgpipe->hw_ep->xfer->pipe != pipe);
1.1    bouyer
1.1    bouyer 	pipe->endpoint->datatoggle = otgpipe->nexttoggle;
1.1    bouyer 	SIMPLEQ_FOREACH(otgpipeiter, &otgpipe->hw_ep->ep_pipes, ep_pipe_list) {
1.1    bouyer 		if (otgpipeiter == otgpipe) {
1.1    bouyer 			/* remove from list */
1.1    bouyer 			SIMPLEQ_REMOVE(&otgpipe->hw_ep->ep_pipes, otgpipe,
1.1    bouyer 			    motg_pipe, ep_pipe_list);
1.1    bouyer 			otgpipe->hw_ep->refcount--;
1.1    bouyer 			/* we're done */
1.1    bouyer 			return;
1.1    bouyer 		}
1.1    bouyer 	}
1.1    bouyer 	panic("motg_device_data_close: not found");
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_device_data_done(usbd_xfer_handle xfer)
1.1    bouyer {
1.8     skrll 	struct motg_pipe *otgpipe __diagused = (struct motg_pipe *)xfer->pipe;
1.1    bouyer 	DPRINTFN(MD_CTRL, ("motg_device_data_done:\n"));
1.1    bouyer 	KASSERT(otgpipe->hw_ep->xfer != xfer);
1.1    bouyer }
1.1    bouyer
1.1    bouyer /*
1.1    bouyer  * Wait here until controller claims to have an interrupt.
1.1    bouyer  * Then call motg_intr and return.  Use timeout to avoid waiting
1.1    bouyer  * too long.
1.1    bouyer  * Only used during boot when interrupts are not enabled yet.
1.1    bouyer  */
1.1    bouyer void
1.1    bouyer motg_waitintr(struct motg_softc *sc, usbd_xfer_handle xfer)
1.1    bouyer {
1.1    bouyer 	int timo = xfer->timeout;
1.1    bouyer
1.1    bouyer 	mutex_enter(&sc->sc_lock);
1.1    bouyer
1.1    bouyer 	DPRINTF(("motg_waitintr: timeout = %dms\n", timo));
1.1    bouyer
1.1    bouyer 	for (; timo >= 0; timo--) {
1.1    bouyer 		mutex_exit(&sc->sc_lock);
1.1    bouyer 		usb_delay_ms(&sc->sc_bus, 1);
1.1    bouyer 		mutex_spin_enter(&sc->sc_intr_lock);
1.1    bouyer 		motg_poll(&sc->sc_bus);
1.1    bouyer 		mutex_spin_exit(&sc->sc_intr_lock);
1.1    bouyer 		mutex_enter(&sc->sc_lock);
1.1    bouyer 		if (xfer->status != USBD_IN_PROGRESS)
1.1    bouyer 			goto done;
1.1    bouyer 	}
1.1    bouyer
1.1    bouyer 	/* Timeout */
1.1    bouyer 	DPRINTF(("motg_waitintr: timeout\n"));
1.1    bouyer 	panic("motg_waitintr: timeout");
1.1    bouyer 	/* XXX handle timeout ! */
1.1    bouyer
1.1    bouyer done:
1.1    bouyer 	mutex_exit(&sc->sc_lock);
1.1    bouyer }
1.1    bouyer
1.1    bouyer void
1.1    bouyer motg_device_clear_toggle(usbd_pipe_handle pipe)
1.1    bouyer {
1.1    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)pipe;
1.1    bouyer 	otgpipe->nexttoggle = 0;
1.1    bouyer }
1.3    bouyer
1.3    bouyer /* Abort a device control request. */
1.3    bouyer static void
1.3    bouyer motg_device_xfer_abort(usbd_xfer_handle xfer)
1.3    bouyer {
1.3    bouyer 	int wake;
1.3    bouyer 	uint8_t csr;
1.3    bouyer 	struct motg_softc *sc = xfer->pipe->device->bus->hci_private;
1.3    bouyer 	struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe;
1.3    bouyer 	KASSERT(mutex_owned(&sc->sc_lock));
1.3    bouyer
1.3    bouyer 	DPRINTF(("motg_device_xfer_abort:\n"));
1.3    bouyer 	if (xfer->hcflags & UXFER_ABORTING) {
1.3    bouyer 		DPRINTF(("motg_device_xfer_abort: already aborting\n"));
1.3    bouyer 		xfer->hcflags |= UXFER_ABORTWAIT;
1.3    bouyer 		while (xfer->hcflags & UXFER_ABORTING)
1.6     skrll 			cv_wait(&xfer->hccv, &sc->sc_lock);
1.3    bouyer 		return;
1.3    bouyer 	}
1.3    bouyer 	xfer->hcflags |= UXFER_ABORTING;
1.3    bouyer 	if (otgpipe->hw_ep->xfer == xfer) {
1.3    bouyer 		KASSERT(xfer->status == USBD_IN_PROGRESS);
1.3    bouyer 		otgpipe->hw_ep->xfer = NULL;
1.3    bouyer 		if (otgpipe->hw_ep->ep_number > 0) {
1.7     skrll 			/* select endpoint */
1.3    bouyer 			UWRITE1(sc, MUSB2_REG_EPINDEX,
1.3    bouyer 			    otgpipe->hw_ep->ep_number);
1.3    bouyer 			if (otgpipe->hw_ep->phase == DATA_OUT) {
1.3    bouyer 				csr = UREAD1(sc, MUSB2_REG_TXCSRL);
1.3    bouyer 				while (csr & MUSB2_MASK_CSRL_TXFIFONEMPTY) {
1.3    bouyer 					csr |= MUSB2_MASK_CSRL_TXFFLUSH;
1.3    bouyer 					UWRITE1(sc, MUSB2_REG_TXCSRL, csr);
1.3    bouyer 					csr = UREAD1(sc, MUSB2_REG_TXCSRL);
1.3    bouyer 				}
1.3    bouyer 				UWRITE1(sc, MUSB2_REG_TXCSRL, 0);
1.3    bouyer 			} else if (otgpipe->hw_ep->phase == DATA_IN) {
1.3    bouyer 				csr = UREAD1(sc, MUSB2_REG_RXCSRL);
1.3    bouyer 				while (csr & MUSB2_MASK_CSRL_RXPKTRDY) {
1.3    bouyer 					csr |= MUSB2_MASK_CSRL_RXFFLUSH;
1.3    bouyer 					UWRITE1(sc, MUSB2_REG_RXCSRL, csr);
1.3    bouyer 					csr = UREAD1(sc, MUSB2_REG_RXCSRL);
1.3    bouyer 				}
1.3    bouyer 				UWRITE1(sc, MUSB2_REG_RXCSRL, 0);
1.3    bouyer 			}
1.3    bouyer 			otgpipe->hw_ep->phase = IDLE;
1.3    bouyer 		}
1.3    bouyer 	}
1.3    bouyer 	xfer->status = USBD_CANCELLED; /* make software ignore it */
1.3    bouyer 	wake = xfer->hcflags & UXFER_ABORTWAIT;
1.3    bouyer 	xfer->hcflags &= ~(UXFER_ABORTING | UXFER_ABORTWAIT);
1.3    bouyer 	usb_transfer_complete(xfer);
1.3    bouyer 	if (wake)
1.3    bouyer 		cv_broadcast(&xfer->hccv);
1.3    bouyer }