pxa2x0_ac97.c revision 1.14.10.1
1 1.14.10.1 christos /* $NetBSD: pxa2x0_ac97.c,v 1.14.10.1 2019/06/10 22:05:57 christos Exp $ */ 2 1.1 scw 3 1.1 scw /* 4 1.1 scw * Copyright (c) 2003, 2005 Wasabi Systems, Inc. 5 1.1 scw * All rights reserved. 6 1.1 scw * 7 1.1 scw * Written by Steve C. Woodford for Wasabi Systems, Inc. 8 1.1 scw * 9 1.1 scw * Redistribution and use in source and binary forms, with or without 10 1.1 scw * modification, are permitted provided that the following conditions 11 1.1 scw * are met: 12 1.1 scw * 1. Redistributions of source code must retain the above copyright 13 1.1 scw * notice, this list of conditions and the following disclaimer. 14 1.1 scw * 2. Redistributions in binary form must reproduce the above copyright 15 1.1 scw * notice, this list of conditions and the following disclaimer in the 16 1.1 scw * documentation and/or other materials provided with the distribution. 17 1.1 scw * 3. All advertising materials mentioning features or use of this software 18 1.1 scw * must display the following acknowledgement: 19 1.1 scw * This product includes software developed for the NetBSD Project by 20 1.1 scw * Wasabi Systems, Inc. 21 1.1 scw * 4. The name of Wasabi Systems, Inc. may not be used to endorse 22 1.1 scw * or promote products derived from this software without specific prior 23 1.1 scw * written permission. 24 1.1 scw * 25 1.1 scw * THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND 26 1.1 scw * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 27 1.1 scw * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 28 1.1 scw * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL WASABI SYSTEMS, INC 29 1.1 scw * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 30 1.1 scw * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 31 1.1 scw * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 32 1.1 scw * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 33 1.1 scw * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 34 1.1 scw * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 35 1.1 scw * POSSIBILITY OF SUCH DAMAGE. 36 1.1 scw */ 37 1.1 scw 38 1.1 scw #include <sys/param.h> 39 1.1 scw #include <sys/systm.h> 40 1.1 scw #include <sys/device.h> 41 1.1 scw #include <sys/kernel.h> 42 1.1 scw #include <sys/malloc.h> 43 1.1 scw #include <sys/select.h> 44 1.1 scw #include <sys/audioio.h> 45 1.10 jmcneill #include <sys/kmem.h> 46 1.1 scw 47 1.1 scw #include <machine/intr.h> 48 1.9 dyoung #include <sys/bus.h> 49 1.1 scw 50 1.14.10.1 christos #include <dev/audio/audio_if.h> 51 1.1 scw #include <dev/ic/ac97reg.h> 52 1.1 scw #include <dev/ic/ac97var.h> 53 1.1 scw 54 1.6 kiyohara #include <arm/xscale/pxa2x0cpu.h> 55 1.1 scw #include <arm/xscale/pxa2x0reg.h> 56 1.1 scw #include <arm/xscale/pxa2x0var.h> 57 1.1 scw #include <arm/xscale/pxa2x0_gpio.h> 58 1.1 scw #include <arm/xscale/pxa2x0_dmac.h> 59 1.1 scw 60 1.1 scw #include "locators.h" 61 1.1 scw 62 1.1 scw struct acu_dma { 63 1.1 scw bus_dmamap_t ad_map; 64 1.5 christos void *ad_addr; 65 1.1 scw #define ACU_N_SEGS 1 /* XXX: We don't support > 1 */ 66 1.1 scw bus_dma_segment_t ad_segs[ACU_N_SEGS]; 67 1.1 scw int ad_nsegs; 68 1.1 scw size_t ad_size; 69 1.1 scw struct dmac_xfer *ad_dx; 70 1.1 scw struct acu_dma *ad_next; 71 1.1 scw }; 72 1.1 scw 73 1.1 scw #define KERNADDR(ad) ((void *)((ad)->ad_addr)) 74 1.1 scw 75 1.1 scw struct acu_softc { 76 1.8 nonaka device_t sc_dev; 77 1.1 scw bus_space_tag_t sc_bust; 78 1.1 scw bus_dma_tag_t sc_dmat; 79 1.1 scw bus_space_handle_t sc_bush; 80 1.1 scw void *sc_irqcookie; 81 1.1 scw int sc_in_reset; 82 1.1 scw u_int sc_dac_rate; 83 1.1 scw u_int sc_adc_rate; 84 1.1 scw 85 1.1 scw /* List of DMA ring-buffers allocated by acu_malloc() */ 86 1.1 scw struct acu_dma *sc_dmas; 87 1.1 scw 88 1.1 scw /* Dummy DMA segment which points to the AC97 PCM Fifo register */ 89 1.1 scw bus_dma_segment_t sc_dr; 90 1.1 scw 91 1.1 scw /* PCM Output (Tx) state */ 92 1.1 scw dmac_peripheral_t sc_txp; 93 1.1 scw struct acu_dma *sc_txdma; 94 1.1 scw void (*sc_txfunc)(void *); 95 1.1 scw void *sc_txarg; 96 1.1 scw 97 1.1 scw /* PCM Input (Rx) state */ 98 1.1 scw dmac_peripheral_t sc_rxp; 99 1.1 scw struct acu_dma *sc_rxdma; 100 1.1 scw void (*sc_rxfunc)(void *); 101 1.1 scw void *sc_rxarg; 102 1.1 scw 103 1.1 scw /* AC97 Codec State */ 104 1.1 scw struct ac97_codec_if *sc_codec_if; 105 1.1 scw struct ac97_host_if sc_host_if; 106 1.1 scw 107 1.1 scw /* Child audio(4) device */ 108 1.12 chs device_t sc_audiodev; 109 1.1 scw 110 1.10 jmcneill /* MPSAFE interfaces */ 111 1.10 jmcneill kmutex_t sc_lock; 112 1.10 jmcneill kmutex_t sc_intr_lock; 113 1.1 scw }; 114 1.1 scw 115 1.8 nonaka static int pxaacu_match(device_t, cfdata_t, void *); 116 1.8 nonaka static void pxaacu_attach(device_t, device_t, void *); 117 1.1 scw 118 1.8 nonaka CFATTACH_DECL_NEW(pxaacu, sizeof(struct acu_softc), 119 1.1 scw pxaacu_match, pxaacu_attach, NULL, NULL); 120 1.1 scw 121 1.1 scw static int acu_codec_attach(void *, struct ac97_codec_if *); 122 1.13 skrll static int acu_codec_read(void *, uint8_t, uint16_t *); 123 1.13 skrll static int acu_codec_write(void *, uint8_t, uint16_t); 124 1.1 scw static int acu_codec_reset(void *); 125 1.1 scw static int acu_intr(void *); 126 1.1 scw 127 1.1 scw static int acu_open(void *, int); 128 1.1 scw static void acu_close(void *); 129 1.14.10.1 christos static int acu_query_format(void *, audio_format_query_t *); 130 1.14.10.1 christos static int acu_set_format(void *, int, 131 1.14.10.1 christos const audio_params_t *, const audio_params_t *, 132 1.14.10.1 christos audio_filter_reg_t *, audio_filter_reg_t *); 133 1.1 scw static int acu_round_blocksize(void *, int, int, const audio_params_t *); 134 1.1 scw static int acu_halt_output(void *); 135 1.1 scw static int acu_halt_input(void *); 136 1.1 scw static int acu_trigger_output(void *, void *, void *, int, void (*)(void *), 137 1.1 scw void *, const audio_params_t *); 138 1.1 scw static int acu_trigger_input(void *, void *, void *, int, void (*)(void *), 139 1.1 scw void *, const audio_params_t *); 140 1.1 scw static void acu_tx_loop_segment(struct dmac_xfer *, int); 141 1.1 scw static void acu_rx_loop_segment(struct dmac_xfer *, int); 142 1.1 scw static int acu_getdev(void *, struct audio_device *); 143 1.1 scw static int acu_mixer_set_port(void *, mixer_ctrl_t *); 144 1.1 scw static int acu_mixer_get_port(void *, mixer_ctrl_t *); 145 1.1 scw static int acu_query_devinfo(void *, mixer_devinfo_t *); 146 1.10 jmcneill static void *acu_malloc(void *, int, size_t); 147 1.10 jmcneill static void acu_free(void *, void *, size_t); 148 1.1 scw static int acu_get_props(void *); 149 1.10 jmcneill static void acu_get_locks(void *, kmutex_t **, kmutex_t **); 150 1.1 scw 151 1.1 scw struct audio_hw_if acu_hw_if = { 152 1.14.10.1 christos .open = acu_open, 153 1.14.10.1 christos .close = acu_close, 154 1.14.10.1 christos .query_format = acu_query_format, 155 1.14.10.1 christos .set_format = acu_set_format, 156 1.14.10.1 christos .round_blocksize = acu_round_blocksize, 157 1.14.10.1 christos .halt_output = acu_halt_output, 158 1.14.10.1 christos .halt_input = acu_halt_input, 159 1.14.10.1 christos .getdev = acu_getdev, 160 1.14.10.1 christos .set_port = acu_mixer_set_port, 161 1.14.10.1 christos .get_port = acu_mixer_get_port, 162 1.14.10.1 christos .query_devinfo = acu_query_devinfo, 163 1.14.10.1 christos .allocm = acu_malloc, 164 1.14.10.1 christos .freem = acu_free, 165 1.14.10.1 christos .get_props = acu_get_props, 166 1.14.10.1 christos .trigger_output = acu_trigger_output, 167 1.14.10.1 christos .trigger_input = acu_trigger_input, 168 1.14.10.1 christos .get_locks = acu_get_locks, 169 1.1 scw }; 170 1.1 scw 171 1.1 scw struct audio_device acu_device = { 172 1.1 scw "PXA250 AC97", 173 1.1 scw "", 174 1.1 scw "acu" 175 1.1 scw }; 176 1.1 scw 177 1.1 scw static const struct audio_format acu_formats[] = { 178 1.14.10.1 christos { 179 1.14.10.1 christos .mode = AUMODE_PLAY | AUMODE_RECORD, 180 1.14.10.1 christos .encoding = AUDIO_ENCODING_SLINEAR_LE, 181 1.14.10.1 christos .validbits = 16, 182 1.14.10.1 christos .precision = 16, 183 1.14.10.1 christos .channels = 2, 184 1.14.10.1 christos .channel_mask = AUFMT_STEREO, 185 1.14.10.1 christos .frequency_type = 0, 186 1.14.10.1 christos /* XXX Need an accurate list of frequencies. */ 187 1.14.10.1 christos .frequency = { 4000, 48000 }, 188 1.14.10.1 christos }, 189 1.1 scw }; 190 1.1 scw #define ACU_NFORMATS (sizeof(acu_formats) / sizeof(struct audio_format)) 191 1.1 scw 192 1.13 skrll static inline uint32_t 193 1.1 scw acu_reg_read(struct acu_softc *sc, int reg) 194 1.1 scw { 195 1.1 scw 196 1.1 scw return (bus_space_read_4(sc->sc_bust, sc->sc_bush, reg)); 197 1.1 scw } 198 1.1 scw 199 1.3 perry static inline void 200 1.13 skrll acu_reg_write(struct acu_softc *sc, int reg, uint32_t val) 201 1.1 scw { 202 1.1 scw 203 1.1 scw bus_space_write_4(sc->sc_bust, sc->sc_bush, reg, val); 204 1.1 scw } 205 1.1 scw 206 1.3 perry static inline int 207 1.1 scw acu_codec_ready(struct acu_softc *sc) 208 1.1 scw { 209 1.1 scw 210 1.1 scw return (acu_reg_read(sc, AC97_GSR) & GSR_PCR); 211 1.1 scw } 212 1.1 scw 213 1.3 perry static inline int 214 1.13 skrll acu_wait_gsr(struct acu_softc *sc, uint32_t bit) 215 1.1 scw { 216 1.1 scw int timeout; 217 1.13 skrll uint32_t rv; 218 1.1 scw 219 1.1 scw for (timeout = 5000; timeout; timeout--) { 220 1.1 scw if ((rv = acu_reg_read(sc, AC97_GSR)) & bit) { 221 1.1 scw acu_reg_write(sc, AC97_GSR, rv | bit); 222 1.1 scw return (0); 223 1.1 scw } 224 1.1 scw delay(1); 225 1.1 scw } 226 1.1 scw 227 1.1 scw return (1); 228 1.1 scw } 229 1.1 scw 230 1.1 scw static int 231 1.8 nonaka pxaacu_match(device_t parent, cfdata_t cf, void *aux) 232 1.1 scw { 233 1.1 scw struct pxaip_attach_args *pxa = aux; 234 1.6 kiyohara struct pxa2x0_gpioconf *gpioconf; 235 1.6 kiyohara u_int gpio; 236 1.6 kiyohara int i; 237 1.1 scw 238 1.1 scw if (pxa->pxa_addr != PXA2X0_AC97_BASE || 239 1.1 scw pxa->pxa_intr != PXA2X0_INT_AC97) 240 1.1 scw return (0); 241 1.1 scw 242 1.6 kiyohara gpioconf = CPU_IS_PXA250 ? pxa25x_pxaacu_gpioconf : 243 1.6 kiyohara pxa27x_pxaacu_gpioconf; 244 1.6 kiyohara for (i = 0; gpioconf[i].pin != -1; i++) { 245 1.6 kiyohara gpio = pxa2x0_gpio_get_function(gpioconf[i].pin); 246 1.6 kiyohara if (GPIO_FN(gpio) != GPIO_FN(gpioconf[i].value) || 247 1.6 kiyohara GPIO_FN_IS_OUT(gpio) != GPIO_FN_IS_OUT(gpioconf[i].value)) 248 1.6 kiyohara return (0); 249 1.6 kiyohara } 250 1.6 kiyohara 251 1.1 scw pxa->pxa_size = PXA2X0_AC97_SIZE; 252 1.1 scw 253 1.1 scw return (1); 254 1.1 scw } 255 1.1 scw 256 1.1 scw static void 257 1.8 nonaka pxaacu_attach(device_t parent, device_t self, void *aux) 258 1.1 scw { 259 1.8 nonaka struct acu_softc *sc = device_private(self); 260 1.1 scw struct pxaip_attach_args *pxa = aux; 261 1.1 scw 262 1.8 nonaka sc->sc_dev = self; 263 1.1 scw sc->sc_bust = pxa->pxa_iot; 264 1.1 scw sc->sc_dmat = pxa->pxa_dmat; 265 1.1 scw 266 1.1 scw aprint_naive("\n"); 267 1.1 scw aprint_normal(": AC97 Controller\n"); 268 1.1 scw 269 1.1 scw if (bus_space_map(sc->sc_bust, pxa->pxa_addr, pxa->pxa_size, 0, 270 1.1 scw &sc->sc_bush)) { 271 1.8 nonaka aprint_error_dev(self, "Can't map registers!\n"); 272 1.1 scw return; 273 1.1 scw } 274 1.1 scw 275 1.11 mrg sc->sc_irqcookie = pxa2x0_intr_establish(pxa->pxa_intr, IPL_AUDIO, 276 1.1 scw acu_intr, sc); 277 1.1 scw KASSERT(sc->sc_irqcookie != NULL); 278 1.1 scw 279 1.1 scw /* Make sure the AC97 clock is enabled */ 280 1.4 thorpej pxa2x0_clkman_config(CKEN_AC97, true); 281 1.1 scw delay(100); 282 1.1 scw 283 1.1 scw /* Do a cold reset */ 284 1.1 scw acu_reg_write(sc, AC97_GCR, 0); 285 1.1 scw delay(100); 286 1.1 scw acu_reg_write(sc, AC97_GCR, GCR_COLD_RST); 287 1.1 scw delay(100); 288 1.1 scw acu_reg_write(sc, AC97_CAR, 0); 289 1.1 scw 290 1.1 scw if (acu_wait_gsr(sc, GSR_PCR)) { 291 1.1 scw acu_reg_write(sc, AC97_GCR, 0); 292 1.1 scw delay(100); 293 1.4 thorpej pxa2x0_clkman_config(CKEN_AC97, false); 294 1.1 scw bus_space_unmap(sc->sc_bust, sc->sc_bush, pxa->pxa_size); 295 1.8 nonaka aprint_error_dev(self, "Primary codec not ready\n"); 296 1.1 scw return; 297 1.1 scw } 298 1.1 scw 299 1.1 scw sc->sc_dr.ds_addr = pxa->pxa_addr + AC97_PCDR; 300 1.1 scw sc->sc_dr.ds_len = 4; 301 1.1 scw 302 1.1 scw sc->sc_codec_if = NULL; 303 1.1 scw sc->sc_host_if.arg = sc; 304 1.1 scw sc->sc_host_if.attach = acu_codec_attach; 305 1.1 scw sc->sc_host_if.read = acu_codec_read; 306 1.1 scw sc->sc_host_if.write = acu_codec_write; 307 1.1 scw sc->sc_host_if.reset = acu_codec_reset; 308 1.1 scw sc->sc_host_if.flags = NULL; 309 1.1 scw sc->sc_in_reset = 0; 310 1.1 scw sc->sc_dac_rate = sc->sc_adc_rate = 0; 311 1.1 scw 312 1.10 jmcneill if (ac97_attach(&sc->sc_host_if, sc->sc_dev, &sc->sc_lock)) { 313 1.8 nonaka aprint_error_dev(self, "Failed to attach primary codec\n"); 314 1.1 scw acu_reg_write(sc, AC97_GCR, 0); 315 1.1 scw delay(100); 316 1.4 thorpej pxa2x0_clkman_config(CKEN_AC97, false); 317 1.1 scw bus_space_unmap(sc->sc_bust, sc->sc_bush, pxa->pxa_size); 318 1.1 scw return; 319 1.1 scw } 320 1.1 scw 321 1.8 nonaka sc->sc_audiodev = audio_attach_mi(&acu_hw_if, sc, sc->sc_dev); 322 1.1 scw 323 1.1 scw /* 324 1.1 scw * As a work-around for braindamage in the PXA250's AC97 controller 325 1.1 scw * (see errata #125), we hold the ACUNIT/Codec in Cold Reset until 326 1.1 scw * acu_open() is called. acu_close() also puts the controller into 327 1.1 scw * Cold Reset. 328 1.1 scw * 329 1.1 scw * While this won't necessarily prevent Rx FIFO overruns, it at least 330 1.1 scw * allows the user to recover by closing then re-opening the audio 331 1.1 scw * device. 332 1.1 scw */ 333 1.1 scw acu_reg_write(sc, AC97_GCR, 0); 334 1.1 scw sc->sc_in_reset = 1; 335 1.1 scw } 336 1.1 scw 337 1.1 scw static int 338 1.1 scw acu_codec_attach(void *arg, struct ac97_codec_if *aci) 339 1.1 scw { 340 1.1 scw struct acu_softc *sc = arg; 341 1.1 scw 342 1.1 scw sc->sc_codec_if = aci; 343 1.1 scw return (0); 344 1.1 scw } 345 1.1 scw 346 1.1 scw static int 347 1.13 skrll acu_codec_read(void *arg, uint8_t codec_reg, uint16_t *valp) 348 1.1 scw { 349 1.1 scw struct acu_softc *sc = arg; 350 1.13 skrll uint32_t val; 351 1.10 jmcneill int reg, rv = 1; 352 1.1 scw 353 1.1 scw /* 354 1.1 scw * If we're currently closed, return non-zero. The ac97 frontend 355 1.1 scw * will use its cached copy of the register instead. 356 1.1 scw */ 357 1.1 scw if (sc->sc_in_reset) 358 1.1 scw return (1); 359 1.1 scw 360 1.1 scw reg = AC97_CODEC_BASE(0) + codec_reg * 2; 361 1.1 scw 362 1.10 jmcneill mutex_spin_enter(&sc->sc_intr_lock); 363 1.1 scw 364 1.1 scw if (!acu_codec_ready(sc) || (acu_reg_read(sc, AC97_CAR) & CAR_CAIP)) 365 1.1 scw goto out_nocar; 366 1.1 scw 367 1.1 scw val = acu_reg_read(sc, AC97_GSR); 368 1.1 scw val |= GSR_RDCS | GSR_SDONE; 369 1.1 scw acu_reg_write(sc, AC97_GSR, val); 370 1.1 scw 371 1.1 scw /* 372 1.1 scw * Dummy read to initiate the real read access 373 1.1 scw */ 374 1.1 scw (void) acu_reg_read(sc, reg); 375 1.1 scw if (acu_wait_gsr(sc, GSR_SDONE)) 376 1.1 scw goto out; 377 1.1 scw 378 1.1 scw (void) acu_reg_read(sc, reg); 379 1.1 scw if (acu_wait_gsr(sc, GSR_SDONE)) 380 1.1 scw goto out; 381 1.1 scw 382 1.1 scw val = acu_reg_read(sc, AC97_GSR); 383 1.1 scw if (val & GSR_RDCS) 384 1.1 scw goto out; 385 1.1 scw 386 1.1 scw *valp = acu_reg_read(sc, reg); 387 1.1 scw if (acu_wait_gsr(sc, GSR_SDONE)) 388 1.1 scw goto out; 389 1.1 scw 390 1.1 scw rv = 0; 391 1.1 scw 392 1.1 scw out: 393 1.1 scw acu_reg_write(sc, AC97_CAR, 0); 394 1.1 scw out_nocar: 395 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 396 1.1 scw delay(10); 397 1.1 scw return (rv); 398 1.1 scw } 399 1.1 scw 400 1.1 scw static int 401 1.13 skrll acu_codec_write(void *arg, uint8_t codec_reg, uint16_t val) 402 1.1 scw { 403 1.1 scw struct acu_softc *sc = arg; 404 1.13 skrll uint16_t rv; 405 1.1 scw 406 1.1 scw /* 407 1.1 scw * If we're currently closed, chances are the user is just 408 1.1 scw * tweaking mixer settings. Pretend the write succeeded. 409 1.1 scw * The ac97 frontend will cache the value anyway, and it'll 410 1.1 scw * be written correctly when the driver is opened. 411 1.1 scw */ 412 1.1 scw if (sc->sc_in_reset) 413 1.1 scw return (0); 414 1.1 scw 415 1.10 jmcneill mutex_spin_enter(&sc->sc_intr_lock); 416 1.1 scw 417 1.1 scw if (!acu_codec_ready(sc) || (acu_reg_read(sc, AC97_CAR) & CAR_CAIP)) { 418 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 419 1.1 scw return (1); 420 1.1 scw } 421 1.1 scw 422 1.1 scw rv = acu_reg_read(sc, AC97_GSR); 423 1.1 scw rv |= GSR_RDCS | GSR_CDONE; 424 1.1 scw acu_reg_write(sc, AC97_GSR, rv); 425 1.1 scw 426 1.1 scw acu_reg_write(sc, AC97_CODEC_BASE(0) + codec_reg * 2, val); 427 1.1 scw 428 1.1 scw /* 429 1.1 scw * Wait for the write to complete 430 1.1 scw */ 431 1.1 scw (void) acu_wait_gsr(sc, GSR_CDONE); 432 1.1 scw acu_reg_write(sc, AC97_CAR, 0); 433 1.1 scw 434 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 435 1.1 scw delay(10); 436 1.1 scw return (0); 437 1.1 scw } 438 1.1 scw 439 1.1 scw static int 440 1.1 scw acu_codec_reset(void *arg) 441 1.1 scw { 442 1.1 scw struct acu_softc *sc = arg; 443 1.13 skrll uint32_t rv; 444 1.1 scw 445 1.1 scw rv = acu_reg_read(sc, AC97_GCR); 446 1.1 scw acu_reg_write(sc, AC97_GCR, rv | GCR_WARM_RST); 447 1.1 scw delay(100); 448 1.1 scw acu_reg_write(sc, AC97_GCR, rv); 449 1.1 scw delay(100); 450 1.1 scw 451 1.1 scw if (acu_wait_gsr(sc, GSR_PCR)) { 452 1.8 nonaka aprint_error_dev(sc->sc_dev, 453 1.8 nonaka "acu_codec_reset: failed to ready after reset\n"); 454 1.1 scw return (ETIMEDOUT); 455 1.1 scw } 456 1.1 scw 457 1.1 scw return (0); 458 1.1 scw } 459 1.1 scw 460 1.1 scw static int 461 1.1 scw acu_intr(void *arg) 462 1.1 scw { 463 1.1 scw struct acu_softc *sc = arg; 464 1.13 skrll uint32_t gsr, reg; 465 1.1 scw 466 1.10 jmcneill mutex_spin_enter(&sc->sc_intr_lock); 467 1.1 scw gsr = acu_reg_read(sc, AC97_GSR); 468 1.1 scw 469 1.1 scw /* 470 1.1 scw * Tx FIFO underruns are no big deal. Just log it and ignore and 471 1.1 scw * subsequent underruns until the next time acu_trigger_output() 472 1.1 scw * is called. 473 1.1 scw */ 474 1.1 scw if ((gsr & GSR_POINT) && (acu_reg_read(sc, AC97_POCR) & AC97_FEFIE)) { 475 1.1 scw acu_reg_write(sc, AC97_POCR, 0); 476 1.1 scw reg = acu_reg_read(sc, AC97_POSR); 477 1.1 scw acu_reg_write(sc, AC97_POSR, reg); 478 1.8 nonaka aprint_error_dev(sc->sc_dev, "Tx PCM Fifo underrun\n"); 479 1.1 scw } 480 1.1 scw 481 1.1 scw /* 482 1.1 scw * Rx FIFO overruns are a different story. See PAX250 Errata #125 483 1.1 scw * for the gory details. 484 1.1 scw * I don't see any way to gracefully recover from this problem, 485 1.1 scw * other than a issuing a Cold Reset in acu_close(). 486 1.1 scw * The best we can do here is to report the problem on the console. 487 1.1 scw */ 488 1.1 scw if ((gsr & GSR_PIINT) && (acu_reg_read(sc, AC97_PICR) & AC97_FEFIE)) { 489 1.1 scw acu_reg_write(sc, AC97_PICR, 0); 490 1.1 scw reg = acu_reg_read(sc, AC97_PISR); 491 1.1 scw acu_reg_write(sc, AC97_PISR, reg); 492 1.8 nonaka aprint_error_dev(sc->sc_dev, "Rx PCM Fifo overrun\n"); 493 1.1 scw } 494 1.1 scw 495 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 496 1.10 jmcneill 497 1.1 scw return (1); 498 1.1 scw } 499 1.1 scw 500 1.1 scw static int 501 1.1 scw acu_open(void *arg, int flags) 502 1.1 scw { 503 1.1 scw struct acu_softc *sc = arg; 504 1.1 scw 505 1.1 scw /* 506 1.1 scw * Deassert Cold Reset 507 1.1 scw */ 508 1.1 scw acu_reg_write(sc, AC97_GCR, GCR_COLD_RST); 509 1.1 scw delay(100); 510 1.1 scw acu_reg_write(sc, AC97_CAR, 0); 511 1.1 scw 512 1.1 scw /* 513 1.1 scw * Wait for the primary codec to become ready 514 1.1 scw */ 515 1.1 scw if (acu_wait_gsr(sc, GSR_PCR)) 516 1.1 scw return (EIO); 517 1.1 scw sc->sc_in_reset = 0; 518 1.1 scw 519 1.1 scw /* 520 1.1 scw * Restore the codec port settings 521 1.1 scw */ 522 1.1 scw sc->sc_codec_if->vtbl->restore_ports(sc->sc_codec_if); 523 1.1 scw 524 1.1 scw /* 525 1.1 scw * Need to reprogram the sample rates, since 'restore_ports' 526 1.1 scw * doesn't do it. 527 1.1 scw * 528 1.1 scw * XXX: These aren't the only two sample rate registers ... 529 1.1 scw */ 530 1.1 scw if (sc->sc_dac_rate) 531 1.1 scw (void) sc->sc_codec_if->vtbl->set_rate(sc->sc_codec_if, 532 1.1 scw AC97_REG_PCM_FRONT_DAC_RATE, &sc->sc_dac_rate); 533 1.1 scw if (sc->sc_adc_rate) 534 1.1 scw (void) sc->sc_codec_if->vtbl->set_rate(sc->sc_codec_if, 535 1.1 scw AC97_REG_PCM_LR_ADC_RATE, &sc->sc_adc_rate); 536 1.1 scw 537 1.1 scw return (0); 538 1.1 scw } 539 1.1 scw 540 1.1 scw static void 541 1.1 scw acu_close(void *arg) 542 1.1 scw { 543 1.1 scw struct acu_softc *sc = arg; 544 1.1 scw 545 1.1 scw /* 546 1.1 scw * Make sure the hardware is quiescent 547 1.1 scw */ 548 1.1 scw acu_halt_output(sc); 549 1.1 scw acu_halt_input(sc); 550 1.1 scw delay(100); 551 1.1 scw 552 1.1 scw /* Assert Cold Reset */ 553 1.1 scw acu_reg_write(sc, AC97_GCR, 0); 554 1.1 scw sc->sc_in_reset = 1; 555 1.1 scw } 556 1.1 scw 557 1.1 scw static int 558 1.14.10.1 christos acu_query_format(void *arg, audio_format_query_t *afp) 559 1.1 scw { 560 1.1 scw 561 1.14.10.1 christos return audio_query_format(acu_formats, ACU_NFORMATS, afp); 562 1.1 scw } 563 1.1 scw 564 1.1 scw static int 565 1.14.10.1 christos acu_set_format(void *arg, int setmode, 566 1.14.10.1 christos const audio_params_t *play, const audio_params_t *rec, 567 1.14.10.1 christos audio_filter_reg_t *pfil, audio_filter_reg_t *rfil) 568 1.1 scw { 569 1.1 scw struct acu_softc *sc = arg; 570 1.14.10.1 christos int rate; 571 1.14.10.1 christos int err; 572 1.1 scw 573 1.14.10.1 christos if ((setmode & AUMODE_PLAY)) { 574 1.14.10.1 christos rate = play->sample_rate; 575 1.14.10.1 christos err = sc->sc_codec_if->vtbl->set_rate(sc->sc_codec_if, 576 1.14.10.1 christos AC97_REG_PCM_FRONT_DAC_RATE, &rate); 577 1.1 scw if (err) 578 1.14.10.1 christos return EINVAL; 579 1.14.10.1 christos sc->sc_dac_rate = play->sample_rate; 580 1.1 scw } 581 1.14.10.1 christos if ((setmode & AUMODE_RECORD)) { 582 1.14.10.1 christos rate = rec->sample_rate; 583 1.14.10.1 christos err = sc->sc_codec_if->vtbl->set_rate(sc->sc_codec_if, 584 1.14.10.1 christos AC97_REG_PCM_LR_ADC_RATE, &rate); 585 1.14.10.1 christos if (err) 586 1.14.10.1 christos return EINVAL; 587 1.14.10.1 christos sc->sc_adc_rate = rec->sample_rate; 588 1.14.10.1 christos } 589 1.14.10.1 christos return 0; 590 1.1 scw } 591 1.1 scw 592 1.1 scw static int 593 1.1 scw acu_round_blocksize(void *arg, int blk, int mode, const audio_params_t *param) 594 1.1 scw { 595 1.1 scw 596 1.1 scw return (blk & ~0x1f); 597 1.1 scw } 598 1.1 scw 599 1.1 scw static int 600 1.1 scw acu_getdev(void *addr, struct audio_device *retp) 601 1.1 scw { 602 1.1 scw 603 1.1 scw *retp = acu_device; 604 1.1 scw return (0); 605 1.1 scw } 606 1.1 scw 607 1.1 scw static int 608 1.1 scw acu_mixer_set_port(void *arg, mixer_ctrl_t *cp) 609 1.1 scw { 610 1.1 scw struct acu_softc *sc = arg; 611 1.1 scw 612 1.1 scw return (sc->sc_codec_if->vtbl->mixer_set_port(sc->sc_codec_if, cp)); 613 1.1 scw } 614 1.1 scw 615 1.1 scw static int 616 1.1 scw acu_mixer_get_port(void *arg, mixer_ctrl_t *cp) 617 1.1 scw { 618 1.1 scw struct acu_softc *sc = arg; 619 1.1 scw 620 1.1 scw return (sc->sc_codec_if->vtbl->mixer_get_port(sc->sc_codec_if, cp)); 621 1.1 scw } 622 1.1 scw 623 1.1 scw static int 624 1.1 scw acu_query_devinfo(void *arg, mixer_devinfo_t *dip) 625 1.1 scw { 626 1.1 scw struct acu_softc *sc = arg; 627 1.1 scw 628 1.1 scw return (sc->sc_codec_if->vtbl->query_devinfo(sc->sc_codec_if, dip)); 629 1.1 scw } 630 1.1 scw 631 1.1 scw static void * 632 1.10 jmcneill acu_malloc(void *arg, int direction, size_t size) 633 1.1 scw { 634 1.1 scw struct acu_softc *sc = arg; 635 1.1 scw struct acu_dma *ad; 636 1.1 scw int error; 637 1.1 scw 638 1.14 chs ad = kmem_alloc(sizeof(*ad), KM_SLEEP); 639 1.1 scw 640 1.10 jmcneill /* XXX */ 641 1.10 jmcneill if ((ad->ad_dx = pxa2x0_dmac_allocate_xfer()) == NULL) 642 1.1 scw goto error; 643 1.1 scw 644 1.1 scw ad->ad_size = size; 645 1.1 scw 646 1.1 scw error = bus_dmamem_alloc(sc->sc_dmat, size, 16, 0, ad->ad_segs, 647 1.10 jmcneill ACU_N_SEGS, &ad->ad_nsegs, BUS_DMA_WAITOK); 648 1.1 scw if (error) 649 1.1 scw goto free_xfer; 650 1.1 scw 651 1.1 scw error = bus_dmamem_map(sc->sc_dmat, ad->ad_segs, ad->ad_nsegs, size, 652 1.10 jmcneill &ad->ad_addr, BUS_DMA_WAITOK | BUS_DMA_COHERENT | BUS_DMA_NOCACHE); 653 1.1 scw if (error) 654 1.1 scw goto free_dmamem; 655 1.1 scw 656 1.1 scw error = bus_dmamap_create(sc->sc_dmat, size, 1, size, 0, 657 1.10 jmcneill BUS_DMA_WAITOK | BUS_DMA_ALLOCNOW, &ad->ad_map); 658 1.1 scw if (error) 659 1.1 scw goto unmap_dmamem; 660 1.1 scw 661 1.1 scw error = bus_dmamap_load(sc->sc_dmat, ad->ad_map, ad->ad_addr, size, 662 1.10 jmcneill NULL, BUS_DMA_WAITOK); 663 1.1 scw if (error) { 664 1.1 scw bus_dmamap_destroy(sc->sc_dmat, ad->ad_map); 665 1.1 scw unmap_dmamem: bus_dmamem_unmap(sc->sc_dmat, ad->ad_addr, size); 666 1.1 scw free_dmamem: bus_dmamem_free(sc->sc_dmat, ad->ad_segs, ad->ad_nsegs); 667 1.1 scw free_xfer: pxa2x0_dmac_free_xfer(ad->ad_dx); 668 1.10 jmcneill error: kmem_free(ad, sizeof(*ad)); 669 1.1 scw return (NULL); 670 1.1 scw } 671 1.1 scw 672 1.1 scw ad->ad_dx->dx_cookie = sc; 673 1.1 scw ad->ad_dx->dx_priority = DMAC_PRIORITY_HIGH; 674 1.1 scw ad->ad_dx->dx_dev_width = DMAC_DEV_WIDTH_4; 675 1.1 scw ad->ad_dx->dx_burst_size = DMAC_BURST_SIZE_32; 676 1.1 scw 677 1.1 scw ad->ad_next = sc->sc_dmas; 678 1.1 scw sc->sc_dmas = ad; 679 1.1 scw return (KERNADDR(ad)); 680 1.1 scw } 681 1.1 scw 682 1.1 scw static void 683 1.10 jmcneill acu_free(void *arg, void *ptr, size_t size) 684 1.1 scw { 685 1.1 scw struct acu_softc *sc = arg; 686 1.1 scw struct acu_dma *ad, **adp; 687 1.1 scw 688 1.1 scw for (adp = &sc->sc_dmas; (ad = *adp) != NULL; adp = &ad->ad_next) { 689 1.1 scw if (KERNADDR(ad) == ptr) { 690 1.1 scw pxa2x0_dmac_abort_xfer(ad->ad_dx); 691 1.1 scw pxa2x0_dmac_free_xfer(ad->ad_dx); 692 1.1 scw ad->ad_segs[0].ds_len = ad->ad_size; /* XXX */ 693 1.1 scw bus_dmamap_unload(sc->sc_dmat, ad->ad_map); 694 1.1 scw bus_dmamap_destroy(sc->sc_dmat, ad->ad_map); 695 1.1 scw bus_dmamem_unmap(sc->sc_dmat, ad->ad_addr, ad->ad_size); 696 1.1 scw bus_dmamem_free(sc->sc_dmat, ad->ad_segs, ad->ad_nsegs); 697 1.1 scw *adp = ad->ad_next; 698 1.10 jmcneill kmem_free(ad, sizeof(*ad)); 699 1.1 scw return; 700 1.1 scw } 701 1.1 scw } 702 1.1 scw } 703 1.1 scw 704 1.1 scw static int 705 1.1 scw acu_get_props(void *arg) 706 1.1 scw { 707 1.1 scw 708 1.14.10.1 christos return (AUDIO_PROP_PLAYBACK | AUDIO_PROP_CAPTURE | 709 1.14.10.1 christos AUDIO_PROP_INDEPENDENT | AUDIO_PROP_FULLDUPLEX); 710 1.1 scw } 711 1.1 scw 712 1.10 jmcneill static void 713 1.10 jmcneill acu_get_locks(void *opaque, kmutex_t **intr, kmutex_t **thread) 714 1.10 jmcneill { 715 1.10 jmcneill struct acu_softc *sc = opaque; 716 1.10 jmcneill 717 1.10 jmcneill *intr = &sc->sc_intr_lock; 718 1.10 jmcneill *thread = &sc->sc_lock; 719 1.10 jmcneill } 720 1.10 jmcneill 721 1.1 scw static int 722 1.1 scw acu_halt_output(void *arg) 723 1.1 scw { 724 1.1 scw struct acu_softc *sc = arg; 725 1.1 scw 726 1.10 jmcneill mutex_spin_enter(&sc->sc_intr_lock); 727 1.1 scw if (sc->sc_txdma) { 728 1.1 scw acu_reg_write(sc, AC97_POCR, 0); 729 1.1 scw acu_reg_write(sc, AC97_POSR, AC97_FIFOE); 730 1.1 scw pxa2x0_dmac_abort_xfer(sc->sc_txdma->ad_dx); 731 1.1 scw sc->sc_txdma = NULL; 732 1.1 scw } 733 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 734 1.1 scw return (0); 735 1.1 scw } 736 1.1 scw 737 1.1 scw static int 738 1.1 scw acu_halt_input(void *arg) 739 1.1 scw { 740 1.1 scw struct acu_softc *sc = arg; 741 1.1 scw 742 1.10 jmcneill mutex_spin_enter(&sc->sc_intr_lock); 743 1.1 scw if (sc->sc_rxdma) { 744 1.1 scw acu_reg_write(sc, AC97_PICR, 0); 745 1.1 scw acu_reg_write(sc, AC97_PISR, AC97_FIFOE); 746 1.1 scw pxa2x0_dmac_abort_xfer(sc->sc_rxdma->ad_dx); 747 1.1 scw sc->sc_rxdma = NULL; 748 1.1 scw } 749 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 750 1.1 scw return (0); 751 1.1 scw } 752 1.1 scw 753 1.1 scw static int 754 1.1 scw acu_trigger_output(void *arg, void *start, void *end, int blksize, 755 1.1 scw void (*tx_func)(void *), void *tx_arg, const audio_params_t *param) 756 1.1 scw { 757 1.1 scw struct acu_softc *sc = arg; 758 1.1 scw struct dmac_xfer *dx; 759 1.1 scw struct acu_dma *ad; 760 1.1 scw int rv; 761 1.1 scw 762 1.1 scw if (sc->sc_txdma) 763 1.1 scw return (EBUSY); 764 1.1 scw 765 1.1 scw sc->sc_txfunc = tx_func; 766 1.1 scw sc->sc_txarg = tx_arg; 767 1.1 scw 768 1.1 scw for (ad = sc->sc_dmas; ad && KERNADDR(ad) != start; ad = ad->ad_next) 769 1.1 scw ; 770 1.1 scw if (ad == NULL) { 771 1.1 scw printf("acu_trigger_output: bad addr %p\n", start); 772 1.1 scw return (EINVAL); 773 1.1 scw } 774 1.1 scw 775 1.1 scw sc->sc_txdma = ad; 776 1.1 scw ad->ad_segs[0].ds_addr = ad->ad_map->dm_segs[0].ds_addr; 777 1.1 scw ad->ad_segs[0].ds_len = (uintptr_t)end - (uintptr_t)start; 778 1.1 scw 779 1.1 scw /* 780 1.1 scw * Fix up a looping DMA request. 781 1.1 scw * The 'done' function will be called for every 'blksize' bytes 782 1.1 scw * transferred by the DMA engine. 783 1.1 scw */ 784 1.1 scw dx = ad->ad_dx; 785 1.1 scw dx->dx_done = acu_tx_loop_segment; 786 1.1 scw dx->dx_peripheral = DMAC_PERIPH_AC97AUDIOTX; 787 1.1 scw dx->dx_flow = DMAC_FLOW_CTRL_DEST; 788 1.1 scw dx->dx_loop_notify = blksize; 789 1.4 thorpej dx->dx_desc[DMAC_DESC_SRC].xd_addr_hold = false; 790 1.1 scw dx->dx_desc[DMAC_DESC_SRC].xd_nsegs = ad->ad_nsegs; 791 1.1 scw dx->dx_desc[DMAC_DESC_SRC].xd_dma_segs = ad->ad_segs; 792 1.4 thorpej dx->dx_desc[DMAC_DESC_DST].xd_addr_hold = true; 793 1.1 scw dx->dx_desc[DMAC_DESC_DST].xd_nsegs = 1; 794 1.1 scw dx->dx_desc[DMAC_DESC_DST].xd_dma_segs = &sc->sc_dr; 795 1.1 scw 796 1.1 scw rv = pxa2x0_dmac_start_xfer(dx); 797 1.1 scw if (rv == 0) { 798 1.1 scw /* 799 1.1 scw * XXX: We should only do this once the request has been 800 1.1 scw * loaded into a DMAC channel. 801 1.1 scw */ 802 1.1 scw acu_reg_write(sc, AC97_POSR, AC97_FIFOE); 803 1.1 scw acu_reg_write(sc, AC97_POCR, AC97_FEFIE); 804 1.1 scw } 805 1.1 scw 806 1.1 scw return (rv); 807 1.1 scw } 808 1.1 scw 809 1.1 scw static int 810 1.1 scw acu_trigger_input(void *arg, void *start, void *end, int blksize, 811 1.1 scw void (*rx_func)(void *), void *rx_arg, const audio_params_t *param) 812 1.1 scw { 813 1.1 scw struct acu_softc *sc = arg; 814 1.1 scw struct dmac_xfer *dx; 815 1.1 scw struct acu_dma *ad; 816 1.1 scw int rv; 817 1.1 scw 818 1.1 scw if (sc->sc_rxdma) 819 1.1 scw return (EBUSY); 820 1.1 scw 821 1.1 scw sc->sc_rxfunc = rx_func; 822 1.1 scw sc->sc_rxarg = rx_arg; 823 1.1 scw 824 1.1 scw for (ad = sc->sc_dmas; ad && KERNADDR(ad) != start; ad = ad->ad_next) 825 1.1 scw ; 826 1.1 scw if (ad == NULL) { 827 1.1 scw printf("acu_trigger_input: bad addr %p\n", start); 828 1.1 scw return (EINVAL); 829 1.1 scw } 830 1.1 scw 831 1.1 scw sc->sc_rxdma = ad; 832 1.1 scw ad->ad_segs[0].ds_addr = ad->ad_map->dm_segs[0].ds_addr; 833 1.1 scw ad->ad_segs[0].ds_len = (uintptr_t)end - (uintptr_t)start; 834 1.1 scw 835 1.1 scw /* 836 1.1 scw * Fix up a looping DMA request. 837 1.1 scw * The 'done' function will be called for every 'blksize' bytes 838 1.1 scw * transferred by the DMA engine. 839 1.1 scw */ 840 1.1 scw dx = ad->ad_dx; 841 1.1 scw dx->dx_done = acu_rx_loop_segment; 842 1.1 scw dx->dx_peripheral = DMAC_PERIPH_AC97AUDIORX; 843 1.1 scw dx->dx_flow = DMAC_FLOW_CTRL_SRC; 844 1.1 scw dx->dx_loop_notify = blksize; 845 1.4 thorpej dx->dx_desc[DMAC_DESC_DST].xd_addr_hold = false; 846 1.1 scw dx->dx_desc[DMAC_DESC_DST].xd_nsegs = ad->ad_nsegs; 847 1.1 scw dx->dx_desc[DMAC_DESC_DST].xd_dma_segs = ad->ad_segs; 848 1.4 thorpej dx->dx_desc[DMAC_DESC_SRC].xd_addr_hold = true; 849 1.1 scw dx->dx_desc[DMAC_DESC_SRC].xd_nsegs = 1; 850 1.1 scw dx->dx_desc[DMAC_DESC_SRC].xd_dma_segs = &sc->sc_dr; 851 1.1 scw 852 1.1 scw rv = pxa2x0_dmac_start_xfer(dx); 853 1.1 scw 854 1.1 scw if (rv == 0) { 855 1.1 scw /* 856 1.1 scw * XXX: We should only do this once the request has been 857 1.1 scw * loaded into a DMAC channel. 858 1.1 scw */ 859 1.1 scw acu_reg_write(sc, AC97_PISR, AC97_FIFOE); 860 1.1 scw acu_reg_write(sc, AC97_PICR, AC97_FEFIE); 861 1.1 scw } 862 1.1 scw 863 1.1 scw return (rv); 864 1.1 scw } 865 1.1 scw 866 1.1 scw static void 867 1.1 scw acu_tx_loop_segment(struct dmac_xfer *dx, int status) 868 1.1 scw { 869 1.1 scw struct acu_softc *sc = dx->dx_cookie; 870 1.1 scw struct acu_dma *ad; 871 1.1 scw 872 1.1 scw if ((ad = sc->sc_txdma) == NULL) 873 1.1 scw panic("acu_tx_loop_segment: bad TX dma descriptor!"); 874 1.1 scw 875 1.1 scw if (ad->ad_dx != dx) 876 1.1 scw panic("acu_tx_loop_segment: xfer mismatch!"); 877 1.1 scw 878 1.1 scw if (status) { 879 1.8 nonaka aprint_error_dev(sc->sc_dev, 880 1.8 nonaka "acu_tx_loop_segment: non-zero completion status %d\n", 881 1.8 nonaka status); 882 1.1 scw } 883 1.1 scw 884 1.10 jmcneill mutex_spin_enter(&sc->sc_intr_lock); 885 1.1 scw (sc->sc_txfunc)(sc->sc_txarg); 886 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 887 1.1 scw } 888 1.1 scw 889 1.1 scw static void 890 1.1 scw acu_rx_loop_segment(struct dmac_xfer *dx, int status) 891 1.1 scw { 892 1.1 scw struct acu_softc *sc = dx->dx_cookie; 893 1.1 scw struct acu_dma *ad; 894 1.1 scw 895 1.1 scw if ((ad = sc->sc_rxdma) == NULL) 896 1.1 scw panic("acu_rx_loop_segment: bad RX dma descriptor!"); 897 1.1 scw 898 1.1 scw if (ad->ad_dx != dx) 899 1.1 scw panic("acu_rx_loop_segment: xfer mismatch!"); 900 1.1 scw 901 1.1 scw if (status) { 902 1.8 nonaka aprint_error_dev(sc->sc_dev, 903 1.8 nonaka "acu_rx_loop_segment: non-zero completion status %d\n", 904 1.8 nonaka status); 905 1.1 scw } 906 1.1 scw 907 1.10 jmcneill mutex_spin_enter(&sc->sc_intr_lock); 908 1.1 scw (sc->sc_rxfunc)(sc->sc_rxarg); 909 1.10 jmcneill mutex_spin_exit(&sc->sc_intr_lock); 910 1.1 scw } 911
Indexes created Thu Oct 23 22:10:10 GMT 2025