motg.c revision 1.12.2.4
1 1.12.2.4 skrll /* $NetBSD: motg.c,v 1.12.2.4 2014/12/01 12:38:39 skrll Exp $ */ 2 1.1 bouyer 3 1.1 bouyer /* 4 1.1 bouyer * Copyright (c) 1998, 2004, 2011, 2012, 2014 The NetBSD Foundation, Inc. 5 1.1 bouyer * All rights reserved. 6 1.1 bouyer * 7 1.1 bouyer * This code is derived from software contributed to The NetBSD Foundation 8 1.1 bouyer * by Lennart Augustsson (lennart (at) augustsson.net) at 9 1.1 bouyer * Carlstedt Research & Technology, Jared D. McNeill (jmcneill (at) invisible.ca), 10 1.1 bouyer * Matthew R. Green (mrg (at) eterna.com.au), and Manuel Bouyer (bouyer (at) netbsd.org). 11 1.1 bouyer * 12 1.1 bouyer * Redistribution and use in source and binary forms, with or without 13 1.1 bouyer * modification, are permitted provided that the following conditions 14 1.1 bouyer * are met: 15 1.1 bouyer * 1. Redistributions of source code must retain the above copyright 16 1.1 bouyer * notice, this list of conditions and the following disclaimer. 17 1.1 bouyer * 2. Redistributions in binary form must reproduce the above copyright 18 1.1 bouyer * notice, this list of conditions and the following disclaimer in the 19 1.1 bouyer * documentation and/or other materials provided with the distribution. 20 1.1 bouyer * 21 1.1 bouyer * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 22 1.1 bouyer * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 23 1.1 bouyer * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 24 1.1 bouyer * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 25 1.1 bouyer * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 26 1.1 bouyer * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 27 1.1 bouyer * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 28 1.1 bouyer * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 29 1.1 bouyer * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 30 1.1 bouyer * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 31 1.1 bouyer * POSSIBILITY OF SUCH DAMAGE. 32 1.1 bouyer */ 33 1.1 bouyer 34 1.1 bouyer 35 1.1 bouyer /* 36 1.1 bouyer * This file contains the driver for the Mentor Graphics Inventra USB 37 1.1 bouyer * 2.0 High Speed Dual-Role controller. 38 1.1 bouyer * 39 1.1 bouyer * NOTE: The current implementation only supports Device Side Mode! 40 1.1 bouyer */ 41 1.1 bouyer 42 1.10 jmcneill #include "opt_motg.h" 43 1.10 jmcneill 44 1.1 bouyer #include <sys/cdefs.h> 45 1.12.2.4 skrll __KERNEL_RCSID(0, "$NetBSD: motg.c,v 1.12.2.4 2014/12/01 12:38:39 skrll Exp $"); 46 1.1 bouyer 47 1.1 bouyer #include <sys/param.h> 48 1.1 bouyer #include <sys/systm.h> 49 1.1 bouyer #include <sys/kernel.h> 50 1.1 bouyer #include <sys/kmem.h> 51 1.1 bouyer #include <sys/device.h> 52 1.1 bouyer #include <sys/select.h> 53 1.1 bouyer #include <sys/extent.h> 54 1.1 bouyer #include <sys/proc.h> 55 1.1 bouyer #include <sys/queue.h> 56 1.1 bouyer #include <sys/bus.h> 57 1.1 bouyer #include <sys/cpu.h> 58 1.1 bouyer 59 1.1 bouyer #include <machine/endian.h> 60 1.1 bouyer 61 1.1 bouyer #include <dev/usb/usb.h> 62 1.1 bouyer #include <dev/usb/usbdi.h> 63 1.1 bouyer #include <dev/usb/usbdivar.h> 64 1.1 bouyer #include <dev/usb/usb_mem.h> 65 1.1 bouyer #include <dev/usb/usb_quirks.h> 66 1.1 bouyer 67 1.10 jmcneill #ifdef MOTG_ALLWINNER 68 1.10 jmcneill #include <arch/arm/allwinner/awin_otgreg.h> 69 1.10 jmcneill #else 70 1.1 bouyer #include <dev/usb/motgreg.h> 71 1.10 jmcneill #endif 72 1.10 jmcneill 73 1.1 bouyer #include <dev/usb/motgvar.h> 74 1.1 bouyer #include <dev/usb/usbroothub_subr.h> 75 1.1 bouyer 76 1.1 bouyer #define MOTG_DEBUG 77 1.1 bouyer #ifdef MOTG_DEBUG 78 1.1 bouyer #define DPRINTF(x) if (motgdebug) printf x 79 1.1 bouyer #define DPRINTFN(n,x) if (motgdebug & (n)) printf x 80 1.1 bouyer #define MD_ROOT 0x0002 81 1.1 bouyer #define MD_CTRL 0x0004 82 1.1 bouyer #define MD_BULK 0x0008 83 1.1 bouyer // int motgdebug = MD_ROOT | MD_CTRL | MD_BULK; 84 1.1 bouyer int motgdebug = 0; 85 1.1 bouyer #else 86 1.1 bouyer #define DPRINTF(x) 87 1.1 bouyer #define DPRINTFN(n,x) 88 1.1 bouyer #endif 89 1.1 bouyer 90 1.1 bouyer /* various timeouts, for various speeds */ 91 1.1 bouyer /* control NAK timeouts */ 92 1.1 bouyer #define NAK_TO_CTRL 10 /* 1024 frames, about 1s */ 93 1.1 bouyer #define NAK_TO_CTRL_HIGH 13 /* 8k microframes, about 0.8s */ 94 1.1 bouyer 95 1.1 bouyer /* intr/iso polling intervals */ 96 1.1 bouyer #define POLL_TO 100 /* 100 frames, about 0.1s */ 97 1.1 bouyer #define POLL_TO_HIGH 10 /* 100 microframes, about 0.12s */ 98 1.1 bouyer 99 1.1 bouyer /* bulk NAK timeouts */ 100 1.3 bouyer #define NAK_TO_BULK 0 /* disabled */ 101 1.3 bouyer #define NAK_TO_BULK_HIGH 0 102 1.1 bouyer 103 1.1 bouyer static void motg_hub_change(struct motg_softc *); 104 1.1 bouyer static usbd_status motg_root_ctrl_transfer(usbd_xfer_handle); 105 1.1 bouyer static usbd_status motg_root_ctrl_start(usbd_xfer_handle); 106 1.1 bouyer static void motg_root_ctrl_abort(usbd_xfer_handle); 107 1.1 bouyer static void motg_root_ctrl_close(usbd_pipe_handle); 108 1.1 bouyer static void motg_root_ctrl_done(usbd_xfer_handle); 109 1.1 bouyer 110 1.1 bouyer static usbd_status motg_root_intr_transfer(usbd_xfer_handle); 111 1.1 bouyer static usbd_status motg_root_intr_start(usbd_xfer_handle); 112 1.1 bouyer static void motg_root_intr_abort(usbd_xfer_handle); 113 1.1 bouyer static void motg_root_intr_close(usbd_pipe_handle); 114 1.1 bouyer static void motg_root_intr_done(usbd_xfer_handle); 115 1.1 bouyer 116 1.1 bouyer static usbd_status motg_open(usbd_pipe_handle); 117 1.1 bouyer static void motg_poll(struct usbd_bus *); 118 1.1 bouyer static void motg_softintr(void *); 119 1.12.2.1 skrll static usbd_status motg_allocm(struct usbd_bus *, usb_dma_t *, uint32_t); 120 1.1 bouyer static void motg_freem(struct usbd_bus *, usb_dma_t *); 121 1.1 bouyer static usbd_xfer_handle motg_allocx(struct usbd_bus *); 122 1.1 bouyer static void motg_freex(struct usbd_bus *, usbd_xfer_handle); 123 1.1 bouyer static void motg_get_lock(struct usbd_bus *, kmutex_t **); 124 1.1 bouyer static void motg_noop(usbd_pipe_handle pipe); 125 1.1 bouyer static usbd_status motg_portreset(struct motg_softc*); 126 1.1 bouyer 127 1.1 bouyer static usbd_status motg_device_ctrl_transfer(usbd_xfer_handle); 128 1.1 bouyer static usbd_status motg_device_ctrl_start(usbd_xfer_handle); 129 1.1 bouyer static void motg_device_ctrl_abort(usbd_xfer_handle); 130 1.1 bouyer static void motg_device_ctrl_close(usbd_pipe_handle); 131 1.1 bouyer static void motg_device_ctrl_done(usbd_xfer_handle); 132 1.1 bouyer static usbd_status motg_device_ctrl_start1(struct motg_softc *); 133 1.1 bouyer static void motg_device_ctrl_read(usbd_xfer_handle); 134 1.1 bouyer static void motg_device_ctrl_intr_rx(struct motg_softc *); 135 1.1 bouyer static void motg_device_ctrl_intr_tx(struct motg_softc *); 136 1.1 bouyer 137 1.1 bouyer static usbd_status motg_device_data_transfer(usbd_xfer_handle); 138 1.1 bouyer static usbd_status motg_device_data_start(usbd_xfer_handle); 139 1.1 bouyer static usbd_status motg_device_data_start1(struct motg_softc *, 140 1.1 bouyer struct motg_hw_ep *); 141 1.1 bouyer static void motg_device_data_abort(usbd_xfer_handle); 142 1.1 bouyer static void motg_device_data_close(usbd_pipe_handle); 143 1.1 bouyer static void motg_device_data_done(usbd_xfer_handle); 144 1.1 bouyer static void motg_device_intr_rx(struct motg_softc *, int); 145 1.1 bouyer static void motg_device_intr_tx(struct motg_softc *, int); 146 1.1 bouyer static void motg_device_data_read(usbd_xfer_handle); 147 1.1 bouyer static void motg_device_data_write(usbd_xfer_handle); 148 1.1 bouyer 149 1.1 bouyer static void motg_waitintr(struct motg_softc *, usbd_xfer_handle); 150 1.3 bouyer static void motg_device_clear_toggle(usbd_pipe_handle); 151 1.3 bouyer static void motg_device_xfer_abort(usbd_xfer_handle); 152 1.1 bouyer 153 1.1 bouyer #define MOTG_INTR_ENDPT 1 154 1.1 bouyer #define UBARR(sc) bus_space_barrier((sc)->sc_iot, (sc)->sc_ioh, 0, (sc)->sc_size, \ 155 1.1 bouyer BUS_SPACE_BARRIER_READ|BUS_SPACE_BARRIER_WRITE) 156 1.1 bouyer #define UWRITE1(sc, r, x) \ 157 1.1 bouyer do { UBARR(sc); bus_space_write_1((sc)->sc_iot, (sc)->sc_ioh, (r), (x)); \ 158 1.1 bouyer } while (/*CONSTCOND*/0) 159 1.1 bouyer #define UWRITE2(sc, r, x) \ 160 1.1 bouyer do { UBARR(sc); bus_space_write_2((sc)->sc_iot, (sc)->sc_ioh, (r), (x)); \ 161 1.1 bouyer } while (/*CONSTCOND*/0) 162 1.1 bouyer #define UWRITE4(sc, r, x) \ 163 1.1 bouyer do { UBARR(sc); bus_space_write_4((sc)->sc_iot, (sc)->sc_ioh, (r), (x)); \ 164 1.1 bouyer } while (/*CONSTCOND*/0) 165 1.1 bouyer 166 1.1 bouyer static __inline uint32_t 167 1.1 bouyer UREAD1(struct motg_softc *sc, bus_size_t r) 168 1.1 bouyer { 169 1.1 bouyer 170 1.1 bouyer UBARR(sc); 171 1.1 bouyer return bus_space_read_1(sc->sc_iot, sc->sc_ioh, r); 172 1.1 bouyer } 173 1.1 bouyer static __inline uint32_t 174 1.1 bouyer UREAD2(struct motg_softc *sc, bus_size_t r) 175 1.1 bouyer { 176 1.1 bouyer 177 1.1 bouyer UBARR(sc); 178 1.1 bouyer return bus_space_read_2(sc->sc_iot, sc->sc_ioh, r); 179 1.1 bouyer } 180 1.4 joerg 181 1.4 joerg #if 0 182 1.1 bouyer static __inline uint32_t 183 1.1 bouyer UREAD4(struct motg_softc *sc, bus_size_t r) 184 1.1 bouyer { 185 1.1 bouyer 186 1.1 bouyer UBARR(sc); 187 1.1 bouyer return bus_space_read_4(sc->sc_iot, sc->sc_ioh, r); 188 1.1 bouyer } 189 1.4 joerg #endif 190 1.1 bouyer 191 1.1 bouyer static void 192 1.7 skrll musbotg_pull_common(struct motg_softc *sc, uint8_t on) 193 1.1 bouyer { 194 1.12.2.2 skrll uint8_t val; 195 1.1 bouyer 196 1.12.2.2 skrll val = UREAD1(sc, MUSB2_REG_POWER); 197 1.12.2.2 skrll if (on) 198 1.12.2.2 skrll val |= MUSB2_MASK_SOFTC; 199 1.12.2.2 skrll else 200 1.12.2.2 skrll val &= ~MUSB2_MASK_SOFTC; 201 1.1 bouyer 202 1.12.2.2 skrll UWRITE1(sc, MUSB2_REG_POWER, val); 203 1.1 bouyer } 204 1.1 bouyer 205 1.1 bouyer const struct usbd_bus_methods motg_bus_methods = { 206 1.12.2.4 skrll .ubm_open = motg_open, 207 1.12.2.4 skrll .ubm_softint = motg_softintr, 208 1.12.2.4 skrll .ubm_dopoll = motg_poll, 209 1.12.2.4 skrll .ubm_allocm = motg_allocm, 210 1.12.2.4 skrll .ubm_freem = motg_freem, 211 1.12.2.4 skrll .ubm_allocx = motg_allocx, 212 1.12.2.4 skrll .ubm_freex = motg_freex, 213 1.12.2.4 skrll .ubm_getlock = motg_get_lock, 214 1.12.2.4 skrll .ubm_newdev = NULL, 215 1.1 bouyer }; 216 1.1 bouyer 217 1.1 bouyer const struct usbd_pipe_methods motg_root_ctrl_methods = { 218 1.12.2.4 skrll .upm_transfer = motg_root_ctrl_transfer, 219 1.12.2.4 skrll .upm_start = motg_root_ctrl_start, 220 1.12.2.4 skrll .upm_abort = motg_root_ctrl_abort, 221 1.12.2.4 skrll .upm_close = motg_root_ctrl_close, 222 1.12.2.4 skrll .upm_cleartoggle = motg_noop, 223 1.12.2.4 skrll .upm_done = motg_root_ctrl_done, 224 1.1 bouyer }; 225 1.1 bouyer 226 1.1 bouyer const struct usbd_pipe_methods motg_root_intr_methods = { 227 1.12.2.4 skrll .upm_transfer = motg_root_intr_transfer, 228 1.12.2.4 skrll .upm_start = motg_root_intr_start, 229 1.12.2.4 skrll .upm_abort = motg_root_intr_abort, 230 1.12.2.4 skrll .upm_close = motg_root_intr_close, 231 1.12.2.4 skrll .upm_cleartoggle = motg_noop, 232 1.12.2.4 skrll .upm_done = motg_root_intr_done, 233 1.1 bouyer }; 234 1.1 bouyer 235 1.1 bouyer const struct usbd_pipe_methods motg_device_ctrl_methods = { 236 1.12.2.4 skrll .upm_transfer = motg_device_ctrl_transfer, 237 1.12.2.4 skrll .upm_start = motg_device_ctrl_start, 238 1.12.2.4 skrll .upm_abort = motg_device_ctrl_abort, 239 1.12.2.4 skrll .upm_close = motg_device_ctrl_close, 240 1.12.2.4 skrll .upm_cleartoggle = motg_noop, 241 1.12.2.4 skrll .upm_done = motg_device_ctrl_done, 242 1.1 bouyer }; 243 1.1 bouyer 244 1.1 bouyer const struct usbd_pipe_methods motg_device_data_methods = { 245 1.12.2.4 skrll .upm_transfer = motg_device_data_transfer, 246 1.12.2.4 skrll .upm_start = motg_device_data_start, 247 1.12.2.4 skrll .upm_abort = motg_device_data_abort, 248 1.12.2.4 skrll .upm_close = motg_device_data_close, 249 1.12.2.4 skrll .upm_cleartoggle = motg_device_clear_toggle, 250 1.12.2.4 skrll .upm_done = motg_device_data_done, 251 1.1 bouyer }; 252 1.1 bouyer 253 1.1 bouyer usbd_status 254 1.1 bouyer motg_init(struct motg_softc *sc) 255 1.1 bouyer { 256 1.1 bouyer uint32_t nrx, ntx, val; 257 1.1 bouyer int dynfifo; 258 1.1 bouyer int offset, i; 259 1.1 bouyer 260 1.1 bouyer if (sc->sc_mode == MOTG_MODE_DEVICE) 261 1.1 bouyer return USBD_NORMAL_COMPLETION; /* not supported */ 262 1.1 bouyer 263 1.1 bouyer /* disable all interrupts */ 264 1.1 bouyer UWRITE1(sc, MUSB2_REG_INTUSBE, 0); 265 1.1 bouyer UWRITE2(sc, MUSB2_REG_INTTXE, 0); 266 1.1 bouyer UWRITE2(sc, MUSB2_REG_INTRXE, 0); 267 1.1 bouyer /* disable pullup */ 268 1.1 bouyer 269 1.7 skrll musbotg_pull_common(sc, 0); 270 1.1 bouyer 271 1.10 jmcneill #ifdef MUSB2_REG_RXDBDIS 272 1.1 bouyer /* disable double packet buffering XXX what's this ? */ 273 1.1 bouyer UWRITE2(sc, MUSB2_REG_RXDBDIS, 0xFFFF); 274 1.1 bouyer UWRITE2(sc, MUSB2_REG_TXDBDIS, 0xFFFF); 275 1.10 jmcneill #endif 276 1.1 bouyer 277 1.1 bouyer /* enable HighSpeed and ISO Update flags */ 278 1.1 bouyer 279 1.1 bouyer UWRITE1(sc, MUSB2_REG_POWER, 280 1.1 bouyer MUSB2_MASK_HSENAB | MUSB2_MASK_ISOUPD); 281 1.1 bouyer 282 1.1 bouyer if (sc->sc_mode == MOTG_MODE_DEVICE) { 283 1.1 bouyer /* clear Session bit, if set */ 284 1.1 bouyer val = UREAD1(sc, MUSB2_REG_DEVCTL); 285 1.1 bouyer val &= ~MUSB2_MASK_SESS; 286 1.1 bouyer UWRITE1(sc, MUSB2_REG_DEVCTL, val); 287 1.1 bouyer } else { 288 1.1 bouyer /* Enter session for Host mode */ 289 1.1 bouyer val = UREAD1(sc, MUSB2_REG_DEVCTL); 290 1.1 bouyer val |= MUSB2_MASK_SESS; 291 1.1 bouyer UWRITE1(sc, MUSB2_REG_DEVCTL, val); 292 1.1 bouyer } 293 1.1 bouyer delay(1000); 294 1.1 bouyer DPRINTF(("DEVCTL 0x%x\n", UREAD1(sc, MUSB2_REG_DEVCTL))); 295 1.1 bouyer 296 1.1 bouyer /* disable testmode */ 297 1.1 bouyer 298 1.1 bouyer UWRITE1(sc, MUSB2_REG_TESTMODE, 0); 299 1.1 bouyer 300 1.10 jmcneill #ifdef MUSB2_REG_MISC 301 1.7 skrll /* set default value */ 302 1.1 bouyer 303 1.1 bouyer UWRITE1(sc, MUSB2_REG_MISC, 0); 304 1.10 jmcneill #endif 305 1.1 bouyer 306 1.7 skrll /* select endpoint index 0 */ 307 1.1 bouyer 308 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, 0); 309 1.1 bouyer 310 1.9 jmcneill if (sc->sc_ep_max == 0) { 311 1.9 jmcneill /* read out number of endpoints */ 312 1.9 jmcneill nrx = (UREAD1(sc, MUSB2_REG_EPINFO) / 16); 313 1.1 bouyer 314 1.9 jmcneill ntx = (UREAD1(sc, MUSB2_REG_EPINFO) % 16); 315 1.1 bouyer 316 1.9 jmcneill /* these numbers exclude the control endpoint */ 317 1.1 bouyer 318 1.9 jmcneill DPRINTF(("RX/TX endpoints: %u/%u\n", nrx, ntx)); 319 1.1 bouyer 320 1.9 jmcneill sc->sc_ep_max = MAX(nrx, ntx); 321 1.9 jmcneill } else { 322 1.9 jmcneill nrx = ntx = sc->sc_ep_max; 323 1.9 jmcneill } 324 1.1 bouyer if (sc->sc_ep_max == 0) { 325 1.1 bouyer aprint_error_dev(sc->sc_dev, " no endpoints\n"); 326 1.1 bouyer return USBD_INVAL; 327 1.1 bouyer } 328 1.1 bouyer KASSERT(sc->sc_ep_max <= MOTG_MAX_HW_EP); 329 1.1 bouyer /* read out configuration data */ 330 1.1 bouyer val = UREAD1(sc, MUSB2_REG_CONFDATA); 331 1.1 bouyer 332 1.1 bouyer DPRINTF(("Config Data: 0x%02x\n", val)); 333 1.1 bouyer 334 1.1 bouyer dynfifo = (val & MUSB2_MASK_CD_DYNFIFOSZ) ? 1 : 0; 335 1.1 bouyer 336 1.7 skrll if (dynfifo) { 337 1.1 bouyer aprint_normal_dev(sc->sc_dev, "Dynamic FIFO sizing detected, " 338 1.1 bouyer "assuming 16Kbytes of FIFO RAM\n"); 339 1.7 skrll } 340 1.7 skrll 341 1.1 bouyer DPRINTF(("HW version: 0x%04x\n", UREAD1(sc, MUSB2_REG_HWVERS))); 342 1.1 bouyer 343 1.1 bouyer /* initialise endpoint profiles */ 344 1.1 bouyer sc->sc_in_ep[0].ep_fifo_size = 64; 345 1.1 bouyer sc->sc_out_ep[0].ep_fifo_size = 0; /* not used */ 346 1.1 bouyer sc->sc_out_ep[0].ep_number = sc->sc_in_ep[0].ep_number = 0; 347 1.1 bouyer SIMPLEQ_INIT(&sc->sc_in_ep[0].ep_pipes); 348 1.1 bouyer offset = 64; 349 1.1 bouyer 350 1.1 bouyer for (i = 1; i <= sc->sc_ep_max; i++) { 351 1.1 bouyer int fiforx_size, fifotx_size, fifo_size; 352 1.1 bouyer 353 1.7 skrll /* select endpoint */ 354 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, i); 355 1.1 bouyer 356 1.11 jmcneill if (sc->sc_ep_fifosize) { 357 1.11 jmcneill fiforx_size = fifotx_size = sc->sc_ep_fifosize; 358 1.11 jmcneill } else { 359 1.11 jmcneill val = UREAD1(sc, MUSB2_REG_FSIZE); 360 1.11 jmcneill fiforx_size = (val & MUSB2_MASK_RX_FSIZE) >> 4; 361 1.11 jmcneill fifotx_size = (val & MUSB2_MASK_TX_FSIZE); 362 1.11 jmcneill } 363 1.1 bouyer 364 1.1 bouyer DPRINTF(("Endpoint %u FIFO size: IN=%u, OUT=%u, DYN=%d\n", 365 1.1 bouyer i, fifotx_size, fiforx_size, dynfifo)); 366 1.1 bouyer 367 1.1 bouyer if (dynfifo) { 368 1.12 jmcneill if (sc->sc_ep_fifosize) { 369 1.12 jmcneill fifo_size = ffs(sc->sc_ep_fifosize) - 1; 370 1.1 bouyer } else { 371 1.12 jmcneill if (i < 3) { 372 1.12 jmcneill fifo_size = 12; /* 4K */ 373 1.12 jmcneill } else if (i < 10) { 374 1.12 jmcneill fifo_size = 10; /* 1K */ 375 1.12 jmcneill } else { 376 1.12 jmcneill fifo_size = 7; /* 128 bytes */ 377 1.12 jmcneill } 378 1.7 skrll } 379 1.1 bouyer if (fiforx_size && (i <= nrx)) { 380 1.1 bouyer fiforx_size = fifo_size; 381 1.1 bouyer if (fifo_size > 7) { 382 1.3 bouyer #if 0 383 1.7 skrll UWRITE1(sc, MUSB2_REG_RXFIFOSZ, 384 1.1 bouyer MUSB2_VAL_FIFOSZ(fifo_size) | 385 1.1 bouyer MUSB2_MASK_FIFODB); 386 1.3 bouyer #else 387 1.7 skrll UWRITE1(sc, MUSB2_REG_RXFIFOSZ, 388 1.3 bouyer MUSB2_VAL_FIFOSZ(fifo_size)); 389 1.3 bouyer #endif 390 1.1 bouyer } else { 391 1.7 skrll UWRITE1(sc, MUSB2_REG_RXFIFOSZ, 392 1.3 bouyer MUSB2_VAL_FIFOSZ(fifo_size)); 393 1.1 bouyer } 394 1.7 skrll UWRITE2(sc, MUSB2_REG_RXFIFOADD, 395 1.1 bouyer offset >> 3); 396 1.1 bouyer offset += (1 << fiforx_size); 397 1.1 bouyer } 398 1.1 bouyer if (fifotx_size && (i <= ntx)) { 399 1.1 bouyer fifotx_size = fifo_size; 400 1.1 bouyer if (fifo_size > 7) { 401 1.3 bouyer #if 0 402 1.7 skrll UWRITE1(sc, MUSB2_REG_TXFIFOSZ, 403 1.7 skrll MUSB2_VAL_FIFOSZ(fifo_size) | 404 1.1 bouyer MUSB2_MASK_FIFODB); 405 1.3 bouyer #else 406 1.7 skrll UWRITE1(sc, MUSB2_REG_TXFIFOSZ, 407 1.7 skrll MUSB2_VAL_FIFOSZ(fifo_size)); 408 1.3 bouyer #endif 409 1.1 bouyer } else { 410 1.7 skrll UWRITE1(sc, MUSB2_REG_TXFIFOSZ, 411 1.7 skrll MUSB2_VAL_FIFOSZ(fifo_size)); 412 1.7 skrll } 413 1.7 skrll 414 1.7 skrll UWRITE2(sc, MUSB2_REG_TXFIFOADD, 415 1.1 bouyer offset >> 3); 416 1.7 skrll 417 1.1 bouyer offset += (1 << fifotx_size); 418 1.1 bouyer } 419 1.1 bouyer } 420 1.1 bouyer if (fiforx_size && (i <= nrx)) { 421 1.1 bouyer sc->sc_in_ep[i].ep_fifo_size = (1 << fiforx_size); 422 1.1 bouyer SIMPLEQ_INIT(&sc->sc_in_ep[i].ep_pipes); 423 1.1 bouyer } 424 1.1 bouyer if (fifotx_size && (i <= ntx)) { 425 1.1 bouyer sc->sc_out_ep[i].ep_fifo_size = (1 << fifotx_size); 426 1.1 bouyer SIMPLEQ_INIT(&sc->sc_out_ep[i].ep_pipes); 427 1.1 bouyer } 428 1.1 bouyer sc->sc_out_ep[i].ep_number = sc->sc_in_ep[i].ep_number = i; 429 1.1 bouyer } 430 1.1 bouyer 431 1.7 skrll 432 1.1 bouyer DPRINTF(("Dynamic FIFO size = %d bytes\n", offset)); 433 1.1 bouyer 434 1.1 bouyer /* turn on default interrupts */ 435 1.1 bouyer 436 1.1 bouyer if (sc->sc_mode == MOTG_MODE_HOST) { 437 1.1 bouyer UWRITE1(sc, MUSB2_REG_INTUSBE, 0xff); 438 1.1 bouyer UWRITE2(sc, MUSB2_REG_INTTXE, 0xffff); 439 1.1 bouyer UWRITE2(sc, MUSB2_REG_INTRXE, 0xffff); 440 1.1 bouyer } else 441 1.1 bouyer UWRITE1(sc, MUSB2_REG_INTUSBE, MUSB2_MASK_IRESET); 442 1.1 bouyer 443 1.1 bouyer sc->sc_xferpool = pool_cache_init(sizeof(struct motg_xfer), 0, 0, 0, 444 1.1 bouyer "motgxfer", NULL, IPL_USB, NULL, NULL, NULL); 445 1.1 bouyer 446 1.1 bouyer mutex_init(&sc->sc_lock, MUTEX_DEFAULT, IPL_SOFTUSB); 447 1.1 bouyer mutex_init(&sc->sc_intr_lock, MUTEX_DEFAULT, IPL_SCHED); 448 1.1 bouyer 449 1.1 bouyer /* Set up the bus struct. */ 450 1.1 bouyer sc->sc_bus.methods = &motg_bus_methods; 451 1.1 bouyer sc->sc_bus.pipe_size = sizeof(struct motg_pipe); 452 1.1 bouyer sc->sc_bus.usbrev = USBREV_2_0; 453 1.1 bouyer sc->sc_bus.hci_private = sc; 454 1.1 bouyer snprintf(sc->sc_vendor, sizeof(sc->sc_vendor), 455 1.1 bouyer "Mentor Graphics"); 456 1.1 bouyer sc->sc_child = config_found(sc->sc_dev, &sc->sc_bus, usbctlprint); 457 1.1 bouyer return USBD_NORMAL_COMPLETION; 458 1.1 bouyer } 459 1.1 bouyer 460 1.1 bouyer static int 461 1.1 bouyer motg_select_ep(struct motg_softc *sc, usbd_pipe_handle pipe) 462 1.1 bouyer { 463 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)pipe; 464 1.1 bouyer usb_endpoint_descriptor_t *ed = pipe->endpoint->edesc; 465 1.1 bouyer struct motg_hw_ep *ep; 466 1.1 bouyer int i, size; 467 1.1 bouyer 468 1.1 bouyer ep = (UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN) ? 469 1.1 bouyer sc->sc_in_ep : sc->sc_out_ep; 470 1.1 bouyer size = UE_GET_SIZE(UGETW(pipe->endpoint->edesc->wMaxPacketSize)); 471 1.1 bouyer 472 1.1 bouyer for (i = sc->sc_ep_max; i >= 1; i--) { 473 1.1 bouyer DPRINTF(("%s_ep[%d].ep_fifo_size %d size %d ref %d\n", 474 1.1 bouyer (UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN) ? 475 1.1 bouyer "in" : "out", i, ep[i].ep_fifo_size, size, ep[i].refcount)); 476 1.1 bouyer if (ep[i].ep_fifo_size >= size) { 477 1.1 bouyer /* found a suitable endpoint */ 478 1.1 bouyer otgpipe->hw_ep = &ep[i]; 479 1.1 bouyer mutex_enter(&sc->sc_lock); 480 1.1 bouyer if (otgpipe->hw_ep->refcount > 0) { 481 1.1 bouyer /* no luck, try next */ 482 1.1 bouyer mutex_exit(&sc->sc_lock); 483 1.1 bouyer otgpipe->hw_ep = NULL; 484 1.1 bouyer } else { 485 1.1 bouyer otgpipe->hw_ep->refcount++; 486 1.1 bouyer SIMPLEQ_INSERT_TAIL(&otgpipe->hw_ep->ep_pipes, 487 1.1 bouyer otgpipe, ep_pipe_list); 488 1.1 bouyer mutex_exit(&sc->sc_lock); 489 1.1 bouyer return 0; 490 1.1 bouyer } 491 1.1 bouyer } 492 1.1 bouyer } 493 1.1 bouyer return -1; 494 1.1 bouyer } 495 1.1 bouyer 496 1.1 bouyer /* Open a new pipe. */ 497 1.1 bouyer usbd_status 498 1.1 bouyer motg_open(usbd_pipe_handle pipe) 499 1.1 bouyer { 500 1.1 bouyer struct motg_softc *sc = pipe->device->bus->hci_private; 501 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)pipe; 502 1.1 bouyer usb_endpoint_descriptor_t *ed = pipe->endpoint->edesc; 503 1.1 bouyer 504 1.1 bouyer DPRINTF(("motg_open: pipe=%p, addr=%d, endpt=%d (%d)\n", 505 1.1 bouyer pipe, pipe->device->address, 506 1.1 bouyer ed->bEndpointAddress, sc->sc_root_addr)); 507 1.1 bouyer 508 1.1 bouyer if (sc->sc_dying) 509 1.1 bouyer return USBD_IOERROR; 510 1.1 bouyer 511 1.1 bouyer /* toggle state needed for bulk endpoints */ 512 1.1 bouyer otgpipe->nexttoggle = pipe->endpoint->datatoggle; 513 1.1 bouyer 514 1.1 bouyer if (pipe->device->address == sc->sc_root_addr) { 515 1.1 bouyer switch (ed->bEndpointAddress) { 516 1.1 bouyer case USB_CONTROL_ENDPOINT: 517 1.1 bouyer pipe->methods = &motg_root_ctrl_methods; 518 1.1 bouyer break; 519 1.1 bouyer case UE_DIR_IN | MOTG_INTR_ENDPT: 520 1.1 bouyer pipe->methods = &motg_root_intr_methods; 521 1.1 bouyer break; 522 1.1 bouyer default: 523 1.1 bouyer return (USBD_INVAL); 524 1.1 bouyer } 525 1.1 bouyer } else { 526 1.1 bouyer switch (ed->bmAttributes & UE_XFERTYPE) { 527 1.1 bouyer case UE_CONTROL: 528 1.1 bouyer pipe->methods = &motg_device_ctrl_methods; 529 1.1 bouyer /* always use sc_in_ep[0] for in and out */ 530 1.1 bouyer otgpipe->hw_ep = &sc->sc_in_ep[0]; 531 1.1 bouyer mutex_enter(&sc->sc_lock); 532 1.1 bouyer otgpipe->hw_ep->refcount++; 533 1.1 bouyer SIMPLEQ_INSERT_TAIL(&otgpipe->hw_ep->ep_pipes, 534 1.1 bouyer otgpipe, ep_pipe_list); 535 1.1 bouyer mutex_exit(&sc->sc_lock); 536 1.1 bouyer break; 537 1.1 bouyer case UE_BULK: 538 1.1 bouyer case UE_INTERRUPT: 539 1.7 skrll DPRINTFN(MD_BULK, 540 1.1 bouyer ("new %s %s pipe wMaxPacketSize %d\n", 541 1.1 bouyer (ed->bmAttributes & UE_XFERTYPE) == UE_BULK ? 542 1.1 bouyer "bulk" : "interrupt", 543 1.1 bouyer (UE_GET_DIR(pipe->endpoint->edesc->bEndpointAddress) == UE_DIR_IN) ? "read" : "write", 544 1.1 bouyer UGETW(pipe->endpoint->edesc->wMaxPacketSize))); 545 1.1 bouyer if (motg_select_ep(sc, pipe) != 0) 546 1.1 bouyer goto bad; 547 1.1 bouyer KASSERT(otgpipe->hw_ep != NULL); 548 1.1 bouyer pipe->methods = &motg_device_data_methods; 549 1.1 bouyer otgpipe->nexttoggle = pipe->endpoint->datatoggle; 550 1.1 bouyer break; 551 1.1 bouyer default: 552 1.1 bouyer goto bad; 553 1.1 bouyer #ifdef notyet 554 1.1 bouyer case UE_ISOCHRONOUS: 555 1.1 bouyer ... 556 1.1 bouyer break; 557 1.1 bouyer #endif /* notyet */ 558 1.1 bouyer } 559 1.1 bouyer } 560 1.1 bouyer return (USBD_NORMAL_COMPLETION); 561 1.1 bouyer 562 1.1 bouyer bad: 563 1.1 bouyer return (USBD_NOMEM); 564 1.1 bouyer } 565 1.1 bouyer 566 1.1 bouyer void 567 1.1 bouyer motg_softintr(void *v) 568 1.1 bouyer { 569 1.1 bouyer struct usbd_bus *bus = v; 570 1.1 bouyer struct motg_softc *sc = bus->hci_private; 571 1.1 bouyer uint16_t rx_status, tx_status; 572 1.1 bouyer uint8_t ctrl_status; 573 1.1 bouyer uint32_t val; 574 1.1 bouyer int i; 575 1.1 bouyer 576 1.1 bouyer KASSERT(sc->sc_bus.use_polling || mutex_owned(&sc->sc_lock)); 577 1.1 bouyer 578 1.1 bouyer DPRINTFN(MD_ROOT | MD_CTRL, 579 1.1 bouyer ("%s: motg_softintr\n", device_xname(sc->sc_dev))); 580 1.1 bouyer 581 1.1 bouyer mutex_spin_enter(&sc->sc_intr_lock); 582 1.1 bouyer rx_status = sc->sc_intr_rx_ep; 583 1.1 bouyer sc->sc_intr_rx_ep = 0; 584 1.1 bouyer tx_status = sc->sc_intr_tx_ep; 585 1.1 bouyer sc->sc_intr_tx_ep = 0; 586 1.1 bouyer ctrl_status = sc->sc_intr_ctrl; 587 1.1 bouyer sc->sc_intr_ctrl = 0; 588 1.1 bouyer mutex_spin_exit(&sc->sc_intr_lock); 589 1.1 bouyer 590 1.1 bouyer ctrl_status |= UREAD1(sc, MUSB2_REG_INTUSB); 591 1.1 bouyer 592 1.1 bouyer if (ctrl_status & (MUSB2_MASK_IRESET | 593 1.1 bouyer MUSB2_MASK_IRESUME | MUSB2_MASK_ISUSP | 594 1.1 bouyer MUSB2_MASK_ICONN | MUSB2_MASK_IDISC)) { 595 1.1 bouyer DPRINTFN(MD_ROOT | MD_CTRL, ("motg_softintr bus 0x%x\n", 596 1.1 bouyer ctrl_status)); 597 1.1 bouyer 598 1.1 bouyer if (ctrl_status & MUSB2_MASK_IRESET) { 599 1.1 bouyer sc->sc_isreset = 1; 600 1.1 bouyer sc->sc_port_suspended = 0; 601 1.1 bouyer sc->sc_port_suspended_change = 1; 602 1.1 bouyer sc->sc_connected_changed = 1; 603 1.1 bouyer sc->sc_port_enabled = 1; 604 1.1 bouyer 605 1.1 bouyer val = UREAD1(sc, MUSB2_REG_POWER); 606 1.1 bouyer if (val & MUSB2_MASK_HSMODE) 607 1.1 bouyer sc->sc_high_speed = 1; 608 1.1 bouyer else 609 1.1 bouyer sc->sc_high_speed = 0; 610 1.1 bouyer DPRINTFN(MD_ROOT | MD_CTRL, ("motg_softintr speed %d\n", 611 1.1 bouyer sc->sc_high_speed)); 612 1.1 bouyer 613 1.1 bouyer /* turn off interrupts */ 614 1.1 bouyer val = MUSB2_MASK_IRESET; 615 1.1 bouyer val &= ~MUSB2_MASK_IRESUME; 616 1.1 bouyer val |= MUSB2_MASK_ISUSP; 617 1.1 bouyer UWRITE1(sc, MUSB2_REG_INTUSBE, val); 618 1.1 bouyer UWRITE2(sc, MUSB2_REG_INTTXE, 0); 619 1.1 bouyer UWRITE2(sc, MUSB2_REG_INTRXE, 0); 620 1.1 bouyer } 621 1.1 bouyer if (ctrl_status & MUSB2_MASK_IRESUME) { 622 1.1 bouyer if (sc->sc_port_suspended) { 623 1.1 bouyer sc->sc_port_suspended = 0; 624 1.1 bouyer sc->sc_port_suspended_change = 1; 625 1.1 bouyer val = UREAD1(sc, MUSB2_REG_INTUSBE); 626 1.1 bouyer /* disable resume interrupt */ 627 1.1 bouyer val &= ~MUSB2_MASK_IRESUME; 628 1.1 bouyer /* enable suspend interrupt */ 629 1.1 bouyer val |= MUSB2_MASK_ISUSP; 630 1.1 bouyer UWRITE1(sc, MUSB2_REG_INTUSBE, val); 631 1.1 bouyer } 632 1.1 bouyer } else if (ctrl_status & MUSB2_MASK_ISUSP) { 633 1.1 bouyer if (!sc->sc_port_suspended) { 634 1.1 bouyer sc->sc_port_suspended = 1; 635 1.1 bouyer sc->sc_port_suspended_change = 1; 636 1.1 bouyer 637 1.1 bouyer val = UREAD1(sc, MUSB2_REG_INTUSBE); 638 1.1 bouyer /* disable suspend interrupt */ 639 1.1 bouyer val &= ~MUSB2_MASK_ISUSP; 640 1.1 bouyer /* enable resume interrupt */ 641 1.1 bouyer val |= MUSB2_MASK_IRESUME; 642 1.1 bouyer UWRITE1(sc, MUSB2_REG_INTUSBE, val); 643 1.1 bouyer } 644 1.1 bouyer } 645 1.1 bouyer if (ctrl_status & MUSB2_MASK_ICONN) { 646 1.1 bouyer sc->sc_connected = 1; 647 1.1 bouyer sc->sc_connected_changed = 1; 648 1.1 bouyer sc->sc_isreset = 1; 649 1.1 bouyer sc->sc_port_enabled = 1; 650 1.1 bouyer } else if (ctrl_status & MUSB2_MASK_IDISC) { 651 1.1 bouyer sc->sc_connected = 0; 652 1.1 bouyer sc->sc_connected_changed = 1; 653 1.1 bouyer sc->sc_isreset = 0; 654 1.1 bouyer sc->sc_port_enabled = 0; 655 1.1 bouyer } 656 1.1 bouyer 657 1.1 bouyer /* complete root HUB interrupt endpoint */ 658 1.1 bouyer 659 1.1 bouyer motg_hub_change(sc); 660 1.1 bouyer } 661 1.1 bouyer /* 662 1.1 bouyer * read in interrupt status and mix with the status we 663 1.1 bouyer * got from the wrapper 664 1.1 bouyer */ 665 1.1 bouyer rx_status |= UREAD2(sc, MUSB2_REG_INTRX); 666 1.1 bouyer tx_status |= UREAD2(sc, MUSB2_REG_INTTX); 667 1.1 bouyer 668 1.1 bouyer if (rx_status & 0x01) 669 1.10 jmcneill panic("ctrl_rx %08x", rx_status); 670 1.1 bouyer if (tx_status & 0x01) 671 1.1 bouyer motg_device_ctrl_intr_tx(sc); 672 1.1 bouyer for (i = 1; i <= sc->sc_ep_max; i++) { 673 1.1 bouyer if (rx_status & (0x01 << i)) 674 1.1 bouyer motg_device_intr_rx(sc, i); 675 1.1 bouyer if (tx_status & (0x01 << i)) 676 1.1 bouyer motg_device_intr_tx(sc, i); 677 1.1 bouyer } 678 1.1 bouyer return; 679 1.1 bouyer } 680 1.1 bouyer 681 1.1 bouyer void 682 1.1 bouyer motg_poll(struct usbd_bus *bus) 683 1.1 bouyer { 684 1.1 bouyer struct motg_softc *sc = bus->hci_private; 685 1.1 bouyer 686 1.1 bouyer sc->sc_intr_poll(sc->sc_intr_poll_arg); 687 1.1 bouyer mutex_enter(&sc->sc_lock); 688 1.1 bouyer motg_softintr(bus); 689 1.1 bouyer mutex_exit(&sc->sc_lock); 690 1.1 bouyer } 691 1.1 bouyer 692 1.1 bouyer int 693 1.1 bouyer motg_intr(struct motg_softc *sc, uint16_t rx_ep, uint16_t tx_ep, 694 1.2 bouyer uint8_t ctrl) 695 1.1 bouyer { 696 1.1 bouyer KASSERT(mutex_owned(&sc->sc_intr_lock)); 697 1.1 bouyer sc->sc_intr_tx_ep = tx_ep; 698 1.1 bouyer sc->sc_intr_rx_ep = rx_ep; 699 1.1 bouyer sc->sc_intr_ctrl = ctrl; 700 1.1 bouyer 701 1.1 bouyer if (!sc->sc_bus.use_polling) { 702 1.1 bouyer usb_schedsoftintr(&sc->sc_bus); 703 1.1 bouyer } 704 1.1 bouyer return 1; 705 1.1 bouyer } 706 1.1 bouyer 707 1.2 bouyer int 708 1.2 bouyer motg_intr_vbus(struct motg_softc *sc, int vbus) 709 1.2 bouyer { 710 1.2 bouyer uint8_t val; 711 1.2 bouyer if (sc->sc_mode == MOTG_MODE_HOST && vbus == 0) { 712 1.2 bouyer DPRINTF(("motg_intr_vbus: vbus down, try to re-enable\n")); 713 1.2 bouyer /* try to re-enter session for Host mode */ 714 1.2 bouyer val = UREAD1(sc, MUSB2_REG_DEVCTL); 715 1.2 bouyer val |= MUSB2_MASK_SESS; 716 1.2 bouyer UWRITE1(sc, MUSB2_REG_DEVCTL, val); 717 1.2 bouyer } 718 1.2 bouyer return 1; 719 1.2 bouyer } 720 1.2 bouyer 721 1.1 bouyer usbd_status 722 1.12.2.1 skrll motg_allocm(struct usbd_bus *bus, usb_dma_t *dma, uint32_t size) 723 1.1 bouyer { 724 1.1 bouyer struct motg_softc *sc = bus->hci_private; 725 1.1 bouyer usbd_status status; 726 1.1 bouyer 727 1.1 bouyer status = usb_allocmem(&sc->sc_bus, size, 0, dma); 728 1.1 bouyer if (status == USBD_NOMEM) 729 1.1 bouyer status = usb_reserve_allocm(&sc->sc_dma_reserve, dma, size); 730 1.1 bouyer return status; 731 1.1 bouyer } 732 1.1 bouyer 733 1.1 bouyer void 734 1.1 bouyer motg_freem(struct usbd_bus *bus, usb_dma_t *dma) 735 1.1 bouyer { 736 1.1 bouyer if (dma->block->flags & USB_DMA_RESERVE) { 737 1.1 bouyer usb_reserve_freem(&((struct motg_softc *)bus)->sc_dma_reserve, 738 1.1 bouyer dma); 739 1.1 bouyer return; 740 1.1 bouyer } 741 1.1 bouyer usb_freemem(&((struct motg_softc *)bus)->sc_bus, dma); 742 1.1 bouyer } 743 1.1 bouyer 744 1.1 bouyer usbd_xfer_handle 745 1.1 bouyer motg_allocx(struct usbd_bus *bus) 746 1.1 bouyer { 747 1.1 bouyer struct motg_softc *sc = bus->hci_private; 748 1.1 bouyer usbd_xfer_handle xfer; 749 1.1 bouyer 750 1.1 bouyer xfer = pool_cache_get(sc->sc_xferpool, PR_NOWAIT); 751 1.1 bouyer if (xfer != NULL) { 752 1.1 bouyer memset(xfer, 0, sizeof(struct motg_xfer)); 753 1.1 bouyer UXFER(xfer)->sc = sc; 754 1.1 bouyer #ifdef DIAGNOSTIC 755 1.1 bouyer // XXX UXFER(xfer)->iinfo.isdone = 1; 756 1.1 bouyer xfer->busy_free = XFER_BUSY; 757 1.1 bouyer #endif 758 1.1 bouyer } 759 1.1 bouyer return (xfer); 760 1.1 bouyer } 761 1.1 bouyer 762 1.1 bouyer void 763 1.1 bouyer motg_freex(struct usbd_bus *bus, usbd_xfer_handle xfer) 764 1.1 bouyer { 765 1.1 bouyer struct motg_softc *sc = bus->hci_private; 766 1.1 bouyer 767 1.1 bouyer #ifdef DIAGNOSTIC 768 1.1 bouyer if (xfer->busy_free != XFER_BUSY) { 769 1.1 bouyer printf("motg_freex: xfer=%p not busy, 0x%08x\n", xfer, 770 1.1 bouyer xfer->busy_free); 771 1.1 bouyer } 772 1.1 bouyer xfer->busy_free = XFER_FREE; 773 1.1 bouyer #endif 774 1.1 bouyer pool_cache_put(sc->sc_xferpool, xfer); 775 1.1 bouyer } 776 1.1 bouyer 777 1.1 bouyer static void 778 1.1 bouyer motg_get_lock(struct usbd_bus *bus, kmutex_t **lock) 779 1.1 bouyer { 780 1.1 bouyer struct motg_softc *sc = bus->hci_private; 781 1.1 bouyer 782 1.1 bouyer *lock = &sc->sc_lock; 783 1.1 bouyer } 784 1.1 bouyer 785 1.1 bouyer /* 786 1.1 bouyer * Data structures and routines to emulate the root hub. 787 1.1 bouyer */ 788 1.1 bouyer usb_device_descriptor_t motg_devd = { 789 1.1 bouyer USB_DEVICE_DESCRIPTOR_SIZE, 790 1.1 bouyer UDESC_DEVICE, /* type */ 791 1.1 bouyer {0x00, 0x01}, /* USB version */ 792 1.1 bouyer UDCLASS_HUB, /* class */ 793 1.1 bouyer UDSUBCLASS_HUB, /* subclass */ 794 1.1 bouyer UDPROTO_FSHUB, /* protocol */ 795 1.1 bouyer 64, /* max packet */ 796 1.1 bouyer {0},{0},{0x00,0x01}, /* device id */ 797 1.1 bouyer 1,2,0, /* string indicies */ 798 1.1 bouyer 1 /* # of configurations */ 799 1.1 bouyer }; 800 1.1 bouyer 801 1.1 bouyer const usb_config_descriptor_t motg_confd = { 802 1.1 bouyer USB_CONFIG_DESCRIPTOR_SIZE, 803 1.1 bouyer UDESC_CONFIG, 804 1.1 bouyer {USB_CONFIG_DESCRIPTOR_SIZE + 805 1.1 bouyer USB_INTERFACE_DESCRIPTOR_SIZE + 806 1.1 bouyer USB_ENDPOINT_DESCRIPTOR_SIZE}, 807 1.1 bouyer 1, 808 1.1 bouyer 1, 809 1.1 bouyer 0, 810 1.1 bouyer UC_ATTR_MBO | UC_SELF_POWERED, 811 1.1 bouyer 0 /* max power */ 812 1.1 bouyer }; 813 1.1 bouyer 814 1.1 bouyer const usb_interface_descriptor_t motg_ifcd = { 815 1.1 bouyer USB_INTERFACE_DESCRIPTOR_SIZE, 816 1.1 bouyer UDESC_INTERFACE, 817 1.1 bouyer 0, 818 1.1 bouyer 0, 819 1.1 bouyer 1, 820 1.1 bouyer UICLASS_HUB, 821 1.1 bouyer UISUBCLASS_HUB, 822 1.1 bouyer UIPROTO_FSHUB, 823 1.1 bouyer 0 824 1.1 bouyer }; 825 1.1 bouyer 826 1.1 bouyer const usb_endpoint_descriptor_t motg_endpd = { 827 1.1 bouyer USB_ENDPOINT_DESCRIPTOR_SIZE, 828 1.1 bouyer UDESC_ENDPOINT, 829 1.1 bouyer UE_DIR_IN | MOTG_INTR_ENDPT, 830 1.1 bouyer UE_INTERRUPT, 831 1.1 bouyer {8}, 832 1.1 bouyer 255 833 1.1 bouyer }; 834 1.1 bouyer 835 1.1 bouyer const usb_hub_descriptor_t motg_hubd = { 836 1.1 bouyer USB_HUB_DESCRIPTOR_SIZE, 837 1.1 bouyer UDESC_HUB, 838 1.1 bouyer 1, 839 1.1 bouyer { UHD_PWR_NO_SWITCH | UHD_OC_INDIVIDUAL, 0 }, 840 1.1 bouyer 50, /* power on to power good */ 841 1.1 bouyer 0, 842 1.1 bouyer { 0x00 }, /* port is removable */ 843 1.1 bouyer { 0 }, 844 1.1 bouyer }; 845 1.1 bouyer 846 1.1 bouyer /* 847 1.1 bouyer * Simulate a hardware hub by handling all the necessary requests. 848 1.1 bouyer */ 849 1.1 bouyer usbd_status 850 1.1 bouyer motg_root_ctrl_transfer(usbd_xfer_handle xfer) 851 1.1 bouyer { 852 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 853 1.1 bouyer usbd_status err; 854 1.1 bouyer 855 1.1 bouyer /* Insert last in queue. */ 856 1.1 bouyer mutex_enter(&sc->sc_lock); 857 1.1 bouyer err = usb_insert_transfer(xfer); 858 1.1 bouyer mutex_exit(&sc->sc_lock); 859 1.1 bouyer if (err) 860 1.1 bouyer return (err); 861 1.1 bouyer 862 1.1 bouyer /* 863 1.1 bouyer * Pipe isn't running (otherwise err would be USBD_INPROG), 864 1.1 bouyer * so start it first. 865 1.1 bouyer */ 866 1.1 bouyer return (motg_root_ctrl_start(SIMPLEQ_FIRST(&xfer->pipe->queue))); 867 1.1 bouyer } 868 1.1 bouyer 869 1.1 bouyer usbd_status 870 1.1 bouyer motg_root_ctrl_start(usbd_xfer_handle xfer) 871 1.1 bouyer { 872 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 873 1.1 bouyer usb_device_request_t *req; 874 1.1 bouyer void *buf = NULL; 875 1.1 bouyer int len, value, index, status, change, l, totlen = 0; 876 1.1 bouyer usb_port_status_t ps; 877 1.1 bouyer usbd_status err; 878 1.1 bouyer uint32_t val; 879 1.1 bouyer 880 1.1 bouyer if (sc->sc_dying) 881 1.1 bouyer return (USBD_IOERROR); 882 1.1 bouyer 883 1.1 bouyer #ifdef DIAGNOSTIC 884 1.1 bouyer if (!(xfer->rqflags & URQ_REQUEST)) 885 1.1 bouyer panic("motg_root_ctrl_start: not a request"); 886 1.1 bouyer #endif 887 1.1 bouyer req = &xfer->request; 888 1.1 bouyer 889 1.1 bouyer DPRINTFN(MD_ROOT,("motg_root_ctrl_control type=0x%02x request=%02x\n", 890 1.1 bouyer req->bmRequestType, req->bRequest)); 891 1.1 bouyer 892 1.1 bouyer len = UGETW(req->wLength); 893 1.1 bouyer value = UGETW(req->wValue); 894 1.1 bouyer index = UGETW(req->wIndex); 895 1.1 bouyer 896 1.1 bouyer if (len != 0) 897 1.1 bouyer buf = KERNADDR(&xfer->dmabuf, 0); 898 1.1 bouyer 899 1.1 bouyer #define C(x,y) ((x) | ((y) << 8)) 900 1.1 bouyer switch(C(req->bRequest, req->bmRequestType)) { 901 1.1 bouyer case C(UR_CLEAR_FEATURE, UT_WRITE_DEVICE): 902 1.1 bouyer case C(UR_CLEAR_FEATURE, UT_WRITE_INTERFACE): 903 1.1 bouyer case C(UR_CLEAR_FEATURE, UT_WRITE_ENDPOINT): 904 1.1 bouyer /* 905 1.1 bouyer * DEVICE_REMOTE_WAKEUP and ENDPOINT_HALT are no-ops 906 1.1 bouyer * for the integrated root hub. 907 1.1 bouyer */ 908 1.1 bouyer break; 909 1.1 bouyer case C(UR_GET_CONFIG, UT_READ_DEVICE): 910 1.1 bouyer if (len > 0) { 911 1.12.2.1 skrll *(uint8_t *)buf = sc->sc_root_conf; 912 1.1 bouyer totlen = 1; 913 1.1 bouyer } 914 1.1 bouyer break; 915 1.1 bouyer case C(UR_GET_DESCRIPTOR, UT_READ_DEVICE): 916 1.1 bouyer DPRINTFN(MD_ROOT,("motg_root_ctrl_control wValue=0x%04x\n", value)); 917 1.1 bouyer if (len == 0) 918 1.1 bouyer break; 919 1.1 bouyer switch(value >> 8) { 920 1.1 bouyer case UDESC_DEVICE: 921 1.1 bouyer if ((value & 0xff) != 0) { 922 1.1 bouyer err = USBD_IOERROR; 923 1.1 bouyer goto ret; 924 1.1 bouyer } 925 1.1 bouyer totlen = l = min(len, USB_DEVICE_DESCRIPTOR_SIZE); 926 1.1 bouyer USETW(motg_devd.idVendor, sc->sc_id_vendor); 927 1.1 bouyer memcpy(buf, &motg_devd, l); 928 1.1 bouyer break; 929 1.1 bouyer case UDESC_CONFIG: 930 1.1 bouyer if ((value & 0xff) != 0) { 931 1.1 bouyer err = USBD_IOERROR; 932 1.1 bouyer goto ret; 933 1.1 bouyer } 934 1.1 bouyer totlen = l = min(len, USB_CONFIG_DESCRIPTOR_SIZE); 935 1.1 bouyer memcpy(buf, &motg_confd, l); 936 1.1 bouyer buf = (char *)buf + l; 937 1.1 bouyer len -= l; 938 1.1 bouyer l = min(len, USB_INTERFACE_DESCRIPTOR_SIZE); 939 1.1 bouyer totlen += l; 940 1.1 bouyer memcpy(buf, &motg_ifcd, l); 941 1.1 bouyer buf = (char *)buf + l; 942 1.1 bouyer len -= l; 943 1.1 bouyer l = min(len, USB_ENDPOINT_DESCRIPTOR_SIZE); 944 1.1 bouyer totlen += l; 945 1.1 bouyer memcpy(buf, &motg_endpd, l); 946 1.1 bouyer break; 947 1.1 bouyer case UDESC_STRING: 948 1.1 bouyer #define sd ((usb_string_descriptor_t *)buf) 949 1.1 bouyer switch (value & 0xff) { 950 1.1 bouyer case 0: /* Language table */ 951 1.1 bouyer totlen = usb_makelangtbl(sd, len); 952 1.1 bouyer break; 953 1.1 bouyer case 1: /* Vendor */ 954 1.1 bouyer totlen = usb_makestrdesc(sd, len, 955 1.1 bouyer sc->sc_vendor); 956 1.1 bouyer break; 957 1.1 bouyer case 2: /* Product */ 958 1.1 bouyer totlen = usb_makestrdesc(sd, len, 959 1.1 bouyer "MOTG root hub"); 960 1.1 bouyer break; 961 1.1 bouyer } 962 1.1 bouyer #undef sd 963 1.1 bouyer break; 964 1.1 bouyer default: 965 1.1 bouyer err = USBD_IOERROR; 966 1.1 bouyer goto ret; 967 1.1 bouyer } 968 1.1 bouyer break; 969 1.1 bouyer case C(UR_GET_INTERFACE, UT_READ_INTERFACE): 970 1.1 bouyer if (len > 0) { 971 1.12.2.1 skrll *(uint8_t *)buf = 0; 972 1.1 bouyer totlen = 1; 973 1.1 bouyer } 974 1.1 bouyer break; 975 1.1 bouyer case C(UR_GET_STATUS, UT_READ_DEVICE): 976 1.1 bouyer if (len > 1) { 977 1.1 bouyer USETW(((usb_status_t *)buf)->wStatus,UDS_SELF_POWERED); 978 1.1 bouyer totlen = 2; 979 1.1 bouyer } 980 1.1 bouyer break; 981 1.1 bouyer case C(UR_GET_STATUS, UT_READ_INTERFACE): 982 1.1 bouyer case C(UR_GET_STATUS, UT_READ_ENDPOINT): 983 1.1 bouyer if (len > 1) { 984 1.1 bouyer USETW(((usb_status_t *)buf)->wStatus, 0); 985 1.1 bouyer totlen = 2; 986 1.1 bouyer } 987 1.1 bouyer break; 988 1.1 bouyer case C(UR_SET_ADDRESS, UT_WRITE_DEVICE): 989 1.1 bouyer if (value >= USB_MAX_DEVICES) { 990 1.1 bouyer err = USBD_IOERROR; 991 1.1 bouyer goto ret; 992 1.1 bouyer } 993 1.1 bouyer sc->sc_root_addr = value; 994 1.1 bouyer break; 995 1.1 bouyer case C(UR_SET_CONFIG, UT_WRITE_DEVICE): 996 1.1 bouyer if (value != 0 && value != 1) { 997 1.1 bouyer err = USBD_IOERROR; 998 1.1 bouyer goto ret; 999 1.1 bouyer } 1000 1.1 bouyer sc->sc_root_conf = value; 1001 1.1 bouyer break; 1002 1.1 bouyer case C(UR_SET_DESCRIPTOR, UT_WRITE_DEVICE): 1003 1.1 bouyer break; 1004 1.1 bouyer case C(UR_SET_FEATURE, UT_WRITE_DEVICE): 1005 1.1 bouyer case C(UR_SET_FEATURE, UT_WRITE_INTERFACE): 1006 1.1 bouyer case C(UR_SET_FEATURE, UT_WRITE_ENDPOINT): 1007 1.1 bouyer err = USBD_IOERROR; 1008 1.1 bouyer goto ret; 1009 1.1 bouyer case C(UR_SET_INTERFACE, UT_WRITE_INTERFACE): 1010 1.1 bouyer break; 1011 1.1 bouyer case C(UR_SYNCH_FRAME, UT_WRITE_ENDPOINT): 1012 1.1 bouyer break; 1013 1.1 bouyer /* Hub requests */ 1014 1.1 bouyer case C(UR_CLEAR_FEATURE, UT_WRITE_CLASS_DEVICE): 1015 1.1 bouyer break; 1016 1.1 bouyer case C(UR_CLEAR_FEATURE, UT_WRITE_CLASS_OTHER): 1017 1.1 bouyer DPRINTFN(MD_ROOT, 1018 1.1 bouyer ("motg_root_ctrl_control: UR_CLEAR_PORT_FEATURE " 1019 1.1 bouyer "port=%d feature=%d\n", 1020 1.1 bouyer index, value)); 1021 1.1 bouyer if (index != 1) { 1022 1.1 bouyer err = USBD_IOERROR; 1023 1.1 bouyer goto ret; 1024 1.1 bouyer } 1025 1.1 bouyer switch(value) { 1026 1.1 bouyer case UHF_PORT_ENABLE: 1027 1.1 bouyer sc->sc_port_enabled = 0; 1028 1.1 bouyer break; 1029 1.1 bouyer case UHF_PORT_SUSPEND: 1030 1.1 bouyer if (sc->sc_port_suspended != 0) { 1031 1.1 bouyer val = UREAD1(sc, MUSB2_REG_POWER); 1032 1.1 bouyer val &= ~MUSB2_MASK_SUSPMODE; 1033 1.1 bouyer val |= MUSB2_MASK_RESUME; 1034 1.1 bouyer UWRITE1(sc, MUSB2_REG_POWER, val); 1035 1.1 bouyer /* wait 20 milliseconds */ 1036 1.1 bouyer usb_delay_ms(&sc->sc_bus, 20); 1037 1.1 bouyer val = UREAD1(sc, MUSB2_REG_POWER); 1038 1.1 bouyer val &= ~MUSB2_MASK_RESUME; 1039 1.1 bouyer UWRITE1(sc, MUSB2_REG_POWER, val); 1040 1.1 bouyer sc->sc_port_suspended = 0; 1041 1.1 bouyer sc->sc_port_suspended_change = 1; 1042 1.1 bouyer } 1043 1.1 bouyer break; 1044 1.1 bouyer case UHF_PORT_RESET: 1045 1.1 bouyer break; 1046 1.1 bouyer case UHF_C_PORT_CONNECTION: 1047 1.1 bouyer break; 1048 1.1 bouyer case UHF_C_PORT_ENABLE: 1049 1.1 bouyer break; 1050 1.1 bouyer case UHF_C_PORT_OVER_CURRENT: 1051 1.1 bouyer break; 1052 1.1 bouyer case UHF_C_PORT_RESET: 1053 1.1 bouyer sc->sc_isreset = 0; 1054 1.1 bouyer err = USBD_NORMAL_COMPLETION; 1055 1.1 bouyer goto ret; 1056 1.1 bouyer case UHF_PORT_POWER: 1057 1.1 bouyer /* XXX todo */ 1058 1.1 bouyer break; 1059 1.1 bouyer case UHF_PORT_CONNECTION: 1060 1.1 bouyer case UHF_PORT_OVER_CURRENT: 1061 1.1 bouyer case UHF_PORT_LOW_SPEED: 1062 1.1 bouyer case UHF_C_PORT_SUSPEND: 1063 1.1 bouyer default: 1064 1.1 bouyer err = USBD_IOERROR; 1065 1.1 bouyer goto ret; 1066 1.1 bouyer } 1067 1.1 bouyer break; 1068 1.1 bouyer case C(UR_GET_BUS_STATE, UT_READ_CLASS_OTHER): 1069 1.1 bouyer err = USBD_IOERROR; 1070 1.1 bouyer goto ret; 1071 1.1 bouyer case C(UR_GET_DESCRIPTOR, UT_READ_CLASS_DEVICE): 1072 1.1 bouyer if (len == 0) 1073 1.1 bouyer break; 1074 1.1 bouyer if ((value & 0xff) != 0) { 1075 1.1 bouyer err = USBD_IOERROR; 1076 1.1 bouyer goto ret; 1077 1.1 bouyer } 1078 1.1 bouyer l = min(len, USB_HUB_DESCRIPTOR_SIZE); 1079 1.1 bouyer totlen = l; 1080 1.1 bouyer memcpy(buf, &motg_hubd, l); 1081 1.1 bouyer break; 1082 1.1 bouyer case C(UR_GET_STATUS, UT_READ_CLASS_DEVICE): 1083 1.1 bouyer if (len != 4) { 1084 1.1 bouyer err = USBD_IOERROR; 1085 1.1 bouyer goto ret; 1086 1.1 bouyer } 1087 1.1 bouyer memset(buf, 0, len); 1088 1.1 bouyer totlen = len; 1089 1.1 bouyer break; 1090 1.1 bouyer case C(UR_GET_STATUS, UT_READ_CLASS_OTHER): 1091 1.1 bouyer if (index != 1) { 1092 1.1 bouyer err = USBD_IOERROR; 1093 1.1 bouyer goto ret; 1094 1.1 bouyer } 1095 1.1 bouyer if (len != 4) { 1096 1.1 bouyer err = USBD_IOERROR; 1097 1.1 bouyer goto ret; 1098 1.1 bouyer } 1099 1.1 bouyer status = change = 0; 1100 1.1 bouyer if (sc->sc_connected) 1101 1.1 bouyer status |= UPS_CURRENT_CONNECT_STATUS; 1102 1.1 bouyer if (sc->sc_connected_changed) { 1103 1.1 bouyer change |= UPS_C_CONNECT_STATUS; 1104 1.1 bouyer sc->sc_connected_changed = 0; 1105 1.1 bouyer } 1106 1.1 bouyer if (sc->sc_port_enabled) 1107 1.1 bouyer status |= UPS_PORT_ENABLED; 1108 1.1 bouyer if (sc->sc_port_enabled_changed) { 1109 1.1 bouyer change |= UPS_C_PORT_ENABLED; 1110 1.1 bouyer sc->sc_port_enabled_changed = 0; 1111 1.1 bouyer } 1112 1.1 bouyer if (sc->sc_port_suspended) 1113 1.1 bouyer status |= UPS_SUSPEND; 1114 1.1 bouyer if (sc->sc_high_speed) 1115 1.1 bouyer status |= UPS_HIGH_SPEED; 1116 1.1 bouyer status |= UPS_PORT_POWER; /* XXX */ 1117 1.1 bouyer if (sc->sc_isreset) 1118 1.1 bouyer change |= UPS_C_PORT_RESET; 1119 1.1 bouyer USETW(ps.wPortStatus, status); 1120 1.1 bouyer USETW(ps.wPortChange, change); 1121 1.1 bouyer l = min(len, sizeof ps); 1122 1.1 bouyer memcpy(buf, &ps, l); 1123 1.1 bouyer totlen = l; 1124 1.1 bouyer break; 1125 1.1 bouyer case C(UR_SET_DESCRIPTOR, UT_WRITE_CLASS_DEVICE): 1126 1.1 bouyer err = USBD_IOERROR; 1127 1.1 bouyer goto ret; 1128 1.1 bouyer case C(UR_SET_FEATURE, UT_WRITE_CLASS_DEVICE): 1129 1.1 bouyer break; 1130 1.1 bouyer case C(UR_SET_FEATURE, UT_WRITE_CLASS_OTHER): 1131 1.1 bouyer if (index != 1) { 1132 1.1 bouyer err = USBD_IOERROR; 1133 1.1 bouyer goto ret; 1134 1.1 bouyer } 1135 1.1 bouyer switch(value) { 1136 1.1 bouyer case UHF_PORT_ENABLE: 1137 1.1 bouyer sc->sc_port_enabled = 1; 1138 1.1 bouyer break; 1139 1.1 bouyer case UHF_PORT_SUSPEND: 1140 1.1 bouyer if (sc->sc_port_suspended == 0) { 1141 1.1 bouyer val = UREAD1(sc, MUSB2_REG_POWER); 1142 1.1 bouyer val |= MUSB2_MASK_SUSPMODE; 1143 1.1 bouyer UWRITE1(sc, MUSB2_REG_POWER, val); 1144 1.1 bouyer /* wait 20 milliseconds */ 1145 1.1 bouyer usb_delay_ms(&sc->sc_bus, 20); 1146 1.1 bouyer sc->sc_port_suspended = 1; 1147 1.1 bouyer sc->sc_port_suspended_change = 1; 1148 1.1 bouyer } 1149 1.1 bouyer break; 1150 1.1 bouyer case UHF_PORT_RESET: 1151 1.1 bouyer err = motg_portreset(sc); 1152 1.1 bouyer goto ret; 1153 1.1 bouyer case UHF_PORT_POWER: 1154 1.1 bouyer /* XXX todo */ 1155 1.1 bouyer err = USBD_NORMAL_COMPLETION; 1156 1.1 bouyer goto ret; 1157 1.1 bouyer case UHF_C_PORT_CONNECTION: 1158 1.1 bouyer case UHF_C_PORT_ENABLE: 1159 1.1 bouyer case UHF_C_PORT_OVER_CURRENT: 1160 1.1 bouyer case UHF_PORT_CONNECTION: 1161 1.1 bouyer case UHF_PORT_OVER_CURRENT: 1162 1.1 bouyer case UHF_PORT_LOW_SPEED: 1163 1.1 bouyer case UHF_C_PORT_SUSPEND: 1164 1.1 bouyer case UHF_C_PORT_RESET: 1165 1.1 bouyer default: 1166 1.1 bouyer err = USBD_IOERROR; 1167 1.1 bouyer goto ret; 1168 1.1 bouyer } 1169 1.1 bouyer break; 1170 1.1 bouyer default: 1171 1.1 bouyer err = USBD_IOERROR; 1172 1.1 bouyer goto ret; 1173 1.1 bouyer } 1174 1.1 bouyer xfer->actlen = totlen; 1175 1.1 bouyer err = USBD_NORMAL_COMPLETION; 1176 1.1 bouyer ret: 1177 1.1 bouyer xfer->status = err; 1178 1.1 bouyer mutex_enter(&sc->sc_lock); 1179 1.1 bouyer usb_transfer_complete(xfer); 1180 1.1 bouyer mutex_exit(&sc->sc_lock); 1181 1.1 bouyer return (USBD_IN_PROGRESS); 1182 1.1 bouyer } 1183 1.1 bouyer 1184 1.1 bouyer /* Abort a root control request. */ 1185 1.1 bouyer void 1186 1.1 bouyer motg_root_ctrl_abort(usbd_xfer_handle xfer) 1187 1.1 bouyer { 1188 1.1 bouyer /* Nothing to do, all transfers are synchronous. */ 1189 1.1 bouyer } 1190 1.1 bouyer 1191 1.1 bouyer /* Close the root pipe. */ 1192 1.1 bouyer void 1193 1.1 bouyer motg_root_ctrl_close(usbd_pipe_handle pipe) 1194 1.1 bouyer { 1195 1.1 bouyer DPRINTFN(MD_ROOT, ("motg_root_ctrl_close\n")); 1196 1.1 bouyer } 1197 1.1 bouyer 1198 1.1 bouyer void 1199 1.1 bouyer motg_root_ctrl_done(usbd_xfer_handle xfer) 1200 1.1 bouyer { 1201 1.1 bouyer } 1202 1.1 bouyer 1203 1.1 bouyer /* Abort a root interrupt request. */ 1204 1.1 bouyer void 1205 1.1 bouyer motg_root_intr_abort(usbd_xfer_handle xfer) 1206 1.1 bouyer { 1207 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1208 1.1 bouyer 1209 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 1210 1.5 skrll KASSERT(xfer->pipe->intrxfer == xfer); 1211 1.1 bouyer 1212 1.1 bouyer sc->sc_intr_xfer = NULL; 1213 1.1 bouyer 1214 1.1 bouyer #ifdef DIAGNOSTIC 1215 1.1 bouyer // XXX UXFER(xfer)->iinfo.isdone = 1; 1216 1.1 bouyer #endif 1217 1.5 skrll xfer->status = USBD_CANCELLED; 1218 1.1 bouyer usb_transfer_complete(xfer); 1219 1.1 bouyer } 1220 1.1 bouyer 1221 1.1 bouyer usbd_status 1222 1.1 bouyer motg_root_intr_transfer(usbd_xfer_handle xfer) 1223 1.1 bouyer { 1224 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1225 1.1 bouyer usbd_status err; 1226 1.1 bouyer 1227 1.1 bouyer /* Insert last in queue. */ 1228 1.1 bouyer mutex_enter(&sc->sc_lock); 1229 1.1 bouyer err = usb_insert_transfer(xfer); 1230 1.1 bouyer mutex_exit(&sc->sc_lock); 1231 1.1 bouyer if (err) 1232 1.1 bouyer return (err); 1233 1.1 bouyer 1234 1.1 bouyer /* 1235 1.1 bouyer * Pipe isn't running (otherwise err would be USBD_INPROG), 1236 1.1 bouyer * start first 1237 1.1 bouyer */ 1238 1.1 bouyer return (motg_root_intr_start(SIMPLEQ_FIRST(&xfer->pipe->queue))); 1239 1.1 bouyer } 1240 1.1 bouyer 1241 1.1 bouyer /* Start a transfer on the root interrupt pipe */ 1242 1.1 bouyer usbd_status 1243 1.1 bouyer motg_root_intr_start(usbd_xfer_handle xfer) 1244 1.1 bouyer { 1245 1.1 bouyer usbd_pipe_handle pipe = xfer->pipe; 1246 1.1 bouyer struct motg_softc *sc = pipe->device->bus->hci_private; 1247 1.1 bouyer 1248 1.1 bouyer DPRINTFN(MD_ROOT, ("motg_root_intr_start: xfer=%p len=%d flags=%d\n", 1249 1.1 bouyer xfer, xfer->length, xfer->flags)); 1250 1.1 bouyer 1251 1.1 bouyer if (sc->sc_dying) 1252 1.1 bouyer return (USBD_IOERROR); 1253 1.1 bouyer 1254 1.1 bouyer sc->sc_intr_xfer = xfer; 1255 1.1 bouyer return (USBD_IN_PROGRESS); 1256 1.1 bouyer } 1257 1.1 bouyer 1258 1.1 bouyer /* Close the root interrupt pipe. */ 1259 1.1 bouyer void 1260 1.1 bouyer motg_root_intr_close(usbd_pipe_handle pipe) 1261 1.1 bouyer { 1262 1.1 bouyer struct motg_softc *sc = pipe->device->bus->hci_private; 1263 1.1 bouyer 1264 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 1265 1.1 bouyer 1266 1.1 bouyer sc->sc_intr_xfer = NULL; 1267 1.1 bouyer DPRINTFN(MD_ROOT, ("motg_root_intr_close\n")); 1268 1.1 bouyer } 1269 1.1 bouyer 1270 1.1 bouyer void 1271 1.1 bouyer motg_root_intr_done(usbd_xfer_handle xfer) 1272 1.1 bouyer { 1273 1.1 bouyer } 1274 1.1 bouyer 1275 1.1 bouyer void 1276 1.1 bouyer motg_noop(usbd_pipe_handle pipe) 1277 1.1 bouyer { 1278 1.1 bouyer } 1279 1.1 bouyer 1280 1.1 bouyer static usbd_status 1281 1.1 bouyer motg_portreset(struct motg_softc *sc) 1282 1.1 bouyer { 1283 1.1 bouyer uint32_t val; 1284 1.1 bouyer 1285 1.1 bouyer val = UREAD1(sc, MUSB2_REG_POWER); 1286 1.1 bouyer val |= MUSB2_MASK_RESET; 1287 1.1 bouyer UWRITE1(sc, MUSB2_REG_POWER, val); 1288 1.1 bouyer /* Wait for 20 msec */ 1289 1.1 bouyer usb_delay_ms(&sc->sc_bus, 20); 1290 1.1 bouyer 1291 1.1 bouyer val = UREAD1(sc, MUSB2_REG_POWER); 1292 1.1 bouyer val &= ~MUSB2_MASK_RESET; 1293 1.1 bouyer UWRITE1(sc, MUSB2_REG_POWER, val); 1294 1.1 bouyer 1295 1.1 bouyer /* determine line speed */ 1296 1.1 bouyer val = UREAD1(sc, MUSB2_REG_POWER); 1297 1.1 bouyer if (val & MUSB2_MASK_HSMODE) 1298 1.1 bouyer sc->sc_high_speed = 1; 1299 1.1 bouyer else 1300 1.1 bouyer sc->sc_high_speed = 0; 1301 1.1 bouyer DPRINTFN(MD_ROOT | MD_CTRL, ("motg_portreset speed %d\n", 1302 1.1 bouyer sc->sc_high_speed)); 1303 1.1 bouyer 1304 1.1 bouyer sc->sc_isreset = 1; 1305 1.1 bouyer sc->sc_port_enabled = 1; 1306 1.1 bouyer return (USBD_NORMAL_COMPLETION); 1307 1.1 bouyer } 1308 1.1 bouyer 1309 1.1 bouyer /* 1310 1.1 bouyer * This routine is executed when an interrupt on the root hub is detected 1311 1.1 bouyer */ 1312 1.1 bouyer static void 1313 1.1 bouyer motg_hub_change(struct motg_softc *sc) 1314 1.1 bouyer { 1315 1.1 bouyer usbd_xfer_handle xfer = sc->sc_intr_xfer; 1316 1.1 bouyer usbd_pipe_handle pipe; 1317 1.1 bouyer u_char *p; 1318 1.1 bouyer 1319 1.1 bouyer DPRINTFN(MD_ROOT, ("motg_hub_change\n")); 1320 1.1 bouyer 1321 1.1 bouyer if (xfer == NULL) 1322 1.1 bouyer return; /* the interrupt pipe is not open */ 1323 1.1 bouyer 1324 1.1 bouyer pipe = xfer->pipe; 1325 1.1 bouyer if (pipe->device == NULL || pipe->device->bus == NULL) 1326 1.1 bouyer return; /* device has detached */ 1327 1.1 bouyer 1328 1.1 bouyer p = KERNADDR(&xfer->dmabuf, 0); 1329 1.1 bouyer p[0] = 1<<1; 1330 1.1 bouyer xfer->actlen = 1; 1331 1.1 bouyer xfer->status = USBD_NORMAL_COMPLETION; 1332 1.1 bouyer usb_transfer_complete(xfer); 1333 1.1 bouyer } 1334 1.1 bouyer 1335 1.1 bouyer static uint8_t 1336 1.12.2.1 skrll motg_speed(uint8_t speed) 1337 1.1 bouyer { 1338 1.1 bouyer switch(speed) { 1339 1.1 bouyer case USB_SPEED_LOW: 1340 1.1 bouyer return MUSB2_MASK_TI_SPEED_LO; 1341 1.1 bouyer case USB_SPEED_FULL: 1342 1.1 bouyer return MUSB2_MASK_TI_SPEED_FS; 1343 1.1 bouyer case USB_SPEED_HIGH: 1344 1.1 bouyer return MUSB2_MASK_TI_SPEED_HS; 1345 1.1 bouyer default: 1346 1.1 bouyer panic("motg: unknown speed %d", speed); 1347 1.1 bouyer /* NOTREACHED */ 1348 1.1 bouyer } 1349 1.1 bouyer } 1350 1.1 bouyer 1351 1.1 bouyer static uint8_t 1352 1.12.2.1 skrll motg_type(uint8_t type) 1353 1.1 bouyer { 1354 1.1 bouyer switch(type) { 1355 1.1 bouyer case UE_CONTROL: 1356 1.1 bouyer return MUSB2_MASK_TI_PROTO_CTRL; 1357 1.1 bouyer case UE_ISOCHRONOUS: 1358 1.1 bouyer return MUSB2_MASK_TI_PROTO_ISOC; 1359 1.1 bouyer case UE_BULK: 1360 1.1 bouyer return MUSB2_MASK_TI_PROTO_BULK; 1361 1.1 bouyer case UE_INTERRUPT: 1362 1.1 bouyer return MUSB2_MASK_TI_PROTO_INTR; 1363 1.1 bouyer default: 1364 1.1 bouyer panic("motg: unknown type %d", type); 1365 1.1 bouyer /* NOTREACHED */ 1366 1.1 bouyer } 1367 1.1 bouyer } 1368 1.1 bouyer 1369 1.1 bouyer static void 1370 1.1 bouyer motg_setup_endpoint_tx(usbd_xfer_handle xfer) 1371 1.1 bouyer { 1372 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1373 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 1374 1.1 bouyer usbd_device_handle dev = otgpipe->pipe.device; 1375 1.1 bouyer int epnumber = otgpipe->hw_ep->ep_number; 1376 1.1 bouyer 1377 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXFADDR(epnumber), dev->address); 1378 1.1 bouyer if (dev->myhsport) { 1379 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXHADDR(epnumber), 1380 1.1 bouyer dev->myhsport->parent->address); 1381 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXHUBPORT(epnumber), 1382 1.1 bouyer dev->myhsport->portno); 1383 1.1 bouyer } else { 1384 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXHADDR(epnumber), 0); 1385 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXHUBPORT(epnumber), 0); 1386 1.1 bouyer } 1387 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXTI, 1388 1.1 bouyer motg_speed(dev->speed) | 1389 1.1 bouyer UE_GET_ADDR(xfer->pipe->endpoint->edesc->bEndpointAddress) | 1390 1.1 bouyer motg_type(UE_GET_XFERTYPE(xfer->pipe->endpoint->edesc->bmAttributes)) 1391 1.1 bouyer ); 1392 1.1 bouyer if (epnumber == 0) { 1393 1.1 bouyer if (sc->sc_high_speed) { 1394 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, 1395 1.1 bouyer NAK_TO_CTRL_HIGH); 1396 1.1 bouyer } else { 1397 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, NAK_TO_CTRL); 1398 1.1 bouyer } 1399 1.1 bouyer } else { 1400 1.1 bouyer if ((xfer->pipe->endpoint->edesc->bmAttributes & UE_XFERTYPE) 1401 1.1 bouyer == UE_BULK) { 1402 1.1 bouyer if (sc->sc_high_speed) { 1403 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, 1404 1.1 bouyer NAK_TO_BULK_HIGH); 1405 1.1 bouyer } else { 1406 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, NAK_TO_BULK); 1407 1.1 bouyer } 1408 1.1 bouyer } else { 1409 1.1 bouyer if (sc->sc_high_speed) { 1410 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, POLL_TO_HIGH); 1411 1.1 bouyer } else { 1412 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, POLL_TO); 1413 1.1 bouyer } 1414 1.1 bouyer } 1415 1.1 bouyer } 1416 1.1 bouyer } 1417 1.1 bouyer 1418 1.1 bouyer static void 1419 1.1 bouyer motg_setup_endpoint_rx(usbd_xfer_handle xfer) 1420 1.1 bouyer { 1421 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1422 1.1 bouyer usbd_device_handle dev = xfer->pipe->device; 1423 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 1424 1.1 bouyer int epnumber = otgpipe->hw_ep->ep_number; 1425 1.1 bouyer 1426 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXFADDR(epnumber), dev->address); 1427 1.1 bouyer if (dev->myhsport) { 1428 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXHADDR(epnumber), 1429 1.1 bouyer dev->myhsport->parent->address); 1430 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXHUBPORT(epnumber), 1431 1.1 bouyer dev->myhsport->portno); 1432 1.1 bouyer } else { 1433 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXHADDR(epnumber), 0); 1434 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXHUBPORT(epnumber), 0); 1435 1.1 bouyer } 1436 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXTI, 1437 1.1 bouyer motg_speed(dev->speed) | 1438 1.1 bouyer UE_GET_ADDR(xfer->pipe->endpoint->edesc->bEndpointAddress) | 1439 1.1 bouyer motg_type(UE_GET_XFERTYPE(xfer->pipe->endpoint->edesc->bmAttributes)) 1440 1.1 bouyer ); 1441 1.1 bouyer if (epnumber == 0) { 1442 1.1 bouyer if (sc->sc_high_speed) { 1443 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, 1444 1.1 bouyer NAK_TO_CTRL_HIGH); 1445 1.1 bouyer } else { 1446 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXNAKLIMIT, NAK_TO_CTRL); 1447 1.1 bouyer } 1448 1.1 bouyer } else { 1449 1.1 bouyer if ((xfer->pipe->endpoint->edesc->bmAttributes & UE_XFERTYPE) 1450 1.1 bouyer == UE_BULK) { 1451 1.1 bouyer if (sc->sc_high_speed) { 1452 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXNAKLIMIT, 1453 1.1 bouyer NAK_TO_BULK_HIGH); 1454 1.1 bouyer } else { 1455 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXNAKLIMIT, NAK_TO_BULK); 1456 1.1 bouyer } 1457 1.1 bouyer } else { 1458 1.1 bouyer if (sc->sc_high_speed) { 1459 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXNAKLIMIT, POLL_TO_HIGH); 1460 1.1 bouyer } else { 1461 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXNAKLIMIT, POLL_TO); 1462 1.1 bouyer } 1463 1.1 bouyer } 1464 1.1 bouyer } 1465 1.1 bouyer } 1466 1.1 bouyer 1467 1.1 bouyer static usbd_status 1468 1.1 bouyer motg_device_ctrl_transfer(usbd_xfer_handle xfer) 1469 1.1 bouyer { 1470 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1471 1.1 bouyer usbd_status err; 1472 1.1 bouyer 1473 1.1 bouyer /* Insert last in queue. */ 1474 1.1 bouyer mutex_enter(&sc->sc_lock); 1475 1.1 bouyer err = usb_insert_transfer(xfer); 1476 1.3 bouyer xfer->status = USBD_NOT_STARTED; 1477 1.1 bouyer mutex_exit(&sc->sc_lock); 1478 1.1 bouyer if (err) 1479 1.1 bouyer return (err); 1480 1.1 bouyer 1481 1.1 bouyer /* 1482 1.1 bouyer * Pipe isn't running (otherwise err would be USBD_INPROG), 1483 1.1 bouyer * so start it first. 1484 1.1 bouyer */ 1485 1.1 bouyer return (motg_device_ctrl_start(SIMPLEQ_FIRST(&xfer->pipe->queue))); 1486 1.1 bouyer } 1487 1.1 bouyer 1488 1.1 bouyer static usbd_status 1489 1.1 bouyer motg_device_ctrl_start(usbd_xfer_handle xfer) 1490 1.1 bouyer { 1491 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1492 1.1 bouyer usbd_status err; 1493 1.1 bouyer mutex_enter(&sc->sc_lock); 1494 1.1 bouyer err = motg_device_ctrl_start1(sc); 1495 1.1 bouyer mutex_exit(&sc->sc_lock); 1496 1.1 bouyer if (err != USBD_IN_PROGRESS) 1497 1.1 bouyer return err; 1498 1.1 bouyer if (sc->sc_bus.use_polling) 1499 1.1 bouyer motg_waitintr(sc, xfer); 1500 1.1 bouyer return USBD_IN_PROGRESS; 1501 1.1 bouyer } 1502 1.1 bouyer 1503 1.1 bouyer static usbd_status 1504 1.1 bouyer motg_device_ctrl_start1(struct motg_softc *sc) 1505 1.1 bouyer { 1506 1.1 bouyer struct motg_hw_ep *ep = &sc->sc_in_ep[0]; 1507 1.3 bouyer usbd_xfer_handle xfer = NULL; 1508 1.1 bouyer struct motg_pipe *otgpipe; 1509 1.1 bouyer usbd_status err = 0; 1510 1.1 bouyer 1511 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 1512 1.1 bouyer if (sc->sc_dying) 1513 1.1 bouyer return (USBD_IOERROR); 1514 1.1 bouyer 1515 1.1 bouyer if (!sc->sc_connected) 1516 1.1 bouyer return (USBD_IOERROR); 1517 1.1 bouyer 1518 1.1 bouyer if (ep->xfer != NULL) { 1519 1.1 bouyer err = USBD_IN_PROGRESS; 1520 1.1 bouyer goto end; 1521 1.1 bouyer } 1522 1.1 bouyer /* locate the first pipe with work to do */ 1523 1.1 bouyer SIMPLEQ_FOREACH(otgpipe, &ep->ep_pipes, ep_pipe_list) { 1524 1.1 bouyer xfer = SIMPLEQ_FIRST(&otgpipe->pipe.queue); 1525 1.3 bouyer DPRINTFN(MD_CTRL, 1526 1.3 bouyer ("motg_device_ctrl_start1 pipe %p xfer %p status %d\n", 1527 1.3 bouyer otgpipe, xfer, (xfer != NULL) ? xfer->status : 0)); 1528 1.7 skrll 1529 1.1 bouyer if (xfer != NULL) { 1530 1.1 bouyer /* move this pipe to the end of the list */ 1531 1.1 bouyer SIMPLEQ_REMOVE(&ep->ep_pipes, otgpipe, 1532 1.1 bouyer motg_pipe, ep_pipe_list); 1533 1.1 bouyer SIMPLEQ_INSERT_TAIL(&ep->ep_pipes, 1534 1.1 bouyer otgpipe, ep_pipe_list); 1535 1.1 bouyer break; 1536 1.1 bouyer } 1537 1.1 bouyer } 1538 1.1 bouyer if (xfer == NULL) { 1539 1.1 bouyer err = USBD_NOT_STARTED; 1540 1.1 bouyer goto end; 1541 1.1 bouyer } 1542 1.3 bouyer xfer->status = USBD_IN_PROGRESS; 1543 1.1 bouyer KASSERT(otgpipe == (struct motg_pipe *)xfer->pipe); 1544 1.1 bouyer KASSERT(otgpipe->hw_ep == ep); 1545 1.1 bouyer #ifdef DIAGNOSTIC 1546 1.1 bouyer if (!(xfer->rqflags & URQ_REQUEST)) 1547 1.1 bouyer panic("motg_device_ctrl_transfer: not a request"); 1548 1.1 bouyer #endif 1549 1.1 bouyer // KASSERT(xfer->actlen == 0); 1550 1.1 bouyer xfer->actlen = 0; 1551 1.1 bouyer 1552 1.1 bouyer ep->xfer = xfer; 1553 1.1 bouyer ep->datalen = xfer->length; 1554 1.1 bouyer if (ep->datalen > 0) 1555 1.1 bouyer ep->data = KERNADDR(&xfer->dmabuf, 0); 1556 1.1 bouyer else 1557 1.1 bouyer ep->data = NULL; 1558 1.1 bouyer if ((xfer->flags & USBD_FORCE_SHORT_XFER) && 1559 1.1 bouyer (ep->datalen % 64) == 0) 1560 1.1 bouyer ep->need_short_xfer = 1; 1561 1.1 bouyer else 1562 1.1 bouyer ep->need_short_xfer = 0; 1563 1.1 bouyer /* now we need send this request */ 1564 1.7 skrll DPRINTFN(MD_CTRL, 1565 1.1 bouyer ("motg_device_ctrl_start1(%p) send data %p len %d short %d speed %d to %d\n", 1566 1.1 bouyer xfer, ep->data, ep->datalen, ep->need_short_xfer, xfer->pipe->device->speed, 1567 1.1 bouyer xfer->pipe->device->address)); 1568 1.1 bouyer KASSERT(ep->phase == IDLE); 1569 1.1 bouyer ep->phase = SETUP; 1570 1.1 bouyer /* select endpoint 0 */ 1571 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, 0); 1572 1.1 bouyer /* fifo should be empty at this point */ 1573 1.1 bouyer KASSERT((UREAD1(sc, MUSB2_REG_TXCSRL) & MUSB2_MASK_CSR0L_TXPKTRDY) == 0); 1574 1.1 bouyer /* send data */ 1575 1.1 bouyer // KASSERT(((vaddr_t)(&xfer->request) & 3) == 0); 1576 1.1 bouyer KASSERT(sizeof(xfer->request) == 8); 1577 1.1 bouyer bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh, MUSB2_REG_EPFIFO(0), 1578 1.1 bouyer (void *)&xfer->request, sizeof(xfer->request)); 1579 1.1 bouyer 1580 1.1 bouyer motg_setup_endpoint_tx(xfer); 1581 1.1 bouyer /* start transaction */ 1582 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 1583 1.1 bouyer MUSB2_MASK_CSR0L_TXPKTRDY | MUSB2_MASK_CSR0L_SETUPPKT); 1584 1.1 bouyer 1585 1.1 bouyer end: 1586 1.1 bouyer if (err) 1587 1.1 bouyer return (err); 1588 1.1 bouyer 1589 1.1 bouyer return (USBD_IN_PROGRESS); 1590 1.1 bouyer } 1591 1.1 bouyer 1592 1.1 bouyer static void 1593 1.1 bouyer motg_device_ctrl_read(usbd_xfer_handle xfer) 1594 1.1 bouyer { 1595 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1596 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 1597 1.1 bouyer /* assume endpoint already selected */ 1598 1.1 bouyer motg_setup_endpoint_rx(xfer); 1599 1.1 bouyer /* start transaction */ 1600 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, MUSB2_MASK_CSR0L_REQPKT); 1601 1.1 bouyer otgpipe->hw_ep->phase = DATA_IN; 1602 1.1 bouyer } 1603 1.1 bouyer 1604 1.1 bouyer static void 1605 1.1 bouyer motg_device_ctrl_intr_rx(struct motg_softc *sc) 1606 1.1 bouyer { 1607 1.1 bouyer struct motg_hw_ep *ep = &sc->sc_in_ep[0]; 1608 1.1 bouyer usbd_xfer_handle xfer = ep->xfer; 1609 1.1 bouyer uint8_t csr; 1610 1.1 bouyer int datalen, max_datalen; 1611 1.1 bouyer char *data; 1612 1.1 bouyer bool got_short; 1613 1.3 bouyer usbd_status new_status = USBD_IN_PROGRESS; 1614 1.1 bouyer 1615 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 1616 1.1 bouyer 1617 1.1 bouyer #ifdef DIAGNOSTIC 1618 1.1 bouyer if (ep->phase != DATA_IN && 1619 1.1 bouyer ep->phase != STATUS_IN) 1620 1.1 bouyer panic("motg_device_ctrl_intr_rx: bad phase %d", ep->phase); 1621 1.1 bouyer #endif 1622 1.12.2.2 skrll /* select endpoint 0 */ 1623 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, 0); 1624 1.1 bouyer 1625 1.1 bouyer /* read out FIFO status */ 1626 1.1 bouyer csr = UREAD1(sc, MUSB2_REG_TXCSRL); 1627 1.7 skrll DPRINTFN(MD_CTRL, 1628 1.7 skrll ("motg_device_ctrl_intr_rx phase %d csr 0x%x xfer %p status %d\n", 1629 1.3 bouyer ep->phase, csr, xfer, (xfer != NULL) ? xfer->status : 0)); 1630 1.1 bouyer 1631 1.1 bouyer if (csr & MUSB2_MASK_CSR0L_NAKTIMO) { 1632 1.1 bouyer csr &= ~MUSB2_MASK_CSR0L_REQPKT; 1633 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, csr); 1634 1.1 bouyer 1635 1.1 bouyer csr &= ~MUSB2_MASK_CSR0L_NAKTIMO; 1636 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, csr); 1637 1.3 bouyer new_status = USBD_TIMEOUT; /* XXX */ 1638 1.1 bouyer goto complete; 1639 1.1 bouyer } 1640 1.1 bouyer if (csr & (MUSB2_MASK_CSR0L_RXSTALL | MUSB2_MASK_CSR0L_ERROR)) { 1641 1.3 bouyer if (csr & MUSB2_MASK_CSR0L_RXSTALL) 1642 1.3 bouyer new_status = USBD_STALLED; 1643 1.3 bouyer else 1644 1.3 bouyer new_status = USBD_IOERROR; 1645 1.1 bouyer /* clear status */ 1646 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 0); 1647 1.1 bouyer goto complete; 1648 1.1 bouyer } 1649 1.1 bouyer if ((csr & MUSB2_MASK_CSR0L_RXPKTRDY) == 0) 1650 1.1 bouyer return; /* no data yet */ 1651 1.1 bouyer 1652 1.3 bouyer if (xfer == NULL || xfer->status != USBD_IN_PROGRESS) 1653 1.1 bouyer goto complete; 1654 1.1 bouyer 1655 1.1 bouyer if (ep->phase == STATUS_IN) { 1656 1.3 bouyer new_status = USBD_NORMAL_COMPLETION; 1657 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 0); 1658 1.1 bouyer goto complete; 1659 1.1 bouyer } 1660 1.1 bouyer datalen = UREAD2(sc, MUSB2_REG_RXCOUNT); 1661 1.7 skrll DPRINTFN(MD_CTRL, 1662 1.7 skrll ("motg_device_ctrl_intr_rx phase %d datalen %d\n", 1663 1.1 bouyer ep->phase, datalen)); 1664 1.1 bouyer KASSERT(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize) > 0); 1665 1.1 bouyer max_datalen = min(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize), 1666 1.1 bouyer ep->datalen); 1667 1.1 bouyer if (datalen > max_datalen) { 1668 1.3 bouyer new_status = USBD_IOERROR; 1669 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 0); 1670 1.1 bouyer goto complete; 1671 1.1 bouyer } 1672 1.1 bouyer got_short = (datalen < max_datalen); 1673 1.1 bouyer if (datalen > 0) { 1674 1.1 bouyer KASSERT(ep->phase == DATA_IN); 1675 1.1 bouyer data = ep->data; 1676 1.1 bouyer ep->data += datalen; 1677 1.1 bouyer ep->datalen -= datalen; 1678 1.1 bouyer xfer->actlen += datalen; 1679 1.1 bouyer if (((vaddr_t)data & 0x3) == 0 && 1680 1.1 bouyer (datalen >> 2) > 0) { 1681 1.7 skrll DPRINTFN(MD_CTRL, 1682 1.1 bouyer ("motg_device_ctrl_intr_rx r4 data %p len %d\n", 1683 1.1 bouyer data, datalen)); 1684 1.1 bouyer bus_space_read_multi_4(sc->sc_iot, sc->sc_ioh, 1685 1.1 bouyer MUSB2_REG_EPFIFO(0), (void *)data, datalen >> 2); 1686 1.1 bouyer data += (datalen & ~0x3); 1687 1.1 bouyer datalen -= (datalen & ~0x3); 1688 1.1 bouyer } 1689 1.7 skrll DPRINTFN(MD_CTRL, 1690 1.1 bouyer ("motg_device_ctrl_intr_rx r1 data %p len %d\n", 1691 1.1 bouyer data, datalen)); 1692 1.1 bouyer if (datalen) { 1693 1.1 bouyer bus_space_read_multi_1(sc->sc_iot, sc->sc_ioh, 1694 1.1 bouyer MUSB2_REG_EPFIFO(0), data, datalen); 1695 1.1 bouyer } 1696 1.1 bouyer } 1697 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, csr & ~MUSB2_MASK_CSR0L_RXPKTRDY); 1698 1.1 bouyer KASSERT(ep->phase == DATA_IN); 1699 1.1 bouyer if (got_short || (ep->datalen == 0)) { 1700 1.1 bouyer if (ep->need_short_xfer == 0) { 1701 1.1 bouyer ep->phase = STATUS_OUT; 1702 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRH, 1703 1.1 bouyer UREAD1(sc, MUSB2_REG_TXCSRH) | 1704 1.1 bouyer MUSB2_MASK_CSR0H_PING_DIS); 1705 1.1 bouyer motg_setup_endpoint_tx(xfer); 1706 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 1707 1.1 bouyer MUSB2_MASK_CSR0L_STATUSPKT | 1708 1.1 bouyer MUSB2_MASK_CSR0L_TXPKTRDY); 1709 1.1 bouyer return; 1710 1.1 bouyer } 1711 1.1 bouyer ep->need_short_xfer = 0; 1712 1.1 bouyer } 1713 1.1 bouyer motg_device_ctrl_read(xfer); 1714 1.1 bouyer return; 1715 1.1 bouyer complete: 1716 1.1 bouyer ep->phase = IDLE; 1717 1.1 bouyer ep->xfer = NULL; 1718 1.3 bouyer if (xfer && xfer->status == USBD_IN_PROGRESS) { 1719 1.3 bouyer KASSERT(new_status != USBD_IN_PROGRESS); 1720 1.3 bouyer xfer->status = new_status; 1721 1.1 bouyer usb_transfer_complete(xfer); 1722 1.3 bouyer } 1723 1.1 bouyer motg_device_ctrl_start1(sc); 1724 1.1 bouyer } 1725 1.1 bouyer 1726 1.1 bouyer static void 1727 1.1 bouyer motg_device_ctrl_intr_tx(struct motg_softc *sc) 1728 1.1 bouyer { 1729 1.1 bouyer struct motg_hw_ep *ep = &sc->sc_in_ep[0]; 1730 1.1 bouyer usbd_xfer_handle xfer = ep->xfer; 1731 1.1 bouyer uint8_t csr; 1732 1.1 bouyer int datalen; 1733 1.1 bouyer char *data; 1734 1.3 bouyer usbd_status new_status = USBD_IN_PROGRESS; 1735 1.1 bouyer 1736 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 1737 1.1 bouyer if (ep->phase == DATA_IN || ep->phase == STATUS_IN) { 1738 1.1 bouyer motg_device_ctrl_intr_rx(sc); 1739 1.1 bouyer return; 1740 1.1 bouyer } 1741 1.1 bouyer 1742 1.1 bouyer #ifdef DIAGNOSTIC 1743 1.1 bouyer if (ep->phase != SETUP && ep->phase != DATA_OUT && 1744 1.1 bouyer ep->phase != STATUS_OUT) 1745 1.1 bouyer panic("motg_device_ctrl_intr_tx: bad phase %d", ep->phase); 1746 1.1 bouyer #endif 1747 1.12.2.2 skrll /* select endpoint 0 */ 1748 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, 0); 1749 1.1 bouyer 1750 1.1 bouyer csr = UREAD1(sc, MUSB2_REG_TXCSRL); 1751 1.7 skrll DPRINTFN(MD_CTRL, 1752 1.7 skrll ("motg_device_ctrl_intr_tx phase %d csr 0x%x xfer %p status %d\n", 1753 1.3 bouyer ep->phase, csr, xfer, (xfer != NULL) ? xfer->status : 0)); 1754 1.1 bouyer 1755 1.1 bouyer if (csr & MUSB2_MASK_CSR0L_RXSTALL) { 1756 1.1 bouyer /* command not accepted */ 1757 1.3 bouyer new_status = USBD_STALLED; 1758 1.1 bouyer /* clear status */ 1759 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 0); 1760 1.1 bouyer goto complete; 1761 1.1 bouyer } 1762 1.1 bouyer if (csr & MUSB2_MASK_CSR0L_NAKTIMO) { 1763 1.3 bouyer new_status = USBD_TIMEOUT; /* XXX */ 1764 1.1 bouyer /* flush fifo */ 1765 1.1 bouyer while (csr & MUSB2_MASK_CSR0L_TXFIFONEMPTY) { 1766 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRH, 1767 1.7 skrll UREAD1(sc, MUSB2_REG_TXCSRH) | 1768 1.1 bouyer MUSB2_MASK_CSR0H_FFLUSH); 1769 1.1 bouyer csr = UREAD1(sc, MUSB2_REG_TXCSRL); 1770 1.1 bouyer } 1771 1.1 bouyer csr &= ~MUSB2_MASK_CSR0L_NAKTIMO; 1772 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, csr); 1773 1.1 bouyer goto complete; 1774 1.1 bouyer } 1775 1.1 bouyer if (csr & MUSB2_MASK_CSR0L_ERROR) { 1776 1.3 bouyer new_status = USBD_IOERROR; 1777 1.1 bouyer /* clear status */ 1778 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 0); 1779 1.1 bouyer goto complete; 1780 1.1 bouyer } 1781 1.1 bouyer if (csr & MUSB2_MASK_CSR0L_TXFIFONEMPTY) { 1782 1.1 bouyer /* data still not sent */ 1783 1.1 bouyer return; 1784 1.1 bouyer } 1785 1.1 bouyer if (xfer == NULL) 1786 1.1 bouyer goto complete; 1787 1.1 bouyer if (ep->phase == STATUS_OUT) { 1788 1.1 bouyer /* 1789 1.1 bouyer * we have sent status and got no error; 1790 1.1 bouyer * declare transfer complete 1791 1.1 bouyer */ 1792 1.7 skrll DPRINTFN(MD_CTRL, 1793 1.3 bouyer ("motg_device_ctrl_intr_tx %p status %d complete\n", 1794 1.3 bouyer xfer, xfer->status)); 1795 1.3 bouyer new_status = USBD_NORMAL_COMPLETION; 1796 1.1 bouyer goto complete; 1797 1.1 bouyer } 1798 1.1 bouyer if (ep->datalen == 0) { 1799 1.1 bouyer if (ep->need_short_xfer) { 1800 1.1 bouyer ep->need_short_xfer = 0; 1801 1.1 bouyer /* one more data phase */ 1802 1.1 bouyer if (xfer->request.bmRequestType & UT_READ) { 1803 1.7 skrll DPRINTFN(MD_CTRL, 1804 1.1 bouyer ("motg_device_ctrl_intr_tx %p to DATA_IN\n", xfer)); 1805 1.1 bouyer motg_device_ctrl_read(xfer); 1806 1.1 bouyer return; 1807 1.1 bouyer } /* else fall back to DATA_OUT */ 1808 1.1 bouyer } else { 1809 1.7 skrll DPRINTFN(MD_CTRL, 1810 1.1 bouyer ("motg_device_ctrl_intr_tx %p to STATUS_IN, csrh 0x%x\n", 1811 1.1 bouyer xfer, UREAD1(sc, MUSB2_REG_TXCSRH))); 1812 1.1 bouyer ep->phase = STATUS_IN; 1813 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRH, 1814 1.1 bouyer UREAD1(sc, MUSB2_REG_RXCSRH) | 1815 1.1 bouyer MUSB2_MASK_CSR0H_PING_DIS); 1816 1.1 bouyer motg_setup_endpoint_rx(xfer); 1817 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 1818 1.1 bouyer MUSB2_MASK_CSR0L_STATUSPKT | 1819 1.1 bouyer MUSB2_MASK_CSR0L_REQPKT); 1820 1.1 bouyer return; 1821 1.1 bouyer } 1822 1.1 bouyer } 1823 1.1 bouyer if (xfer->request.bmRequestType & UT_READ) { 1824 1.1 bouyer motg_device_ctrl_read(xfer); 1825 1.1 bouyer return; 1826 1.1 bouyer } 1827 1.1 bouyer /* setup a dataout phase */ 1828 1.1 bouyer datalen = min(ep->datalen, 1829 1.1 bouyer UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)); 1830 1.1 bouyer ep->phase = DATA_OUT; 1831 1.7 skrll DPRINTFN(MD_CTRL, 1832 1.1 bouyer ("motg_device_ctrl_intr_tx %p to DATA_OUT, csrh 0x%x\n", xfer, 1833 1.1 bouyer UREAD1(sc, MUSB2_REG_TXCSRH))); 1834 1.1 bouyer if (datalen) { 1835 1.1 bouyer data = ep->data; 1836 1.1 bouyer ep->data += datalen; 1837 1.1 bouyer ep->datalen -= datalen; 1838 1.1 bouyer xfer->actlen += datalen; 1839 1.1 bouyer if (((vaddr_t)data & 0x3) == 0 && 1840 1.1 bouyer (datalen >> 2) > 0) { 1841 1.1 bouyer bus_space_write_multi_4(sc->sc_iot, sc->sc_ioh, 1842 1.1 bouyer MUSB2_REG_EPFIFO(0), (void *)data, datalen >> 2); 1843 1.1 bouyer data += (datalen & ~0x3); 1844 1.1 bouyer datalen -= (datalen & ~0x3); 1845 1.1 bouyer } 1846 1.1 bouyer if (datalen) { 1847 1.1 bouyer bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh, 1848 1.1 bouyer MUSB2_REG_EPFIFO(0), data, datalen); 1849 1.1 bouyer } 1850 1.1 bouyer } 1851 1.1 bouyer /* send data */ 1852 1.1 bouyer motg_setup_endpoint_tx(xfer); 1853 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, MUSB2_MASK_CSR0L_TXPKTRDY); 1854 1.1 bouyer return; 1855 1.1 bouyer 1856 1.1 bouyer complete: 1857 1.1 bouyer ep->phase = IDLE; 1858 1.1 bouyer ep->xfer = NULL; 1859 1.3 bouyer if (xfer && xfer->status == USBD_IN_PROGRESS) { 1860 1.3 bouyer KASSERT(new_status != USBD_IN_PROGRESS); 1861 1.3 bouyer xfer->status = new_status; 1862 1.1 bouyer usb_transfer_complete(xfer); 1863 1.3 bouyer } 1864 1.1 bouyer motg_device_ctrl_start1(sc); 1865 1.1 bouyer } 1866 1.1 bouyer 1867 1.1 bouyer /* Abort a device control request. */ 1868 1.1 bouyer void 1869 1.1 bouyer motg_device_ctrl_abort(usbd_xfer_handle xfer) 1870 1.1 bouyer { 1871 1.1 bouyer DPRINTFN(MD_CTRL, ("motg_device_ctrl_abort:\n")); 1872 1.3 bouyer motg_device_xfer_abort(xfer); 1873 1.1 bouyer } 1874 1.1 bouyer 1875 1.1 bouyer /* Close a device control pipe */ 1876 1.1 bouyer void 1877 1.1 bouyer motg_device_ctrl_close(usbd_pipe_handle pipe) 1878 1.1 bouyer { 1879 1.8 skrll struct motg_softc *sc __diagused = pipe->device->bus->hci_private; 1880 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)pipe; 1881 1.1 bouyer struct motg_pipe *otgpipeiter; 1882 1.1 bouyer 1883 1.1 bouyer DPRINTFN(MD_CTRL, ("motg_device_ctrl_close:\n")); 1884 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 1885 1.1 bouyer KASSERT(otgpipe->hw_ep->xfer == NULL || 1886 1.1 bouyer otgpipe->hw_ep->xfer->pipe != pipe); 1887 1.1 bouyer 1888 1.1 bouyer SIMPLEQ_FOREACH(otgpipeiter, &otgpipe->hw_ep->ep_pipes, ep_pipe_list) { 1889 1.1 bouyer if (otgpipeiter == otgpipe) { 1890 1.1 bouyer /* remove from list */ 1891 1.1 bouyer SIMPLEQ_REMOVE(&otgpipe->hw_ep->ep_pipes, otgpipe, 1892 1.1 bouyer motg_pipe, ep_pipe_list); 1893 1.1 bouyer otgpipe->hw_ep->refcount--; 1894 1.1 bouyer /* we're done */ 1895 1.1 bouyer return; 1896 1.1 bouyer } 1897 1.1 bouyer } 1898 1.1 bouyer panic("motg_device_ctrl_close: not found"); 1899 1.1 bouyer } 1900 1.1 bouyer 1901 1.1 bouyer void 1902 1.1 bouyer motg_device_ctrl_done(usbd_xfer_handle xfer) 1903 1.1 bouyer { 1904 1.8 skrll struct motg_pipe *otgpipe __diagused = (struct motg_pipe *)xfer->pipe; 1905 1.1 bouyer DPRINTFN(MD_CTRL, ("motg_device_ctrl_done:\n")); 1906 1.1 bouyer KASSERT(otgpipe->hw_ep->xfer != xfer); 1907 1.1 bouyer } 1908 1.1 bouyer 1909 1.1 bouyer static usbd_status 1910 1.1 bouyer motg_device_data_transfer(usbd_xfer_handle xfer) 1911 1.1 bouyer { 1912 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1913 1.1 bouyer usbd_status err; 1914 1.1 bouyer 1915 1.1 bouyer /* Insert last in queue. */ 1916 1.1 bouyer mutex_enter(&sc->sc_lock); 1917 1.3 bouyer DPRINTF(("motg_device_data_transfer(%p) status %d\n", 1918 1.3 bouyer xfer, xfer->status)); 1919 1.1 bouyer err = usb_insert_transfer(xfer); 1920 1.3 bouyer xfer->status = USBD_NOT_STARTED; 1921 1.1 bouyer mutex_exit(&sc->sc_lock); 1922 1.1 bouyer if (err) 1923 1.1 bouyer return (err); 1924 1.1 bouyer 1925 1.1 bouyer /* 1926 1.1 bouyer * Pipe isn't running (otherwise err would be USBD_INPROG), 1927 1.1 bouyer * so start it first. 1928 1.1 bouyer */ 1929 1.1 bouyer return (motg_device_data_start(SIMPLEQ_FIRST(&xfer->pipe->queue))); 1930 1.1 bouyer } 1931 1.1 bouyer 1932 1.1 bouyer static usbd_status 1933 1.1 bouyer motg_device_data_start(usbd_xfer_handle xfer) 1934 1.1 bouyer { 1935 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 1936 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 1937 1.1 bouyer usbd_status err; 1938 1.1 bouyer mutex_enter(&sc->sc_lock); 1939 1.3 bouyer DPRINTF(("motg_device_data_start(%p) status %d\n", 1940 1.3 bouyer xfer, xfer->status)); 1941 1.1 bouyer err = motg_device_data_start1(sc, otgpipe->hw_ep); 1942 1.1 bouyer mutex_exit(&sc->sc_lock); 1943 1.1 bouyer if (err != USBD_IN_PROGRESS) 1944 1.1 bouyer return err; 1945 1.1 bouyer if (sc->sc_bus.use_polling) 1946 1.1 bouyer motg_waitintr(sc, xfer); 1947 1.1 bouyer return USBD_IN_PROGRESS; 1948 1.1 bouyer } 1949 1.1 bouyer 1950 1.1 bouyer static usbd_status 1951 1.1 bouyer motg_device_data_start1(struct motg_softc *sc, struct motg_hw_ep *ep) 1952 1.1 bouyer { 1953 1.3 bouyer usbd_xfer_handle xfer = NULL; 1954 1.1 bouyer struct motg_pipe *otgpipe; 1955 1.1 bouyer usbd_status err = 0; 1956 1.8 skrll uint32_t val __diagused; 1957 1.1 bouyer 1958 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 1959 1.1 bouyer if (sc->sc_dying) 1960 1.1 bouyer return (USBD_IOERROR); 1961 1.1 bouyer 1962 1.1 bouyer if (!sc->sc_connected) 1963 1.1 bouyer return (USBD_IOERROR); 1964 1.1 bouyer 1965 1.1 bouyer if (ep->xfer != NULL) { 1966 1.1 bouyer err = USBD_IN_PROGRESS; 1967 1.1 bouyer goto end; 1968 1.1 bouyer } 1969 1.1 bouyer /* locate the first pipe with work to do */ 1970 1.1 bouyer SIMPLEQ_FOREACH(otgpipe, &ep->ep_pipes, ep_pipe_list) { 1971 1.1 bouyer xfer = SIMPLEQ_FIRST(&otgpipe->pipe.queue); 1972 1.3 bouyer DPRINTFN(MD_BULK, 1973 1.3 bouyer ("motg_device_data_start1 pipe %p xfer %p status %d\n", 1974 1.3 bouyer otgpipe, xfer, (xfer != NULL) ? xfer->status : 0)); 1975 1.1 bouyer if (xfer != NULL) { 1976 1.1 bouyer /* move this pipe to the end of the list */ 1977 1.1 bouyer SIMPLEQ_REMOVE(&ep->ep_pipes, otgpipe, 1978 1.1 bouyer motg_pipe, ep_pipe_list); 1979 1.1 bouyer SIMPLEQ_INSERT_TAIL(&ep->ep_pipes, 1980 1.1 bouyer otgpipe, ep_pipe_list); 1981 1.1 bouyer break; 1982 1.1 bouyer } 1983 1.1 bouyer } 1984 1.1 bouyer if (xfer == NULL) { 1985 1.1 bouyer err = USBD_NOT_STARTED; 1986 1.1 bouyer goto end; 1987 1.1 bouyer } 1988 1.3 bouyer xfer->status = USBD_IN_PROGRESS; 1989 1.1 bouyer KASSERT(otgpipe == (struct motg_pipe *)xfer->pipe); 1990 1.1 bouyer KASSERT(otgpipe->hw_ep == ep); 1991 1.1 bouyer #ifdef DIAGNOSTIC 1992 1.1 bouyer if (xfer->rqflags & URQ_REQUEST) 1993 1.1 bouyer panic("motg_device_data_transfer: a request"); 1994 1.1 bouyer #endif 1995 1.1 bouyer // KASSERT(xfer->actlen == 0); 1996 1.1 bouyer xfer->actlen = 0; 1997 1.1 bouyer 1998 1.1 bouyer ep->xfer = xfer; 1999 1.1 bouyer ep->datalen = xfer->length; 2000 1.1 bouyer KASSERT(ep->datalen > 0); 2001 1.1 bouyer ep->data = KERNADDR(&xfer->dmabuf, 0); 2002 1.1 bouyer if ((xfer->flags & USBD_FORCE_SHORT_XFER) && 2003 1.1 bouyer (ep->datalen % 64) == 0) 2004 1.1 bouyer ep->need_short_xfer = 1; 2005 1.1 bouyer else 2006 1.1 bouyer ep->need_short_xfer = 0; 2007 1.1 bouyer /* now we need send this request */ 2008 1.7 skrll DPRINTFN(MD_BULK, 2009 1.1 bouyer ("motg_device_data_start1(%p) %s data %p len %d short %d speed %d to %d\n", 2010 1.7 skrll xfer, 2011 1.1 bouyer UE_GET_DIR(xfer->pipe->endpoint->edesc->bEndpointAddress) == UE_DIR_IN ? "read" : "write", 2012 1.1 bouyer ep->data, ep->datalen, ep->need_short_xfer, xfer->pipe->device->speed, 2013 1.1 bouyer xfer->pipe->device->address)); 2014 1.1 bouyer KASSERT(ep->phase == IDLE); 2015 1.1 bouyer /* select endpoint */ 2016 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, ep->ep_number); 2017 1.1 bouyer if (UE_GET_DIR(xfer->pipe->endpoint->edesc->bEndpointAddress) 2018 1.1 bouyer == UE_DIR_IN) { 2019 1.1 bouyer val = UREAD1(sc, MUSB2_REG_RXCSRL); 2020 1.1 bouyer KASSERT((val & MUSB2_MASK_CSRL_RXPKTRDY) == 0); 2021 1.1 bouyer motg_device_data_read(xfer); 2022 1.1 bouyer } else { 2023 1.1 bouyer ep->phase = DATA_OUT; 2024 1.1 bouyer val = UREAD1(sc, MUSB2_REG_TXCSRL); 2025 1.1 bouyer KASSERT((val & MUSB2_MASK_CSRL_TXPKTRDY) == 0); 2026 1.1 bouyer motg_device_data_write(xfer); 2027 1.1 bouyer } 2028 1.1 bouyer end: 2029 1.1 bouyer if (err) 2030 1.1 bouyer return (err); 2031 1.1 bouyer 2032 1.1 bouyer return (USBD_IN_PROGRESS); 2033 1.1 bouyer } 2034 1.1 bouyer 2035 1.1 bouyer static void 2036 1.1 bouyer motg_device_data_read(usbd_xfer_handle xfer) 2037 1.1 bouyer { 2038 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 2039 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 2040 1.1 bouyer uint32_t val; 2041 1.1 bouyer 2042 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 2043 1.1 bouyer /* assume endpoint already selected */ 2044 1.1 bouyer motg_setup_endpoint_rx(xfer); 2045 1.1 bouyer /* Max packet size */ 2046 1.1 bouyer UWRITE2(sc, MUSB2_REG_RXMAXP, 2047 1.1 bouyer UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)); 2048 1.1 bouyer /* Data Toggle */ 2049 1.1 bouyer val = UREAD1(sc, MUSB2_REG_RXCSRH); 2050 1.1 bouyer val |= MUSB2_MASK_CSRH_RXDT_WREN; 2051 1.1 bouyer if (otgpipe->nexttoggle) 2052 1.1 bouyer val |= MUSB2_MASK_CSRH_RXDT_VAL; 2053 1.1 bouyer else 2054 1.1 bouyer val &= ~MUSB2_MASK_CSRH_RXDT_VAL; 2055 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRH, val); 2056 1.1 bouyer 2057 1.7 skrll DPRINTFN(MD_BULK, 2058 1.1 bouyer ("motg_device_data_read %p to DATA_IN on ep %d, csrh 0x%x\n", 2059 1.1 bouyer xfer, otgpipe->hw_ep->ep_number, UREAD1(sc, MUSB2_REG_RXCSRH))); 2060 1.1 bouyer /* start transaction */ 2061 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, MUSB2_MASK_CSRL_RXREQPKT); 2062 1.1 bouyer otgpipe->hw_ep->phase = DATA_IN; 2063 1.1 bouyer } 2064 1.1 bouyer 2065 1.1 bouyer static void 2066 1.1 bouyer motg_device_data_write(usbd_xfer_handle xfer) 2067 1.1 bouyer { 2068 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 2069 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 2070 1.1 bouyer struct motg_hw_ep *ep = otgpipe->hw_ep; 2071 1.1 bouyer int datalen; 2072 1.1 bouyer char *data; 2073 1.1 bouyer uint32_t val; 2074 1.1 bouyer 2075 1.1 bouyer KASSERT(xfer!=NULL); 2076 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 2077 1.1 bouyer 2078 1.1 bouyer datalen = min(ep->datalen, 2079 1.1 bouyer UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)); 2080 1.1 bouyer ep->phase = DATA_OUT; 2081 1.7 skrll DPRINTFN(MD_BULK, 2082 1.1 bouyer ("motg_device_data_write %p to DATA_OUT on ep %d, len %d csrh 0x%x\n", 2083 1.1 bouyer xfer, ep->ep_number, datalen, UREAD1(sc, MUSB2_REG_TXCSRH))); 2084 1.1 bouyer 2085 1.1 bouyer /* assume endpoint already selected */ 2086 1.1 bouyer /* write data to fifo */ 2087 1.1 bouyer data = ep->data; 2088 1.1 bouyer ep->data += datalen; 2089 1.1 bouyer ep->datalen -= datalen; 2090 1.1 bouyer xfer->actlen += datalen; 2091 1.1 bouyer if (((vaddr_t)data & 0x3) == 0 && 2092 1.1 bouyer (datalen >> 2) > 0) { 2093 1.1 bouyer bus_space_write_multi_4(sc->sc_iot, sc->sc_ioh, 2094 1.1 bouyer MUSB2_REG_EPFIFO(ep->ep_number), 2095 1.1 bouyer (void *)data, datalen >> 2); 2096 1.1 bouyer data += (datalen & ~0x3); 2097 1.1 bouyer datalen -= (datalen & ~0x3); 2098 1.1 bouyer } 2099 1.1 bouyer if (datalen) { 2100 1.1 bouyer bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh, 2101 1.1 bouyer MUSB2_REG_EPFIFO(ep->ep_number), data, datalen); 2102 1.1 bouyer } 2103 1.1 bouyer 2104 1.1 bouyer motg_setup_endpoint_tx(xfer); 2105 1.1 bouyer /* Max packet size */ 2106 1.1 bouyer UWRITE2(sc, MUSB2_REG_TXMAXP, 2107 1.1 bouyer UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)); 2108 1.1 bouyer /* Data Toggle */ 2109 1.1 bouyer val = UREAD1(sc, MUSB2_REG_TXCSRH); 2110 1.1 bouyer val |= MUSB2_MASK_CSRH_TXDT_WREN; 2111 1.1 bouyer if (otgpipe->nexttoggle) 2112 1.1 bouyer val |= MUSB2_MASK_CSRH_TXDT_VAL; 2113 1.1 bouyer else 2114 1.1 bouyer val &= ~MUSB2_MASK_CSRH_TXDT_VAL; 2115 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRH, val); 2116 1.1 bouyer 2117 1.1 bouyer /* start transaction */ 2118 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, MUSB2_MASK_CSRL_TXPKTRDY); 2119 1.1 bouyer } 2120 1.1 bouyer 2121 1.1 bouyer static void 2122 1.1 bouyer motg_device_intr_rx(struct motg_softc *sc, int epnumber) 2123 1.1 bouyer { 2124 1.1 bouyer struct motg_hw_ep *ep = &sc->sc_in_ep[epnumber]; 2125 1.1 bouyer usbd_xfer_handle xfer = ep->xfer; 2126 1.1 bouyer uint8_t csr; 2127 1.1 bouyer int datalen, max_datalen; 2128 1.1 bouyer char *data; 2129 1.1 bouyer bool got_short; 2130 1.3 bouyer usbd_status new_status = USBD_IN_PROGRESS; 2131 1.1 bouyer 2132 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 2133 1.1 bouyer KASSERT(ep->ep_number == epnumber); 2134 1.1 bouyer 2135 1.7 skrll DPRINTFN(MD_BULK, 2136 1.1 bouyer ("motg_device_intr_rx on ep %d\n", epnumber)); 2137 1.12.2.2 skrll /* select endpoint */ 2138 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, epnumber); 2139 1.1 bouyer 2140 1.1 bouyer /* read out FIFO status */ 2141 1.1 bouyer csr = UREAD1(sc, MUSB2_REG_RXCSRL); 2142 1.7 skrll DPRINTFN(MD_BULK, 2143 1.7 skrll ("motg_device_intr_rx phase %d csr 0x%x\n", 2144 1.1 bouyer ep->phase, csr)); 2145 1.1 bouyer 2146 1.1 bouyer if ((csr & (MUSB2_MASK_CSRL_RXNAKTO | MUSB2_MASK_CSRL_RXSTALL | 2147 1.1 bouyer MUSB2_MASK_CSRL_RXERROR | MUSB2_MASK_CSRL_RXPKTRDY)) == 0) 2148 1.1 bouyer return; 2149 1.1 bouyer 2150 1.1 bouyer #ifdef DIAGNOSTIC 2151 1.1 bouyer if (ep->phase != DATA_IN) 2152 1.1 bouyer panic("motg_device_intr_rx: bad phase %d", ep->phase); 2153 1.1 bouyer #endif 2154 1.1 bouyer if (csr & MUSB2_MASK_CSRL_RXNAKTO) { 2155 1.1 bouyer csr &= ~MUSB2_MASK_CSRL_RXREQPKT; 2156 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, csr); 2157 1.1 bouyer 2158 1.1 bouyer csr &= ~MUSB2_MASK_CSRL_RXNAKTO; 2159 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, csr); 2160 1.3 bouyer new_status = USBD_TIMEOUT; /* XXX */ 2161 1.1 bouyer goto complete; 2162 1.1 bouyer } 2163 1.1 bouyer if (csr & (MUSB2_MASK_CSRL_RXSTALL | MUSB2_MASK_CSRL_RXERROR)) { 2164 1.7 skrll if (csr & MUSB2_MASK_CSRL_RXSTALL) 2165 1.3 bouyer new_status = USBD_STALLED; 2166 1.3 bouyer else 2167 1.3 bouyer new_status = USBD_IOERROR; 2168 1.1 bouyer /* clear status */ 2169 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, 0); 2170 1.1 bouyer goto complete; 2171 1.1 bouyer } 2172 1.1 bouyer KASSERT(csr & MUSB2_MASK_CSRL_RXPKTRDY); 2173 1.1 bouyer 2174 1.3 bouyer if (xfer == NULL || xfer->status != USBD_IN_PROGRESS) { 2175 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, 0); 2176 1.1 bouyer goto complete; 2177 1.1 bouyer } 2178 1.1 bouyer 2179 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 2180 1.1 bouyer otgpipe->nexttoggle = otgpipe->nexttoggle ^ 1; 2181 1.1 bouyer 2182 1.1 bouyer datalen = UREAD2(sc, MUSB2_REG_RXCOUNT); 2183 1.7 skrll DPRINTFN(MD_BULK, 2184 1.7 skrll ("motg_device_intr_rx phase %d datalen %d\n", 2185 1.1 bouyer ep->phase, datalen)); 2186 1.1 bouyer KASSERT(UE_GET_SIZE(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)) > 0); 2187 1.1 bouyer max_datalen = min( 2188 1.1 bouyer UE_GET_SIZE(UGETW(xfer->pipe->endpoint->edesc->wMaxPacketSize)), 2189 1.1 bouyer ep->datalen); 2190 1.1 bouyer if (datalen > max_datalen) { 2191 1.3 bouyer new_status = USBD_IOERROR; 2192 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, 0); 2193 1.1 bouyer goto complete; 2194 1.1 bouyer } 2195 1.1 bouyer got_short = (datalen < max_datalen); 2196 1.1 bouyer if (datalen > 0) { 2197 1.1 bouyer KASSERT(ep->phase == DATA_IN); 2198 1.1 bouyer data = ep->data; 2199 1.1 bouyer ep->data += datalen; 2200 1.1 bouyer ep->datalen -= datalen; 2201 1.1 bouyer xfer->actlen += datalen; 2202 1.1 bouyer if (((vaddr_t)data & 0x3) == 0 && 2203 1.1 bouyer (datalen >> 2) > 0) { 2204 1.7 skrll DPRINTFN(MD_BULK, 2205 1.1 bouyer ("motg_device_intr_rx r4 data %p len %d\n", 2206 1.1 bouyer data, datalen)); 2207 1.1 bouyer bus_space_read_multi_4(sc->sc_iot, sc->sc_ioh, 2208 1.1 bouyer MUSB2_REG_EPFIFO(ep->ep_number), 2209 1.1 bouyer (void *)data, datalen >> 2); 2210 1.1 bouyer data += (datalen & ~0x3); 2211 1.1 bouyer datalen -= (datalen & ~0x3); 2212 1.1 bouyer } 2213 1.7 skrll DPRINTFN(MD_BULK, 2214 1.1 bouyer ("motg_device_intr_rx r1 data %p len %d\n", 2215 1.1 bouyer data, datalen)); 2216 1.1 bouyer if (datalen) { 2217 1.1 bouyer bus_space_read_multi_1(sc->sc_iot, sc->sc_ioh, 2218 1.1 bouyer MUSB2_REG_EPFIFO(ep->ep_number), data, datalen); 2219 1.1 bouyer } 2220 1.1 bouyer } 2221 1.1 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, 0); 2222 1.1 bouyer KASSERT(ep->phase == DATA_IN); 2223 1.1 bouyer if (got_short || (ep->datalen == 0)) { 2224 1.1 bouyer if (ep->need_short_xfer == 0) { 2225 1.3 bouyer new_status = USBD_NORMAL_COMPLETION; 2226 1.1 bouyer goto complete; 2227 1.1 bouyer } 2228 1.1 bouyer ep->need_short_xfer = 0; 2229 1.1 bouyer } 2230 1.1 bouyer motg_device_data_read(xfer); 2231 1.1 bouyer return; 2232 1.1 bouyer complete: 2233 1.7 skrll DPRINTFN(MD_BULK, 2234 1.1 bouyer ("motg_device_intr_rx xfer %p complete, status %d\n", xfer, 2235 1.1 bouyer (xfer != NULL) ? xfer->status : 0)); 2236 1.1 bouyer ep->phase = IDLE; 2237 1.1 bouyer ep->xfer = NULL; 2238 1.3 bouyer if (xfer && xfer->status == USBD_IN_PROGRESS) { 2239 1.3 bouyer KASSERT(new_status != USBD_IN_PROGRESS); 2240 1.3 bouyer xfer->status = new_status; 2241 1.1 bouyer usb_transfer_complete(xfer); 2242 1.3 bouyer } 2243 1.1 bouyer motg_device_data_start1(sc, ep); 2244 1.1 bouyer } 2245 1.1 bouyer 2246 1.1 bouyer static void 2247 1.1 bouyer motg_device_intr_tx(struct motg_softc *sc, int epnumber) 2248 1.1 bouyer { 2249 1.1 bouyer struct motg_hw_ep *ep = &sc->sc_out_ep[epnumber]; 2250 1.1 bouyer usbd_xfer_handle xfer = ep->xfer; 2251 1.1 bouyer uint8_t csr; 2252 1.1 bouyer struct motg_pipe *otgpipe; 2253 1.3 bouyer usbd_status new_status = USBD_IN_PROGRESS; 2254 1.1 bouyer 2255 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 2256 1.1 bouyer KASSERT(ep->ep_number == epnumber); 2257 1.1 bouyer 2258 1.7 skrll DPRINTFN(MD_BULK, 2259 1.1 bouyer ("motg_device_intr_tx on ep %d\n", epnumber)); 2260 1.12.2.2 skrll /* select endpoint */ 2261 1.1 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, epnumber); 2262 1.1 bouyer 2263 1.1 bouyer csr = UREAD1(sc, MUSB2_REG_TXCSRL); 2264 1.7 skrll DPRINTFN(MD_BULK, 2265 1.7 skrll ("motg_device_intr_tx phase %d csr 0x%x\n", 2266 1.1 bouyer ep->phase, csr)); 2267 1.1 bouyer 2268 1.1 bouyer if (csr & (MUSB2_MASK_CSRL_TXSTALLED|MUSB2_MASK_CSRL_TXERROR)) { 2269 1.1 bouyer /* command not accepted */ 2270 1.7 skrll if (csr & MUSB2_MASK_CSRL_TXSTALLED) 2271 1.3 bouyer new_status = USBD_STALLED; 2272 1.3 bouyer else 2273 1.3 bouyer new_status = USBD_IOERROR; 2274 1.1 bouyer /* clear status */ 2275 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 0); 2276 1.1 bouyer goto complete; 2277 1.1 bouyer } 2278 1.1 bouyer if (csr & MUSB2_MASK_CSRL_TXNAKTO) { 2279 1.3 bouyer new_status = USBD_TIMEOUT; /* XXX */ 2280 1.3 bouyer csr &= ~MUSB2_MASK_CSRL_TXNAKTO; 2281 1.3 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, csr); 2282 1.1 bouyer /* flush fifo */ 2283 1.1 bouyer while (csr & MUSB2_MASK_CSRL_TXFIFONEMPTY) { 2284 1.1 bouyer csr |= MUSB2_MASK_CSRL_TXFFLUSH; 2285 1.3 bouyer csr &= ~MUSB2_MASK_CSRL_TXNAKTO; 2286 1.1 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, csr); 2287 1.3 bouyer delay(1000); 2288 1.1 bouyer csr = UREAD1(sc, MUSB2_REG_TXCSRL); 2289 1.3 bouyer DPRINTFN(MD_BULK, ("TX fifo flush ep %d CSR 0x%x\n", 2290 1.3 bouyer epnumber, csr)); 2291 1.1 bouyer } 2292 1.1 bouyer goto complete; 2293 1.1 bouyer } 2294 1.1 bouyer if (csr & (MUSB2_MASK_CSRL_TXFIFONEMPTY|MUSB2_MASK_CSRL_TXPKTRDY)) { 2295 1.1 bouyer /* data still not sent */ 2296 1.1 bouyer return; 2297 1.1 bouyer } 2298 1.3 bouyer if (xfer == NULL || xfer->status != USBD_IN_PROGRESS) 2299 1.1 bouyer goto complete; 2300 1.1 bouyer #ifdef DIAGNOSTIC 2301 1.1 bouyer if (ep->phase != DATA_OUT) 2302 1.1 bouyer panic("motg_device_intr_tx: bad phase %d", ep->phase); 2303 1.1 bouyer #endif 2304 1.7 skrll 2305 1.1 bouyer otgpipe = (struct motg_pipe *)xfer->pipe; 2306 1.1 bouyer otgpipe->nexttoggle = otgpipe->nexttoggle ^ 1; 2307 1.1 bouyer 2308 1.1 bouyer if (ep->datalen == 0) { 2309 1.1 bouyer if (ep->need_short_xfer) { 2310 1.1 bouyer ep->need_short_xfer = 0; 2311 1.1 bouyer /* one more data phase */ 2312 1.1 bouyer } else { 2313 1.3 bouyer new_status = USBD_NORMAL_COMPLETION; 2314 1.1 bouyer goto complete; 2315 1.1 bouyer } 2316 1.1 bouyer } 2317 1.1 bouyer motg_device_data_write(xfer); 2318 1.1 bouyer return; 2319 1.1 bouyer 2320 1.1 bouyer complete: 2321 1.7 skrll DPRINTFN(MD_BULK, 2322 1.1 bouyer ("motg_device_intr_tx xfer %p complete, status %d\n", xfer, 2323 1.1 bouyer (xfer != NULL) ? xfer->status : 0)); 2324 1.1 bouyer #ifdef DIAGNOSTIC 2325 1.3 bouyer if (xfer && xfer->status == USBD_IN_PROGRESS && ep->phase != DATA_OUT) 2326 1.1 bouyer panic("motg_device_intr_tx: bad phase %d", ep->phase); 2327 1.1 bouyer #endif 2328 1.1 bouyer ep->phase = IDLE; 2329 1.1 bouyer ep->xfer = NULL; 2330 1.3 bouyer if (xfer && xfer->status == USBD_IN_PROGRESS) { 2331 1.3 bouyer KASSERT(new_status != USBD_IN_PROGRESS); 2332 1.3 bouyer xfer->status = new_status; 2333 1.1 bouyer usb_transfer_complete(xfer); 2334 1.3 bouyer } 2335 1.1 bouyer motg_device_data_start1(sc, ep); 2336 1.1 bouyer } 2337 1.1 bouyer 2338 1.1 bouyer /* Abort a device control request. */ 2339 1.1 bouyer void 2340 1.1 bouyer motg_device_data_abort(usbd_xfer_handle xfer) 2341 1.1 bouyer { 2342 1.1 bouyer #ifdef DIAGNOSTIC 2343 1.1 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 2344 1.1 bouyer #endif 2345 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 2346 1.1 bouyer 2347 1.3 bouyer DPRINTFN(MD_BULK, ("motg_device_data_abort:\n")); 2348 1.3 bouyer motg_device_xfer_abort(xfer); 2349 1.1 bouyer } 2350 1.1 bouyer 2351 1.1 bouyer /* Close a device control pipe */ 2352 1.1 bouyer void 2353 1.1 bouyer motg_device_data_close(usbd_pipe_handle pipe) 2354 1.1 bouyer { 2355 1.8 skrll struct motg_softc *sc __diagused = pipe->device->bus->hci_private; 2356 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)pipe; 2357 1.1 bouyer struct motg_pipe *otgpipeiter; 2358 1.1 bouyer 2359 1.1 bouyer DPRINTFN(MD_CTRL, ("motg_device_data_close:\n")); 2360 1.1 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 2361 1.1 bouyer KASSERT(otgpipe->hw_ep->xfer == NULL || 2362 1.1 bouyer otgpipe->hw_ep->xfer->pipe != pipe); 2363 1.1 bouyer 2364 1.1 bouyer pipe->endpoint->datatoggle = otgpipe->nexttoggle; 2365 1.1 bouyer SIMPLEQ_FOREACH(otgpipeiter, &otgpipe->hw_ep->ep_pipes, ep_pipe_list) { 2366 1.1 bouyer if (otgpipeiter == otgpipe) { 2367 1.1 bouyer /* remove from list */ 2368 1.1 bouyer SIMPLEQ_REMOVE(&otgpipe->hw_ep->ep_pipes, otgpipe, 2369 1.1 bouyer motg_pipe, ep_pipe_list); 2370 1.1 bouyer otgpipe->hw_ep->refcount--; 2371 1.1 bouyer /* we're done */ 2372 1.1 bouyer return; 2373 1.1 bouyer } 2374 1.1 bouyer } 2375 1.1 bouyer panic("motg_device_data_close: not found"); 2376 1.1 bouyer } 2377 1.1 bouyer 2378 1.1 bouyer void 2379 1.1 bouyer motg_device_data_done(usbd_xfer_handle xfer) 2380 1.1 bouyer { 2381 1.8 skrll struct motg_pipe *otgpipe __diagused = (struct motg_pipe *)xfer->pipe; 2382 1.1 bouyer DPRINTFN(MD_CTRL, ("motg_device_data_done:\n")); 2383 1.1 bouyer KASSERT(otgpipe->hw_ep->xfer != xfer); 2384 1.1 bouyer } 2385 1.1 bouyer 2386 1.1 bouyer /* 2387 1.1 bouyer * Wait here until controller claims to have an interrupt. 2388 1.1 bouyer * Then call motg_intr and return. Use timeout to avoid waiting 2389 1.1 bouyer * too long. 2390 1.1 bouyer * Only used during boot when interrupts are not enabled yet. 2391 1.1 bouyer */ 2392 1.1 bouyer void 2393 1.1 bouyer motg_waitintr(struct motg_softc *sc, usbd_xfer_handle xfer) 2394 1.1 bouyer { 2395 1.1 bouyer int timo = xfer->timeout; 2396 1.1 bouyer 2397 1.1 bouyer mutex_enter(&sc->sc_lock); 2398 1.1 bouyer 2399 1.1 bouyer DPRINTF(("motg_waitintr: timeout = %dms\n", timo)); 2400 1.1 bouyer 2401 1.1 bouyer for (; timo >= 0; timo--) { 2402 1.1 bouyer mutex_exit(&sc->sc_lock); 2403 1.1 bouyer usb_delay_ms(&sc->sc_bus, 1); 2404 1.1 bouyer mutex_spin_enter(&sc->sc_intr_lock); 2405 1.1 bouyer motg_poll(&sc->sc_bus); 2406 1.1 bouyer mutex_spin_exit(&sc->sc_intr_lock); 2407 1.1 bouyer mutex_enter(&sc->sc_lock); 2408 1.1 bouyer if (xfer->status != USBD_IN_PROGRESS) 2409 1.1 bouyer goto done; 2410 1.1 bouyer } 2411 1.1 bouyer 2412 1.1 bouyer /* Timeout */ 2413 1.1 bouyer DPRINTF(("motg_waitintr: timeout\n")); 2414 1.1 bouyer panic("motg_waitintr: timeout"); 2415 1.1 bouyer /* XXX handle timeout ! */ 2416 1.1 bouyer 2417 1.1 bouyer done: 2418 1.1 bouyer mutex_exit(&sc->sc_lock); 2419 1.1 bouyer } 2420 1.1 bouyer 2421 1.1 bouyer void 2422 1.1 bouyer motg_device_clear_toggle(usbd_pipe_handle pipe) 2423 1.1 bouyer { 2424 1.1 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)pipe; 2425 1.1 bouyer otgpipe->nexttoggle = 0; 2426 1.1 bouyer } 2427 1.3 bouyer 2428 1.3 bouyer /* Abort a device control request. */ 2429 1.3 bouyer static void 2430 1.3 bouyer motg_device_xfer_abort(usbd_xfer_handle xfer) 2431 1.3 bouyer { 2432 1.3 bouyer int wake; 2433 1.3 bouyer uint8_t csr; 2434 1.3 bouyer struct motg_softc *sc = xfer->pipe->device->bus->hci_private; 2435 1.3 bouyer struct motg_pipe *otgpipe = (struct motg_pipe *)xfer->pipe; 2436 1.3 bouyer KASSERT(mutex_owned(&sc->sc_lock)); 2437 1.3 bouyer 2438 1.3 bouyer DPRINTF(("motg_device_xfer_abort:\n")); 2439 1.3 bouyer if (xfer->hcflags & UXFER_ABORTING) { 2440 1.3 bouyer DPRINTF(("motg_device_xfer_abort: already aborting\n")); 2441 1.3 bouyer xfer->hcflags |= UXFER_ABORTWAIT; 2442 1.3 bouyer while (xfer->hcflags & UXFER_ABORTING) 2443 1.6 skrll cv_wait(&xfer->hccv, &sc->sc_lock); 2444 1.3 bouyer return; 2445 1.3 bouyer } 2446 1.3 bouyer xfer->hcflags |= UXFER_ABORTING; 2447 1.3 bouyer if (otgpipe->hw_ep->xfer == xfer) { 2448 1.3 bouyer KASSERT(xfer->status == USBD_IN_PROGRESS); 2449 1.3 bouyer otgpipe->hw_ep->xfer = NULL; 2450 1.3 bouyer if (otgpipe->hw_ep->ep_number > 0) { 2451 1.7 skrll /* select endpoint */ 2452 1.3 bouyer UWRITE1(sc, MUSB2_REG_EPINDEX, 2453 1.3 bouyer otgpipe->hw_ep->ep_number); 2454 1.3 bouyer if (otgpipe->hw_ep->phase == DATA_OUT) { 2455 1.3 bouyer csr = UREAD1(sc, MUSB2_REG_TXCSRL); 2456 1.3 bouyer while (csr & MUSB2_MASK_CSRL_TXFIFONEMPTY) { 2457 1.3 bouyer csr |= MUSB2_MASK_CSRL_TXFFLUSH; 2458 1.3 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, csr); 2459 1.3 bouyer csr = UREAD1(sc, MUSB2_REG_TXCSRL); 2460 1.3 bouyer } 2461 1.3 bouyer UWRITE1(sc, MUSB2_REG_TXCSRL, 0); 2462 1.3 bouyer } else if (otgpipe->hw_ep->phase == DATA_IN) { 2463 1.3 bouyer csr = UREAD1(sc, MUSB2_REG_RXCSRL); 2464 1.3 bouyer while (csr & MUSB2_MASK_CSRL_RXPKTRDY) { 2465 1.3 bouyer csr |= MUSB2_MASK_CSRL_RXFFLUSH; 2466 1.3 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, csr); 2467 1.3 bouyer csr = UREAD1(sc, MUSB2_REG_RXCSRL); 2468 1.3 bouyer } 2469 1.3 bouyer UWRITE1(sc, MUSB2_REG_RXCSRL, 0); 2470 1.3 bouyer } 2471 1.3 bouyer otgpipe->hw_ep->phase = IDLE; 2472 1.3 bouyer } 2473 1.3 bouyer } 2474 1.3 bouyer xfer->status = USBD_CANCELLED; /* make software ignore it */ 2475 1.3 bouyer wake = xfer->hcflags & UXFER_ABORTWAIT; 2476 1.3 bouyer xfer->hcflags &= ~(UXFER_ABORTING | UXFER_ABORTWAIT); 2477 1.3 bouyer usb_transfer_complete(xfer); 2478 1.3 bouyer if (wake) 2479 1.3 bouyer cv_broadcast(&xfer->hccv); 2480 1.3 bouyer } 2481
Indexes created Tue Oct 14 21:09:58 GMT 2025