diff --git a/sys/dev/sound/pci/hda/hdaa.c b/sys/dev/sound/pci/hda/hdaa.c index ac62c04b5374..1e486b01b168 100644 --- a/sys/dev/sound/pci/hda/hdaa.c +++ b/sys/dev/sound/pci/hda/hdaa.c @@ -1,7147 +1,7147 @@ /*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2006 Stephane E. Potvin * Copyright (c) 2006 Ariff Abdullah * Copyright (c) 2008-2012 Alexander Motin * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * Intel High Definition Audio (Audio function) driver for FreeBSD. */ #ifdef HAVE_KERNEL_OPTION_HEADERS #include "opt_snd.h" #endif #include #include #include #include #include #include #include "mixer_if.h" #define hdaa_lock(devinfo) snd_mtxlock((devinfo)->lock) #define hdaa_unlock(devinfo) snd_mtxunlock((devinfo)->lock) #define hdaa_lockassert(devinfo) snd_mtxassert((devinfo)->lock) static const struct { const char *key; uint32_t value; } hdaa_quirks_tab[] = { { "softpcmvol", HDAA_QUIRK_SOFTPCMVOL }, { "fixedrate", HDAA_QUIRK_FIXEDRATE }, { "forcestereo", HDAA_QUIRK_FORCESTEREO }, { "eapdinv", HDAA_QUIRK_EAPDINV }, { "senseinv", HDAA_QUIRK_SENSEINV }, { "ivref50", HDAA_QUIRK_IVREF50 }, { "ivref80", HDAA_QUIRK_IVREF80 }, { "ivref100", HDAA_QUIRK_IVREF100 }, { "ovref50", HDAA_QUIRK_OVREF50 }, { "ovref80", HDAA_QUIRK_OVREF80 }, { "ovref100", HDAA_QUIRK_OVREF100 }, { "ivref", HDAA_QUIRK_IVREF }, { "ovref", HDAA_QUIRK_OVREF }, { "vref", HDAA_QUIRK_VREF }, }; #define HDA_PARSE_MAXDEPTH 10 MALLOC_DEFINE(M_HDAA, "hdaa", "HDA Audio"); static const char *HDA_COLORS[16] = {"Unknown", "Black", "Grey", "Blue", "Green", "Red", "Orange", "Yellow", "Purple", "Pink", "Res.A", "Res.B", "Res.C", "Res.D", "White", "Other"}; static const char *HDA_DEVS[16] = {"Line-out", "Speaker", "Headphones", "CD", "SPDIF-out", "Digital-out", "Modem-line", "Modem-handset", "Line-in", "AUX", "Mic", "Telephony", "SPDIF-in", "Digital-in", "Res.E", "Other"}; static const char *HDA_CONNS[4] = {"Jack", "None", "Fixed", "Both"}; static const char *HDA_CONNECTORS[16] = { "Unknown", "1/8", "1/4", "ATAPI", "RCA", "Optical", "Digital", "Analog", "DIN", "XLR", "RJ-11", "Combo", "0xc", "0xd", "0xe", "Other" }; static const char *HDA_LOCS[64] = { "0x00", "Rear", "Front", "Left", "Right", "Top", "Bottom", "Rear-panel", "Drive-bay", "0x09", "0x0a", "0x0b", "0x0c", "0x0d", "0x0e", "0x0f", "Internal", "0x11", "0x12", "0x13", "0x14", "0x15", "0x16", "Riser", "0x18", "Onboard", "0x1a", "0x1b", "0x1c", "0x1d", "0x1e", "0x1f", "External", "Ext-Rear", "Ext-Front", "Ext-Left", "Ext-Right", "Ext-Top", "Ext-Bottom", "0x07", "0x28", "0x29", "0x2a", "0x2b", "0x2c", "0x2d", "0x2e", "0x2f", "Other", "0x31", "0x32", "0x33", "0x34", "0x35", "Other-Bott", "Lid-In", "Lid-Out", "0x39", "0x3a", "0x3b", "0x3c", "0x3d", "0x3e", "0x3f" }; static const char *HDA_GPIO_ACTIONS[8] = { "keep", "set", "clear", "disable", "input", "0x05", "0x06", "0x07"}; static const char *HDA_HDMI_CODING_TYPES[18] = { "undefined", "LPCM", "AC-3", "MPEG1", "MP3", "MPEG2", "AAC-LC", "DTS", "ATRAC", "DSD", "E-AC-3", "DTS-HD", "MLP", "DST", "WMAPro", "HE-AAC", "HE-AACv2", "MPEG-Surround" }; /* Default */ static uint32_t hdaa_fmt[] = { SND_FORMAT(AFMT_S16_LE, 2, 0), 0 }; static struct pcmchan_caps hdaa_caps = {48000, 48000, hdaa_fmt, 0}; static const struct { uint32_t rate; int valid; uint16_t base; uint16_t mul; uint16_t div; } hda_rate_tab[] = { { 8000, 1, 0x0000, 0x0000, 0x0500 }, /* (48000 * 1) / 6 */ { 9600, 0, 0x0000, 0x0000, 0x0400 }, /* (48000 * 1) / 5 */ { 12000, 0, 0x0000, 0x0000, 0x0300 }, /* (48000 * 1) / 4 */ { 16000, 1, 0x0000, 0x0000, 0x0200 }, /* (48000 * 1) / 3 */ { 18000, 0, 0x0000, 0x1000, 0x0700 }, /* (48000 * 3) / 8 */ { 19200, 0, 0x0000, 0x0800, 0x0400 }, /* (48000 * 2) / 5 */ { 24000, 0, 0x0000, 0x0000, 0x0100 }, /* (48000 * 1) / 2 */ { 28800, 0, 0x0000, 0x1000, 0x0400 }, /* (48000 * 3) / 5 */ { 32000, 1, 0x0000, 0x0800, 0x0200 }, /* (48000 * 2) / 3 */ { 36000, 0, 0x0000, 0x1000, 0x0300 }, /* (48000 * 3) / 4 */ { 38400, 0, 0x0000, 0x1800, 0x0400 }, /* (48000 * 4) / 5 */ { 48000, 1, 0x0000, 0x0000, 0x0000 }, /* (48000 * 1) / 1 */ { 64000, 0, 0x0000, 0x1800, 0x0200 }, /* (48000 * 4) / 3 */ { 72000, 0, 0x0000, 0x1000, 0x0100 }, /* (48000 * 3) / 2 */ { 96000, 1, 0x0000, 0x0800, 0x0000 }, /* (48000 * 2) / 1 */ { 144000, 0, 0x0000, 0x1000, 0x0000 }, /* (48000 * 3) / 1 */ { 192000, 1, 0x0000, 0x1800, 0x0000 }, /* (48000 * 4) / 1 */ { 8820, 0, 0x4000, 0x0000, 0x0400 }, /* (44100 * 1) / 5 */ { 11025, 1, 0x4000, 0x0000, 0x0300 }, /* (44100 * 1) / 4 */ { 12600, 0, 0x4000, 0x0800, 0x0600 }, /* (44100 * 2) / 7 */ { 14700, 0, 0x4000, 0x0000, 0x0200 }, /* (44100 * 1) / 3 */ { 17640, 0, 0x4000, 0x0800, 0x0400 }, /* (44100 * 2) / 5 */ { 18900, 0, 0x4000, 0x1000, 0x0600 }, /* (44100 * 3) / 7 */ { 22050, 1, 0x4000, 0x0000, 0x0100 }, /* (44100 * 1) / 2 */ { 25200, 0, 0x4000, 0x1800, 0x0600 }, /* (44100 * 4) / 7 */ { 26460, 0, 0x4000, 0x1000, 0x0400 }, /* (44100 * 3) / 5 */ { 29400, 0, 0x4000, 0x0800, 0x0200 }, /* (44100 * 2) / 3 */ { 33075, 0, 0x4000, 0x1000, 0x0300 }, /* (44100 * 3) / 4 */ { 35280, 0, 0x4000, 0x1800, 0x0400 }, /* (44100 * 4) / 5 */ { 44100, 1, 0x4000, 0x0000, 0x0000 }, /* (44100 * 1) / 1 */ { 58800, 0, 0x4000, 0x1800, 0x0200 }, /* (44100 * 4) / 3 */ { 66150, 0, 0x4000, 0x1000, 0x0100 }, /* (44100 * 3) / 2 */ { 88200, 1, 0x4000, 0x0800, 0x0000 }, /* (44100 * 2) / 1 */ { 132300, 0, 0x4000, 0x1000, 0x0000 }, /* (44100 * 3) / 1 */ { 176400, 1, 0x4000, 0x1800, 0x0000 }, /* (44100 * 4) / 1 */ }; #define HDA_RATE_TAB_LEN (sizeof(hda_rate_tab) / sizeof(hda_rate_tab[0])) const static char *ossnames[] = SOUND_DEVICE_NAMES; /**************************************************************************** * Function prototypes ****************************************************************************/ static int hdaa_pcmchannel_setup(struct hdaa_chan *); static void hdaa_widget_connection_select(struct hdaa_widget *, uint8_t); static void hdaa_audio_ctl_amp_set(struct hdaa_audio_ctl *, uint32_t, int, int); static struct hdaa_audio_ctl *hdaa_audio_ctl_amp_get(struct hdaa_devinfo *, nid_t, int, int, int); static void hdaa_audio_ctl_amp_set_internal(struct hdaa_devinfo *, nid_t, int, int, int, int, int, int); static void hdaa_dump_pin_config(struct hdaa_widget *w, uint32_t conf); static char * hdaa_audio_ctl_ossmixer_mask2allname(uint32_t mask, char *buf, size_t len) { int i, first = 1; bzero(buf, len); for (i = 0; i < SOUND_MIXER_NRDEVICES; i++) { if (mask & (1 << i)) { if (first == 0) strlcat(buf, ", ", len); strlcat(buf, ossnames[i], len); first = 0; } } return (buf); } static struct hdaa_audio_ctl * hdaa_audio_ctl_each(struct hdaa_devinfo *devinfo, int *index) { if (devinfo == NULL || index == NULL || devinfo->ctl == NULL || devinfo->ctlcnt < 1 || *index < 0 || *index >= devinfo->ctlcnt) return (NULL); return (&devinfo->ctl[(*index)++]); } static struct hdaa_audio_ctl * hdaa_audio_ctl_amp_get(struct hdaa_devinfo *devinfo, nid_t nid, int dir, int index, int cnt) { struct hdaa_audio_ctl *ctl; int i, found = 0; if (devinfo == NULL || devinfo->ctl == NULL) return (NULL); i = 0; while ((ctl = hdaa_audio_ctl_each(devinfo, &i)) != NULL) { if (ctl->enable == 0) continue; if (ctl->widget->nid != nid) continue; if (dir && ctl->ndir != dir) continue; if (index >= 0 && ctl->ndir == HDAA_CTL_IN && ctl->dir == ctl->ndir && ctl->index != index) continue; found++; if (found == cnt || cnt <= 0) return (ctl); } return (NULL); } static const struct matrix { struct pcmchan_matrix m; int analog; } matrixes[] = { { SND_CHN_MATRIX_MAP_1_0, 1 }, { SND_CHN_MATRIX_MAP_2_0, 1 }, { SND_CHN_MATRIX_MAP_2_1, 0 }, { SND_CHN_MATRIX_MAP_3_0, 0 }, { SND_CHN_MATRIX_MAP_3_1, 0 }, { SND_CHN_MATRIX_MAP_4_0, 1 }, { SND_CHN_MATRIX_MAP_4_1, 0 }, { SND_CHN_MATRIX_MAP_5_0, 0 }, { SND_CHN_MATRIX_MAP_5_1, 1 }, { SND_CHN_MATRIX_MAP_6_0, 0 }, { SND_CHN_MATRIX_MAP_6_1, 0 }, { SND_CHN_MATRIX_MAP_7_0, 0 }, { SND_CHN_MATRIX_MAP_7_1, 1 }, }; static const char *channel_names[] = SND_CHN_T_NAMES; /* * Connected channels change handler. */ static void hdaa_channels_handler(struct hdaa_audio_as *as) { struct hdaa_pcm_devinfo *pdevinfo = as->pdevinfo; struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_chan *ch = &devinfo->chans[as->chans[0]]; struct hdaa_widget *w; uint8_t *eld; int total, sub, assume, channels; size_t i; uint16_t cpins, upins, tpins; cpins = upins = 0; eld = NULL; for (i = 0; i < 16; i++) { if (as->pins[i] <= 0) continue; w = hdaa_widget_get(devinfo, as->pins[i]); if (w == NULL) continue; if (w->wclass.pin.connected == 1) cpins |= (1 << i); else if (w->wclass.pin.connected != 0) upins |= (1 << i); if (w->eld != NULL && w->eld_len >= 8) eld = w->eld; } tpins = cpins | upins; if (as->hpredir >= 0) tpins &= 0x7fff; if (tpins == 0) tpins = as->pinset; total = sub = assume = channels = 0; if (eld) { /* Map CEA speakers to sound(4) channels. */ if (eld[7] & 0x01) /* Front Left/Right */ channels |= SND_CHN_T_MASK_FL | SND_CHN_T_MASK_FR; if (eld[7] & 0x02) /* Low Frequency Effect */ channels |= SND_CHN_T_MASK_LF; if (eld[7] & 0x04) /* Front Center */ channels |= SND_CHN_T_MASK_FC; if (eld[7] & 0x08) { /* Rear Left/Right */ /* If we have both RLR and RLRC, report RLR as side. */ if (eld[7] & 0x40) /* Rear Left/Right Center */ channels |= SND_CHN_T_MASK_SL | SND_CHN_T_MASK_SR; else channels |= SND_CHN_T_MASK_BL | SND_CHN_T_MASK_BR; } if (eld[7] & 0x10) /* Rear center */ channels |= SND_CHN_T_MASK_BC; if (eld[7] & 0x20) /* Front Left/Right Center */ channels |= SND_CHN_T_MASK_FLC | SND_CHN_T_MASK_FRC; if (eld[7] & 0x40) /* Rear Left/Right Center */ channels |= SND_CHN_T_MASK_BL | SND_CHN_T_MASK_BR; } else if (as->pinset != 0 && (tpins & 0xffe0) == 0) { /* Map UAA speakers to sound(4) channels. */ if (tpins & 0x0001) channels |= SND_CHN_T_MASK_FL | SND_CHN_T_MASK_FR; if (tpins & 0x0002) channels |= SND_CHN_T_MASK_FC | SND_CHN_T_MASK_LF; if (tpins & 0x0004) channels |= SND_CHN_T_MASK_BL | SND_CHN_T_MASK_BR; if (tpins & 0x0008) channels |= SND_CHN_T_MASK_FLC | SND_CHN_T_MASK_FRC; if (tpins & 0x0010) { /* If there is no back pin, report side as back. */ if ((as->pinset & 0x0004) == 0) channels |= SND_CHN_T_MASK_BL | SND_CHN_T_MASK_BR; else channels |= SND_CHN_T_MASK_SL | SND_CHN_T_MASK_SR; } } else if (as->mixed) { /* Mixed assoc can be only stereo or theoretically mono. */ if (ch->channels == 1) channels |= SND_CHN_T_MASK_FC; else channels |= SND_CHN_T_MASK_FL | SND_CHN_T_MASK_FR; } if (channels) { /* We have some usable channels info. */ HDA_BOOTVERBOSE( device_printf(pdevinfo->dev, "%s channel set is: ", as->dir == HDAA_CTL_OUT ? "Playback" : "Recording"); for (i = 0; i < SND_CHN_T_MAX; i++) if (channels & (1 << i)) printf("%s, ", channel_names[i]); printf("\n"); ); /* Look for maximal fitting matrix. */ for (i = 0; i < nitems(matrixes); i++) { if (as->pinset != 0 && matrixes[i].analog == 0) continue; if ((matrixes[i].m.mask & ~channels) == 0) { total = matrixes[i].m.channels; sub = matrixes[i].m.ext; } } } if (total == 0) { assume = 1; total = ch->channels; sub = (total == 6 || total == 8) ? 1 : 0; } HDA_BOOTVERBOSE( device_printf(pdevinfo->dev, "%s channel matrix is: %s%d.%d (%s)\n", as->dir == HDAA_CTL_OUT ? "Playback" : "Recording", assume ? "unknown, assuming " : "", total - sub, sub, cpins != 0 ? "connected" : (upins != 0 ? "unknown" : "disconnected")); ); } /* * Headphones redirection change handler. */ static void hdaa_hpredir_handler(struct hdaa_widget *w) { struct hdaa_devinfo *devinfo = w->devinfo; struct hdaa_audio_as *as = &devinfo->as[w->bindas]; struct hdaa_widget *w1; struct hdaa_audio_ctl *ctl; uint32_t val; int j, connected = w->wclass.pin.connected; HDA_BOOTVERBOSE( device_printf((as->pdevinfo && as->pdevinfo->dev) ? as->pdevinfo->dev : devinfo->dev, "Redirect output to: %s\n", connected ? "headphones": "main"); ); /* (Un)Mute headphone pin. */ ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_IN, -1, 1); if (ctl != NULL && ctl->mute) { /* If pin has muter - use it. */ val = connected ? 0 : 1; if (val != ctl->forcemute) { ctl->forcemute = val; hdaa_audio_ctl_amp_set(ctl, HDAA_AMP_MUTE_DEFAULT, HDAA_AMP_VOL_DEFAULT, HDAA_AMP_VOL_DEFAULT); } } else { /* If there is no muter - disable pin output. */ if (connected) val = w->wclass.pin.ctrl | HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE; else val = w->wclass.pin.ctrl & ~HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE; if (val != w->wclass.pin.ctrl) { w->wclass.pin.ctrl = val; hda_command(devinfo->dev, HDA_CMD_SET_PIN_WIDGET_CTRL(0, w->nid, w->wclass.pin.ctrl)); } } /* (Un)Mute other pins. */ for (j = 0; j < 15; j++) { if (as->pins[j] <= 0) continue; ctl = hdaa_audio_ctl_amp_get(devinfo, as->pins[j], HDAA_CTL_IN, -1, 1); if (ctl != NULL && ctl->mute) { /* If pin has muter - use it. */ val = connected ? 1 : 0; if (val == ctl->forcemute) continue; ctl->forcemute = val; hdaa_audio_ctl_amp_set(ctl, HDAA_AMP_MUTE_DEFAULT, HDAA_AMP_VOL_DEFAULT, HDAA_AMP_VOL_DEFAULT); continue; } /* If there is no muter - disable pin output. */ w1 = hdaa_widget_get(devinfo, as->pins[j]); if (w1 != NULL) { if (connected) val = w1->wclass.pin.ctrl & ~HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE; else val = w1->wclass.pin.ctrl | HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE; if (val != w1->wclass.pin.ctrl) { w1->wclass.pin.ctrl = val; hda_command(devinfo->dev, HDA_CMD_SET_PIN_WIDGET_CTRL(0, w1->nid, w1->wclass.pin.ctrl)); } } } } /* * Recording source change handler. */ static void hdaa_autorecsrc_handler(struct hdaa_audio_as *as, struct hdaa_widget *w) { struct hdaa_pcm_devinfo *pdevinfo = as->pdevinfo; struct hdaa_devinfo *devinfo; struct hdaa_widget *w1; int i, mask, fullmask, prio, bestprio; char buf[128]; if (!as->mixed || pdevinfo == NULL || pdevinfo->mixer == NULL) return; /* Don't touch anything if we asked not to. */ if (pdevinfo->autorecsrc == 0 || (pdevinfo->autorecsrc == 1 && w != NULL)) return; /* Don't touch anything if "mix" or "speaker" selected. */ if (pdevinfo->recsrc & (SOUND_MASK_IMIX | SOUND_MASK_SPEAKER)) return; /* Don't touch anything if several selected. */ if (ffs(pdevinfo->recsrc) != fls(pdevinfo->recsrc)) return; devinfo = pdevinfo->devinfo; mask = fullmask = 0; bestprio = 0; for (i = 0; i < 16; i++) { if (as->pins[i] <= 0) continue; w1 = hdaa_widget_get(devinfo, as->pins[i]); if (w1 == NULL || w1->enable == 0) continue; if (w1->wclass.pin.connected == 0) continue; prio = (w1->wclass.pin.connected == 1) ? 2 : 1; if (prio < bestprio) continue; if (prio > bestprio) { mask = 0; bestprio = prio; } mask |= (1 << w1->ossdev); fullmask |= (1 << w1->ossdev); } if (mask == 0) return; /* Prefer newly connected input. */ if (w != NULL && (mask & (1 << w->ossdev))) mask = (1 << w->ossdev); /* Prefer previously selected input */ if (mask & pdevinfo->recsrc) mask &= pdevinfo->recsrc; /* Prefer mic. */ if (mask & SOUND_MASK_MIC) mask = SOUND_MASK_MIC; /* Prefer monitor (2nd mic). */ if (mask & SOUND_MASK_MONITOR) mask = SOUND_MASK_MONITOR; /* Just take first one. */ mask = (1 << (ffs(mask) - 1)); HDA_BOOTVERBOSE( hdaa_audio_ctl_ossmixer_mask2allname(mask, buf, sizeof(buf)); device_printf(pdevinfo->dev, "Automatically set rec source to: %s\n", buf); ); hdaa_unlock(devinfo); mix_setrecsrc(pdevinfo->mixer, mask); hdaa_lock(devinfo); } /* * Jack presence detection event handler. */ static void hdaa_presence_handler(struct hdaa_widget *w) { struct hdaa_devinfo *devinfo = w->devinfo; struct hdaa_audio_as *as; uint32_t res; int connected, old; if (w->enable == 0 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) return; if (HDA_PARAM_PIN_CAP_PRESENCE_DETECT_CAP(w->wclass.pin.cap) == 0 || (HDA_CONFIG_DEFAULTCONF_MISC(w->wclass.pin.config) & 1) != 0) return; res = hda_command(devinfo->dev, HDA_CMD_GET_PIN_SENSE(0, w->nid)); connected = (res & HDA_CMD_GET_PIN_SENSE_PRESENCE_DETECT) != 0; if (devinfo->quirks & HDAA_QUIRK_SENSEINV) connected = !connected; old = w->wclass.pin.connected; if (connected == old) return; w->wclass.pin.connected = connected; HDA_BOOTVERBOSE( if (connected || old != 2) { device_printf(devinfo->dev, "Pin sense: nid=%d sense=0x%08x (%sconnected)\n", w->nid, res, !connected ? "dis" : ""); } ); as = &devinfo->as[w->bindas]; if (as->hpredir >= 0 && as->pins[15] == w->nid) hdaa_hpredir_handler(w); if (as->dir == HDAA_CTL_IN && old != 2) hdaa_autorecsrc_handler(as, w); if (old != 2) hdaa_channels_handler(as); } /* * Callback for poll based presence detection. */ static void hdaa_jack_poll_callback(void *arg) { struct hdaa_devinfo *devinfo = arg; struct hdaa_widget *w; int i; hdaa_lock(devinfo); if (devinfo->poll_ival == 0) { hdaa_unlock(devinfo); return; } for (i = 0; i < devinfo->ascnt; i++) { if (devinfo->as[i].hpredir < 0) continue; w = hdaa_widget_get(devinfo, devinfo->as[i].pins[15]); if (w == NULL || w->enable == 0 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; hdaa_presence_handler(w); } callout_reset(&devinfo->poll_jack, devinfo->poll_ival, hdaa_jack_poll_callback, devinfo); hdaa_unlock(devinfo); } static void hdaa_eld_dump(struct hdaa_widget *w) { struct hdaa_devinfo *devinfo = w->devinfo; device_t dev = devinfo->dev; uint8_t *sad; int mnl, i, sadc, fmt; if (w->eld == NULL || w->eld_len < 4) return; device_printf(dev, "ELD nid=%d: ELD_Ver=%u Baseline_ELD_Len=%u\n", w->nid, w->eld[0] >> 3, w->eld[2]); if ((w->eld[0] >> 3) != 0x02) return; mnl = w->eld[4] & 0x1f; device_printf(dev, "ELD nid=%d: CEA_EDID_Ver=%u MNL=%u\n", w->nid, w->eld[4] >> 5, mnl); sadc = w->eld[5] >> 4; device_printf(dev, "ELD nid=%d: SAD_Count=%u Conn_Type=%u S_AI=%u HDCP=%u\n", w->nid, sadc, (w->eld[5] >> 2) & 0x3, (w->eld[5] >> 1) & 0x1, w->eld[5] & 0x1); device_printf(dev, "ELD nid=%d: Aud_Synch_Delay=%ums\n", w->nid, w->eld[6] * 2); device_printf(dev, "ELD nid=%d: Channels=0x%b\n", w->nid, w->eld[7], "\020\07RLRC\06FLRC\05RC\04RLR\03FC\02LFE\01FLR"); device_printf(dev, "ELD nid=%d: Port_ID=0x%02x%02x%02x%02x%02x%02x%02x%02x\n", w->nid, w->eld[8], w->eld[9], w->eld[10], w->eld[11], w->eld[12], w->eld[13], w->eld[14], w->eld[15]); device_printf(dev, "ELD nid=%d: Manufacturer_Name=0x%02x%02x\n", w->nid, w->eld[16], w->eld[17]); device_printf(dev, "ELD nid=%d: Product_Code=0x%02x%02x\n", w->nid, w->eld[18], w->eld[19]); device_printf(dev, "ELD nid=%d: Monitor_Name_String='%.*s'\n", w->nid, mnl, &w->eld[20]); for (i = 0; i < sadc; i++) { sad = &w->eld[20 + mnl + i * 3]; fmt = (sad[0] >> 3) & 0x0f; if (fmt == HDA_HDMI_CODING_TYPE_REF_CTX) { fmt = (sad[2] >> 3) & 0x1f; if (fmt < 1 || fmt > 3) fmt = 0; else fmt += 14; } device_printf(dev, "ELD nid=%d: %s %dch freqs=0x%b", w->nid, HDA_HDMI_CODING_TYPES[fmt], (sad[0] & 0x07) + 1, sad[1], "\020\007192\006176\00596\00488\00348\00244\00132"); switch (fmt) { case HDA_HDMI_CODING_TYPE_LPCM: printf(" sizes=0x%b", sad[2] & 0x07, "\020\00324\00220\00116"); break; case HDA_HDMI_CODING_TYPE_AC3: case HDA_HDMI_CODING_TYPE_MPEG1: case HDA_HDMI_CODING_TYPE_MP3: case HDA_HDMI_CODING_TYPE_MPEG2: case HDA_HDMI_CODING_TYPE_AACLC: case HDA_HDMI_CODING_TYPE_DTS: case HDA_HDMI_CODING_TYPE_ATRAC: printf(" max_bitrate=%d", sad[2] * 8000); break; case HDA_HDMI_CODING_TYPE_WMAPRO: printf(" profile=%d", sad[2] & 0x07); break; } printf("\n"); } } static void hdaa_eld_handler(struct hdaa_widget *w) { struct hdaa_devinfo *devinfo = w->devinfo; uint32_t res; int i; if (w->enable == 0 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) return; if (HDA_PARAM_PIN_CAP_PRESENCE_DETECT_CAP(w->wclass.pin.cap) == 0 || (HDA_CONFIG_DEFAULTCONF_MISC(w->wclass.pin.config) & 1) != 0) return; res = hda_command(devinfo->dev, HDA_CMD_GET_PIN_SENSE(0, w->nid)); if ((w->eld != 0) == ((res & HDA_CMD_GET_PIN_SENSE_ELD_VALID) != 0)) return; if (w->eld != NULL) { w->eld_len = 0; free(w->eld, M_HDAA); w->eld = NULL; } HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Pin sense: nid=%d sense=0x%08x " "(%sconnected, ELD %svalid)\n", w->nid, res, (res & HDA_CMD_GET_PIN_SENSE_PRESENCE_DETECT) ? "" : "dis", (res & HDA_CMD_GET_PIN_SENSE_ELD_VALID) ? "" : "in"); ); if ((res & HDA_CMD_GET_PIN_SENSE_ELD_VALID) == 0) return; res = hda_command(devinfo->dev, HDA_CMD_GET_HDMI_DIP_SIZE(0, w->nid, 0x08)); if (res == HDA_INVALID) return; w->eld_len = res & 0xff; if (w->eld_len != 0) w->eld = malloc(w->eld_len, M_HDAA, M_ZERO | M_NOWAIT); if (w->eld == NULL) { w->eld_len = 0; return; } for (i = 0; i < w->eld_len; i++) { res = hda_command(devinfo->dev, HDA_CMD_GET_HDMI_ELDD(0, w->nid, i)); if (res & 0x80000000) w->eld[i] = res & 0xff; } HDA_BOOTVERBOSE( hdaa_eld_dump(w); ); hdaa_channels_handler(&devinfo->as[w->bindas]); } /* * Pin sense initializer. */ static void hdaa_sense_init(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as; struct hdaa_widget *w; int i, poll = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (HDA_PARAM_AUDIO_WIDGET_CAP_UNSOL_CAP(w->param.widget_cap)) { if (w->unsol < 0) w->unsol = HDAC_UNSOL_ALLOC( device_get_parent(devinfo->dev), devinfo->dev, w->nid); hda_command(devinfo->dev, HDA_CMD_SET_UNSOLICITED_RESPONSE(0, w->nid, HDA_CMD_SET_UNSOLICITED_RESPONSE_ENABLE | w->unsol)); } as = &devinfo->as[w->bindas]; if (as->hpredir >= 0 && as->pins[15] == w->nid) { if (HDA_PARAM_PIN_CAP_PRESENCE_DETECT_CAP(w->wclass.pin.cap) == 0 || (HDA_CONFIG_DEFAULTCONF_MISC(w->wclass.pin.config) & 1) != 0) { device_printf(devinfo->dev, "No presence detection support at nid %d\n", w->nid); } else { if (w->unsol < 0) poll = 1; HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Headphones redirection for " "association %d nid=%d using %s.\n", w->bindas, w->nid, (w->unsol < 0) ? "polling" : "unsolicited responses"); ); } } hdaa_presence_handler(w); if (!HDA_PARAM_PIN_CAP_DP(w->wclass.pin.cap) && !HDA_PARAM_PIN_CAP_HDMI(w->wclass.pin.cap)) continue; hdaa_eld_handler(w); } if (poll) { callout_reset(&devinfo->poll_jack, 1, hdaa_jack_poll_callback, devinfo); } } static void hdaa_sense_deinit(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; int i; callout_stop(&devinfo->poll_jack); for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (w->unsol < 0) continue; hda_command(devinfo->dev, HDA_CMD_SET_UNSOLICITED_RESPONSE(0, w->nid, 0)); HDAC_UNSOL_FREE( device_get_parent(devinfo->dev), devinfo->dev, w->unsol); w->unsol = -1; } } uint32_t hdaa_widget_pin_patch(uint32_t config, const char *str) { char buf[256]; char *key, *value, *rest, *bad; int ival, i; strlcpy(buf, str, sizeof(buf)); rest = buf; while ((key = strsep(&rest, "=")) != NULL) { value = strsep(&rest, " \t"); if (value == NULL) break; ival = strtol(value, &bad, 10); if (strcmp(key, "seq") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_SEQUENCE_MASK; config |= ((ival << HDA_CONFIG_DEFAULTCONF_SEQUENCE_SHIFT) & HDA_CONFIG_DEFAULTCONF_SEQUENCE_MASK); } else if (strcmp(key, "as") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_ASSOCIATION_MASK; config |= ((ival << HDA_CONFIG_DEFAULTCONF_ASSOCIATION_SHIFT) & HDA_CONFIG_DEFAULTCONF_ASSOCIATION_MASK); } else if (strcmp(key, "misc") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_MISC_MASK; config |= ((ival << HDA_CONFIG_DEFAULTCONF_MISC_SHIFT) & HDA_CONFIG_DEFAULTCONF_MISC_MASK); } else if (strcmp(key, "color") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_COLOR_MASK; if (bad[0] == 0) { config |= ((ival << HDA_CONFIG_DEFAULTCONF_COLOR_SHIFT) & HDA_CONFIG_DEFAULTCONF_COLOR_MASK); } for (i = 0; i < 16; i++) { if (strcasecmp(HDA_COLORS[i], value) == 0) { config |= (i << HDA_CONFIG_DEFAULTCONF_COLOR_SHIFT); break; } } } else if (strcmp(key, "ctype") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_CONNECTION_TYPE_MASK; if (bad[0] == 0) { config |= ((ival << HDA_CONFIG_DEFAULTCONF_CONNECTION_TYPE_SHIFT) & HDA_CONFIG_DEFAULTCONF_CONNECTION_TYPE_MASK); } for (i = 0; i < 16; i++) { if (strcasecmp(HDA_CONNECTORS[i], value) == 0) { config |= (i << HDA_CONFIG_DEFAULTCONF_CONNECTION_TYPE_SHIFT); break; } } } else if (strcmp(key, "device") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_DEVICE_MASK; if (bad[0] == 0) { config |= ((ival << HDA_CONFIG_DEFAULTCONF_DEVICE_SHIFT) & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK); continue; } for (i = 0; i < 16; i++) { if (strcasecmp(HDA_DEVS[i], value) == 0) { config |= (i << HDA_CONFIG_DEFAULTCONF_DEVICE_SHIFT); break; } } } else if (strcmp(key, "loc") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_LOCATION_MASK; if (bad[0] == 0) { config |= ((ival << HDA_CONFIG_DEFAULTCONF_LOCATION_SHIFT) & HDA_CONFIG_DEFAULTCONF_LOCATION_MASK); continue; } for (i = 0; i < 64; i++) { if (strcasecmp(HDA_LOCS[i], value) == 0) { config |= (i << HDA_CONFIG_DEFAULTCONF_LOCATION_SHIFT); break; } } } else if (strcmp(key, "conn") == 0) { config &= ~HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK; if (bad[0] == 0) { config |= ((ival << HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_SHIFT) & HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK); continue; } for (i = 0; i < 4; i++) { if (strcasecmp(HDA_CONNS[i], value) == 0) { config |= (i << HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_SHIFT); break; } } } } return (config); } uint32_t hdaa_gpio_patch(uint32_t gpio, const char *str) { char buf[256]; char *key, *value, *rest; int ikey, i; strlcpy(buf, str, sizeof(buf)); rest = buf; while ((key = strsep(&rest, "=")) != NULL) { value = strsep(&rest, " \t"); if (value == NULL) break; ikey = strtol(key, NULL, 10); if (ikey < 0 || ikey > 7) continue; for (i = 0; i < 7; i++) { if (strcasecmp(HDA_GPIO_ACTIONS[i], value) == 0) { gpio &= ~HDAA_GPIO_MASK(ikey); gpio |= i << HDAA_GPIO_SHIFT(ikey); break; } } } return (gpio); } static void hdaa_local_patch_pin(struct hdaa_widget *w) { device_t dev = w->devinfo->dev; const char *res = NULL; uint32_t config, orig; char buf[32]; config = orig = w->wclass.pin.config; snprintf(buf, sizeof(buf), "cad%u.nid%u.config", hda_get_codec_id(dev), w->nid); if (resource_string_value(device_get_name( device_get_parent(device_get_parent(dev))), device_get_unit(device_get_parent(device_get_parent(dev))), buf, &res) == 0) { if (strncmp(res, "0x", 2) == 0) { config = strtol(res + 2, NULL, 16); } else { config = hdaa_widget_pin_patch(config, res); } } snprintf(buf, sizeof(buf), "nid%u.config", w->nid); if (resource_string_value(device_get_name(dev), device_get_unit(dev), buf, &res) == 0) { if (strncmp(res, "0x", 2) == 0) { config = strtol(res + 2, NULL, 16); } else { config = hdaa_widget_pin_patch(config, res); } } HDA_BOOTVERBOSE( if (config != orig) device_printf(w->devinfo->dev, "Patching pin config nid=%u 0x%08x -> 0x%08x\n", w->nid, orig, config); ); w->wclass.pin.newconf = w->wclass.pin.config = config; } static void hdaa_dump_audio_formats_sb(struct sbuf *sb, uint32_t fcap, uint32_t pcmcap) { uint32_t cap; cap = fcap; if (cap != 0) { sbuf_printf(sb, " Stream cap: 0x%08x", cap); if (HDA_PARAM_SUPP_STREAM_FORMATS_AC3(cap)) sbuf_printf(sb, " AC3"); if (HDA_PARAM_SUPP_STREAM_FORMATS_FLOAT32(cap)) sbuf_printf(sb, " FLOAT32"); if (HDA_PARAM_SUPP_STREAM_FORMATS_PCM(cap)) sbuf_printf(sb, " PCM"); sbuf_printf(sb, "\n"); } cap = pcmcap; if (cap != 0) { sbuf_printf(sb, " PCM cap: 0x%08x", cap); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_8BIT(cap)) sbuf_printf(sb, " 8"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_16BIT(cap)) sbuf_printf(sb, " 16"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_20BIT(cap)) sbuf_printf(sb, " 20"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_24BIT(cap)) sbuf_printf(sb, " 24"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_32BIT(cap)) sbuf_printf(sb, " 32"); sbuf_printf(sb, " bits,"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_8KHZ(cap)) sbuf_printf(sb, " 8"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_11KHZ(cap)) sbuf_printf(sb, " 11"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_16KHZ(cap)) sbuf_printf(sb, " 16"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_22KHZ(cap)) sbuf_printf(sb, " 22"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_32KHZ(cap)) sbuf_printf(sb, " 32"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_44KHZ(cap)) sbuf_printf(sb, " 44"); sbuf_printf(sb, " 48"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_88KHZ(cap)) sbuf_printf(sb, " 88"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_96KHZ(cap)) sbuf_printf(sb, " 96"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_176KHZ(cap)) sbuf_printf(sb, " 176"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_192KHZ(cap)) sbuf_printf(sb, " 192"); sbuf_printf(sb, " KHz\n"); } } static void hdaa_dump_pin_sb(struct sbuf *sb, struct hdaa_widget *w) { uint32_t pincap, conf; pincap = w->wclass.pin.cap; sbuf_printf(sb, " Pin cap: 0x%08x", pincap); if (HDA_PARAM_PIN_CAP_IMP_SENSE_CAP(pincap)) sbuf_printf(sb, " ISC"); if (HDA_PARAM_PIN_CAP_TRIGGER_REQD(pincap)) sbuf_printf(sb, " TRQD"); if (HDA_PARAM_PIN_CAP_PRESENCE_DETECT_CAP(pincap)) sbuf_printf(sb, " PDC"); if (HDA_PARAM_PIN_CAP_HEADPHONE_CAP(pincap)) sbuf_printf(sb, " HP"); if (HDA_PARAM_PIN_CAP_OUTPUT_CAP(pincap)) sbuf_printf(sb, " OUT"); if (HDA_PARAM_PIN_CAP_INPUT_CAP(pincap)) sbuf_printf(sb, " IN"); if (HDA_PARAM_PIN_CAP_BALANCED_IO_PINS(pincap)) sbuf_printf(sb, " BAL"); if (HDA_PARAM_PIN_CAP_HDMI(pincap)) sbuf_printf(sb, " HDMI"); if (HDA_PARAM_PIN_CAP_VREF_CTRL(pincap)) { sbuf_printf(sb, " VREF["); if (HDA_PARAM_PIN_CAP_VREF_CTRL_50(pincap)) sbuf_printf(sb, " 50"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_80(pincap)) sbuf_printf(sb, " 80"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_100(pincap)) sbuf_printf(sb, " 100"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_GROUND(pincap)) sbuf_printf(sb, " GROUND"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_HIZ(pincap)) sbuf_printf(sb, " HIZ"); sbuf_printf(sb, " ]"); } if (HDA_PARAM_PIN_CAP_EAPD_CAP(pincap)) sbuf_printf(sb, " EAPD"); if (HDA_PARAM_PIN_CAP_DP(pincap)) sbuf_printf(sb, " DP"); if (HDA_PARAM_PIN_CAP_HBR(pincap)) sbuf_printf(sb, " HBR"); sbuf_printf(sb, "\n"); conf = w->wclass.pin.config; sbuf_printf(sb, " Pin config: 0x%08x", conf); sbuf_printf(sb, " as=%d seq=%d " "device=%s conn=%s ctype=%s loc=%s color=%s misc=%d\n", HDA_CONFIG_DEFAULTCONF_ASSOCIATION(conf), HDA_CONFIG_DEFAULTCONF_SEQUENCE(conf), HDA_DEVS[HDA_CONFIG_DEFAULTCONF_DEVICE(conf)], HDA_CONNS[HDA_CONFIG_DEFAULTCONF_CONNECTIVITY(conf)], HDA_CONNECTORS[HDA_CONFIG_DEFAULTCONF_CONNECTION_TYPE(conf)], HDA_LOCS[HDA_CONFIG_DEFAULTCONF_LOCATION(conf)], HDA_COLORS[HDA_CONFIG_DEFAULTCONF_COLOR(conf)], HDA_CONFIG_DEFAULTCONF_MISC(conf)); sbuf_printf(sb, " Pin control: 0x%08x", w->wclass.pin.ctrl); if (w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_HPHN_ENABLE) sbuf_printf(sb, " HP"); if (w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_IN_ENABLE) sbuf_printf(sb, " IN"); if (w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE) sbuf_printf(sb, " OUT"); if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) { if ((w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK) == 0x03) sbuf_printf(sb, " HBR"); else if ((w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK) != 0) sbuf_printf(sb, " EPTs"); } else { if ((w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK) != 0) sbuf_printf(sb, " VREFs"); } sbuf_printf(sb, "\n"); } static void hdaa_dump_amp_sb(struct sbuf *sb, uint32_t cap, const char *banner) { int offset, size, step; offset = HDA_PARAM_OUTPUT_AMP_CAP_OFFSET(cap); size = HDA_PARAM_OUTPUT_AMP_CAP_STEPSIZE(cap); step = HDA_PARAM_OUTPUT_AMP_CAP_NUMSTEPS(cap); sbuf_printf(sb, " %s amp: 0x%08x " "mute=%d step=%d size=%d offset=%d (%+d/%+ddB)\n", banner, cap, HDA_PARAM_OUTPUT_AMP_CAP_MUTE_CAP(cap), step, size, offset, ((0 - offset) * (size + 1)) / 4, ((step - offset) * (size + 1)) / 4); } static int hdaa_sysctl_caps(SYSCTL_HANDLER_ARGS) { struct hdaa_devinfo *devinfo; struct hdaa_widget *w, *cw; struct sbuf sb; char buf[64]; int error, j; w = (struct hdaa_widget *)oidp->oid_arg1; devinfo = w->devinfo; sbuf_new_for_sysctl(&sb, NULL, 256, req); sbuf_printf(&sb, "%s%s\n", w->name, (w->enable == 0) ? " [DISABLED]" : ""); sbuf_printf(&sb, " Widget cap: 0x%08x", w->param.widget_cap); if (w->param.widget_cap & 0x0ee1) { if (HDA_PARAM_AUDIO_WIDGET_CAP_LR_SWAP(w->param.widget_cap)) sbuf_printf(&sb, " LRSWAP"); if (HDA_PARAM_AUDIO_WIDGET_CAP_POWER_CTRL(w->param.widget_cap)) sbuf_printf(&sb, " PWR"); if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) sbuf_printf(&sb, " DIGITAL"); if (HDA_PARAM_AUDIO_WIDGET_CAP_UNSOL_CAP(w->param.widget_cap)) sbuf_printf(&sb, " UNSOL"); if (HDA_PARAM_AUDIO_WIDGET_CAP_PROC_WIDGET(w->param.widget_cap)) sbuf_printf(&sb, " PROC"); if (HDA_PARAM_AUDIO_WIDGET_CAP_STRIPE(w->param.widget_cap)) sbuf_printf(&sb, " STRIPE(x%d)", 1 << (fls(w->wclass.conv.stripecap) - 1)); j = HDA_PARAM_AUDIO_WIDGET_CAP_CC(w->param.widget_cap); if (j == 1) sbuf_printf(&sb, " STEREO"); else if (j > 1) sbuf_printf(&sb, " %dCH", j + 1); } sbuf_printf(&sb, "\n"); if (w->bindas != -1) { sbuf_printf(&sb, " Association: %d (0x%04x)\n", w->bindas, w->bindseqmask); } if (w->ossmask != 0 || w->ossdev >= 0) { sbuf_printf(&sb, " OSS: %s", hdaa_audio_ctl_ossmixer_mask2allname(w->ossmask, buf, sizeof(buf))); if (w->ossdev >= 0) sbuf_printf(&sb, " (%s)", ossnames[w->ossdev]); sbuf_printf(&sb, "\n"); } if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) { hdaa_dump_audio_formats_sb(&sb, w->param.supp_stream_formats, w->param.supp_pcm_size_rate); } else if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX || w->waspin) hdaa_dump_pin_sb(&sb, w); if (w->param.eapdbtl != HDA_INVALID) { sbuf_printf(&sb, " EAPD: 0x%08x%s%s%s\n", w->param.eapdbtl, (w->param.eapdbtl & HDA_CMD_SET_EAPD_BTL_ENABLE_LR_SWAP) ? " LRSWAP" : "", (w->param.eapdbtl & HDA_CMD_SET_EAPD_BTL_ENABLE_EAPD) ? " EAPD" : "", (w->param.eapdbtl & HDA_CMD_SET_EAPD_BTL_ENABLE_BTL) ? " BTL" : ""); } if (HDA_PARAM_AUDIO_WIDGET_CAP_OUT_AMP(w->param.widget_cap) && w->param.outamp_cap != 0) hdaa_dump_amp_sb(&sb, w->param.outamp_cap, "Output"); if (HDA_PARAM_AUDIO_WIDGET_CAP_IN_AMP(w->param.widget_cap) && w->param.inamp_cap != 0) hdaa_dump_amp_sb(&sb, w->param.inamp_cap, " Input"); if (w->nconns > 0) sbuf_printf(&sb, " Connections: %d\n", w->nconns); for (j = 0; j < w->nconns; j++) { cw = hdaa_widget_get(devinfo, w->conns[j]); sbuf_printf(&sb, " + %s<- nid=%d [%s]", (w->connsenable[j] == 0)?"[DISABLED] ":"", w->conns[j], (cw == NULL) ? "GHOST!" : cw->name); if (cw == NULL) sbuf_printf(&sb, " [UNKNOWN]"); else if (cw->enable == 0) sbuf_printf(&sb, " [DISABLED]"); if (w->nconns > 1 && w->selconn == j && w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) sbuf_printf(&sb, " (selected)"); sbuf_printf(&sb, "\n"); } error = sbuf_finish(&sb); sbuf_delete(&sb); return (error); } static int hdaa_sysctl_config(SYSCTL_HANDLER_ARGS) { char buf[256]; int error; uint32_t conf; conf = *(uint32_t *)oidp->oid_arg1; snprintf(buf, sizeof(buf), "0x%08x as=%d seq=%d " "device=%s conn=%s ctype=%s loc=%s color=%s misc=%d", conf, HDA_CONFIG_DEFAULTCONF_ASSOCIATION(conf), HDA_CONFIG_DEFAULTCONF_SEQUENCE(conf), HDA_DEVS[HDA_CONFIG_DEFAULTCONF_DEVICE(conf)], HDA_CONNS[HDA_CONFIG_DEFAULTCONF_CONNECTIVITY(conf)], HDA_CONNECTORS[HDA_CONFIG_DEFAULTCONF_CONNECTION_TYPE(conf)], HDA_LOCS[HDA_CONFIG_DEFAULTCONF_LOCATION(conf)], HDA_COLORS[HDA_CONFIG_DEFAULTCONF_COLOR(conf)], HDA_CONFIG_DEFAULTCONF_MISC(conf)); error = sysctl_handle_string(oidp, buf, sizeof(buf), req); if (error != 0 || req->newptr == NULL) return (error); if (strncmp(buf, "0x", 2) == 0) conf = strtol(buf + 2, NULL, 16); else conf = hdaa_widget_pin_patch(conf, buf); *(uint32_t *)oidp->oid_arg1 = conf; return (0); } static void hdaa_config_fetch(const char *str, uint32_t *on, uint32_t *off) { size_t k; int i = 0, j, len, inv; for (;;) { while (str[i] != '\0' && (str[i] == ',' || isspace(str[i]) != 0)) i++; if (str[i] == '\0') return; j = i; while (str[j] != '\0' && !(str[j] == ',' || isspace(str[j]) != 0)) j++; len = j - i; if (len > 2 && strncmp(str + i, "no", 2) == 0) inv = 2; else inv = 0; for (k = 0; len > inv && k < nitems(hdaa_quirks_tab); k++) { if (strncmp(str + i + inv, hdaa_quirks_tab[k].key, len - inv) != 0) continue; if (len - inv != strlen(hdaa_quirks_tab[k].key)) continue; if (inv == 0) { *on |= hdaa_quirks_tab[k].value; *off &= ~hdaa_quirks_tab[k].value; } else { *off |= hdaa_quirks_tab[k].value; *on &= ~hdaa_quirks_tab[k].value; } break; } i = j; } } static int hdaa_sysctl_quirks(SYSCTL_HANDLER_ARGS) { char buf[256]; int error, n = 0; size_t i; uint32_t quirks, quirks_off; quirks = *(uint32_t *)oidp->oid_arg1; buf[0] = 0; for (i = 0; i < nitems(hdaa_quirks_tab); i++) { if ((quirks & hdaa_quirks_tab[i].value) != 0) n += snprintf(buf + n, sizeof(buf) - n, "%s%s", n != 0 ? "," : "", hdaa_quirks_tab[i].key); } error = sysctl_handle_string(oidp, buf, sizeof(buf), req); if (error != 0 || req->newptr == NULL) return (error); if (strncmp(buf, "0x", 2) == 0) quirks = strtol(buf + 2, NULL, 16); else { quirks = 0; hdaa_config_fetch(buf, &quirks, &quirks_off); } *(uint32_t *)oidp->oid_arg1 = quirks; return (0); } static void hdaa_local_patch(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; const char *res = NULL; uint32_t quirks_on = 0, quirks_off = 0, x; int i; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL) continue; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) hdaa_local_patch_pin(w); } if (resource_string_value(device_get_name(devinfo->dev), device_get_unit(devinfo->dev), "config", &res) == 0) { if (res != NULL && strlen(res) > 0) hdaa_config_fetch(res, &quirks_on, &quirks_off); devinfo->quirks |= quirks_on; devinfo->quirks &= ~quirks_off; } if (devinfo->newquirks == -1) devinfo->newquirks = devinfo->quirks; else devinfo->quirks = devinfo->newquirks; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, "Config options: 0x%08x\n", devinfo->quirks); ); if (resource_string_value(device_get_name(devinfo->dev), device_get_unit(devinfo->dev), "gpio_config", &res) == 0) { if (strncmp(res, "0x", 2) == 0) { devinfo->gpio = strtol(res + 2, NULL, 16); } else { devinfo->gpio = hdaa_gpio_patch(devinfo->gpio, res); } } if (devinfo->newgpio == -1) devinfo->newgpio = devinfo->gpio; else devinfo->gpio = devinfo->newgpio; if (devinfo->newgpo == -1) devinfo->newgpo = devinfo->gpo; else devinfo->gpo = devinfo->newgpo; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, "GPIO config options:"); for (i = 0; i < 7; i++) { x = (devinfo->gpio & HDAA_GPIO_MASK(i)) >> HDAA_GPIO_SHIFT(i); if (x != 0) printf(" %d=%s", i, HDA_GPIO_ACTIONS[x]); } printf("\n"); ); } static void hdaa_widget_connection_parse(struct hdaa_widget *w) { uint32_t res; int i, j, max, ents, entnum; nid_t nid = w->nid; nid_t cnid, addcnid, prevcnid; w->nconns = 0; res = hda_command(w->devinfo->dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_CONN_LIST_LENGTH)); ents = HDA_PARAM_CONN_LIST_LENGTH_LIST_LENGTH(res); if (ents < 1) return; entnum = HDA_PARAM_CONN_LIST_LENGTH_LONG_FORM(res) ? 2 : 4; max = (sizeof(w->conns) / sizeof(w->conns[0])) - 1; prevcnid = 0; #define CONN_RMASK(e) (1 << ((32 / (e)) - 1)) #define CONN_NMASK(e) (CONN_RMASK(e) - 1) #define CONN_RESVAL(r, e, n) ((r) >> ((32 / (e)) * (n))) #define CONN_RANGE(r, e, n) (CONN_RESVAL(r, e, n) & CONN_RMASK(e)) #define CONN_CNID(r, e, n) (CONN_RESVAL(r, e, n) & CONN_NMASK(e)) for (i = 0; i < ents; i += entnum) { res = hda_command(w->devinfo->dev, HDA_CMD_GET_CONN_LIST_ENTRY(0, nid, i)); for (j = 0; j < entnum; j++) { cnid = CONN_CNID(res, entnum, j); if (cnid == 0) { if (w->nconns < ents) device_printf(w->devinfo->dev, "WARNING: nid=%d has zero cnid " "entnum=%d j=%d index=%d " "entries=%d found=%d res=0x%08x\n", nid, entnum, j, i, ents, w->nconns, res); else goto getconns_out; } if (cnid < w->devinfo->startnode || cnid >= w->devinfo->endnode) { HDA_BOOTVERBOSE( device_printf(w->devinfo->dev, "WARNING: nid=%d has cnid outside " "of the AFG range j=%d " "entnum=%d index=%d res=0x%08x\n", nid, j, entnum, i, res); ); } if (CONN_RANGE(res, entnum, j) == 0) addcnid = cnid; else if (prevcnid == 0 || prevcnid >= cnid) { device_printf(w->devinfo->dev, "WARNING: Invalid child range " "nid=%d index=%d j=%d entnum=%d " "prevcnid=%d cnid=%d res=0x%08x\n", nid, i, j, entnum, prevcnid, cnid, res); addcnid = cnid; } else addcnid = prevcnid + 1; while (addcnid <= cnid) { if (w->nconns > max) { device_printf(w->devinfo->dev, "Adding %d (nid=%d): " "Max connection reached! max=%d\n", addcnid, nid, max + 1); goto getconns_out; } w->connsenable[w->nconns] = 1; w->conns[w->nconns++] = addcnid++; } prevcnid = cnid; } } getconns_out: return; } static void hdaa_widget_parse(struct hdaa_widget *w) { device_t dev = w->devinfo->dev; uint32_t wcap, cap; nid_t nid = w->nid; char buf[64]; w->param.widget_cap = wcap = hda_command(dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_AUDIO_WIDGET_CAP)); w->type = HDA_PARAM_AUDIO_WIDGET_CAP_TYPE(wcap); hdaa_widget_connection_parse(w); if (HDA_PARAM_AUDIO_WIDGET_CAP_OUT_AMP(wcap)) { if (HDA_PARAM_AUDIO_WIDGET_CAP_AMP_OVR(wcap)) w->param.outamp_cap = hda_command(dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_OUTPUT_AMP_CAP)); else w->param.outamp_cap = w->devinfo->outamp_cap; } else w->param.outamp_cap = 0; if (HDA_PARAM_AUDIO_WIDGET_CAP_IN_AMP(wcap)) { if (HDA_PARAM_AUDIO_WIDGET_CAP_AMP_OVR(wcap)) w->param.inamp_cap = hda_command(dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_INPUT_AMP_CAP)); else w->param.inamp_cap = w->devinfo->inamp_cap; } else w->param.inamp_cap = 0; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) { if (HDA_PARAM_AUDIO_WIDGET_CAP_FORMAT_OVR(wcap)) { cap = hda_command(dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_SUPP_STREAM_FORMATS)); w->param.supp_stream_formats = (cap != 0) ? cap : w->devinfo->supp_stream_formats; cap = hda_command(dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_SUPP_PCM_SIZE_RATE)); w->param.supp_pcm_size_rate = (cap != 0) ? cap : w->devinfo->supp_pcm_size_rate; } else { w->param.supp_stream_formats = w->devinfo->supp_stream_formats; w->param.supp_pcm_size_rate = w->devinfo->supp_pcm_size_rate; } if (HDA_PARAM_AUDIO_WIDGET_CAP_STRIPE(w->param.widget_cap)) { w->wclass.conv.stripecap = hda_command(dev, HDA_CMD_GET_STRIPE_CONTROL(0, w->nid)) >> 20; } else w->wclass.conv.stripecap = 1; } else { w->param.supp_stream_formats = 0; w->param.supp_pcm_size_rate = 0; } if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) { w->wclass.pin.original = w->wclass.pin.newconf = w->wclass.pin.config = hda_command(dev, HDA_CMD_GET_CONFIGURATION_DEFAULT(0, w->nid)); w->wclass.pin.cap = hda_command(dev, HDA_CMD_GET_PARAMETER(0, w->nid, HDA_PARAM_PIN_CAP)); w->wclass.pin.ctrl = hda_command(dev, HDA_CMD_GET_PIN_WIDGET_CTRL(0, nid)); w->wclass.pin.connected = 2; if (HDA_PARAM_PIN_CAP_EAPD_CAP(w->wclass.pin.cap)) { w->param.eapdbtl = hda_command(dev, HDA_CMD_GET_EAPD_BTL_ENABLE(0, nid)); w->param.eapdbtl &= 0x7; w->param.eapdbtl |= HDA_CMD_SET_EAPD_BTL_ENABLE_EAPD; } else w->param.eapdbtl = HDA_INVALID; } w->unsol = -1; hdaa_unlock(w->devinfo); snprintf(buf, sizeof(buf), "nid%d", w->nid); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, buf, CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, w, 0, hdaa_sysctl_caps, "A", "Node capabilities"); if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) { snprintf(buf, sizeof(buf), "nid%d_config", w->nid); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, buf, CTLTYPE_STRING | CTLFLAG_RW | CTLFLAG_MPSAFE, &w->wclass.pin.newconf, 0, hdaa_sysctl_config, "A", "Current pin configuration"); snprintf(buf, sizeof(buf), "nid%d_original", w->nid); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, buf, CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, &w->wclass.pin.original, 0, hdaa_sysctl_config, "A", "Original pin configuration"); } hdaa_lock(w->devinfo); } static void hdaa_widget_postprocess(struct hdaa_widget *w) { const char *typestr; w->type = HDA_PARAM_AUDIO_WIDGET_CAP_TYPE(w->param.widget_cap); switch (w->type) { case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT: typestr = "audio output"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT: typestr = "audio input"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER: typestr = "audio mixer"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR: typestr = "audio selector"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX: typestr = "pin"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_POWER_WIDGET: typestr = "power widget"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_VOLUME_WIDGET: typestr = "volume widget"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_BEEP_WIDGET: typestr = "beep widget"; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_VENDOR_WIDGET: typestr = "vendor widget"; break; default: typestr = "unknown type"; break; } strlcpy(w->name, typestr, sizeof(w->name)); if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) { uint32_t config; const char *devstr; int conn, color; config = w->wclass.pin.config; devstr = HDA_DEVS[(config & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK) >> HDA_CONFIG_DEFAULTCONF_DEVICE_SHIFT]; conn = (config & HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK) >> HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_SHIFT; color = (config & HDA_CONFIG_DEFAULTCONF_COLOR_MASK) >> HDA_CONFIG_DEFAULTCONF_COLOR_SHIFT; strlcat(w->name, ": ", sizeof(w->name)); strlcat(w->name, devstr, sizeof(w->name)); strlcat(w->name, " (", sizeof(w->name)); if (conn == 0 && color != 0 && color != 15) { strlcat(w->name, HDA_COLORS[color], sizeof(w->name)); strlcat(w->name, " ", sizeof(w->name)); } strlcat(w->name, HDA_CONNS[conn], sizeof(w->name)); strlcat(w->name, ")", sizeof(w->name)); } } struct hdaa_widget * hdaa_widget_get(struct hdaa_devinfo *devinfo, nid_t nid) { if (devinfo == NULL || devinfo->widget == NULL || nid < devinfo->startnode || nid >= devinfo->endnode) return (NULL); return (&devinfo->widget[nid - devinfo->startnode]); } static void hdaa_audio_ctl_amp_set_internal(struct hdaa_devinfo *devinfo, nid_t nid, int index, int lmute, int rmute, int left, int right, int dir) { uint16_t v = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, "Setting amplifier nid=%d index=%d %s mute=%d/%d vol=%d/%d\n", nid,index,dir ? "in" : "out",lmute,rmute,left,right); ); if (left != right || lmute != rmute) { v = (1 << (15 - dir)) | (1 << 13) | (index << 8) | (lmute << 7) | left; hda_command(devinfo->dev, HDA_CMD_SET_AMP_GAIN_MUTE(0, nid, v)); v = (1 << (15 - dir)) | (1 << 12) | (index << 8) | (rmute << 7) | right; } else v = (1 << (15 - dir)) | (3 << 12) | (index << 8) | (lmute << 7) | left; hda_command(devinfo->dev, HDA_CMD_SET_AMP_GAIN_MUTE(0, nid, v)); } static void hdaa_audio_ctl_amp_set(struct hdaa_audio_ctl *ctl, uint32_t mute, int left, int right) { nid_t nid; int lmute, rmute; nid = ctl->widget->nid; /* Save new values if valid. */ if (mute != HDAA_AMP_MUTE_DEFAULT) ctl->muted = mute; if (left != HDAA_AMP_VOL_DEFAULT) ctl->left = left; if (right != HDAA_AMP_VOL_DEFAULT) ctl->right = right; /* Prepare effective values */ if (ctl->forcemute) { lmute = 1; rmute = 1; left = 0; right = 0; } else { lmute = HDAA_AMP_LEFT_MUTED(ctl->muted); rmute = HDAA_AMP_RIGHT_MUTED(ctl->muted); left = ctl->left; right = ctl->right; } /* Apply effective values */ if (ctl->dir & HDAA_CTL_OUT) hdaa_audio_ctl_amp_set_internal(ctl->widget->devinfo, nid, ctl->index, lmute, rmute, left, right, 0); if (ctl->dir & HDAA_CTL_IN) hdaa_audio_ctl_amp_set_internal(ctl->widget->devinfo, nid, ctl->index, lmute, rmute, left, right, 1); } static void hdaa_widget_connection_select(struct hdaa_widget *w, uint8_t index) { if (w == NULL || w->nconns < 1 || index > (w->nconns - 1)) return; HDA_BOOTHVERBOSE( device_printf(w->devinfo->dev, "Setting selector nid=%d index=%d\n", w->nid, index); ); hda_command(w->devinfo->dev, HDA_CMD_SET_CONNECTION_SELECT_CONTROL(0, w->nid, index)); w->selconn = index; } /**************************************************************************** * Device Methods ****************************************************************************/ static void * hdaa_channel_init(kobj_t obj, void *data, struct snd_dbuf *b, struct pcm_channel *c, int dir) { struct hdaa_chan *ch = data; struct hdaa_pcm_devinfo *pdevinfo = ch->pdevinfo; struct hdaa_devinfo *devinfo = pdevinfo->devinfo; hdaa_lock(devinfo); if (devinfo->quirks & HDAA_QUIRK_FIXEDRATE) { ch->caps.minspeed = ch->caps.maxspeed = 48000; ch->pcmrates[0] = 48000; ch->pcmrates[1] = 0; } ch->dir = dir; ch->b = b; ch->c = c; ch->blksz = pdevinfo->chan_size / pdevinfo->chan_blkcnt; ch->blkcnt = pdevinfo->chan_blkcnt; hdaa_unlock(devinfo); if (sndbuf_alloc(ch->b, bus_get_dma_tag(devinfo->dev), hda_get_dma_nocache(devinfo->dev) ? BUS_DMA_NOCACHE : BUS_DMA_COHERENT, pdevinfo->chan_size) != 0) return (NULL); return (ch); } static int hdaa_channel_setformat(kobj_t obj, void *data, uint32_t format) { struct hdaa_chan *ch = data; int i; for (i = 0; ch->caps.fmtlist[i] != 0; i++) { if (format == ch->caps.fmtlist[i]) { ch->fmt = format; return (0); } } return (EINVAL); } static uint32_t hdaa_channel_setspeed(kobj_t obj, void *data, uint32_t speed) { struct hdaa_chan *ch = data; uint32_t spd = 0, threshold; int i; /* First look for equal or multiple frequency. */ for (i = 0; ch->pcmrates[i] != 0; i++) { spd = ch->pcmrates[i]; if (speed != 0 && spd / speed * speed == spd) { ch->spd = spd; return (spd); } } /* If no match, just find nearest. */ for (i = 0; ch->pcmrates[i] != 0; i++) { spd = ch->pcmrates[i]; threshold = spd + ((ch->pcmrates[i + 1] != 0) ? ((ch->pcmrates[i + 1] - spd) >> 1) : 0); if (speed < threshold) break; } ch->spd = spd; return (spd); } static uint16_t hdaa_stream_format(struct hdaa_chan *ch) { int i; uint16_t fmt; fmt = 0; if (ch->fmt & AFMT_S16_LE) fmt |= ch->bit16 << 4; else if (ch->fmt & AFMT_S32_LE) fmt |= ch->bit32 << 4; else fmt |= 1 << 4; for (i = 0; i < HDA_RATE_TAB_LEN; i++) { if (hda_rate_tab[i].valid && ch->spd == hda_rate_tab[i].rate) { fmt |= hda_rate_tab[i].base; fmt |= hda_rate_tab[i].mul; fmt |= hda_rate_tab[i].div; break; } } fmt |= (AFMT_CHANNEL(ch->fmt) - 1); return (fmt); } static int hdaa_allowed_stripes(uint16_t fmt) { static const int bits[8] = { 8, 16, 20, 24, 32, 32, 32, 32 }; int size; size = bits[(fmt >> 4) & 0x03]; size *= (fmt & 0x0f) + 1; size *= ((fmt >> 11) & 0x07) + 1; return (0xffffffffU >> (32 - fls(size / 8))); } static void hdaa_audio_setup(struct hdaa_chan *ch) { struct hdaa_audio_as *as = &ch->devinfo->as[ch->as]; struct hdaa_widget *w, *wp; int i, j, k, chn, cchn, totalchn, totalextchn, c; uint16_t fmt, dfmt; /* Mapping channel pairs to codec pins/converters. */ const static uint16_t convmap[2][5] = /* 1.0 2.0 4.0 5.1 7.1 */ {{ 0x0010, 0x0001, 0x0201, 0x0231, 0x4231 }, /* no dup. */ { 0x0010, 0x0001, 0x2201, 0x2231, 0x4231 }}; /* side dup. */ /* Mapping formats to HDMI channel allocations. */ const static uint8_t hdmica[2][8] = /* 1 2 3 4 5 6 7 8 */ {{ 0x02, 0x00, 0x04, 0x08, 0x0a, 0x0e, 0x12, 0x12 }, /* x.0 */ { 0x01, 0x03, 0x01, 0x03, 0x09, 0x0b, 0x0f, 0x13 }}; /* x.1 */ /* Mapping formats to HDMI channels order. */ const static uint32_t hdmich[2][8] = /* 1 / 5 2 / 6 3 / 7 4 / 8 */ {{ 0xFFFF0F00, 0xFFFFFF10, 0xFFF2FF10, 0xFF32FF10, 0xFF324F10, 0xF5324F10, 0x54326F10, 0x54326F10 }, /* x.0 */ { 0xFFFFF000, 0xFFFF0100, 0xFFFFF210, 0xFFFF2310, 0xFF32F410, 0xFF324510, 0xF6324510, 0x76325410 }}; /* x.1 */ int convmapid = -1; nid_t nid; uint8_t csum; totalchn = AFMT_CHANNEL(ch->fmt); totalextchn = AFMT_EXTCHANNEL(ch->fmt); HDA_BOOTHVERBOSE( device_printf(ch->pdevinfo->dev, "PCMDIR_%s: Stream setup fmt=%08x (%d.%d) speed=%d\n", (ch->dir == PCMDIR_PLAY) ? "PLAY" : "REC", ch->fmt, totalchn - totalextchn, totalextchn, ch->spd); ); fmt = hdaa_stream_format(ch); /* Set channels to I/O converters mapping for known speaker setups. */ if ((as->pinset == 0x0007 || as->pinset == 0x0013) || /* Standard 5.1 */ (as->pinset == 0x0017)) /* Standard 7.1 */ convmapid = (ch->dir == PCMDIR_PLAY); dfmt = HDA_CMD_SET_DIGITAL_CONV_FMT1_DIGEN; if (ch->fmt & AFMT_AC3) dfmt |= HDA_CMD_SET_DIGITAL_CONV_FMT1_NAUDIO; chn = 0; for (i = 0; ch->io[i] != -1; i++) { w = hdaa_widget_get(ch->devinfo, ch->io[i]); if (w == NULL) continue; /* If HP redirection is enabled, but failed to use same DAC, make last DAC to duplicate first one. */ if (as->fakeredir && i == (as->pincnt - 1)) { c = (ch->sid << 4); } else { /* Map channels to I/O converters, if set. */ if (convmapid >= 0) chn = (((convmap[convmapid][totalchn / 2] >> i * 4) & 0xf) - 1) * 2; if (chn < 0 || chn >= totalchn) { c = 0; } else { c = (ch->sid << 4) | chn; } } hda_command(ch->devinfo->dev, HDA_CMD_SET_CONV_FMT(0, ch->io[i], fmt)); if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) { hda_command(ch->devinfo->dev, HDA_CMD_SET_DIGITAL_CONV_FMT1(0, ch->io[i], dfmt)); } hda_command(ch->devinfo->dev, HDA_CMD_SET_CONV_STREAM_CHAN(0, ch->io[i], c)); if (HDA_PARAM_AUDIO_WIDGET_CAP_STRIPE(w->param.widget_cap)) { hda_command(ch->devinfo->dev, HDA_CMD_SET_STRIPE_CONTROL(0, w->nid, ch->stripectl)); } cchn = HDA_PARAM_AUDIO_WIDGET_CAP_CC(w->param.widget_cap); if (cchn > 1 && chn < totalchn) { cchn = min(cchn, totalchn - chn - 1); hda_command(ch->devinfo->dev, HDA_CMD_SET_CONV_CHAN_COUNT(0, ch->io[i], cchn)); } HDA_BOOTHVERBOSE( device_printf(ch->pdevinfo->dev, "PCMDIR_%s: Stream setup nid=%d: " "fmt=0x%04x, dfmt=0x%04x, chan=0x%04x, " "chan_count=0x%02x, stripe=%d\n", (ch->dir == PCMDIR_PLAY) ? "PLAY" : "REC", ch->io[i], fmt, dfmt, c, cchn, ch->stripectl); ); for (j = 0; j < 16; j++) { if (as->dacs[ch->asindex][j] != ch->io[i]) continue; nid = as->pins[j]; wp = hdaa_widget_get(ch->devinfo, nid); if (wp == NULL) continue; if (!HDA_PARAM_PIN_CAP_DP(wp->wclass.pin.cap) && !HDA_PARAM_PIN_CAP_HDMI(wp->wclass.pin.cap)) continue; /* Set channel mapping. */ for (k = 0; k < 8; k++) { hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_CHAN_SLOT(0, nid, (((hdmich[totalextchn == 0 ? 0 : 1][totalchn - 1] >> (k * 4)) & 0xf) << 4) | k)); } /* * Enable High Bit Rate (HBR) Encoded Packet Type * (EPT), if supported and needed (8ch data). */ if (HDA_PARAM_PIN_CAP_HDMI(wp->wclass.pin.cap) && HDA_PARAM_PIN_CAP_HBR(wp->wclass.pin.cap)) { wp->wclass.pin.ctrl &= ~HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK; if ((ch->fmt & AFMT_AC3) && (cchn == 7)) wp->wclass.pin.ctrl |= 0x03; hda_command(ch->devinfo->dev, HDA_CMD_SET_PIN_WIDGET_CTRL(0, nid, wp->wclass.pin.ctrl)); } /* Stop audio infoframe transmission. */ hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_INDEX(0, nid, 0x00)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_XMIT(0, nid, 0x00)); /* Clear audio infoframe buffer. */ hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_INDEX(0, nid, 0x00)); for (k = 0; k < 32; k++) hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x00)); /* Write HDMI/DisplayPort audio infoframe. */ hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_INDEX(0, nid, 0x00)); if (w->eld != NULL && w->eld_len >= 6 && ((w->eld[5] >> 2) & 0x3) == 1) { /* DisplayPort */ hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x84)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x1b)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x44)); } else { /* HDMI */ hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x84)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x01)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x0a)); csum = 0; csum -= 0x84 + 0x01 + 0x0a + (totalchn - 1) + hdmica[totalextchn == 0 ? 0 : 1][totalchn - 1]; hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, csum)); } hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, totalchn - 1)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x00)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, 0x00)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_DATA(0, nid, hdmica[totalextchn == 0 ? 0 : 1][totalchn - 1])); /* Start audio infoframe transmission. */ hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_INDEX(0, nid, 0x00)); hda_command(ch->devinfo->dev, HDA_CMD_SET_HDMI_DIP_XMIT(0, nid, 0xc0)); } chn += cchn + 1; } } /* * Greatest Common Divisor. */ static unsigned gcd(unsigned a, unsigned b) { u_int c; while (b != 0) { c = a; a = b; b = (c % b); } return (a); } /* * Least Common Multiple. */ static unsigned lcm(unsigned a, unsigned b) { return ((a * b) / gcd(a, b)); } static int hdaa_channel_setfragments(kobj_t obj, void *data, uint32_t blksz, uint32_t blkcnt) { struct hdaa_chan *ch = data; blksz -= blksz % lcm(HDA_DMA_ALIGNMENT, sndbuf_getalign(ch->b)); if (blksz > (sndbuf_getmaxsize(ch->b) / HDA_BDL_MIN)) blksz = sndbuf_getmaxsize(ch->b) / HDA_BDL_MIN; if (blksz < HDA_BLK_MIN) blksz = HDA_BLK_MIN; if (blkcnt > HDA_BDL_MAX) blkcnt = HDA_BDL_MAX; if (blkcnt < HDA_BDL_MIN) blkcnt = HDA_BDL_MIN; while ((blksz * blkcnt) > sndbuf_getmaxsize(ch->b)) { if ((blkcnt >> 1) >= HDA_BDL_MIN) blkcnt >>= 1; else if ((blksz >> 1) >= HDA_BLK_MIN) blksz >>= 1; else break; } if ((sndbuf_getblksz(ch->b) != blksz || sndbuf_getblkcnt(ch->b) != blkcnt) && sndbuf_resize(ch->b, blkcnt, blksz) != 0) device_printf(ch->devinfo->dev, "%s: failed blksz=%u blkcnt=%u\n", __func__, blksz, blkcnt); ch->blksz = sndbuf_getblksz(ch->b); ch->blkcnt = sndbuf_getblkcnt(ch->b); return (0); } static uint32_t hdaa_channel_setblocksize(kobj_t obj, void *data, uint32_t blksz) { struct hdaa_chan *ch = data; hdaa_channel_setfragments(obj, data, blksz, ch->pdevinfo->chan_blkcnt); return (ch->blksz); } static void hdaa_channel_stop(struct hdaa_chan *ch) { struct hdaa_devinfo *devinfo = ch->devinfo; struct hdaa_widget *w; int i; if ((ch->flags & HDAA_CHN_RUNNING) == 0) return; ch->flags &= ~HDAA_CHN_RUNNING; HDAC_STREAM_STOP(device_get_parent(devinfo->dev), devinfo->dev, ch->dir == PCMDIR_PLAY ? 1 : 0, ch->sid); for (i = 0; ch->io[i] != -1; i++) { w = hdaa_widget_get(ch->devinfo, ch->io[i]); if (w == NULL) continue; if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) { hda_command(devinfo->dev, HDA_CMD_SET_DIGITAL_CONV_FMT1(0, ch->io[i], 0)); } hda_command(devinfo->dev, HDA_CMD_SET_CONV_STREAM_CHAN(0, ch->io[i], 0)); } HDAC_STREAM_FREE(device_get_parent(devinfo->dev), devinfo->dev, ch->dir == PCMDIR_PLAY ? 1 : 0, ch->sid); } static int hdaa_channel_start(struct hdaa_chan *ch) { struct hdaa_devinfo *devinfo = ch->devinfo; uint32_t fmt; fmt = hdaa_stream_format(ch); ch->stripectl = fls(ch->stripecap & hdaa_allowed_stripes(fmt) & hda_get_stripes_mask(devinfo->dev)) - 1; ch->sid = HDAC_STREAM_ALLOC(device_get_parent(devinfo->dev), devinfo->dev, ch->dir == PCMDIR_PLAY ? 1 : 0, fmt, ch->stripectl, &ch->dmapos); if (ch->sid <= 0) return (EBUSY); hdaa_audio_setup(ch); HDAC_STREAM_RESET(device_get_parent(devinfo->dev), devinfo->dev, ch->dir == PCMDIR_PLAY ? 1 : 0, ch->sid); HDAC_STREAM_START(device_get_parent(devinfo->dev), devinfo->dev, ch->dir == PCMDIR_PLAY ? 1 : 0, ch->sid, sndbuf_getbufaddr(ch->b), ch->blksz, ch->blkcnt); ch->flags |= HDAA_CHN_RUNNING; return (0); } static int hdaa_channel_trigger(kobj_t obj, void *data, int go) { struct hdaa_chan *ch = data; int error = 0; if (!PCMTRIG_COMMON(go)) return (0); hdaa_lock(ch->devinfo); switch (go) { case PCMTRIG_START: error = hdaa_channel_start(ch); break; case PCMTRIG_STOP: case PCMTRIG_ABORT: hdaa_channel_stop(ch); break; default: break; } hdaa_unlock(ch->devinfo); return (error); } static uint32_t hdaa_channel_getptr(kobj_t obj, void *data) { struct hdaa_chan *ch = data; struct hdaa_devinfo *devinfo = ch->devinfo; uint32_t ptr; hdaa_lock(devinfo); if (ch->dmapos != NULL) { ptr = *(ch->dmapos); } else { ptr = HDAC_STREAM_GETPTR( device_get_parent(devinfo->dev), devinfo->dev, ch->dir == PCMDIR_PLAY ? 1 : 0, ch->sid); } hdaa_unlock(devinfo); /* * Round to available space and force 128 bytes alignment. */ ptr %= ch->blksz * ch->blkcnt; ptr &= HDA_BLK_ALIGN; return (ptr); } static struct pcmchan_caps * hdaa_channel_getcaps(kobj_t obj, void *data) { return (&((struct hdaa_chan *)data)->caps); } static kobj_method_t hdaa_channel_methods[] = { KOBJMETHOD(channel_init, hdaa_channel_init), KOBJMETHOD(channel_setformat, hdaa_channel_setformat), KOBJMETHOD(channel_setspeed, hdaa_channel_setspeed), KOBJMETHOD(channel_setblocksize, hdaa_channel_setblocksize), KOBJMETHOD(channel_setfragments, hdaa_channel_setfragments), KOBJMETHOD(channel_trigger, hdaa_channel_trigger), KOBJMETHOD(channel_getptr, hdaa_channel_getptr), KOBJMETHOD(channel_getcaps, hdaa_channel_getcaps), KOBJMETHOD_END }; CHANNEL_DECLARE(hdaa_channel); static int hdaa_audio_ctl_ossmixer_init(struct snd_mixer *m) { struct hdaa_pcm_devinfo *pdevinfo = mix_getdevinfo(m); struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w, *cw; uint32_t mask, recmask; int i, j; hdaa_lock(devinfo); pdevinfo->mixer = m; /* Make sure that in case of soft volume it won't stay muted. */ for (i = 0; i < SOUND_MIXER_NRDEVICES; i++) { pdevinfo->left[i] = 100; pdevinfo->right[i] = 100; } /* Declare volume controls assigned to this association. */ mask = pdevinfo->ossmask; if (pdevinfo->playas >= 0) { /* Declate EAPD as ogain control. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX || w->param.eapdbtl == HDA_INVALID || w->bindas != pdevinfo->playas) continue; mask |= SOUND_MASK_OGAIN; break; } /* Declare soft PCM volume if needed. */ if ((mask & SOUND_MASK_PCM) == 0 || (devinfo->quirks & HDAA_QUIRK_SOFTPCMVOL) || pdevinfo->minamp[SOUND_MIXER_PCM] == pdevinfo->maxamp[SOUND_MIXER_PCM]) { mask |= SOUND_MASK_PCM; pcm_setflags(pdevinfo->dev, pcm_getflags(pdevinfo->dev) | SD_F_SOFTPCMVOL); HDA_BOOTHVERBOSE( device_printf(pdevinfo->dev, "Forcing Soft PCM volume\n"); ); } /* Declare master volume if needed. */ if ((mask & SOUND_MASK_VOLUME) == 0) { mask |= SOUND_MASK_VOLUME; mix_setparentchild(m, SOUND_MIXER_VOLUME, SOUND_MASK_PCM); mix_setrealdev(m, SOUND_MIXER_VOLUME, SOUND_MIXER_NONE); HDA_BOOTHVERBOSE( device_printf(pdevinfo->dev, "Forcing master volume with PCM\n"); ); } } /* Declare record sources available to this association. */ recmask = 0; if (pdevinfo->recas >= 0) { for (i = 0; i < 16; i++) { if (devinfo->as[pdevinfo->recas].dacs[0][i] < 0) continue; w = hdaa_widget_get(devinfo, devinfo->as[pdevinfo->recas].dacs[0][i]); if (w == NULL || w->enable == 0) continue; for (j = 0; j < w->nconns; j++) { if (w->connsenable[j] == 0) continue; cw = hdaa_widget_get(devinfo, w->conns[j]); if (cw == NULL || cw->enable == 0) continue; if (cw->bindas != pdevinfo->recas && cw->bindas != -2) continue; recmask |= cw->ossmask; } } } recmask &= (1 << SOUND_MIXER_NRDEVICES) - 1; mask &= (1 << SOUND_MIXER_NRDEVICES) - 1; pdevinfo->ossmask = mask; mix_setrecdevs(m, recmask); mix_setdevs(m, mask); hdaa_unlock(devinfo); return (0); } /* * Update amplification per pdevinfo per ossdev, calculate summary coefficient * and write it to codec, update *left and *right to reflect remaining error. */ static void hdaa_audio_ctl_dev_set(struct hdaa_audio_ctl *ctl, int ossdev, int mute, int *left, int *right) { int i, zleft, zright, sleft, sright, smute, lval, rval; ctl->devleft[ossdev] = *left; ctl->devright[ossdev] = *right; ctl->devmute[ossdev] = mute; smute = sleft = sright = zleft = zright = 0; for (i = 0; i < SOUND_MIXER_NRDEVICES; i++) { sleft += ctl->devleft[i]; sright += ctl->devright[i]; smute |= ctl->devmute[i]; if (i == ossdev) continue; zleft += ctl->devleft[i]; zright += ctl->devright[i]; } lval = QDB2VAL(ctl, sleft); rval = QDB2VAL(ctl, sright); hdaa_audio_ctl_amp_set(ctl, smute, lval, rval); *left -= VAL2QDB(ctl, lval) - VAL2QDB(ctl, QDB2VAL(ctl, zleft)); *right -= VAL2QDB(ctl, rval) - VAL2QDB(ctl, QDB2VAL(ctl, zright)); } /* * Trace signal from source, setting volumes on the way. */ static void hdaa_audio_ctl_source_volume(struct hdaa_pcm_devinfo *pdevinfo, int ossdev, nid_t nid, int index, int mute, int left, int right, int depth) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w, *wc; struct hdaa_audio_ctl *ctl; int i, j, conns = 0; if (depth > HDA_PARSE_MAXDEPTH) return; w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return; /* Count number of active inputs. */ if (depth > 0) { for (j = 0; j < w->nconns; j++) { if (!w->connsenable[j]) continue; conns++; } } /* If this is not a first step - use input mixer. Pins have common input ctl so care must be taken. */ if (depth > 0 && (conns == 1 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX)) { ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_IN, index, 1); if (ctl) hdaa_audio_ctl_dev_set(ctl, ossdev, mute, &left, &right); } /* If widget has own ossdev - not traverse it. It will be traversed on its own. */ if (w->ossdev >= 0 && depth > 0) return; /* We must not traverse pin */ if ((w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) && depth > 0) return; /* * If signals mixed, we can't assign controls farther. * Ignore this on depth zero. Caller must knows why. */ if (conns > 1 && (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER || w->selconn != index)) return; ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_OUT, -1, 1); if (ctl) hdaa_audio_ctl_dev_set(ctl, ossdev, mute, &left, &right); for (i = devinfo->startnode; i < devinfo->endnode; i++) { wc = hdaa_widget_get(devinfo, i); if (wc == NULL || wc->enable == 0) continue; for (j = 0; j < wc->nconns; j++) { if (wc->connsenable[j] && wc->conns[j] == nid) { hdaa_audio_ctl_source_volume(pdevinfo, ossdev, wc->nid, j, mute, left, right, depth + 1); } } } return; } /* * Trace signal from destination, setting volumes on the way. */ static void hdaa_audio_ctl_dest_volume(struct hdaa_pcm_devinfo *pdevinfo, int ossdev, nid_t nid, int index, int mute, int left, int right, int depth) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w, *wc; struct hdaa_audio_ctl *ctl; int i, j, consumers, cleft, cright; if (depth > HDA_PARSE_MAXDEPTH) return; w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return; if (depth > 0) { /* If this node produce output for several consumers, we can't touch it. */ consumers = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { wc = hdaa_widget_get(devinfo, i); if (wc == NULL || wc->enable == 0) continue; for (j = 0; j < wc->nconns; j++) { if (wc->connsenable[j] && wc->conns[j] == nid) consumers++; } } /* The only exception is if real HP redirection is configured and this is a duplication point. XXX: Actually exception is not completely correct. XXX: Duplication point check is not perfect. */ if ((consumers == 2 && (w->bindas < 0 || as[w->bindas].hpredir < 0 || as[w->bindas].fakeredir || (w->bindseqmask & (1 << 15)) == 0)) || consumers > 2) return; /* Else use it's output mixer. */ ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_OUT, -1, 1); if (ctl) hdaa_audio_ctl_dev_set(ctl, ossdev, mute, &left, &right); } /* We must not traverse pin */ if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && depth > 0) return; for (i = 0; i < w->nconns; i++) { if (w->connsenable[i] == 0) continue; if (index >= 0 && i != index) continue; cleft = left; cright = right; ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_IN, i, 1); if (ctl) hdaa_audio_ctl_dev_set(ctl, ossdev, mute, &cleft, &cright); hdaa_audio_ctl_dest_volume(pdevinfo, ossdev, w->conns[i], -1, mute, cleft, cright, depth + 1); } } /* * Set volumes for the specified pdevinfo and ossdev. */ static void hdaa_audio_ctl_dev_volume(struct hdaa_pcm_devinfo *pdevinfo, unsigned dev) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w, *cw; uint32_t mute; int lvol, rvol; int i, j; mute = 0; if (pdevinfo->left[dev] == 0) { mute |= HDAA_AMP_MUTE_LEFT; lvol = -4000; } else lvol = ((pdevinfo->maxamp[dev] - pdevinfo->minamp[dev]) * pdevinfo->left[dev] + 50) / 100 + pdevinfo->minamp[dev]; if (pdevinfo->right[dev] == 0) { mute |= HDAA_AMP_MUTE_RIGHT; rvol = -4000; } else rvol = ((pdevinfo->maxamp[dev] - pdevinfo->minamp[dev]) * pdevinfo->right[dev] + 50) / 100 + pdevinfo->minamp[dev]; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->bindas < 0) { if (pdevinfo->index != 0) continue; } else { if (w->bindas != pdevinfo->playas && w->bindas != pdevinfo->recas) continue; } if (dev == SOUND_MIXER_RECLEV && w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) { hdaa_audio_ctl_dest_volume(pdevinfo, dev, w->nid, -1, mute, lvol, rvol, 0); continue; } if (dev == SOUND_MIXER_VOLUME && w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && devinfo->as[w->bindas].dir == HDAA_CTL_OUT) { hdaa_audio_ctl_dest_volume(pdevinfo, dev, w->nid, -1, mute, lvol, rvol, 0); continue; } if (dev == SOUND_MIXER_IGAIN && w->pflags & HDAA_ADC_MONITOR) { for (j = 0; j < w->nconns; j++) { if (!w->connsenable[j]) continue; cw = hdaa_widget_get(devinfo, w->conns[j]); if (cw == NULL || cw->enable == 0) continue; if (cw->bindas == -1) continue; if (cw->bindas >= 0 && devinfo->as[cw->bindas].dir != HDAA_CTL_IN) continue; hdaa_audio_ctl_dest_volume(pdevinfo, dev, w->nid, j, mute, lvol, rvol, 0); } continue; } if (w->ossdev != dev) continue; hdaa_audio_ctl_source_volume(pdevinfo, dev, w->nid, -1, mute, lvol, rvol, 0); if (dev == SOUND_MIXER_IMIX && (w->pflags & HDAA_IMIX_AS_DST)) hdaa_audio_ctl_dest_volume(pdevinfo, dev, w->nid, -1, mute, lvol, rvol, 0); } } /* * OSS Mixer set method. */ static int hdaa_audio_ctl_ossmixer_set(struct snd_mixer *m, unsigned dev, unsigned left, unsigned right) { struct hdaa_pcm_devinfo *pdevinfo = mix_getdevinfo(m); struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w; int i; hdaa_lock(devinfo); /* Save new values. */ pdevinfo->left[dev] = left; pdevinfo->right[dev] = right; /* 'ogain' is the special case implemented with EAPD. */ if (dev == SOUND_MIXER_OGAIN) { uint32_t orig; w = NULL; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX || w->param.eapdbtl == HDA_INVALID) continue; break; } if (i >= devinfo->endnode) { hdaa_unlock(devinfo); return (-1); } orig = w->param.eapdbtl; if (left == 0) w->param.eapdbtl &= ~HDA_CMD_SET_EAPD_BTL_ENABLE_EAPD; else w->param.eapdbtl |= HDA_CMD_SET_EAPD_BTL_ENABLE_EAPD; if (orig != w->param.eapdbtl) { uint32_t val; val = w->param.eapdbtl; if (devinfo->quirks & HDAA_QUIRK_EAPDINV) val ^= HDA_CMD_SET_EAPD_BTL_ENABLE_EAPD; hda_command(devinfo->dev, HDA_CMD_SET_EAPD_BTL_ENABLE(0, w->nid, val)); } hdaa_unlock(devinfo); return (left | (left << 8)); } /* Recalculate all controls related to this OSS device. */ hdaa_audio_ctl_dev_volume(pdevinfo, dev); hdaa_unlock(devinfo); return (left | (right << 8)); } /* * Set mixer settings to our own default values: * +20dB for mics, -10dB for analog vol, mute for igain, 0dB for others. */ static void hdaa_audio_ctl_set_defaults(struct hdaa_pcm_devinfo *pdevinfo) { int amp, vol, dev; for (dev = 0; dev < SOUND_MIXER_NRDEVICES; dev++) { if ((pdevinfo->ossmask & (1 << dev)) == 0) continue; /* If the value was overridden, leave it as is. */ if (resource_int_value(device_get_name(pdevinfo->dev), device_get_unit(pdevinfo->dev), ossnames[dev], &vol) == 0) continue; vol = -1; if (dev == SOUND_MIXER_OGAIN) vol = 100; else if (dev == SOUND_MIXER_IGAIN) vol = 0; else if (dev == SOUND_MIXER_MIC || dev == SOUND_MIXER_MONITOR) amp = 20 * 4; /* +20dB */ else if (dev == SOUND_MIXER_VOLUME && !pdevinfo->digital) amp = -10 * 4; /* -10dB */ else amp = 0; if (vol < 0 && (pdevinfo->maxamp[dev] - pdevinfo->minamp[dev]) <= 0) { vol = 100; } else if (vol < 0) { vol = ((amp - pdevinfo->minamp[dev]) * 100 + (pdevinfo->maxamp[dev] - pdevinfo->minamp[dev]) / 2) / (pdevinfo->maxamp[dev] - pdevinfo->minamp[dev]); vol = imin(imax(vol, 1), 100); } mix_set(pdevinfo->mixer, dev, vol, vol); } } /* * Recursively commutate specified record source. */ static uint32_t hdaa_audio_ctl_recsel_comm(struct hdaa_pcm_devinfo *pdevinfo, uint32_t src, nid_t nid, int depth) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w, *cw; struct hdaa_audio_ctl *ctl; char buf[64]; int i, muted; uint32_t res = 0; if (depth > HDA_PARSE_MAXDEPTH) return (0); w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return (0); for (i = 0; i < w->nconns; i++) { if (w->connsenable[i] == 0) continue; cw = hdaa_widget_get(devinfo, w->conns[i]); if (cw == NULL || cw->enable == 0 || cw->bindas == -1) continue; /* Call recursively to trace signal to it's source if needed. */ if ((src & cw->ossmask) != 0) { if (cw->ossdev < 0) { res |= hdaa_audio_ctl_recsel_comm(pdevinfo, src, w->conns[i], depth + 1); } else { res |= cw->ossmask; } } /* We have two special cases: mixers and others (selectors). */ if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) { ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_IN, i, 1); if (ctl == NULL) continue; /* If we have input control on this node mute them * according to requested sources. */ muted = (src & cw->ossmask) ? 0 : 1; if (muted != ctl->forcemute) { ctl->forcemute = muted; hdaa_audio_ctl_amp_set(ctl, HDAA_AMP_MUTE_DEFAULT, HDAA_AMP_VOL_DEFAULT, HDAA_AMP_VOL_DEFAULT); } HDA_BOOTHVERBOSE( device_printf(pdevinfo->dev, "Recsel (%s): nid %d source %d %s\n", hdaa_audio_ctl_ossmixer_mask2allname( src, buf, sizeof(buf)), nid, i, muted?"mute":"unmute"); ); } else { if (w->nconns == 1) break; if ((src & cw->ossmask) == 0) continue; /* If we found requested source - select it and exit. */ hdaa_widget_connection_select(w, i); HDA_BOOTHVERBOSE( device_printf(pdevinfo->dev, "Recsel (%s): nid %d source %d select\n", hdaa_audio_ctl_ossmixer_mask2allname( src, buf, sizeof(buf)), nid, i); ); break; } } return (res); } static uint32_t hdaa_audio_ctl_ossmixer_setrecsrc(struct snd_mixer *m, uint32_t src) { struct hdaa_pcm_devinfo *pdevinfo = mix_getdevinfo(m); struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w; struct hdaa_audio_as *as; struct hdaa_audio_ctl *ctl; struct hdaa_chan *ch; int i, j; uint32_t ret = 0xffffffff; hdaa_lock(devinfo); if (pdevinfo->recas < 0) { hdaa_unlock(devinfo); return (0); } as = &devinfo->as[pdevinfo->recas]; /* For non-mixed associations we always recording everything. */ if (!as->mixed) { hdaa_unlock(devinfo); return (mix_getrecdevs(m)); } /* Commutate requested recsrc for each ADC. */ for (j = 0; j < as->num_chans; j++) { ch = &devinfo->chans[as->chans[j]]; for (i = 0; ch->io[i] >= 0; i++) { w = hdaa_widget_get(devinfo, ch->io[i]); if (w == NULL || w->enable == 0) continue; ret &= hdaa_audio_ctl_recsel_comm(pdevinfo, src, ch->io[i], 0); } } if (ret == 0xffffffff) ret = 0; /* * Some controls could be shared. Reset volumes for controls * related to previously chosen devices, as they may no longer * affect the signal. */ i = 0; while ((ctl = hdaa_audio_ctl_each(devinfo, &i)) != NULL) { if (ctl->enable == 0 || !(ctl->ossmask & pdevinfo->recsrc)) continue; if (!((pdevinfo->playas >= 0 && ctl->widget->bindas == pdevinfo->playas) || (pdevinfo->recas >= 0 && ctl->widget->bindas == pdevinfo->recas) || (pdevinfo->index == 0 && ctl->widget->bindas == -2))) continue; for (j = 0; j < SOUND_MIXER_NRDEVICES; j++) { if (pdevinfo->recsrc & (1 << j)) { ctl->devleft[j] = 0; ctl->devright[j] = 0; ctl->devmute[j] = 0; } } } /* * Some controls could be shared. Set volumes for controls * related to devices selected both previously and now. */ for (j = 0; j < SOUND_MIXER_NRDEVICES; j++) { if ((ret | pdevinfo->recsrc) & (1 << j)) hdaa_audio_ctl_dev_volume(pdevinfo, j); } pdevinfo->recsrc = ret; hdaa_unlock(devinfo); return (ret); } static kobj_method_t hdaa_audio_ctl_ossmixer_methods[] = { KOBJMETHOD(mixer_init, hdaa_audio_ctl_ossmixer_init), KOBJMETHOD(mixer_set, hdaa_audio_ctl_ossmixer_set), KOBJMETHOD(mixer_setrecsrc, hdaa_audio_ctl_ossmixer_setrecsrc), KOBJMETHOD_END }; MIXER_DECLARE(hdaa_audio_ctl_ossmixer); static void hdaa_dump_gpi(struct hdaa_devinfo *devinfo) { device_t dev = devinfo->dev; int i; uint32_t data, wake, unsol, sticky; if (HDA_PARAM_GPIO_COUNT_NUM_GPI(devinfo->gpio_cap) > 0) { data = hda_command(dev, HDA_CMD_GET_GPI_DATA(0, devinfo->nid)); wake = hda_command(dev, HDA_CMD_GET_GPI_WAKE_ENABLE_MASK(0, devinfo->nid)); unsol = hda_command(dev, HDA_CMD_GET_GPI_UNSOLICITED_ENABLE_MASK(0, devinfo->nid)); sticky = hda_command(dev, HDA_CMD_GET_GPI_STICKY_MASK(0, devinfo->nid)); for (i = 0; i < HDA_PARAM_GPIO_COUNT_NUM_GPI(devinfo->gpio_cap); i++) { device_printf(dev, " GPI%d:%s%s%s state=%d", i, (sticky & (1 << i)) ? " sticky" : "", (unsol & (1 << i)) ? " unsol" : "", (wake & (1 << i)) ? " wake" : "", (data >> i) & 1); } } } static void hdaa_dump_gpio(struct hdaa_devinfo *devinfo) { device_t dev = devinfo->dev; int i; uint32_t data, dir, enable, wake, unsol, sticky; if (HDA_PARAM_GPIO_COUNT_NUM_GPIO(devinfo->gpio_cap) > 0) { data = hda_command(dev, HDA_CMD_GET_GPIO_DATA(0, devinfo->nid)); enable = hda_command(dev, HDA_CMD_GET_GPIO_ENABLE_MASK(0, devinfo->nid)); dir = hda_command(dev, HDA_CMD_GET_GPIO_DIRECTION(0, devinfo->nid)); wake = hda_command(dev, HDA_CMD_GET_GPIO_WAKE_ENABLE_MASK(0, devinfo->nid)); unsol = hda_command(dev, HDA_CMD_GET_GPIO_UNSOLICITED_ENABLE_MASK(0, devinfo->nid)); sticky = hda_command(dev, HDA_CMD_GET_GPIO_STICKY_MASK(0, devinfo->nid)); for (i = 0; i < HDA_PARAM_GPIO_COUNT_NUM_GPIO(devinfo->gpio_cap); i++) { device_printf(dev, " GPIO%d: ", i); if ((enable & (1 << i)) == 0) { printf("disabled\n"); continue; } if ((dir & (1 << i)) == 0) { printf("input%s%s%s", (sticky & (1 << i)) ? " sticky" : "", (unsol & (1 << i)) ? " unsol" : "", (wake & (1 << i)) ? " wake" : ""); } else printf("output"); printf(" state=%d\n", (data >> i) & 1); } } } static void hdaa_dump_gpo(struct hdaa_devinfo *devinfo) { device_t dev = devinfo->dev; int i; uint32_t data; if (HDA_PARAM_GPIO_COUNT_NUM_GPO(devinfo->gpio_cap) > 0) { data = hda_command(dev, HDA_CMD_GET_GPO_DATA(0, devinfo->nid)); for (i = 0; i < HDA_PARAM_GPIO_COUNT_NUM_GPO(devinfo->gpio_cap); i++) { - device_printf(dev, " GPO%d: state=%d", i, + device_printf(dev, " GPO%d: state=%d\n", i, (data >> i) & 1); } } } static void hdaa_audio_parse(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; uint32_t res; int i; nid_t nid; nid = devinfo->nid; res = hda_command(devinfo->dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_GPIO_COUNT)); devinfo->gpio_cap = res; HDA_BOOTVERBOSE( device_printf(devinfo->dev, "NumGPIO=%d NumGPO=%d " "NumGPI=%d GPIWake=%d GPIUnsol=%d\n", HDA_PARAM_GPIO_COUNT_NUM_GPIO(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_NUM_GPO(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_NUM_GPI(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_GPI_WAKE(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_GPI_UNSOL(devinfo->gpio_cap)); hdaa_dump_gpi(devinfo); hdaa_dump_gpio(devinfo); hdaa_dump_gpo(devinfo); ); res = hda_command(devinfo->dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_SUPP_STREAM_FORMATS)); devinfo->supp_stream_formats = res; res = hda_command(devinfo->dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_SUPP_PCM_SIZE_RATE)); devinfo->supp_pcm_size_rate = res; res = hda_command(devinfo->dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_OUTPUT_AMP_CAP)); devinfo->outamp_cap = res; res = hda_command(devinfo->dev, HDA_CMD_GET_PARAMETER(0, nid, HDA_PARAM_INPUT_AMP_CAP)); devinfo->inamp_cap = res; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL) device_printf(devinfo->dev, "Ghost widget! nid=%d!\n", i); else { w->devinfo = devinfo; w->nid = i; w->enable = 1; w->selconn = -1; w->pflags = 0; w->ossdev = -1; w->bindas = -1; w->param.eapdbtl = HDA_INVALID; hdaa_widget_parse(w); } } } static void hdaa_audio_postprocess(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; int i; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL) continue; hdaa_widget_postprocess(w); } } static void hdaa_audio_ctl_parse(struct hdaa_devinfo *devinfo) { struct hdaa_audio_ctl *ctls; struct hdaa_widget *w, *cw; int i, j, cnt, max, ocap, icap; int mute, offset, step, size; /* XXX This is redundant */ max = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->param.outamp_cap != 0) max++; if (w->param.inamp_cap != 0) { switch (w->type) { case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR: case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER: for (j = 0; j < w->nconns; j++) { cw = hdaa_widget_get(devinfo, w->conns[j]); if (cw == NULL || cw->enable == 0) continue; max++; } break; default: max++; break; } } } devinfo->ctlcnt = max; if (max < 1) return; ctls = malloc(sizeof(*ctls) * max, M_HDAA, M_ZERO | M_NOWAIT); if (ctls == NULL) { /* Blekh! */ device_printf(devinfo->dev, "unable to allocate ctls!\n"); devinfo->ctlcnt = 0; return; } cnt = 0; for (i = devinfo->startnode; cnt < max && i < devinfo->endnode; i++) { if (cnt >= max) { device_printf(devinfo->dev, "%s: Ctl overflow!\n", __func__); break; } w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; ocap = w->param.outamp_cap; icap = w->param.inamp_cap; if (ocap != 0) { mute = HDA_PARAM_OUTPUT_AMP_CAP_MUTE_CAP(ocap); step = HDA_PARAM_OUTPUT_AMP_CAP_NUMSTEPS(ocap); size = HDA_PARAM_OUTPUT_AMP_CAP_STEPSIZE(ocap); offset = HDA_PARAM_OUTPUT_AMP_CAP_OFFSET(ocap); /*if (offset > step) { HDA_BOOTVERBOSE( device_printf(devinfo->dev, "BUGGY outamp: nid=%d " "[offset=%d > step=%d]\n", w->nid, offset, step); ); offset = step; }*/ ctls[cnt].enable = 1; ctls[cnt].widget = w; ctls[cnt].mute = mute; ctls[cnt].step = step; ctls[cnt].size = size; ctls[cnt].offset = offset; ctls[cnt].left = offset; ctls[cnt].right = offset; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX || w->waspin) ctls[cnt].ndir = HDAA_CTL_IN; else ctls[cnt].ndir = HDAA_CTL_OUT; ctls[cnt++].dir = HDAA_CTL_OUT; } if (icap != 0) { mute = HDA_PARAM_OUTPUT_AMP_CAP_MUTE_CAP(icap); step = HDA_PARAM_OUTPUT_AMP_CAP_NUMSTEPS(icap); size = HDA_PARAM_OUTPUT_AMP_CAP_STEPSIZE(icap); offset = HDA_PARAM_OUTPUT_AMP_CAP_OFFSET(icap); /*if (offset > step) { HDA_BOOTVERBOSE( device_printf(devinfo->dev, "BUGGY inamp: nid=%d " "[offset=%d > step=%d]\n", w->nid, offset, step); ); offset = step; }*/ switch (w->type) { case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR: case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER: for (j = 0; j < w->nconns; j++) { if (cnt >= max) { device_printf(devinfo->dev, "%s: Ctl overflow!\n", __func__); break; } cw = hdaa_widget_get(devinfo, w->conns[j]); if (cw == NULL || cw->enable == 0) continue; ctls[cnt].enable = 1; ctls[cnt].widget = w; ctls[cnt].childwidget = cw; ctls[cnt].index = j; ctls[cnt].mute = mute; ctls[cnt].step = step; ctls[cnt].size = size; ctls[cnt].offset = offset; ctls[cnt].left = offset; ctls[cnt].right = offset; ctls[cnt].ndir = HDAA_CTL_IN; ctls[cnt++].dir = HDAA_CTL_IN; } break; default: if (cnt >= max) { device_printf(devinfo->dev, "%s: Ctl overflow!\n", __func__); break; } ctls[cnt].enable = 1; ctls[cnt].widget = w; ctls[cnt].mute = mute; ctls[cnt].step = step; ctls[cnt].size = size; ctls[cnt].offset = offset; ctls[cnt].left = offset; ctls[cnt].right = offset; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) ctls[cnt].ndir = HDAA_CTL_OUT; else ctls[cnt].ndir = HDAA_CTL_IN; ctls[cnt++].dir = HDAA_CTL_IN; break; } } } devinfo->ctl = ctls; } static void hdaa_audio_as_parse(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as; struct hdaa_widget *w; int i, j, cnt, max, type, dir, assoc, seq, first, hpredir; /* Count present associations */ max = 0; for (j = 1; j < 16; j++) { for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (HDA_CONFIG_DEFAULTCONF_ASSOCIATION(w->wclass.pin.config) != j) continue; max++; if (j != 15) /* There could be many 1-pin assocs #15 */ break; } } devinfo->ascnt = max; if (max < 1) return; as = malloc(sizeof(*as) * max, M_HDAA, M_ZERO | M_NOWAIT); if (as == NULL) { /* Blekh! */ device_printf(devinfo->dev, "unable to allocate assocs!\n"); devinfo->ascnt = 0; return; } for (i = 0; i < max; i++) { as[i].hpredir = -1; as[i].digital = 0; as[i].num_chans = 1; as[i].location = -1; } /* Scan associations skipping as=0. */ cnt = 0; for (j = 1; j < 16 && cnt < max; j++) { first = 16; hpredir = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; assoc = HDA_CONFIG_DEFAULTCONF_ASSOCIATION(w->wclass.pin.config); seq = HDA_CONFIG_DEFAULTCONF_SEQUENCE(w->wclass.pin.config); if (assoc != j) { continue; } KASSERT(cnt < max, ("%s: Associations overflow (%d of %d)", __func__, cnt, max)); type = w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK; /* Get pin direction. */ if (type == HDA_CONFIG_DEFAULTCONF_DEVICE_LINE_OUT || type == HDA_CONFIG_DEFAULTCONF_DEVICE_SPEAKER || type == HDA_CONFIG_DEFAULTCONF_DEVICE_HP_OUT || type == HDA_CONFIG_DEFAULTCONF_DEVICE_SPDIF_OUT || type == HDA_CONFIG_DEFAULTCONF_DEVICE_DIGITAL_OTHER_OUT) dir = HDAA_CTL_OUT; else dir = HDAA_CTL_IN; /* If this is a first pin - create new association. */ if (as[cnt].pincnt == 0) { as[cnt].enable = 1; as[cnt].index = j; as[cnt].dir = dir; } if (seq < first) first = seq; /* Check association correctness. */ if (as[cnt].pins[seq] != 0) { device_printf(devinfo->dev, "%s: Duplicate pin %d (%d) " "in association %d! Disabling association.\n", __func__, seq, w->nid, j); as[cnt].enable = 0; } if (dir != as[cnt].dir) { device_printf(devinfo->dev, "%s: Pin %d has wrong " "direction for association %d! Disabling " "association.\n", __func__, w->nid, j); as[cnt].enable = 0; } if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) { as[cnt].digital |= 0x1; if (HDA_PARAM_PIN_CAP_HDMI(w->wclass.pin.cap)) as[cnt].digital |= 0x2; if (HDA_PARAM_PIN_CAP_DP(w->wclass.pin.cap)) as[cnt].digital |= 0x4; } if (as[cnt].location == -1) { as[cnt].location = HDA_CONFIG_DEFAULTCONF_LOCATION(w->wclass.pin.config); } else if (as[cnt].location != HDA_CONFIG_DEFAULTCONF_LOCATION(w->wclass.pin.config)) { as[cnt].location = -2; } /* Headphones with seq=15 may mean redirection. */ if (type == HDA_CONFIG_DEFAULTCONF_DEVICE_HP_OUT && seq == 15) hpredir = 1; as[cnt].pins[seq] = w->nid; as[cnt].pincnt++; /* Association 15 is a multiple unassociated pins. */ if (j == 15) cnt++; } if (j != 15 && as[cnt].pincnt > 0) { if (hpredir && as[cnt].pincnt > 1) as[cnt].hpredir = first; cnt++; } } for (i = 0; i < max; i++) { if (as[i].dir == HDAA_CTL_IN && (as[i].pincnt == 1 || as[i].pins[14] > 0 || as[i].pins[15] > 0)) as[i].mixed = 1; } HDA_BOOTVERBOSE( device_printf(devinfo->dev, "%d associations found:\n", max); for (i = 0; i < max; i++) { device_printf(devinfo->dev, "Association %d (%d) %s%s:\n", i, as[i].index, (as[i].dir == HDAA_CTL_IN)?"in":"out", as[i].enable?"":" (disabled)"); for (j = 0; j < 16; j++) { if (as[i].pins[j] == 0) continue; device_printf(devinfo->dev, " Pin nid=%d seq=%d\n", as[i].pins[j], j); } } ); devinfo->as = as; } /* * Trace path from DAC to pin. */ static nid_t hdaa_audio_trace_dac(struct hdaa_devinfo *devinfo, int as, int seq, nid_t nid, int dupseq, int min, int only, int depth) { struct hdaa_widget *w; int i, im = -1; nid_t m = 0, ret; if (depth > HDA_PARSE_MAXDEPTH) return (0); w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return (0); HDA_BOOTHVERBOSE( if (!only) { device_printf(devinfo->dev, " %*stracing via nid %d\n", depth + 1, "", w->nid); } ); /* Use only unused widgets */ if (w->bindas >= 0 && w->bindas != as) { HDA_BOOTHVERBOSE( if (!only) { device_printf(devinfo->dev, " %*snid %d busy by association %d\n", depth + 1, "", w->nid, w->bindas); } ); return (0); } if (dupseq < 0) { if (w->bindseqmask != 0) { HDA_BOOTHVERBOSE( if (!only) { device_printf(devinfo->dev, " %*snid %d busy by seqmask %x\n", depth + 1, "", w->nid, w->bindseqmask); } ); return (0); } } else { /* If this is headphones - allow duplicate first pin. */ if (w->bindseqmask != 0 && (w->bindseqmask & (1 << dupseq)) == 0) { HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*snid %d busy by seqmask %x\n", depth + 1, "", w->nid, w->bindseqmask); ); return (0); } } switch (w->type) { case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT: /* Do not traverse input. AD1988 has digital monitor for which we are not ready. */ break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT: /* If we are tracing HP take only dac of first pin. */ if ((only == 0 || only == w->nid) && (w->nid >= min) && (dupseq < 0 || w->nid == devinfo->as[as].dacs[0][dupseq])) m = w->nid; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX: if (depth > 0) break; /* Fall */ default: /* Find reachable DACs with smallest nid respecting constraints. */ for (i = 0; i < w->nconns; i++) { if (w->connsenable[i] == 0) continue; if (w->selconn != -1 && w->selconn != i) continue; if ((ret = hdaa_audio_trace_dac(devinfo, as, seq, w->conns[i], dupseq, min, only, depth + 1)) != 0) { if (m == 0 || ret < m) { m = ret; im = i; } if (only || dupseq >= 0) break; } } if (im >= 0 && only && ((w->nconns > 1 && w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR)) w->selconn = im; break; } if (m && only) { w->bindas = as; w->bindseqmask |= (1 << seq); } HDA_BOOTHVERBOSE( if (!only) { device_printf(devinfo->dev, " %*snid %d returned %d\n", depth + 1, "", w->nid, m); } ); return (m); } /* * Trace path from widget to ADC. */ static nid_t hdaa_audio_trace_adc(struct hdaa_devinfo *devinfo, int as, int seq, nid_t nid, int mixed, int min, int only, int depth, int *length, int onlylength) { struct hdaa_widget *w, *wc; int i, j, im, lm = HDA_PARSE_MAXDEPTH; nid_t m = 0, ret; if (depth > HDA_PARSE_MAXDEPTH) return (0); w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return (0); HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*stracing via nid %d\n", depth + 1, "", w->nid); ); /* Use only unused widgets */ if (w->bindas >= 0 && w->bindas != as) { HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*snid %d busy by association %d\n", depth + 1, "", w->nid, w->bindas); ); return (0); } if (!mixed && w->bindseqmask != 0) { HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*snid %d busy by seqmask %x\n", depth + 1, "", w->nid, w->bindseqmask); ); return (0); } switch (w->type) { case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT: if ((only == 0 || only == w->nid) && (w->nid >= min) && (onlylength == 0 || onlylength == depth)) { m = w->nid; *length = depth; } break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX: if (depth > 0) break; /* Fall */ default: /* Try to find reachable ADCs with specified nid. */ for (j = devinfo->startnode; j < devinfo->endnode; j++) { wc = hdaa_widget_get(devinfo, j); if (wc == NULL || wc->enable == 0) continue; im = -1; for (i = 0; i < wc->nconns; i++) { if (wc->connsenable[i] == 0) continue; if (wc->conns[i] != nid) continue; if ((ret = hdaa_audio_trace_adc(devinfo, as, seq, j, mixed, min, only, depth + 1, length, onlylength)) != 0) { if (m == 0 || ret < m || (ret == m && *length < lm)) { m = ret; im = i; lm = *length; } else *length = lm; if (only) break; } } if (im >= 0 && only && ((wc->nconns > 1 && wc->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) || wc->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR)) wc->selconn = im; } break; } if (m && only) { w->bindas = as; w->bindseqmask |= (1 << seq); } HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*snid %d returned %d\n", depth + 1, "", w->nid, m); ); return (m); } /* * Erase trace path of the specified association. */ static void hdaa_audio_undo_trace(struct hdaa_devinfo *devinfo, int as, int seq) { struct hdaa_widget *w; int i; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->bindas == as) { if (seq >= 0) { w->bindseqmask &= ~(1 << seq); if (w->bindseqmask == 0) { w->bindas = -1; w->selconn = -1; } } else { w->bindas = -1; w->bindseqmask = 0; w->selconn = -1; } } } } /* * Trace association path from DAC to output */ static int hdaa_audio_trace_as_out(struct hdaa_devinfo *devinfo, int as, int seq) { struct hdaa_audio_as *ases = devinfo->as; int i, hpredir; nid_t min, res; /* Find next pin */ for (i = seq; i < 16 && ases[as].pins[i] == 0; i++) ; /* Check if there is no any left. If so - we succeeded. */ if (i == 16) return (1); hpredir = (i == 15 && ases[as].fakeredir == 0)?ases[as].hpredir:-1; min = 0; do { HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Tracing pin %d with min nid %d", ases[as].pins[i], min); if (hpredir >= 0) printf(" and hpredir %d", hpredir); printf("\n"); ); /* Trace this pin taking min nid into account. */ res = hdaa_audio_trace_dac(devinfo, as, i, ases[as].pins[i], hpredir, min, 0, 0); if (res == 0) { /* If we failed - return to previous and redo it. */ HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Unable to trace pin %d seq %d with min " "nid %d", ases[as].pins[i], i, min); if (hpredir >= 0) printf(" and hpredir %d", hpredir); printf("\n"); ); return (0); } HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Pin %d traced to DAC %d", ases[as].pins[i], res); if (hpredir >= 0) printf(" and hpredir %d", hpredir); if (ases[as].fakeredir) printf(" with fake redirection"); printf("\n"); ); /* Trace again to mark the path */ hdaa_audio_trace_dac(devinfo, as, i, ases[as].pins[i], hpredir, min, res, 0); ases[as].dacs[0][i] = res; /* We succeeded, so call next. */ if (hdaa_audio_trace_as_out(devinfo, as, i + 1)) return (1); /* If next failed, we should retry with next min */ hdaa_audio_undo_trace(devinfo, as, i); ases[as].dacs[0][i] = 0; min = res + 1; } while (1); } /* * Check equivalency of two DACs. */ static int hdaa_audio_dacs_equal(struct hdaa_widget *w1, struct hdaa_widget *w2) { struct hdaa_devinfo *devinfo = w1->devinfo; struct hdaa_widget *w3; int i, j, c1, c2; if (memcmp(&w1->param, &w2->param, sizeof(w1->param))) return (0); for (i = devinfo->startnode; i < devinfo->endnode; i++) { w3 = hdaa_widget_get(devinfo, i); if (w3 == NULL || w3->enable == 0) continue; if (w3->bindas != w1->bindas) continue; if (w3->nconns == 0) continue; c1 = c2 = -1; for (j = 0; j < w3->nconns; j++) { if (w3->connsenable[j] == 0) continue; if (w3->conns[j] == w1->nid) c1 = j; if (w3->conns[j] == w2->nid) c2 = j; } if (c1 < 0) continue; if (c2 < 0) return (0); if (w3->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) return (0); } return (1); } /* * Check equivalency of two ADCs. */ static int hdaa_audio_adcs_equal(struct hdaa_widget *w1, struct hdaa_widget *w2) { struct hdaa_devinfo *devinfo = w1->devinfo; struct hdaa_widget *w3, *w4; int i; if (memcmp(&w1->param, &w2->param, sizeof(w1->param))) return (0); if (w1->nconns != 1 || w2->nconns != 1) return (0); if (w1->conns[0] == w2->conns[0]) return (1); w3 = hdaa_widget_get(devinfo, w1->conns[0]); if (w3 == NULL || w3->enable == 0) return (0); w4 = hdaa_widget_get(devinfo, w2->conns[0]); if (w4 == NULL || w4->enable == 0) return (0); if (w3->bindas == w4->bindas && w3->bindseqmask == w4->bindseqmask) return (1); if (w4->bindas >= 0) return (0); if (w3->type != w4->type) return (0); if (memcmp(&w3->param, &w4->param, sizeof(w3->param))) return (0); if (w3->nconns != w4->nconns) return (0); for (i = 0; i < w3->nconns; i++) { if (w3->conns[i] != w4->conns[i]) return (0); } return (1); } /* * Look for equivalent DAC/ADC to implement second channel. */ static void hdaa_audio_adddac(struct hdaa_devinfo *devinfo, int asid) { struct hdaa_audio_as *as = &devinfo->as[asid]; struct hdaa_widget *w1, *w2; int i, pos; nid_t nid1, nid2; HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Looking for additional %sC " "for association %d (%d)\n", (as->dir == HDAA_CTL_OUT) ? "DA" : "AD", asid, as->index); ); /* Find the existing DAC position and return if found more the one. */ pos = -1; for (i = 0; i < 16; i++) { if (as->dacs[0][i] <= 0) continue; if (pos >= 0 && as->dacs[0][i] != as->dacs[0][pos]) return; pos = i; } nid1 = as->dacs[0][pos]; w1 = hdaa_widget_get(devinfo, nid1); w2 = NULL; for (nid2 = devinfo->startnode; nid2 < devinfo->endnode; nid2++) { w2 = hdaa_widget_get(devinfo, nid2); if (w2 == NULL || w2->enable == 0) continue; if (w2->bindas >= 0) continue; if (w1->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT) { if (w2->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT) continue; if (hdaa_audio_dacs_equal(w1, w2)) break; } else { if (w2->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) continue; if (hdaa_audio_adcs_equal(w1, w2)) break; } } if (nid2 >= devinfo->endnode) return; w2->bindas = w1->bindas; w2->bindseqmask = w1->bindseqmask; if (w1->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) { HDA_BOOTVERBOSE( device_printf(devinfo->dev, " ADC %d considered equal to ADC %d\n", nid2, nid1); ); w1 = hdaa_widget_get(devinfo, w1->conns[0]); w2 = hdaa_widget_get(devinfo, w2->conns[0]); w2->bindas = w1->bindas; w2->bindseqmask = w1->bindseqmask; } else { HDA_BOOTVERBOSE( device_printf(devinfo->dev, " DAC %d considered equal to DAC %d\n", nid2, nid1); ); } for (i = 0; i < 16; i++) { if (as->dacs[0][i] <= 0) continue; as->dacs[as->num_chans][i] = nid2; } as->num_chans++; } /* * Trace association path from input to ADC */ static int hdaa_audio_trace_as_in(struct hdaa_devinfo *devinfo, int as) { struct hdaa_audio_as *ases = devinfo->as; struct hdaa_widget *w; int i, j, k, length; for (j = devinfo->startnode; j < devinfo->endnode; j++) { w = hdaa_widget_get(devinfo, j); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) continue; if (w->bindas >= 0 && w->bindas != as) continue; /* Find next pin */ for (i = 0; i < 16; i++) { if (ases[as].pins[i] == 0) continue; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Tracing pin %d to ADC %d\n", ases[as].pins[i], j); ); /* Trace this pin taking goal into account. */ if (hdaa_audio_trace_adc(devinfo, as, i, ases[as].pins[i], 1, 0, j, 0, &length, 0) == 0) { /* If we failed - return to previous and redo it. */ HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Unable to trace pin %d to ADC %d, undo traces\n", ases[as].pins[i], j); ); hdaa_audio_undo_trace(devinfo, as, -1); for (k = 0; k < 16; k++) ases[as].dacs[0][k] = 0; break; } HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Pin %d traced to ADC %d\n", ases[as].pins[i], j); ); ases[as].dacs[0][i] = j; } if (i == 16) return (1); } return (0); } /* * Trace association path from input to multiple ADCs */ static int hdaa_audio_trace_as_in_mch(struct hdaa_devinfo *devinfo, int as, int seq) { struct hdaa_audio_as *ases = devinfo->as; int i, length; nid_t min, res; /* Find next pin */ for (i = seq; i < 16 && ases[as].pins[i] == 0; i++) ; /* Check if there is no any left. If so - we succeeded. */ if (i == 16) return (1); min = 0; do { HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Tracing pin %d with min nid %d", ases[as].pins[i], min); printf("\n"); ); /* Trace this pin taking min nid into account. */ res = hdaa_audio_trace_adc(devinfo, as, i, ases[as].pins[i], 0, min, 0, 0, &length, 0); if (res == 0) { /* If we failed - return to previous and redo it. */ HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Unable to trace pin %d seq %d with min " "nid %d", ases[as].pins[i], i, min); printf("\n"); ); return (0); } HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Pin %d traced to ADC %d\n", ases[as].pins[i], res); ); /* Trace again to mark the path */ hdaa_audio_trace_adc(devinfo, as, i, ases[as].pins[i], 0, min, res, 0, &length, length); ases[as].dacs[0][i] = res; /* We succeeded, so call next. */ if (hdaa_audio_trace_as_in_mch(devinfo, as, i + 1)) return (1); /* If next failed, we should retry with next min */ hdaa_audio_undo_trace(devinfo, as, i); ases[as].dacs[0][i] = 0; min = res + 1; } while (1); } /* * Trace input monitor path from mixer to output association. */ static int hdaa_audio_trace_to_out(struct hdaa_devinfo *devinfo, nid_t nid, int depth) { struct hdaa_audio_as *ases = devinfo->as; struct hdaa_widget *w, *wc; int i, j; nid_t res = 0; if (depth > HDA_PARSE_MAXDEPTH) return (0); w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return (0); HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*stracing via nid %d\n", depth + 1, "", w->nid); ); /* Use only unused widgets */ if (depth > 0 && w->bindas != -1) { if (w->bindas < 0 || ases[w->bindas].dir == HDAA_CTL_OUT) { HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*snid %d found output association %d\n", depth + 1, "", w->nid, w->bindas); ); if (w->bindas >= 0) w->pflags |= HDAA_ADC_MONITOR; return (1); } else { HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*snid %d busy by input association %d\n", depth + 1, "", w->nid, w->bindas); ); return (0); } } switch (w->type) { case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT: /* Do not traverse input. AD1988 has digital monitor for which we are not ready. */ break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX: if (depth > 0) break; /* Fall */ default: /* Try to find reachable ADCs with specified nid. */ for (j = devinfo->startnode; j < devinfo->endnode; j++) { wc = hdaa_widget_get(devinfo, j); if (wc == NULL || wc->enable == 0) continue; for (i = 0; i < wc->nconns; i++) { if (wc->connsenable[i] == 0) continue; if (wc->conns[i] != nid) continue; if (hdaa_audio_trace_to_out(devinfo, j, depth + 1) != 0) { res = 1; if (wc->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR && wc->selconn == -1) wc->selconn = i; } } } break; } if (res && w->bindas == -1) w->bindas = -2; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " %*snid %d returned %d\n", depth + 1, "", w->nid, res); ); return (res); } /* * Trace extra associations (beeper, monitor) */ static void hdaa_audio_trace_as_extra(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w; int j; /* Input monitor */ /* Find mixer associated with input, but supplying signal for output associations. Hope it will be input monitor. */ HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Tracing input monitor\n"); ); for (j = devinfo->startnode; j < devinfo->endnode; j++) { w = hdaa_widget_get(devinfo, j); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) continue; if (w->bindas < 0 || as[w->bindas].dir != HDAA_CTL_IN) continue; HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Tracing nid %d to out\n", j); ); if (hdaa_audio_trace_to_out(devinfo, w->nid, 0)) { HDA_BOOTVERBOSE( device_printf(devinfo->dev, " nid %d is input monitor\n", w->nid); ); w->ossdev = SOUND_MIXER_IMIX; } } /* Other inputs monitor */ /* Find input pins supplying signal for output associations. Hope it will be input monitoring. */ HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Tracing other input monitors\n"); ); for (j = devinfo->startnode; j < devinfo->endnode; j++) { w = hdaa_widget_get(devinfo, j); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (w->bindas < 0 || as[w->bindas].dir != HDAA_CTL_IN) continue; HDA_BOOTVERBOSE( device_printf(devinfo->dev, " Tracing nid %d to out\n", j); ); if (hdaa_audio_trace_to_out(devinfo, w->nid, 0)) { HDA_BOOTVERBOSE( device_printf(devinfo->dev, " nid %d is input monitor\n", w->nid); ); } } /* Beeper */ HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Tracing beeper\n"); ); for (j = devinfo->startnode; j < devinfo->endnode; j++) { w = hdaa_widget_get(devinfo, j); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_BEEP_WIDGET) continue; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Tracing nid %d to out\n", j); ); if (hdaa_audio_trace_to_out(devinfo, w->nid, 0)) { HDA_BOOTVERBOSE( device_printf(devinfo->dev, " nid %d traced to out\n", j); ); } w->bindas = -2; } } /* * Bind assotiations to PCM channels */ static void hdaa_audio_bind_as(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; int i, j, cnt = 0, free; for (j = 0; j < devinfo->ascnt; j++) { if (as[j].enable) cnt += as[j].num_chans; } if (devinfo->num_chans == 0) { devinfo->chans = malloc(sizeof(struct hdaa_chan) * cnt, M_HDAA, M_ZERO | M_NOWAIT); if (devinfo->chans == NULL) { device_printf(devinfo->dev, "Channels memory allocation failed!\n"); return; } } else { devinfo->chans = (struct hdaa_chan *)realloc(devinfo->chans, sizeof(struct hdaa_chan) * (devinfo->num_chans + cnt), M_HDAA, M_ZERO | M_NOWAIT); if (devinfo->chans == NULL) { devinfo->num_chans = 0; device_printf(devinfo->dev, "Channels memory allocation failed!\n"); return; } /* Fixup relative pointers after realloc */ for (j = 0; j < devinfo->num_chans; j++) devinfo->chans[j].caps.fmtlist = devinfo->chans[j].fmtlist; } free = devinfo->num_chans; devinfo->num_chans += cnt; for (j = free; j < free + cnt; j++) { devinfo->chans[j].devinfo = devinfo; devinfo->chans[j].as = -1; } /* Assign associations in order of their numbers, */ for (j = 0; j < devinfo->ascnt; j++) { if (as[j].enable == 0) continue; for (i = 0; i < as[j].num_chans; i++) { devinfo->chans[free].as = j; devinfo->chans[free].asindex = i; devinfo->chans[free].dir = (as[j].dir == HDAA_CTL_IN) ? PCMDIR_REC : PCMDIR_PLAY; hdaa_pcmchannel_setup(&devinfo->chans[free]); as[j].chans[i] = free; free++; } } } static void hdaa_audio_disable_nonaudio(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; int i; /* Disable power and volume widgets. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_POWER_WIDGET || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_VOLUME_WIDGET) { w->enable = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling nid %d due to it's" " non-audio type.\n", w->nid); ); } } } static void hdaa_audio_disable_useless(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w, *cw; struct hdaa_audio_ctl *ctl; int done, found, i, j, k; /* Disable useless pins. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) { if ((w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK) == HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_NONE) { w->enable = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling pin nid %d due" " to None connectivity.\n", w->nid); ); } else if ((w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_ASSOCIATION_MASK) == 0) { w->enable = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling unassociated" " pin nid %d.\n", w->nid); ); } } } do { done = 1; /* Disable and mute controls for disabled widgets. */ i = 0; while ((ctl = hdaa_audio_ctl_each(devinfo, &i)) != NULL) { if (ctl->enable == 0) continue; if (ctl->widget->enable == 0 || (ctl->childwidget != NULL && ctl->childwidget->enable == 0)) { ctl->forcemute = 1; ctl->muted = HDAA_AMP_MUTE_ALL; ctl->left = 0; ctl->right = 0; ctl->enable = 0; if (ctl->ndir == HDAA_CTL_IN) ctl->widget->connsenable[ctl->index] = 0; done = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling ctl %d nid %d cnid %d due" " to disabled widget.\n", i, ctl->widget->nid, (ctl->childwidget != NULL)? ctl->childwidget->nid:-1); ); } } /* Disable useless widgets. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; /* Disable inputs with disabled child widgets. */ for (j = 0; j < w->nconns; j++) { if (w->connsenable[j]) { cw = hdaa_widget_get(devinfo, w->conns[j]); if (cw == NULL || cw->enable == 0) { w->connsenable[j] = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling nid %d connection %d due" " to disabled child widget.\n", i, j); ); } } } if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR && w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) continue; /* Disable mixers and selectors without inputs. */ found = 0; for (j = 0; j < w->nconns; j++) { if (w->connsenable[j]) { found = 1; break; } } if (found == 0) { w->enable = 0; done = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling nid %d due to all it's" " inputs disabled.\n", w->nid); ); } /* Disable nodes without consumers. */ if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_SELECTOR && w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) continue; found = 0; for (k = devinfo->startnode; k < devinfo->endnode; k++) { cw = hdaa_widget_get(devinfo, k); if (cw == NULL || cw->enable == 0) continue; for (j = 0; j < cw->nconns; j++) { if (cw->connsenable[j] && cw->conns[j] == i) { found = 1; break; } } } if (found == 0) { w->enable = 0; done = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling nid %d due to all it's" " consumers disabled.\n", w->nid); ); } } } while (done == 0); } static void hdaa_audio_disable_unas(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w, *cw; struct hdaa_audio_ctl *ctl; int i, j, k; /* Disable unassosiated widgets. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->bindas == -1) { w->enable = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling unassociated nid %d.\n", w->nid); ); } } /* Disable input connections on input pin and * output on output. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (w->bindas < 0) continue; if (as[w->bindas].dir == HDAA_CTL_IN) { for (j = 0; j < w->nconns; j++) { if (w->connsenable[j] == 0) continue; w->connsenable[j] = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling connection to input pin " "nid %d conn %d.\n", i, j); ); } ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_IN, -1, 1); if (ctl && ctl->enable) { ctl->forcemute = 1; ctl->muted = HDAA_AMP_MUTE_ALL; ctl->left = 0; ctl->right = 0; ctl->enable = 0; } } else { ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_OUT, -1, 1); if (ctl && ctl->enable) { ctl->forcemute = 1; ctl->muted = HDAA_AMP_MUTE_ALL; ctl->left = 0; ctl->right = 0; ctl->enable = 0; } for (k = devinfo->startnode; k < devinfo->endnode; k++) { cw = hdaa_widget_get(devinfo, k); if (cw == NULL || cw->enable == 0) continue; for (j = 0; j < cw->nconns; j++) { if (cw->connsenable[j] && cw->conns[j] == i) { cw->connsenable[j] = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling connection from output pin " "nid %d conn %d cnid %d.\n", k, j, i); ); if (cw->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && cw->nconns > 1) continue; ctl = hdaa_audio_ctl_amp_get(devinfo, k, HDAA_CTL_IN, j, 1); if (ctl && ctl->enable) { ctl->forcemute = 1; ctl->muted = HDAA_AMP_MUTE_ALL; ctl->left = 0; ctl->right = 0; ctl->enable = 0; } } } } } } } static void hdaa_audio_disable_notselected(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w; int i, j; /* On playback path we can safely disable all unseleted inputs. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->nconns <= 1) continue; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) continue; if (w->bindas < 0 || as[w->bindas].dir == HDAA_CTL_IN) continue; for (j = 0; j < w->nconns; j++) { if (w->connsenable[j] == 0) continue; if (w->selconn < 0 || w->selconn == j) continue; w->connsenable[j] = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling unselected connection " "nid %d conn %d.\n", i, j); ); } } } static void hdaa_audio_disable_crossas(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *ases = devinfo->as; struct hdaa_widget *w, *cw; struct hdaa_audio_ctl *ctl; int i, j; /* Disable crossassociatement and unwanted crosschannel connections. */ /* ... using selectors */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->nconns <= 1) continue; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) continue; /* Allow any -> mix */ if (w->bindas == -2) continue; for (j = 0; j < w->nconns; j++) { if (w->connsenable[j] == 0) continue; cw = hdaa_widget_get(devinfo, w->conns[j]); if (cw == NULL || w->enable == 0) continue; /* Allow mix -> out. */ if (cw->bindas == -2 && w->bindas >= 0 && ases[w->bindas].dir == HDAA_CTL_OUT) continue; /* Allow mix -> mixed-in. */ if (cw->bindas == -2 && w->bindas >= 0 && ases[w->bindas].mixed) continue; /* Allow in -> mix. */ if ((w->pflags & HDAA_ADC_MONITOR) && cw->bindas >= 0 && ases[cw->bindas].dir == HDAA_CTL_IN) continue; /* Allow if have common as/seqs. */ if (w->bindas == cw->bindas && (w->bindseqmask & cw->bindseqmask) != 0) continue; w->connsenable[j] = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling crossassociatement connection " "nid %d conn %d cnid %d.\n", i, j, cw->nid); ); } } /* ... using controls */ i = 0; while ((ctl = hdaa_audio_ctl_each(devinfo, &i)) != NULL) { if (ctl->enable == 0 || ctl->childwidget == NULL) continue; /* Allow any -> mix */ if (ctl->widget->bindas == -2) continue; /* Allow mix -> out. */ if (ctl->childwidget->bindas == -2 && ctl->widget->bindas >= 0 && ases[ctl->widget->bindas].dir == HDAA_CTL_OUT) continue; /* Allow mix -> mixed-in. */ if (ctl->childwidget->bindas == -2 && ctl->widget->bindas >= 0 && ases[ctl->widget->bindas].mixed) continue; /* Allow in -> mix. */ if ((ctl->widget->pflags & HDAA_ADC_MONITOR) && ctl->childwidget->bindas >= 0 && ases[ctl->childwidget->bindas].dir == HDAA_CTL_IN) continue; /* Allow if have common as/seqs. */ if (ctl->widget->bindas == ctl->childwidget->bindas && (ctl->widget->bindseqmask & ctl->childwidget->bindseqmask) != 0) continue; ctl->forcemute = 1; ctl->muted = HDAA_AMP_MUTE_ALL; ctl->left = 0; ctl->right = 0; ctl->enable = 0; if (ctl->ndir == HDAA_CTL_IN) ctl->widget->connsenable[ctl->index] = 0; HDA_BOOTHVERBOSE( device_printf(devinfo->dev, " Disabling crossassociatement connection " "ctl %d nid %d cnid %d.\n", i, ctl->widget->nid, ctl->childwidget->nid); ); } } /* * Find controls to control amplification for source and calculate possible * amplification range. */ static int hdaa_audio_ctl_source_amp(struct hdaa_devinfo *devinfo, nid_t nid, int index, int ossdev, int ctlable, int depth, int *minamp, int *maxamp) { struct hdaa_widget *w, *wc; struct hdaa_audio_ctl *ctl; int i, j, conns = 0, tminamp, tmaxamp, cminamp, cmaxamp, found = 0; if (depth > HDA_PARSE_MAXDEPTH) return (found); w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return (found); /* Count number of active inputs. */ if (depth > 0) { for (j = 0; j < w->nconns; j++) { if (!w->connsenable[j]) continue; conns++; } } /* If this is not a first step - use input mixer. Pins have common input ctl so care must be taken. */ if (depth > 0 && ctlable && (conns == 1 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX)) { ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_IN, index, 1); if (ctl) { ctl->ossmask |= (1 << ossdev); found++; if (*minamp == *maxamp) { *minamp += MINQDB(ctl); *maxamp += MAXQDB(ctl); } } } /* If widget has own ossdev - not traverse it. It will be traversed on its own. */ if (w->ossdev >= 0 && depth > 0) return (found); /* We must not traverse pin */ if ((w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) && depth > 0) return (found); /* record that this widget exports such signal, */ w->ossmask |= (1 << ossdev); /* * If signals mixed, we can't assign controls farther. * Ignore this on depth zero. Caller must knows why. */ if (conns > 1 && w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) ctlable = 0; if (ctlable) { ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_OUT, -1, 1); if (ctl) { ctl->ossmask |= (1 << ossdev); found++; if (*minamp == *maxamp) { *minamp += MINQDB(ctl); *maxamp += MAXQDB(ctl); } } } cminamp = cmaxamp = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { wc = hdaa_widget_get(devinfo, i); if (wc == NULL || wc->enable == 0) continue; for (j = 0; j < wc->nconns; j++) { if (wc->connsenable[j] && wc->conns[j] == nid) { tminamp = tmaxamp = 0; found += hdaa_audio_ctl_source_amp(devinfo, wc->nid, j, ossdev, ctlable, depth + 1, &tminamp, &tmaxamp); if (cminamp == 0 && cmaxamp == 0) { cminamp = tminamp; cmaxamp = tmaxamp; } else if (tminamp != tmaxamp) { cminamp = imax(cminamp, tminamp); cmaxamp = imin(cmaxamp, tmaxamp); } } } } if (*minamp == *maxamp && cminamp < cmaxamp) { *minamp += cminamp; *maxamp += cmaxamp; } return (found); } /* * Find controls to control amplification for destination and calculate * possible amplification range. */ static int hdaa_audio_ctl_dest_amp(struct hdaa_devinfo *devinfo, nid_t nid, int index, int ossdev, int depth, int *minamp, int *maxamp) { struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w, *wc; struct hdaa_audio_ctl *ctl; int i, j, consumers, tminamp, tmaxamp, cminamp, cmaxamp, found = 0; if (depth > HDA_PARSE_MAXDEPTH) return (found); w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return (found); if (depth > 0) { /* If this node produce output for several consumers, we can't touch it. */ consumers = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { wc = hdaa_widget_get(devinfo, i); if (wc == NULL || wc->enable == 0) continue; for (j = 0; j < wc->nconns; j++) { if (wc->connsenable[j] && wc->conns[j] == nid) consumers++; } } /* The only exception is if real HP redirection is configured and this is a duplication point. XXX: Actually exception is not completely correct. XXX: Duplication point check is not perfect. */ if ((consumers == 2 && (w->bindas < 0 || as[w->bindas].hpredir < 0 || as[w->bindas].fakeredir || (w->bindseqmask & (1 << 15)) == 0)) || consumers > 2) return (found); /* Else use it's output mixer. */ ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_OUT, -1, 1); if (ctl) { ctl->ossmask |= (1 << ossdev); found++; if (*minamp == *maxamp) { *minamp += MINQDB(ctl); *maxamp += MAXQDB(ctl); } } } /* We must not traverse pin */ if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && depth > 0) return (found); cminamp = cmaxamp = 0; for (i = 0; i < w->nconns; i++) { if (w->connsenable[i] == 0) continue; if (index >= 0 && i != index) continue; tminamp = tmaxamp = 0; ctl = hdaa_audio_ctl_amp_get(devinfo, w->nid, HDAA_CTL_IN, i, 1); if (ctl) { ctl->ossmask |= (1 << ossdev); found++; if (*minamp == *maxamp) { tminamp += MINQDB(ctl); tmaxamp += MAXQDB(ctl); } } found += hdaa_audio_ctl_dest_amp(devinfo, w->conns[i], -1, ossdev, depth + 1, &tminamp, &tmaxamp); if (cminamp == 0 && cmaxamp == 0) { cminamp = tminamp; cmaxamp = tmaxamp; } else if (tminamp != tmaxamp) { cminamp = imax(cminamp, tminamp); cmaxamp = imin(cmaxamp, tmaxamp); } } if (*minamp == *maxamp && cminamp < cmaxamp) { *minamp += cminamp; *maxamp += cmaxamp; } return (found); } /* * Assign OSS names to sound sources */ static void hdaa_audio_assign_names(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w; int i, j; int type = -1, use, used = 0; static const int types[7][13] = { { SOUND_MIXER_LINE, SOUND_MIXER_LINE1, SOUND_MIXER_LINE2, SOUND_MIXER_LINE3, -1 }, /* line */ { SOUND_MIXER_MONITOR, SOUND_MIXER_MIC, -1 }, /* int mic */ { SOUND_MIXER_MIC, SOUND_MIXER_MONITOR, -1 }, /* ext mic */ { SOUND_MIXER_CD, -1 }, /* cd */ { SOUND_MIXER_SPEAKER, -1 }, /* speaker */ { SOUND_MIXER_DIGITAL1, SOUND_MIXER_DIGITAL2, SOUND_MIXER_DIGITAL3, -1 }, /* digital */ { SOUND_MIXER_LINE, SOUND_MIXER_LINE1, SOUND_MIXER_LINE2, SOUND_MIXER_LINE3, SOUND_MIXER_PHONEIN, SOUND_MIXER_PHONEOUT, SOUND_MIXER_VIDEO, SOUND_MIXER_RADIO, SOUND_MIXER_DIGITAL1, SOUND_MIXER_DIGITAL2, SOUND_MIXER_DIGITAL3, SOUND_MIXER_MONITOR, -1 } /* others */ }; /* Surely known names */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->bindas == -1) continue; use = -1; switch (w->type) { case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX: if (as[w->bindas].dir == HDAA_CTL_OUT) break; type = -1; switch (w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK) { case HDA_CONFIG_DEFAULTCONF_DEVICE_LINE_IN: type = 0; break; case HDA_CONFIG_DEFAULTCONF_DEVICE_MIC_IN: if ((w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK) == HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_JACK) break; type = 1; break; case HDA_CONFIG_DEFAULTCONF_DEVICE_CD: type = 3; break; case HDA_CONFIG_DEFAULTCONF_DEVICE_SPEAKER: type = 4; break; case HDA_CONFIG_DEFAULTCONF_DEVICE_SPDIF_IN: case HDA_CONFIG_DEFAULTCONF_DEVICE_DIGITAL_OTHER_IN: type = 5; break; } if (type == -1) break; j = 0; while (types[type][j] >= 0 && (used & (1 << types[type][j])) != 0) { j++; } if (types[type][j] >= 0) use = types[type][j]; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT: use = SOUND_MIXER_PCM; break; case HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_BEEP_WIDGET: use = SOUND_MIXER_SPEAKER; break; default: break; } if (use >= 0) { w->ossdev = use; used |= (1 << use); } } /* Semi-known names */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->ossdev >= 0) continue; if (w->bindas == -1) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (as[w->bindas].dir == HDAA_CTL_OUT) continue; type = -1; switch (w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK) { case HDA_CONFIG_DEFAULTCONF_DEVICE_LINE_OUT: case HDA_CONFIG_DEFAULTCONF_DEVICE_SPEAKER: case HDA_CONFIG_DEFAULTCONF_DEVICE_HP_OUT: case HDA_CONFIG_DEFAULTCONF_DEVICE_AUX: type = 0; break; case HDA_CONFIG_DEFAULTCONF_DEVICE_MIC_IN: type = 2; break; case HDA_CONFIG_DEFAULTCONF_DEVICE_SPDIF_OUT: case HDA_CONFIG_DEFAULTCONF_DEVICE_DIGITAL_OTHER_OUT: type = 5; break; } if (type == -1) break; j = 0; while (types[type][j] >= 0 && (used & (1 << types[type][j])) != 0) { j++; } if (types[type][j] >= 0) { w->ossdev = types[type][j]; used |= (1 << types[type][j]); } } /* Others */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->ossdev >= 0) continue; if (w->bindas == -1) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (as[w->bindas].dir == HDAA_CTL_OUT) continue; j = 0; while (types[6][j] >= 0 && (used & (1 << types[6][j])) != 0) { j++; } if (types[6][j] >= 0) { w->ossdev = types[6][j]; used |= (1 << types[6][j]); } } } static void hdaa_audio_build_tree(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; int j, res; /* Trace all associations in order of their numbers. */ for (j = 0; j < devinfo->ascnt; j++) { if (as[j].enable == 0) continue; HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Tracing association %d (%d)\n", j, as[j].index); ); if (as[j].dir == HDAA_CTL_OUT) { retry: res = hdaa_audio_trace_as_out(devinfo, j, 0); if (res == 0 && as[j].hpredir >= 0 && as[j].fakeredir == 0) { /* If CODEC can't do analog HP redirection try to make it using one more DAC. */ as[j].fakeredir = 1; goto retry; } } else if (as[j].mixed) res = hdaa_audio_trace_as_in(devinfo, j); else res = hdaa_audio_trace_as_in_mch(devinfo, j, 0); if (res) { HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Association %d (%d) trace succeeded\n", j, as[j].index); ); } else { HDA_BOOTVERBOSE( device_printf(devinfo->dev, "Association %d (%d) trace failed\n", j, as[j].index); ); as[j].enable = 0; } } /* Look for additional DACs/ADCs. */ for (j = 0; j < devinfo->ascnt; j++) { if (as[j].enable == 0) continue; hdaa_audio_adddac(devinfo, j); } /* Trace mixer and beeper pseudo associations. */ hdaa_audio_trace_as_extra(devinfo); } /* * Store in pdevinfo new data about whether and how we can control signal * for OSS device to/from specified widget. */ static void hdaa_adjust_amp(struct hdaa_widget *w, int ossdev, int found, int minamp, int maxamp) { struct hdaa_devinfo *devinfo = w->devinfo; struct hdaa_pcm_devinfo *pdevinfo; if (w->bindas >= 0) pdevinfo = devinfo->as[w->bindas].pdevinfo; else pdevinfo = &devinfo->devs[0]; if (found) pdevinfo->ossmask |= (1 << ossdev); if (minamp == 0 && maxamp == 0) return; if (pdevinfo->minamp[ossdev] == 0 && pdevinfo->maxamp[ossdev] == 0) { pdevinfo->minamp[ossdev] = minamp; pdevinfo->maxamp[ossdev] = maxamp; } else { pdevinfo->minamp[ossdev] = imax(pdevinfo->minamp[ossdev], minamp); pdevinfo->maxamp[ossdev] = imin(pdevinfo->maxamp[ossdev], maxamp); } } /* * Trace signals from/to all possible sources/destionstions to find possible * recording sources, OSS device control ranges and to assign controls. */ static void hdaa_audio_assign_mixers(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w, *cw; int i, j, minamp, maxamp, found; /* Assign mixers to the tree. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; minamp = maxamp = 0; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_BEEP_WIDGET || (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && as[w->bindas].dir == HDAA_CTL_IN)) { if (w->ossdev < 0) continue; found = hdaa_audio_ctl_source_amp(devinfo, w->nid, -1, w->ossdev, 1, 0, &minamp, &maxamp); hdaa_adjust_amp(w, w->ossdev, found, minamp, maxamp); } else if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) { found = hdaa_audio_ctl_dest_amp(devinfo, w->nid, -1, SOUND_MIXER_RECLEV, 0, &minamp, &maxamp); hdaa_adjust_amp(w, SOUND_MIXER_RECLEV, found, minamp, maxamp); } else if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && as[w->bindas].dir == HDAA_CTL_OUT) { found = hdaa_audio_ctl_dest_amp(devinfo, w->nid, -1, SOUND_MIXER_VOLUME, 0, &minamp, &maxamp); hdaa_adjust_amp(w, SOUND_MIXER_VOLUME, found, minamp, maxamp); } if (w->ossdev == SOUND_MIXER_IMIX) { minamp = maxamp = 0; found = hdaa_audio_ctl_source_amp(devinfo, w->nid, -1, w->ossdev, 1, 0, &minamp, &maxamp); if (minamp == maxamp) { /* If we are unable to control input monitor as source - try to control it as destination. */ found += hdaa_audio_ctl_dest_amp(devinfo, w->nid, -1, w->ossdev, 0, &minamp, &maxamp); w->pflags |= HDAA_IMIX_AS_DST; } hdaa_adjust_amp(w, w->ossdev, found, minamp, maxamp); } if (w->pflags & HDAA_ADC_MONITOR) { for (j = 0; j < w->nconns; j++) { if (!w->connsenable[j]) continue; cw = hdaa_widget_get(devinfo, w->conns[j]); if (cw == NULL || cw->enable == 0) continue; if (cw->bindas == -1) continue; if (cw->bindas >= 0 && as[cw->bindas].dir != HDAA_CTL_IN) continue; minamp = maxamp = 0; found = hdaa_audio_ctl_dest_amp(devinfo, w->nid, j, SOUND_MIXER_IGAIN, 0, &minamp, &maxamp); hdaa_adjust_amp(w, SOUND_MIXER_IGAIN, found, minamp, maxamp); } } } } static void hdaa_audio_prepare_pin_ctrl(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w; uint32_t pincap; int i; for (i = 0; i < devinfo->nodecnt; i++) { w = &devinfo->widget[i]; if (w == NULL) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && w->waspin == 0) continue; pincap = w->wclass.pin.cap; /* Disable everything. */ if (devinfo->init_clear) { w->wclass.pin.ctrl &= ~( HDA_CMD_SET_PIN_WIDGET_CTRL_HPHN_ENABLE | HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE | HDA_CMD_SET_PIN_WIDGET_CTRL_IN_ENABLE | HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK); } if (w->enable == 0) { /* Pin is unused so left it disabled. */ continue; } else if (w->waspin) { /* Enable input for beeper input. */ w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_IN_ENABLE; } else if (w->bindas < 0 || as[w->bindas].enable == 0) { /* Pin is unused so left it disabled. */ continue; } else if (as[w->bindas].dir == HDAA_CTL_IN) { /* Input pin, configure for input. */ if (HDA_PARAM_PIN_CAP_INPUT_CAP(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_IN_ENABLE; if ((devinfo->quirks & HDAA_QUIRK_IVREF100) && HDA_PARAM_PIN_CAP_VREF_CTRL_100(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE( HDA_CMD_PIN_WIDGET_CTRL_VREF_ENABLE_100); else if ((devinfo->quirks & HDAA_QUIRK_IVREF80) && HDA_PARAM_PIN_CAP_VREF_CTRL_80(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE( HDA_CMD_PIN_WIDGET_CTRL_VREF_ENABLE_80); else if ((devinfo->quirks & HDAA_QUIRK_IVREF50) && HDA_PARAM_PIN_CAP_VREF_CTRL_50(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE( HDA_CMD_PIN_WIDGET_CTRL_VREF_ENABLE_50); } else { /* Output pin, configure for output. */ if (HDA_PARAM_PIN_CAP_OUTPUT_CAP(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE; if (HDA_PARAM_PIN_CAP_HEADPHONE_CAP(pincap) && (w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK) == HDA_CONFIG_DEFAULTCONF_DEVICE_HP_OUT) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_HPHN_ENABLE; if ((devinfo->quirks & HDAA_QUIRK_OVREF100) && HDA_PARAM_PIN_CAP_VREF_CTRL_100(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE( HDA_CMD_PIN_WIDGET_CTRL_VREF_ENABLE_100); else if ((devinfo->quirks & HDAA_QUIRK_OVREF80) && HDA_PARAM_PIN_CAP_VREF_CTRL_80(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE( HDA_CMD_PIN_WIDGET_CTRL_VREF_ENABLE_80); else if ((devinfo->quirks & HDAA_QUIRK_OVREF50) && HDA_PARAM_PIN_CAP_VREF_CTRL_50(pincap)) w->wclass.pin.ctrl |= HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE( HDA_CMD_PIN_WIDGET_CTRL_VREF_ENABLE_50); } } } static void hdaa_audio_ctl_commit(struct hdaa_devinfo *devinfo) { struct hdaa_audio_ctl *ctl; int i, z; i = 0; while ((ctl = hdaa_audio_ctl_each(devinfo, &i)) != NULL) { if (ctl->enable == 0 || ctl->ossmask != 0) { /* Mute disabled and mixer controllable controls. * Last will be initialized by mixer_init(). * This expected to reduce click on startup. */ hdaa_audio_ctl_amp_set(ctl, HDAA_AMP_MUTE_ALL, 0, 0); continue; } /* Init fixed controls to 0dB amplification. */ z = ctl->offset; if (z > ctl->step) z = ctl->step; hdaa_audio_ctl_amp_set(ctl, HDAA_AMP_MUTE_NONE, z, z); } } static void hdaa_gpio_commit(struct hdaa_devinfo *devinfo) { uint32_t gdata, gmask, gdir; int i, numgpio; numgpio = HDA_PARAM_GPIO_COUNT_NUM_GPIO(devinfo->gpio_cap); if (devinfo->gpio != 0 && numgpio != 0) { gdata = hda_command(devinfo->dev, HDA_CMD_GET_GPIO_DATA(0, devinfo->nid)); gmask = hda_command(devinfo->dev, HDA_CMD_GET_GPIO_ENABLE_MASK(0, devinfo->nid)); gdir = hda_command(devinfo->dev, HDA_CMD_GET_GPIO_DIRECTION(0, devinfo->nid)); for (i = 0; i < numgpio; i++) { if ((devinfo->gpio & HDAA_GPIO_MASK(i)) == HDAA_GPIO_SET(i)) { gdata |= (1 << i); gmask |= (1 << i); gdir |= (1 << i); } else if ((devinfo->gpio & HDAA_GPIO_MASK(i)) == HDAA_GPIO_CLEAR(i)) { gdata &= ~(1 << i); gmask |= (1 << i); gdir |= (1 << i); } else if ((devinfo->gpio & HDAA_GPIO_MASK(i)) == HDAA_GPIO_DISABLE(i)) { gmask &= ~(1 << i); } else if ((devinfo->gpio & HDAA_GPIO_MASK(i)) == HDAA_GPIO_INPUT(i)) { gmask |= (1 << i); gdir &= ~(1 << i); } } HDA_BOOTVERBOSE( device_printf(devinfo->dev, "GPIO commit\n"); ); hda_command(devinfo->dev, HDA_CMD_SET_GPIO_ENABLE_MASK(0, devinfo->nid, gmask)); hda_command(devinfo->dev, HDA_CMD_SET_GPIO_DIRECTION(0, devinfo->nid, gdir)); hda_command(devinfo->dev, HDA_CMD_SET_GPIO_DATA(0, devinfo->nid, gdata)); HDA_BOOTVERBOSE( hdaa_dump_gpio(devinfo); ); } } static void hdaa_gpo_commit(struct hdaa_devinfo *devinfo) { uint32_t gdata; int i, numgpo; numgpo = HDA_PARAM_GPIO_COUNT_NUM_GPO(devinfo->gpio_cap); if (devinfo->gpo != 0 && numgpo != 0) { gdata = hda_command(devinfo->dev, HDA_CMD_GET_GPO_DATA(0, devinfo->nid)); for (i = 0; i < numgpo; i++) { if ((devinfo->gpio & HDAA_GPIO_MASK(i)) == HDAA_GPIO_SET(i)) { gdata |= (1 << i); } else if ((devinfo->gpio & HDAA_GPIO_MASK(i)) == HDAA_GPIO_CLEAR(i)) { gdata &= ~(1 << i); } } HDA_BOOTVERBOSE( device_printf(devinfo->dev, "GPO commit\n"); ); hda_command(devinfo->dev, HDA_CMD_SET_GPO_DATA(0, devinfo->nid, gdata)); HDA_BOOTVERBOSE( hdaa_dump_gpo(devinfo); ); } } static void hdaa_audio_commit(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; int i; /* Commit controls. */ hdaa_audio_ctl_commit(devinfo); /* Commit selectors, pins and EAPD. */ for (i = 0; i < devinfo->nodecnt; i++) { w = &devinfo->widget[i]; if (w == NULL) continue; if (w->selconn == -1) w->selconn = 0; if (w->nconns > 0) hdaa_widget_connection_select(w, w->selconn); if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX || w->waspin) { hda_command(devinfo->dev, HDA_CMD_SET_PIN_WIDGET_CTRL(0, w->nid, w->wclass.pin.ctrl)); } if (w->param.eapdbtl != HDA_INVALID) { uint32_t val; val = w->param.eapdbtl; if (devinfo->quirks & HDAA_QUIRK_EAPDINV) val ^= HDA_CMD_SET_EAPD_BTL_ENABLE_EAPD; hda_command(devinfo->dev, HDA_CMD_SET_EAPD_BTL_ENABLE(0, w->nid, val)); } } hdaa_gpio_commit(devinfo); hdaa_gpo_commit(devinfo); } static void hdaa_powerup(struct hdaa_devinfo *devinfo) { int i; hda_command(devinfo->dev, HDA_CMD_SET_POWER_STATE(0, devinfo->nid, HDA_CMD_POWER_STATE_D0)); DELAY(100); for (i = devinfo->startnode; i < devinfo->endnode; i++) { hda_command(devinfo->dev, HDA_CMD_SET_POWER_STATE(0, i, HDA_CMD_POWER_STATE_D0)); } DELAY(1000); } static int hdaa_pcmchannel_setup(struct hdaa_chan *ch) { struct hdaa_devinfo *devinfo = ch->devinfo; struct hdaa_audio_as *as = devinfo->as; struct hdaa_widget *w; uint32_t cap, fmtcap, pcmcap; int i, j, ret, channels, onlystereo; uint16_t pinset; ch->caps = hdaa_caps; ch->caps.fmtlist = ch->fmtlist; ch->bit16 = 1; ch->bit32 = 0; ch->pcmrates[0] = 48000; ch->pcmrates[1] = 0; ch->stripecap = 0xff; ret = 0; channels = 0; onlystereo = 1; pinset = 0; fmtcap = devinfo->supp_stream_formats; pcmcap = devinfo->supp_pcm_size_rate; for (i = 0; i < 16; i++) { /* Check as is correct */ if (ch->as < 0) break; /* Cound only present DACs */ if (as[ch->as].dacs[ch->asindex][i] <= 0) continue; /* Ignore duplicates */ for (j = 0; j < ret; j++) { if (ch->io[j] == as[ch->as].dacs[ch->asindex][i]) break; } if (j < ret) continue; w = hdaa_widget_get(devinfo, as[ch->as].dacs[ch->asindex][i]); if (w == NULL || w->enable == 0) continue; cap = w->param.supp_stream_formats; if (!HDA_PARAM_SUPP_STREAM_FORMATS_PCM(cap) && !HDA_PARAM_SUPP_STREAM_FORMATS_AC3(cap)) continue; /* Many CODECs does not declare AC3 support on SPDIF. I don't beleave that they doesn't support it! */ if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) cap |= HDA_PARAM_SUPP_STREAM_FORMATS_AC3_MASK; if (ret == 0) { fmtcap = cap; pcmcap = w->param.supp_pcm_size_rate; } else { fmtcap &= cap; pcmcap &= w->param.supp_pcm_size_rate; } ch->io[ret++] = as[ch->as].dacs[ch->asindex][i]; ch->stripecap &= w->wclass.conv.stripecap; /* Do not count redirection pin/dac channels. */ if (i == 15 && as[ch->as].hpredir >= 0) continue; channels += HDA_PARAM_AUDIO_WIDGET_CAP_CC(w->param.widget_cap) + 1; if (HDA_PARAM_AUDIO_WIDGET_CAP_CC(w->param.widget_cap) != 1) onlystereo = 0; pinset |= (1 << i); } ch->io[ret] = -1; ch->channels = channels; if (as[ch->as].fakeredir) ret--; /* Standard speaks only about stereo pins and playback, ... */ if ((!onlystereo) || as[ch->as].mixed) pinset = 0; /* ..., but there it gives us info about speakers layout. */ as[ch->as].pinset = pinset; ch->supp_stream_formats = fmtcap; ch->supp_pcm_size_rate = pcmcap; /* * 8bit = 0 * 16bit = 1 * 20bit = 2 * 24bit = 3 * 32bit = 4 */ if (ret > 0) { i = 0; if (HDA_PARAM_SUPP_STREAM_FORMATS_PCM(fmtcap)) { if (HDA_PARAM_SUPP_PCM_SIZE_RATE_16BIT(pcmcap)) ch->bit16 = 1; else if (HDA_PARAM_SUPP_PCM_SIZE_RATE_8BIT(pcmcap)) ch->bit16 = 0; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_24BIT(pcmcap)) ch->bit32 = 3; else if (HDA_PARAM_SUPP_PCM_SIZE_RATE_20BIT(pcmcap)) ch->bit32 = 2; else if (HDA_PARAM_SUPP_PCM_SIZE_RATE_32BIT(pcmcap)) ch->bit32 = 4; if (!(devinfo->quirks & HDAA_QUIRK_FORCESTEREO)) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 1, 0); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 1, 0); } if (channels >= 2) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 2, 0); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 2, 0); } if (channels >= 3 && !onlystereo) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 3, 0); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 3, 0); ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 3, 1); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 3, 1); } if (channels >= 4) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 4, 0); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 4, 0); if (!onlystereo) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 4, 1); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 4, 1); } } if (channels >= 5 && !onlystereo) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 5, 0); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 5, 0); ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 5, 1); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 5, 1); } if (channels >= 6) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 6, 1); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 6, 1); if (!onlystereo) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 6, 0); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 6, 0); } } if (channels >= 7 && !onlystereo) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 7, 0); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 7, 0); ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 7, 1); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 7, 1); } if (channels >= 8) { ch->fmtlist[i++] = SND_FORMAT(AFMT_S16_LE, 8, 1); if (ch->bit32) ch->fmtlist[i++] = SND_FORMAT(AFMT_S32_LE, 8, 1); } } if (HDA_PARAM_SUPP_STREAM_FORMATS_AC3(fmtcap)) { ch->fmtlist[i++] = SND_FORMAT(AFMT_AC3, 2, 0); if (channels >= 8) { ch->fmtlist[i++] = SND_FORMAT(AFMT_AC3, 8, 1); } } ch->fmtlist[i] = 0; i = 0; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_8KHZ(pcmcap)) ch->pcmrates[i++] = 8000; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_11KHZ(pcmcap)) ch->pcmrates[i++] = 11025; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_16KHZ(pcmcap)) ch->pcmrates[i++] = 16000; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_22KHZ(pcmcap)) ch->pcmrates[i++] = 22050; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_32KHZ(pcmcap)) ch->pcmrates[i++] = 32000; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_44KHZ(pcmcap)) ch->pcmrates[i++] = 44100; /* if (HDA_PARAM_SUPP_PCM_SIZE_RATE_48KHZ(pcmcap)) */ ch->pcmrates[i++] = 48000; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_88KHZ(pcmcap)) ch->pcmrates[i++] = 88200; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_96KHZ(pcmcap)) ch->pcmrates[i++] = 96000; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_176KHZ(pcmcap)) ch->pcmrates[i++] = 176400; if (HDA_PARAM_SUPP_PCM_SIZE_RATE_192KHZ(pcmcap)) ch->pcmrates[i++] = 192000; /* if (HDA_PARAM_SUPP_PCM_SIZE_RATE_384KHZ(pcmcap)) */ ch->pcmrates[i] = 0; if (i > 0) { ch->caps.minspeed = ch->pcmrates[0]; ch->caps.maxspeed = ch->pcmrates[i - 1]; } } return (ret); } static void hdaa_prepare_pcms(struct hdaa_devinfo *devinfo) { struct hdaa_audio_as *as = devinfo->as; int i, j, k, apdev = 0, ardev = 0, dpdev = 0, drdev = 0; for (i = 0; i < devinfo->ascnt; i++) { if (as[i].enable == 0) continue; if (as[i].dir == HDAA_CTL_IN) { if (as[i].digital) drdev++; else ardev++; } else { if (as[i].digital) dpdev++; else apdev++; } } devinfo->num_devs = max(ardev, apdev) + max(drdev, dpdev); devinfo->devs = malloc(devinfo->num_devs * sizeof(struct hdaa_pcm_devinfo), M_HDAA, M_ZERO | M_NOWAIT); if (devinfo->devs == NULL) { device_printf(devinfo->dev, "Unable to allocate memory for devices\n"); return; } for (i = 0; i < devinfo->num_devs; i++) { devinfo->devs[i].index = i; devinfo->devs[i].devinfo = devinfo; devinfo->devs[i].playas = -1; devinfo->devs[i].recas = -1; devinfo->devs[i].digital = 255; } for (i = 0; i < devinfo->ascnt; i++) { if (as[i].enable == 0) continue; for (j = 0; j < devinfo->num_devs; j++) { if (devinfo->devs[j].digital != 255 && (!devinfo->devs[j].digital) != (!as[i].digital)) continue; if (as[i].dir == HDAA_CTL_IN) { if (devinfo->devs[j].recas >= 0) continue; devinfo->devs[j].recas = i; } else { if (devinfo->devs[j].playas >= 0) continue; devinfo->devs[j].playas = i; } as[i].pdevinfo = &devinfo->devs[j]; for (k = 0; k < as[i].num_chans; k++) { devinfo->chans[as[i].chans[k]].pdevinfo = &devinfo->devs[j]; } devinfo->devs[j].digital = as[i].digital; break; } } } static void hdaa_create_pcms(struct hdaa_devinfo *devinfo) { int i; for (i = 0; i < devinfo->num_devs; i++) { struct hdaa_pcm_devinfo *pdevinfo = &devinfo->devs[i]; pdevinfo->dev = device_add_child(devinfo->dev, "pcm", DEVICE_UNIT_ANY); device_set_ivars(pdevinfo->dev, (void *)pdevinfo); } } static void hdaa_dump_ctls(struct hdaa_pcm_devinfo *pdevinfo, const char *banner, uint32_t flag) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_audio_ctl *ctl; char buf[64]; int i, j, printed = 0; if (flag == 0) { flag = ~(SOUND_MASK_VOLUME | SOUND_MASK_PCM | SOUND_MASK_CD | SOUND_MASK_LINE | SOUND_MASK_RECLEV | SOUND_MASK_MIC | SOUND_MASK_SPEAKER | SOUND_MASK_IGAIN | SOUND_MASK_OGAIN | SOUND_MASK_IMIX | SOUND_MASK_MONITOR); } for (j = 0; j < SOUND_MIXER_NRDEVICES; j++) { if ((flag & (1 << j)) == 0) continue; i = 0; printed = 0; while ((ctl = hdaa_audio_ctl_each(devinfo, &i)) != NULL) { if (ctl->enable == 0 || ctl->widget->enable == 0) continue; if (!((pdevinfo->playas >= 0 && ctl->widget->bindas == pdevinfo->playas) || (pdevinfo->recas >= 0 && ctl->widget->bindas == pdevinfo->recas) || (ctl->widget->bindas == -2 && pdevinfo->index == 0))) continue; if ((ctl->ossmask & (1 << j)) == 0) continue; if (printed == 0) { if (banner != NULL) { device_printf(pdevinfo->dev, "%s", banner); } else { device_printf(pdevinfo->dev, "Unknown Ctl"); } printf(" (OSS: %s)", hdaa_audio_ctl_ossmixer_mask2allname(1 << j, buf, sizeof(buf))); if (pdevinfo->ossmask & (1 << j)) { printf(": %+d/%+ddB\n", pdevinfo->minamp[j] / 4, pdevinfo->maxamp[j] / 4); } else printf("\n"); printed = 1; } device_printf(pdevinfo->dev, " +- ctl %2d (nid %3d %s", i, ctl->widget->nid, (ctl->ndir == HDAA_CTL_IN)?"in ":"out"); if (ctl->ndir == HDAA_CTL_IN && ctl->ndir == ctl->dir) printf(" %2d): ", ctl->index); else printf("): "); if (ctl->step > 0) { printf("%+d/%+ddB (%d steps)%s\n", MINQDB(ctl) / 4, MAXQDB(ctl) / 4, ctl->step + 1, ctl->mute?" + mute":""); } else printf("%s\n", ctl->mute?"mute":""); } } if (printed) device_printf(pdevinfo->dev, "\n"); } static void hdaa_dump_audio_formats(device_t dev, uint32_t fcap, uint32_t pcmcap) { uint32_t cap; cap = fcap; if (cap != 0) { device_printf(dev, " Stream cap: 0x%08x", cap); if (HDA_PARAM_SUPP_STREAM_FORMATS_AC3(cap)) printf(" AC3"); if (HDA_PARAM_SUPP_STREAM_FORMATS_FLOAT32(cap)) printf(" FLOAT32"); if (HDA_PARAM_SUPP_STREAM_FORMATS_PCM(cap)) printf(" PCM"); printf("\n"); } cap = pcmcap; if (cap != 0) { device_printf(dev, " PCM cap: 0x%08x", cap); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_8BIT(cap)) printf(" 8"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_16BIT(cap)) printf(" 16"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_20BIT(cap)) printf(" 20"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_24BIT(cap)) printf(" 24"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_32BIT(cap)) printf(" 32"); printf(" bits,"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_8KHZ(cap)) printf(" 8"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_11KHZ(cap)) printf(" 11"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_16KHZ(cap)) printf(" 16"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_22KHZ(cap)) printf(" 22"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_32KHZ(cap)) printf(" 32"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_44KHZ(cap)) printf(" 44"); printf(" 48"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_88KHZ(cap)) printf(" 88"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_96KHZ(cap)) printf(" 96"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_176KHZ(cap)) printf(" 176"); if (HDA_PARAM_SUPP_PCM_SIZE_RATE_192KHZ(cap)) printf(" 192"); printf(" KHz\n"); } } static void hdaa_dump_pin(struct hdaa_widget *w) { uint32_t pincap; pincap = w->wclass.pin.cap; device_printf(w->devinfo->dev, " Pin cap: 0x%08x", pincap); if (HDA_PARAM_PIN_CAP_IMP_SENSE_CAP(pincap)) printf(" ISC"); if (HDA_PARAM_PIN_CAP_TRIGGER_REQD(pincap)) printf(" TRQD"); if (HDA_PARAM_PIN_CAP_PRESENCE_DETECT_CAP(pincap)) printf(" PDC"); if (HDA_PARAM_PIN_CAP_HEADPHONE_CAP(pincap)) printf(" HP"); if (HDA_PARAM_PIN_CAP_OUTPUT_CAP(pincap)) printf(" OUT"); if (HDA_PARAM_PIN_CAP_INPUT_CAP(pincap)) printf(" IN"); if (HDA_PARAM_PIN_CAP_BALANCED_IO_PINS(pincap)) printf(" BAL"); if (HDA_PARAM_PIN_CAP_HDMI(pincap)) printf(" HDMI"); if (HDA_PARAM_PIN_CAP_VREF_CTRL(pincap)) { printf(" VREF["); if (HDA_PARAM_PIN_CAP_VREF_CTRL_50(pincap)) printf(" 50"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_80(pincap)) printf(" 80"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_100(pincap)) printf(" 100"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_GROUND(pincap)) printf(" GROUND"); if (HDA_PARAM_PIN_CAP_VREF_CTRL_HIZ(pincap)) printf(" HIZ"); printf(" ]"); } if (HDA_PARAM_PIN_CAP_EAPD_CAP(pincap)) printf(" EAPD"); if (HDA_PARAM_PIN_CAP_DP(pincap)) printf(" DP"); if (HDA_PARAM_PIN_CAP_HBR(pincap)) printf(" HBR"); printf("\n"); device_printf(w->devinfo->dev, " Pin config: 0x%08x\n", w->wclass.pin.config); device_printf(w->devinfo->dev, " Pin control: 0x%08x", w->wclass.pin.ctrl); if (w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_HPHN_ENABLE) printf(" HP"); if (w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_IN_ENABLE) printf(" IN"); if (w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_OUT_ENABLE) printf(" OUT"); if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) { if ((w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK) == 0x03) printf(" HBR"); else if ((w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK) != 0) printf(" EPTs"); } else { if ((w->wclass.pin.ctrl & HDA_CMD_SET_PIN_WIDGET_CTRL_VREF_ENABLE_MASK) != 0) printf(" VREFs"); } printf("\n"); } static void hdaa_dump_pin_config(struct hdaa_widget *w, uint32_t conf) { device_printf(w->devinfo->dev, "%2d %08x %-2d %-2d " "%-13s %-5s %-7s %-10s %-7s %d%s\n", w->nid, conf, HDA_CONFIG_DEFAULTCONF_ASSOCIATION(conf), HDA_CONFIG_DEFAULTCONF_SEQUENCE(conf), HDA_DEVS[HDA_CONFIG_DEFAULTCONF_DEVICE(conf)], HDA_CONNS[HDA_CONFIG_DEFAULTCONF_CONNECTIVITY(conf)], HDA_CONNECTORS[HDA_CONFIG_DEFAULTCONF_CONNECTION_TYPE(conf)], HDA_LOCS[HDA_CONFIG_DEFAULTCONF_LOCATION(conf)], HDA_COLORS[HDA_CONFIG_DEFAULTCONF_COLOR(conf)], HDA_CONFIG_DEFAULTCONF_MISC(conf), (w->enable == 0)?" DISA":""); } static void hdaa_dump_pin_configs(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; int i; device_printf(devinfo->dev, "nid 0x as seq " "device conn jack loc color misc\n"); for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; hdaa_dump_pin_config(w, w->wclass.pin.config); } } static void hdaa_dump_amp(device_t dev, uint32_t cap, const char *banner) { int offset, size, step; offset = HDA_PARAM_OUTPUT_AMP_CAP_OFFSET(cap); size = HDA_PARAM_OUTPUT_AMP_CAP_STEPSIZE(cap); step = HDA_PARAM_OUTPUT_AMP_CAP_NUMSTEPS(cap); device_printf(dev, " %s amp: 0x%08x " "mute=%d step=%d size=%d offset=%d (%+d/%+ddB)\n", banner, cap, HDA_PARAM_OUTPUT_AMP_CAP_MUTE_CAP(cap), step, size, offset, ((0 - offset) * (size + 1)) / 4, ((step - offset) * (size + 1)) / 4); } static void hdaa_dump_nodes(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w, *cw; char buf[64]; int i, j; device_printf(devinfo->dev, "\n"); device_printf(devinfo->dev, "Default parameters:\n"); hdaa_dump_audio_formats(devinfo->dev, devinfo->supp_stream_formats, devinfo->supp_pcm_size_rate); hdaa_dump_amp(devinfo->dev, devinfo->inamp_cap, " Input"); hdaa_dump_amp(devinfo->dev, devinfo->outamp_cap, "Output"); for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL) { device_printf(devinfo->dev, "Ghost widget nid=%d\n", i); continue; } device_printf(devinfo->dev, "\n"); device_printf(devinfo->dev, " nid: %d%s\n", w->nid, (w->enable == 0) ? " [DISABLED]" : ""); device_printf(devinfo->dev, " Name: %s\n", w->name); device_printf(devinfo->dev, " Widget cap: 0x%08x", w->param.widget_cap); if (w->param.widget_cap & 0x0ee1) { if (HDA_PARAM_AUDIO_WIDGET_CAP_LR_SWAP(w->param.widget_cap)) printf(" LRSWAP"); if (HDA_PARAM_AUDIO_WIDGET_CAP_POWER_CTRL(w->param.widget_cap)) printf(" PWR"); if (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap)) printf(" DIGITAL"); if (HDA_PARAM_AUDIO_WIDGET_CAP_UNSOL_CAP(w->param.widget_cap)) printf(" UNSOL"); if (HDA_PARAM_AUDIO_WIDGET_CAP_PROC_WIDGET(w->param.widget_cap)) printf(" PROC"); if (HDA_PARAM_AUDIO_WIDGET_CAP_STRIPE(w->param.widget_cap)) printf(" STRIPE(x%d)", 1 << (fls(w->wclass.conv.stripecap) - 1)); j = HDA_PARAM_AUDIO_WIDGET_CAP_CC(w->param.widget_cap); if (j == 1) printf(" STEREO"); else if (j > 1) printf(" %dCH", j + 1); } printf("\n"); if (w->bindas != -1) { device_printf(devinfo->dev, " Association: %d (0x%04x)\n", w->bindas, w->bindseqmask); } if (w->ossmask != 0 || w->ossdev >= 0) { device_printf(devinfo->dev, " OSS: %s", hdaa_audio_ctl_ossmixer_mask2allname(w->ossmask, buf, sizeof(buf))); if (w->ossdev >= 0) printf(" (%s)", ossnames[w->ossdev]); printf("\n"); } if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_OUTPUT || w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) { hdaa_dump_audio_formats(devinfo->dev, w->param.supp_stream_formats, w->param.supp_pcm_size_rate); } else if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX || w->waspin) hdaa_dump_pin(w); if (w->param.eapdbtl != HDA_INVALID) device_printf(devinfo->dev, " EAPD: 0x%08x\n", w->param.eapdbtl); if (HDA_PARAM_AUDIO_WIDGET_CAP_OUT_AMP(w->param.widget_cap) && w->param.outamp_cap != 0) hdaa_dump_amp(devinfo->dev, w->param.outamp_cap, "Output"); if (HDA_PARAM_AUDIO_WIDGET_CAP_IN_AMP(w->param.widget_cap) && w->param.inamp_cap != 0) hdaa_dump_amp(devinfo->dev, w->param.inamp_cap, " Input"); if (w->nconns > 0) device_printf(devinfo->dev, " Connections: %d\n", w->nconns); for (j = 0; j < w->nconns; j++) { cw = hdaa_widget_get(devinfo, w->conns[j]); device_printf(devinfo->dev, " + %s<- nid=%d [%s]", (w->connsenable[j] == 0)?"[DISABLED] ":"", w->conns[j], (cw == NULL) ? "GHOST!" : cw->name); if (cw == NULL) printf(" [UNKNOWN]"); else if (cw->enable == 0) printf(" [DISABLED]"); if (w->nconns > 1 && w->selconn == j && w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_MIXER) printf(" (selected)"); printf("\n"); } } } static void hdaa_dump_dst_nid(struct hdaa_pcm_devinfo *pdevinfo, nid_t nid, int depth) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w, *cw; char buf[64]; int i; if (depth > HDA_PARSE_MAXDEPTH) return; w = hdaa_widget_get(devinfo, nid); if (w == NULL || w->enable == 0) return; if (depth == 0) device_printf(pdevinfo->dev, "%*s", 4, ""); else device_printf(pdevinfo->dev, "%*s + <- ", 4 + (depth - 1) * 7, ""); printf("nid=%d [%s]", w->nid, w->name); if (depth > 0) { if (w->ossmask == 0) { printf("\n"); return; } printf(" [src: %s]", hdaa_audio_ctl_ossmixer_mask2allname( w->ossmask, buf, sizeof(buf))); if (w->ossdev >= 0) { printf("\n"); return; } } printf("\n"); for (i = 0; i < w->nconns; i++) { if (w->connsenable[i] == 0) continue; cw = hdaa_widget_get(devinfo, w->conns[i]); if (cw == NULL || cw->enable == 0 || cw->bindas == -1) continue; hdaa_dump_dst_nid(pdevinfo, w->conns[i], depth + 1); } } static void hdaa_dump_dac(struct hdaa_pcm_devinfo *pdevinfo) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_audio_as *as; struct hdaa_widget *w; nid_t *nids; int chid, i; if (pdevinfo->playas < 0) return; device_printf(pdevinfo->dev, "Playback:\n"); chid = devinfo->as[pdevinfo->playas].chans[0]; hdaa_dump_audio_formats(pdevinfo->dev, devinfo->chans[chid].supp_stream_formats, devinfo->chans[chid].supp_pcm_size_rate); for (i = 0; i < devinfo->as[pdevinfo->playas].num_chans; i++) { chid = devinfo->as[pdevinfo->playas].chans[i]; device_printf(pdevinfo->dev, " DAC:"); for (nids = devinfo->chans[chid].io; *nids != -1; nids++) printf(" %d", *nids); printf("\n"); } as = &devinfo->as[pdevinfo->playas]; for (i = 0; i < 16; i++) { if (as->pins[i] <= 0) continue; w = hdaa_widget_get(devinfo, as->pins[i]); if (w == NULL || w->enable == 0) continue; device_printf(pdevinfo->dev, "\n"); hdaa_dump_dst_nid(pdevinfo, as->pins[i], 0); } device_printf(pdevinfo->dev, "\n"); } static void hdaa_dump_adc(struct hdaa_pcm_devinfo *pdevinfo) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w; nid_t *nids; int chid, i; if (pdevinfo->recas < 0) return; device_printf(pdevinfo->dev, "Record:\n"); chid = devinfo->as[pdevinfo->recas].chans[0]; hdaa_dump_audio_formats(pdevinfo->dev, devinfo->chans[chid].supp_stream_formats, devinfo->chans[chid].supp_pcm_size_rate); for (i = 0; i < devinfo->as[pdevinfo->recas].num_chans; i++) { chid = devinfo->as[pdevinfo->recas].chans[i]; device_printf(pdevinfo->dev, " ADC:"); for (nids = devinfo->chans[chid].io; *nids != -1; nids++) printf(" %d", *nids); printf("\n"); } for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_AUDIO_INPUT) continue; if (w->bindas != pdevinfo->recas) continue; device_printf(pdevinfo->dev, "\n"); hdaa_dump_dst_nid(pdevinfo, i, 0); } device_printf(pdevinfo->dev, "\n"); } static void hdaa_dump_mix(struct hdaa_pcm_devinfo *pdevinfo) { struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_widget *w; int i; int printed = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0) continue; if (w->ossdev != SOUND_MIXER_IMIX) continue; if (w->bindas != pdevinfo->recas) continue; if (printed == 0) { printed = 1; device_printf(pdevinfo->dev, "Input Mix:\n"); } device_printf(pdevinfo->dev, "\n"); hdaa_dump_dst_nid(pdevinfo, i, 0); } if (printed) device_printf(pdevinfo->dev, "\n"); } static void hdaa_pindump(device_t dev) { struct hdaa_devinfo *devinfo = device_get_softc(dev); struct hdaa_widget *w; uint32_t res, pincap, delay; int i; device_printf(dev, "Dumping AFG pins:\n"); device_printf(dev, "nid 0x as seq " "device conn jack loc color misc\n"); for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; hdaa_dump_pin_config(w, w->wclass.pin.config); pincap = w->wclass.pin.cap; device_printf(dev, " Caps: %2s %3s %2s %4s %4s", HDA_PARAM_PIN_CAP_INPUT_CAP(pincap)?"IN":"", HDA_PARAM_PIN_CAP_OUTPUT_CAP(pincap)?"OUT":"", HDA_PARAM_PIN_CAP_HEADPHONE_CAP(pincap)?"HP":"", HDA_PARAM_PIN_CAP_EAPD_CAP(pincap)?"EAPD":"", HDA_PARAM_PIN_CAP_VREF_CTRL(pincap)?"VREF":""); if (HDA_PARAM_PIN_CAP_IMP_SENSE_CAP(pincap) || HDA_PARAM_PIN_CAP_PRESENCE_DETECT_CAP(pincap)) { if (HDA_PARAM_PIN_CAP_TRIGGER_REQD(pincap)) { delay = 0; hda_command(dev, HDA_CMD_SET_PIN_SENSE(0, w->nid, 0)); do { res = hda_command(dev, HDA_CMD_GET_PIN_SENSE(0, w->nid)); if (res != 0x7fffffff && res != 0xffffffff) break; DELAY(10); } while (++delay < 10000); } else { delay = 0; res = hda_command(dev, HDA_CMD_GET_PIN_SENSE(0, w->nid)); } printf(" Sense: 0x%08x (%sconnected%s)", res, (res & HDA_CMD_GET_PIN_SENSE_PRESENCE_DETECT) ? "" : "dis", (HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL(w->param.widget_cap) && (res & HDA_CMD_GET_PIN_SENSE_ELD_VALID)) ? ", ELD valid" : ""); if (delay > 0) printf(" delay %dus", delay * 10); } printf("\n"); } device_printf(dev, "NumGPIO=%d NumGPO=%d NumGPI=%d GPIWake=%d GPIUnsol=%d\n", HDA_PARAM_GPIO_COUNT_NUM_GPIO(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_NUM_GPO(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_NUM_GPI(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_GPI_WAKE(devinfo->gpio_cap), HDA_PARAM_GPIO_COUNT_GPI_UNSOL(devinfo->gpio_cap)); hdaa_dump_gpi(devinfo); hdaa_dump_gpio(devinfo); hdaa_dump_gpo(devinfo); } static void hdaa_configure(device_t dev) { struct hdaa_devinfo *devinfo = device_get_softc(dev); struct hdaa_audio_ctl *ctl; int i; HDA_BOOTHVERBOSE( device_printf(dev, "Applying built-in patches...\n"); ); hdaa_patch(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Applying local patches...\n"); ); hdaa_local_patch(devinfo); hdaa_audio_postprocess(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Parsing Ctls...\n"); ); hdaa_audio_ctl_parse(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Disabling nonaudio...\n"); ); hdaa_audio_disable_nonaudio(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Disabling useless...\n"); ); hdaa_audio_disable_useless(devinfo); HDA_BOOTVERBOSE( device_printf(dev, "Patched pins configuration:\n"); hdaa_dump_pin_configs(devinfo); ); HDA_BOOTHVERBOSE( device_printf(dev, "Parsing pin associations...\n"); ); hdaa_audio_as_parse(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Building AFG tree...\n"); ); hdaa_audio_build_tree(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Disabling unassociated " "widgets...\n"); ); hdaa_audio_disable_unas(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Disabling nonselected " "inputs...\n"); ); hdaa_audio_disable_notselected(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Disabling useless...\n"); ); hdaa_audio_disable_useless(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Disabling " "crossassociatement connections...\n"); ); hdaa_audio_disable_crossas(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Disabling useless...\n"); ); hdaa_audio_disable_useless(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Binding associations to channels...\n"); ); hdaa_audio_bind_as(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Assigning names to signal sources...\n"); ); hdaa_audio_assign_names(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Preparing PCM devices...\n"); ); hdaa_prepare_pcms(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Assigning mixers to the tree...\n"); ); hdaa_audio_assign_mixers(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Preparing pin controls...\n"); ); hdaa_audio_prepare_pin_ctrl(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "AFG commit...\n"); ); hdaa_audio_commit(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Applying direct built-in patches...\n"); ); hdaa_patch_direct(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Pin sense init...\n"); ); hdaa_sense_init(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Creating PCM devices...\n"); ); hdaa_unlock(devinfo); hdaa_create_pcms(devinfo); hdaa_lock(devinfo); HDA_BOOTVERBOSE( if (devinfo->quirks != 0) { device_printf(dev, "FG config/quirks:"); for (i = 0; i < nitems(hdaa_quirks_tab); i++) { if ((devinfo->quirks & hdaa_quirks_tab[i].value) == hdaa_quirks_tab[i].value) printf(" %s", hdaa_quirks_tab[i].key); } printf("\n"); } ); HDA_BOOTHVERBOSE( device_printf(dev, "\n"); device_printf(dev, "+-----------+\n"); device_printf(dev, "| HDA NODES |\n"); device_printf(dev, "+-----------+\n"); hdaa_dump_nodes(devinfo); device_printf(dev, "\n"); device_printf(dev, "+----------------+\n"); device_printf(dev, "| HDA AMPLIFIERS |\n"); device_printf(dev, "+----------------+\n"); device_printf(dev, "\n"); i = 0; while ((ctl = hdaa_audio_ctl_each(devinfo, &i)) != NULL) { device_printf(dev, "%3d: nid %3d %s (%s) index %d", i, (ctl->widget != NULL) ? ctl->widget->nid : -1, (ctl->ndir == HDAA_CTL_IN)?"in ":"out", (ctl->dir == HDAA_CTL_IN)?"in ":"out", ctl->index); if (ctl->childwidget != NULL) printf(" cnid %3d", ctl->childwidget->nid); else printf(" "); printf(" ossmask=0x%08x\n", ctl->ossmask); device_printf(dev, " mute: %d step: %3d size: %3d off: %3d%s\n", ctl->mute, ctl->step, ctl->size, ctl->offset, (ctl->enable == 0) ? " [DISABLED]" : ((ctl->ossmask == 0) ? " [UNUSED]" : "")); } device_printf(dev, "\n"); ); } static void hdaa_unconfigure(device_t dev) { struct hdaa_devinfo *devinfo = device_get_softc(dev); struct hdaa_widget *w; int i, j; HDA_BOOTHVERBOSE( device_printf(dev, "Pin sense deinit...\n"); ); hdaa_sense_deinit(devinfo); free(devinfo->ctl, M_HDAA); devinfo->ctl = NULL; devinfo->ctlcnt = 0; free(devinfo->as, M_HDAA); devinfo->as = NULL; devinfo->ascnt = 0; free(devinfo->devs, M_HDAA); devinfo->devs = NULL; devinfo->num_devs = 0; free(devinfo->chans, M_HDAA); devinfo->chans = NULL; devinfo->num_chans = 0; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL) continue; w->enable = 1; w->selconn = -1; w->pflags = 0; w->bindas = -1; w->bindseqmask = 0; w->ossdev = -1; w->ossmask = 0; for (j = 0; j < w->nconns; j++) w->connsenable[j] = 1; if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) w->wclass.pin.config = w->wclass.pin.newconf; if (w->eld != NULL) { w->eld_len = 0; free(w->eld, M_HDAA); w->eld = NULL; } } } static int hdaa_sysctl_gpi_state(SYSCTL_HANDLER_ARGS) { struct hdaa_devinfo *devinfo = oidp->oid_arg1; device_t dev = devinfo->dev; char buf[256]; int n = 0, i, numgpi; uint32_t data = 0; buf[0] = 0; hdaa_lock(devinfo); numgpi = HDA_PARAM_GPIO_COUNT_NUM_GPI(devinfo->gpio_cap); if (numgpi > 0) { data = hda_command(dev, HDA_CMD_GET_GPI_DATA(0, devinfo->nid)); } hdaa_unlock(devinfo); for (i = 0; i < numgpi; i++) { n += snprintf(buf + n, sizeof(buf) - n, "%s%d=%d", n != 0 ? " " : "", i, ((data >> i) & 1)); } return (sysctl_handle_string(oidp, buf, sizeof(buf), req)); } static int hdaa_sysctl_gpio_state(SYSCTL_HANDLER_ARGS) { struct hdaa_devinfo *devinfo = oidp->oid_arg1; device_t dev = devinfo->dev; char buf[256]; int n = 0, i, numgpio; uint32_t data = 0, enable = 0, dir = 0; buf[0] = 0; hdaa_lock(devinfo); numgpio = HDA_PARAM_GPIO_COUNT_NUM_GPIO(devinfo->gpio_cap); if (numgpio > 0) { data = hda_command(dev, HDA_CMD_GET_GPIO_DATA(0, devinfo->nid)); enable = hda_command(dev, HDA_CMD_GET_GPIO_ENABLE_MASK(0, devinfo->nid)); dir = hda_command(dev, HDA_CMD_GET_GPIO_DIRECTION(0, devinfo->nid)); } hdaa_unlock(devinfo); for (i = 0; i < numgpio; i++) { n += snprintf(buf + n, sizeof(buf) - n, "%s%d=", n != 0 ? " " : "", i); if ((enable & (1 << i)) == 0) { n += snprintf(buf + n, sizeof(buf) - n, "disabled"); continue; } n += snprintf(buf + n, sizeof(buf) - n, "%sput(%d)", ((dir >> i) & 1) ? "out" : "in", ((data >> i) & 1)); } return (sysctl_handle_string(oidp, buf, sizeof(buf), req)); } static int hdaa_sysctl_gpio_config(SYSCTL_HANDLER_ARGS) { struct hdaa_devinfo *devinfo = oidp->oid_arg1; char buf[256]; int error, n = 0, i, numgpio; uint32_t gpio, x; gpio = devinfo->newgpio; numgpio = HDA_PARAM_GPIO_COUNT_NUM_GPIO(devinfo->gpio_cap); buf[0] = 0; for (i = 0; i < numgpio; i++) { x = (gpio & HDAA_GPIO_MASK(i)) >> HDAA_GPIO_SHIFT(i); n += snprintf(buf + n, sizeof(buf) - n, "%s%d=%s", n != 0 ? " " : "", i, HDA_GPIO_ACTIONS[x]); } error = sysctl_handle_string(oidp, buf, sizeof(buf), req); if (error != 0 || req->newptr == NULL) return (error); if (strncmp(buf, "0x", 2) == 0) gpio = strtol(buf + 2, NULL, 16); else gpio = hdaa_gpio_patch(gpio, buf); hdaa_lock(devinfo); devinfo->newgpio = devinfo->gpio = gpio; hdaa_gpio_commit(devinfo); hdaa_unlock(devinfo); return (0); } static int hdaa_sysctl_gpo_state(SYSCTL_HANDLER_ARGS) { struct hdaa_devinfo *devinfo = oidp->oid_arg1; device_t dev = devinfo->dev; char buf[256]; int n = 0, i, numgpo; uint32_t data = 0; buf[0] = 0; hdaa_lock(devinfo); numgpo = HDA_PARAM_GPIO_COUNT_NUM_GPO(devinfo->gpio_cap); if (numgpo > 0) { data = hda_command(dev, HDA_CMD_GET_GPO_DATA(0, devinfo->nid)); } hdaa_unlock(devinfo); for (i = 0; i < numgpo; i++) { n += snprintf(buf + n, sizeof(buf) - n, "%s%d=%d", n != 0 ? " " : "", i, ((data >> i) & 1)); } return (sysctl_handle_string(oidp, buf, sizeof(buf), req)); } static int hdaa_sysctl_gpo_config(SYSCTL_HANDLER_ARGS) { struct hdaa_devinfo *devinfo = oidp->oid_arg1; char buf[256]; int error, n = 0, i, numgpo; uint32_t gpo, x; gpo = devinfo->newgpo; numgpo = HDA_PARAM_GPIO_COUNT_NUM_GPO(devinfo->gpio_cap); buf[0] = 0; for (i = 0; i < numgpo; i++) { x = (gpo & HDAA_GPIO_MASK(i)) >> HDAA_GPIO_SHIFT(i); n += snprintf(buf + n, sizeof(buf) - n, "%s%d=%s", n != 0 ? " " : "", i, HDA_GPIO_ACTIONS[x]); } error = sysctl_handle_string(oidp, buf, sizeof(buf), req); if (error != 0 || req->newptr == NULL) return (error); if (strncmp(buf, "0x", 2) == 0) gpo = strtol(buf + 2, NULL, 16); else gpo = hdaa_gpio_patch(gpo, buf); hdaa_lock(devinfo); devinfo->newgpo = devinfo->gpo = gpo; hdaa_gpo_commit(devinfo); hdaa_unlock(devinfo); return (0); } static int hdaa_sysctl_reconfig(SYSCTL_HANDLER_ARGS) { device_t dev; struct hdaa_devinfo *devinfo; int error, val; dev = oidp->oid_arg1; devinfo = device_get_softc(dev); if (devinfo == NULL) return (EINVAL); val = 0; error = sysctl_handle_int(oidp, &val, 0, req); if (error != 0 || req->newptr == NULL || val == 0) return (error); HDA_BOOTHVERBOSE( device_printf(dev, "Reconfiguration...\n"); ); bus_topo_lock(); if ((error = device_delete_children(dev)) != 0) { bus_topo_unlock(); return (error); } hdaa_lock(devinfo); hdaa_unconfigure(dev); hdaa_configure(dev); hdaa_unlock(devinfo); bus_attach_children(dev); HDA_BOOTHVERBOSE( device_printf(dev, "Reconfiguration done\n"); ); bus_topo_unlock(); return (0); } static int hdaa_suspend(device_t dev) { struct hdaa_devinfo *devinfo = device_get_softc(dev); int i; HDA_BOOTHVERBOSE( device_printf(dev, "Suspend...\n"); ); hdaa_lock(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Stop streams...\n"); ); for (i = 0; i < devinfo->num_chans; i++) { if (devinfo->chans[i].flags & HDAA_CHN_RUNNING) { devinfo->chans[i].flags |= HDAA_CHN_SUSPEND; hdaa_channel_stop(&devinfo->chans[i]); } } HDA_BOOTHVERBOSE( device_printf(dev, "Power down FG" " nid=%d to the D3 state...\n", devinfo->nid); ); hda_command(devinfo->dev, HDA_CMD_SET_POWER_STATE(0, devinfo->nid, HDA_CMD_POWER_STATE_D3)); callout_stop(&devinfo->poll_jack); hdaa_unlock(devinfo); callout_drain(&devinfo->poll_jack); HDA_BOOTHVERBOSE( device_printf(dev, "Suspend done\n"); ); return (0); } static int hdaa_resume(device_t dev) { struct hdaa_devinfo *devinfo = device_get_softc(dev); int i; HDA_BOOTHVERBOSE( device_printf(dev, "Resume...\n"); ); hdaa_lock(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Power up audio FG nid=%d...\n", devinfo->nid); ); hdaa_powerup(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "AFG commit...\n"); ); hdaa_audio_commit(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Applying direct built-in patches...\n"); ); hdaa_patch_direct(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Pin sense init...\n"); ); hdaa_sense_init(devinfo); hdaa_unlock(devinfo); for (i = 0; i < devinfo->num_devs; i++) { struct hdaa_pcm_devinfo *pdevinfo = &devinfo->devs[i]; HDA_BOOTHVERBOSE( device_printf(pdevinfo->dev, "OSS mixer reinitialization...\n"); ); if (mixer_reinit(pdevinfo->dev) == -1) device_printf(pdevinfo->dev, "unable to reinitialize the mixer\n"); } hdaa_lock(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Start streams...\n"); ); for (i = 0; i < devinfo->num_chans; i++) { if (devinfo->chans[i].flags & HDAA_CHN_SUSPEND) { devinfo->chans[i].flags &= ~HDAA_CHN_SUSPEND; hdaa_channel_start(&devinfo->chans[i]); } } hdaa_unlock(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Resume done\n"); ); return (0); } static int hdaa_probe(device_t dev) { const char *pdesc; if (hda_get_node_type(dev) != HDA_PARAM_FCT_GRP_TYPE_NODE_TYPE_AUDIO) return (ENXIO); pdesc = device_get_desc(device_get_parent(dev)); device_set_descf(dev, "%.*s Audio Function Group", (int)(strlen(pdesc) - 10), pdesc); return (BUS_PROBE_DEFAULT); } static int hdaa_attach(device_t dev) { struct hdaa_devinfo *devinfo = device_get_softc(dev); uint32_t res; nid_t nid = hda_get_node_id(dev); devinfo->dev = dev; devinfo->lock = HDAC_GET_MTX(device_get_parent(dev), dev); devinfo->nid = nid; devinfo->newquirks = -1; devinfo->newgpio = -1; devinfo->newgpo = -1; callout_init(&devinfo->poll_jack, 1); devinfo->poll_ival = hz; hdaa_lock(devinfo); res = hda_command(dev, HDA_CMD_GET_PARAMETER(0 , nid, HDA_PARAM_SUB_NODE_COUNT)); hdaa_unlock(devinfo); devinfo->nodecnt = HDA_PARAM_SUB_NODE_COUNT_TOTAL(res); devinfo->startnode = HDA_PARAM_SUB_NODE_COUNT_START(res); devinfo->endnode = devinfo->startnode + devinfo->nodecnt; HDA_BOOTVERBOSE( device_printf(dev, "Subsystem ID: 0x%08x\n", hda_get_subsystem_id(dev)); ); HDA_BOOTHVERBOSE( device_printf(dev, "Audio Function Group at nid=%d: %d subnodes %d-%d\n", nid, devinfo->nodecnt, devinfo->startnode, devinfo->endnode - 1); ); if (devinfo->nodecnt > 0) devinfo->widget = malloc(sizeof(*(devinfo->widget)) * devinfo->nodecnt, M_HDAA, M_WAITOK | M_ZERO); else devinfo->widget = NULL; hdaa_lock(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Powering up...\n"); ); hdaa_powerup(devinfo); HDA_BOOTHVERBOSE( device_printf(dev, "Parsing audio FG...\n"); ); hdaa_audio_parse(devinfo); HDA_BOOTVERBOSE( device_printf(dev, "Original pins configuration:\n"); hdaa_dump_pin_configs(devinfo); ); hdaa_configure(dev); hdaa_unlock(devinfo); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "config", CTLTYPE_STRING | CTLFLAG_RW | CTLFLAG_MPSAFE, &devinfo->newquirks, 0, hdaa_sysctl_quirks, "A", "Configuration options"); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "gpi_state", CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, devinfo, 0, hdaa_sysctl_gpi_state, "A", "GPI state"); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "gpio_state", CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, devinfo, 0, hdaa_sysctl_gpio_state, "A", "GPIO state"); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "gpio_config", CTLTYPE_STRING | CTLFLAG_RW | CTLFLAG_MPSAFE, devinfo, 0, hdaa_sysctl_gpio_config, "A", "GPIO configuration"); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "gpo_state", CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, devinfo, 0, hdaa_sysctl_gpo_state, "A", "GPO state"); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "gpo_config", CTLTYPE_STRING | CTLFLAG_RW | CTLFLAG_MPSAFE, devinfo, 0, hdaa_sysctl_gpo_config, "A", "GPO configuration"); SYSCTL_ADD_PROC(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "reconfig", CTLTYPE_INT | CTLFLAG_RW, dev, 0, hdaa_sysctl_reconfig, "I", "Reprocess configuration"); SYSCTL_ADD_INT(device_get_sysctl_ctx(dev), SYSCTL_CHILDREN(device_get_sysctl_tree(dev)), OID_AUTO, "init_clear", CTLFLAG_RW, &devinfo->init_clear, 1,"Clear initial pin widget configuration"); bus_attach_children(dev); return (0); } static int hdaa_detach(device_t dev) { struct hdaa_devinfo *devinfo = device_get_softc(dev); int error; if ((error = bus_generic_detach(dev)) != 0) return (error); hdaa_lock(devinfo); hdaa_unconfigure(dev); devinfo->poll_ival = 0; callout_stop(&devinfo->poll_jack); hdaa_unlock(devinfo); callout_drain(&devinfo->poll_jack); free(devinfo->widget, M_HDAA); return (0); } static int hdaa_print_child(device_t dev, device_t child) { struct hdaa_devinfo *devinfo = device_get_softc(dev); struct hdaa_pcm_devinfo *pdevinfo = (struct hdaa_pcm_devinfo *)device_get_ivars(child); struct hdaa_audio_as *as; int retval, first = 1, i; retval = bus_print_child_header(dev, child); retval += printf(" at nid "); if (pdevinfo->playas >= 0) { as = &devinfo->as[pdevinfo->playas]; for (i = 0; i < 16; i++) { if (as->pins[i] <= 0) continue; retval += printf("%s%d", first ? "" : ",", as->pins[i]); first = 0; } } if (pdevinfo->recas >= 0) { if (pdevinfo->playas >= 0) { retval += printf(" and "); first = 1; } as = &devinfo->as[pdevinfo->recas]; for (i = 0; i < 16; i++) { if (as->pins[i] <= 0) continue; retval += printf("%s%d", first ? "" : ",", as->pins[i]); first = 0; } } retval += bus_print_child_footer(dev, child); return (retval); } static int hdaa_child_location(device_t dev, device_t child, struct sbuf *sb) { struct hdaa_devinfo *devinfo = device_get_softc(dev); struct hdaa_pcm_devinfo *pdevinfo = (struct hdaa_pcm_devinfo *)device_get_ivars(child); struct hdaa_audio_as *as; int first = 1, i; sbuf_printf(sb, "nid="); if (pdevinfo->playas >= 0) { as = &devinfo->as[pdevinfo->playas]; for (i = 0; i < 16; i++) { if (as->pins[i] <= 0) continue; sbuf_printf(sb, "%s%d", first ? "" : ",", as->pins[i]); first = 0; } } if (pdevinfo->recas >= 0) { as = &devinfo->as[pdevinfo->recas]; for (i = 0; i < 16; i++) { if (as->pins[i] <= 0) continue; sbuf_printf(sb, "%s%d", first ? "" : ",", as->pins[i]); first = 0; } } return (0); } static void hdaa_stream_intr(device_t dev, int dir, int stream) { struct hdaa_devinfo *devinfo = device_get_softc(dev); struct hdaa_chan *ch; int i; for (i = 0; i < devinfo->num_chans; i++) { ch = &devinfo->chans[i]; if (!(ch->flags & HDAA_CHN_RUNNING)) continue; if (ch->dir == ((dir == 1) ? PCMDIR_PLAY : PCMDIR_REC) && ch->sid == stream) { hdaa_unlock(devinfo); chn_intr(ch->c); hdaa_lock(devinfo); } } } static void hdaa_unsol_intr(device_t dev, uint32_t resp) { struct hdaa_devinfo *devinfo = device_get_softc(dev); struct hdaa_widget *w; int i, tag, flags; HDA_BOOTHVERBOSE( device_printf(dev, "Unsolicited response %08x\n", resp); ); tag = resp >> 26; for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL || w->enable == 0 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; if (w->unsol != tag) continue; if (HDA_PARAM_PIN_CAP_DP(w->wclass.pin.cap) || HDA_PARAM_PIN_CAP_HDMI(w->wclass.pin.cap)) flags = resp & 0x03; else flags = 0x01; if (flags & 0x01) hdaa_presence_handler(w); if (flags & 0x02) hdaa_eld_handler(w); } } static device_method_t hdaa_methods[] = { /* device interface */ DEVMETHOD(device_probe, hdaa_probe), DEVMETHOD(device_attach, hdaa_attach), DEVMETHOD(device_detach, hdaa_detach), DEVMETHOD(device_suspend, hdaa_suspend), DEVMETHOD(device_resume, hdaa_resume), /* Bus interface */ DEVMETHOD(bus_print_child, hdaa_print_child), DEVMETHOD(bus_child_location, hdaa_child_location), DEVMETHOD(hdac_stream_intr, hdaa_stream_intr), DEVMETHOD(hdac_unsol_intr, hdaa_unsol_intr), DEVMETHOD(hdac_pindump, hdaa_pindump), DEVMETHOD_END }; static driver_t hdaa_driver = { "hdaa", hdaa_methods, sizeof(struct hdaa_devinfo), }; DRIVER_MODULE(snd_hda, hdacc, hdaa_driver, NULL, NULL); static void hdaa_chan_formula(struct hdaa_devinfo *devinfo, int asid, char *buf, int buflen) { struct hdaa_audio_as *as; int c; as = &devinfo->as[asid]; c = devinfo->chans[as->chans[0]].channels; if (c == 1) snprintf(buf, buflen, "mono"); else if (c == 2) { if (as->hpredir < 0) buf[0] = 0; else snprintf(buf, buflen, "2.0"); } else if (as->pinset == 0x0003) snprintf(buf, buflen, "3.1"); else if (as->pinset == 0x0005 || as->pinset == 0x0011) snprintf(buf, buflen, "4.0"); else if (as->pinset == 0x0007 || as->pinset == 0x0013) snprintf(buf, buflen, "5.1"); else if (as->pinset == 0x0017) snprintf(buf, buflen, "7.1"); else snprintf(buf, buflen, "%dch", c); if (as->hpredir >= 0) strlcat(buf, "+HP", buflen); } static int hdaa_chan_type(struct hdaa_devinfo *devinfo, int asid) { struct hdaa_audio_as *as; struct hdaa_widget *w; int i, t = -1, t1; as = &devinfo->as[asid]; for (i = 0; i < 16; i++) { w = hdaa_widget_get(devinfo, as->pins[i]); if (w == NULL || w->enable == 0 || w->type != HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) continue; t1 = HDA_CONFIG_DEFAULTCONF_DEVICE(w->wclass.pin.config); if (t == -1) t = t1; else if (t != t1) { t = -2; break; } } return (t); } static int hdaa_sysctl_32bit(SYSCTL_HANDLER_ARGS) { struct hdaa_audio_as *as = (struct hdaa_audio_as *)oidp->oid_arg1; struct hdaa_pcm_devinfo *pdevinfo = as->pdevinfo; struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_chan *ch; int error, val, i; uint32_t pcmcap; ch = &devinfo->chans[as->chans[0]]; val = (ch->bit32 == 4) ? 32 : ((ch->bit32 == 3) ? 24 : ((ch->bit32 == 2) ? 20 : 0)); error = sysctl_handle_int(oidp, &val, 0, req); if (error != 0 || req->newptr == NULL) return (error); pcmcap = ch->supp_pcm_size_rate; if (val == 32 && HDA_PARAM_SUPP_PCM_SIZE_RATE_32BIT(pcmcap)) ch->bit32 = 4; else if (val == 24 && HDA_PARAM_SUPP_PCM_SIZE_RATE_24BIT(pcmcap)) ch->bit32 = 3; else if (val == 20 && HDA_PARAM_SUPP_PCM_SIZE_RATE_20BIT(pcmcap)) ch->bit32 = 2; else return (EINVAL); for (i = 1; i < as->num_chans; i++) devinfo->chans[as->chans[i]].bit32 = ch->bit32; return (0); } static int hdaa_pcm_probe(device_t dev) { struct hdaa_pcm_devinfo *pdevinfo = (struct hdaa_pcm_devinfo *)device_get_ivars(dev); struct hdaa_devinfo *devinfo = pdevinfo->devinfo; const char *pdesc; char chans1[8], chans2[8]; int loc1, loc2, t1, t2; if (pdevinfo->playas >= 0) loc1 = devinfo->as[pdevinfo->playas].location; else loc1 = devinfo->as[pdevinfo->recas].location; if (pdevinfo->recas >= 0) loc2 = devinfo->as[pdevinfo->recas].location; else loc2 = loc1; if (loc1 != loc2) loc1 = -2; if (loc1 >= 0 && HDA_LOCS[loc1][0] == '0') loc1 = -2; chans1[0] = 0; chans2[0] = 0; t1 = t2 = -1; if (pdevinfo->playas >= 0) { hdaa_chan_formula(devinfo, pdevinfo->playas, chans1, sizeof(chans1)); t1 = hdaa_chan_type(devinfo, pdevinfo->playas); } if (pdevinfo->recas >= 0) { hdaa_chan_formula(devinfo, pdevinfo->recas, chans2, sizeof(chans2)); t2 = hdaa_chan_type(devinfo, pdevinfo->recas); } if (chans1[0] != 0 || chans2[0] != 0) { if (chans1[0] == 0 && pdevinfo->playas >= 0) snprintf(chans1, sizeof(chans1), "2.0"); else if (chans2[0] == 0 && pdevinfo->recas >= 0) snprintf(chans2, sizeof(chans2), "2.0"); if (strcmp(chans1, chans2) == 0) chans2[0] = 0; } if (t1 == -1) t1 = t2; else if (t2 == -1) t2 = t1; if (t1 != t2) t1 = -2; if (pdevinfo->digital) t1 = -2; pdesc = device_get_desc(device_get_parent(dev)); device_set_descf(dev, "%.*s (%s%s%s%s%s%s%s%s%s)", (int)(strlen(pdesc) - 21), pdesc, loc1 >= 0 ? HDA_LOCS[loc1] : "", loc1 >= 0 ? " " : "", (pdevinfo->digital == 0x7)?"HDMI/DP": ((pdevinfo->digital == 0x5)?"DisplayPort": ((pdevinfo->digital == 0x3)?"HDMI": ((pdevinfo->digital)?"Digital":"Analog"))), chans1[0] ? " " : "", chans1, chans2[0] ? "/" : "", chans2, t1 >= 0 ? " " : "", t1 >= 0 ? HDA_DEVS[t1] : ""); return (BUS_PROBE_SPECIFIC); } static int hdaa_pcm_attach(device_t dev) { struct hdaa_pcm_devinfo *pdevinfo = (struct hdaa_pcm_devinfo *)device_get_ivars(dev); struct hdaa_devinfo *devinfo = pdevinfo->devinfo; struct hdaa_audio_as *as; struct snddev_info *d; char status[SND_STATUSLEN]; int i; pdevinfo->chan_size = pcm_getbuffersize(dev, HDA_BUFSZ_MIN, HDA_BUFSZ_DEFAULT, HDA_BUFSZ_MAX); HDA_BOOTVERBOSE( hdaa_dump_dac(pdevinfo); hdaa_dump_adc(pdevinfo); hdaa_dump_mix(pdevinfo); hdaa_dump_ctls(pdevinfo, "Master Volume", SOUND_MASK_VOLUME); hdaa_dump_ctls(pdevinfo, "PCM Volume", SOUND_MASK_PCM); hdaa_dump_ctls(pdevinfo, "CD Volume", SOUND_MASK_CD); hdaa_dump_ctls(pdevinfo, "Microphone Volume", SOUND_MASK_MIC); hdaa_dump_ctls(pdevinfo, "Microphone2 Volume", SOUND_MASK_MONITOR); hdaa_dump_ctls(pdevinfo, "Line-in Volume", SOUND_MASK_LINE); hdaa_dump_ctls(pdevinfo, "Speaker/Beep Volume", SOUND_MASK_SPEAKER); hdaa_dump_ctls(pdevinfo, "Recording Level", SOUND_MASK_RECLEV); hdaa_dump_ctls(pdevinfo, "Input Mix Level", SOUND_MASK_IMIX); hdaa_dump_ctls(pdevinfo, "Input Monitoring Level", SOUND_MASK_IGAIN); hdaa_dump_ctls(pdevinfo, NULL, 0); ); if (resource_int_value(device_get_name(dev), device_get_unit(dev), "blocksize", &i) == 0 && i > 0) { i &= HDA_BLK_ALIGN; if (i < HDA_BLK_MIN) i = HDA_BLK_MIN; pdevinfo->chan_blkcnt = pdevinfo->chan_size / i; i = 0; while (pdevinfo->chan_blkcnt >> i) i++; pdevinfo->chan_blkcnt = 1 << (i - 1); if (pdevinfo->chan_blkcnt < HDA_BDL_MIN) pdevinfo->chan_blkcnt = HDA_BDL_MIN; else if (pdevinfo->chan_blkcnt > HDA_BDL_MAX) pdevinfo->chan_blkcnt = HDA_BDL_MAX; } else pdevinfo->chan_blkcnt = HDA_BDL_DEFAULT; /* * We don't register interrupt handler with snd_setup_intr * in pcm device. Mark pcm device as MPSAFE manually. */ pcm_setflags(dev, pcm_getflags(dev) | SD_F_MPSAFE); HDA_BOOTHVERBOSE( device_printf(dev, "OSS mixer initialization...\n"); ); if (mixer_init(dev, &hdaa_audio_ctl_ossmixer_class, pdevinfo) != 0) device_printf(dev, "Can't register mixer\n"); HDA_BOOTHVERBOSE( device_printf(dev, "Registering PCM channels...\n"); ); pcm_init(dev, pdevinfo); pdevinfo->registered++; d = device_get_softc(dev); if (pdevinfo->playas >= 0) { as = &devinfo->as[pdevinfo->playas]; for (i = 0; i < as->num_chans; i++) pcm_addchan(dev, PCMDIR_PLAY, &hdaa_channel_class, &devinfo->chans[as->chans[i]]); SYSCTL_ADD_PROC(&d->play_sysctl_ctx, SYSCTL_CHILDREN(d->play_sysctl_tree), OID_AUTO, "32bit", CTLTYPE_INT | CTLFLAG_RW | CTLFLAG_MPSAFE, as, sizeof(as), hdaa_sysctl_32bit, "I", "Resolution of 32bit samples (20/24/32bit)"); } if (pdevinfo->recas >= 0) { as = &devinfo->as[pdevinfo->recas]; for (i = 0; i < as->num_chans; i++) pcm_addchan(dev, PCMDIR_REC, &hdaa_channel_class, &devinfo->chans[as->chans[i]]); SYSCTL_ADD_PROC(&d->rec_sysctl_ctx, SYSCTL_CHILDREN(d->rec_sysctl_tree), OID_AUTO, "32bit", CTLTYPE_INT | CTLFLAG_RW | CTLFLAG_MPSAFE, as, sizeof(as), hdaa_sysctl_32bit, "I", "Resolution of 32bit samples (20/24/32bit)"); pdevinfo->autorecsrc = 2; resource_int_value(device_get_name(dev), device_get_unit(dev), "rec.autosrc", &pdevinfo->autorecsrc); SYSCTL_ADD_INT(&d->rec_sysctl_ctx, SYSCTL_CHILDREN(d->rec_sysctl_tree), OID_AUTO, "autosrc", CTLFLAG_RW, &pdevinfo->autorecsrc, 0, "Automatic recording source selection"); } if (pdevinfo->mixer != NULL) { hdaa_audio_ctl_set_defaults(pdevinfo); hdaa_lock(devinfo); if (pdevinfo->playas >= 0) { as = &devinfo->as[pdevinfo->playas]; hdaa_channels_handler(as); } if (pdevinfo->recas >= 0) { as = &devinfo->as[pdevinfo->recas]; hdaa_autorecsrc_handler(as, NULL); hdaa_channels_handler(as); } hdaa_unlock(devinfo); } snprintf(status, SND_STATUSLEN, "on %s", device_get_nameunit(device_get_parent(dev))); return (pcm_register(dev, status)); } static int hdaa_pcm_detach(device_t dev) { struct hdaa_pcm_devinfo *pdevinfo = (struct hdaa_pcm_devinfo *)device_get_ivars(dev); int err; if (pdevinfo->registered > 0) { err = pcm_unregister(dev); if (err != 0) return (err); } return (0); } static device_method_t hdaa_pcm_methods[] = { /* device interface */ DEVMETHOD(device_probe, hdaa_pcm_probe), DEVMETHOD(device_attach, hdaa_pcm_attach), DEVMETHOD(device_detach, hdaa_pcm_detach), DEVMETHOD_END }; static driver_t hdaa_pcm_driver = { "pcm", hdaa_pcm_methods, PCM_SOFTC_SIZE, }; DRIVER_MODULE(snd_hda_pcm, hdaa, hdaa_pcm_driver, NULL, NULL); MODULE_DEPEND(snd_hda, sound, SOUND_MINVER, SOUND_PREFVER, SOUND_MAXVER); MODULE_VERSION(snd_hda, 1); diff --git a/sys/dev/sound/pci/hda/hdaa_patches.c b/sys/dev/sound/pci/hda/hdaa_patches.c index 8ad1c845c254..0e88a63e2423 100644 --- a/sys/dev/sound/pci/hda/hdaa_patches.c +++ b/sys/dev/sound/pci/hda/hdaa_patches.c @@ -1,774 +1,780 @@ /*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2006 Stephane E. Potvin * Copyright (c) 2006 Ariff Abdullah * Copyright (c) 2008-2012 Alexander Motin * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * Intel High Definition Audio (Audio function quirks) driver for FreeBSD. */ #ifdef HAVE_KERNEL_OPTION_HEADERS #include "opt_snd.h" #endif #include #include #include #include #include #include "pin_patch.h" #include "pin_patch_realtek.h" static const struct { uint32_t model; uint32_t id; uint32_t subsystemid; uint32_t set, unset; uint32_t gpio; } hdac_quirks[] = { /* * XXX Force stereo quirk. Monoural recording / playback * on few codecs (especially ALC880) seems broken or * perhaps unsupported. */ { HDA_MATCH_ALL, HDA_MATCH_ALL, HDA_MATCH_ALL, HDAA_QUIRK_FORCESTEREO | HDAA_QUIRK_IVREF, 0, 0 }, { ACER_ALL_SUBVENDOR, HDA_MATCH_ALL, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { ASUS_G2K_SUBVENDOR, HDA_CODEC_ALC660, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { ASUS_M5200_SUBVENDOR, HDA_CODEC_ALC880, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { ASUS_A7M_SUBVENDOR, HDA_CODEC_ALC880, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { ASUS_A7T_SUBVENDOR, HDA_CODEC_ALC882, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { ASUS_W2J_SUBVENDOR, HDA_CODEC_ALC882, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { ASUS_U5F_SUBVENDOR, HDA_CODEC_AD1986A, HDA_MATCH_ALL, HDAA_QUIRK_EAPDINV, 0, 0 }, { ASUS_A8X_SUBVENDOR, HDA_CODEC_AD1986A, HDA_MATCH_ALL, HDAA_QUIRK_EAPDINV, 0, 0 }, { ASUS_F3JC_SUBVENDOR, HDA_CODEC_ALC861, HDA_MATCH_ALL, HDAA_QUIRK_OVREF, 0, 0 }, { UNIWILL_9075_SUBVENDOR, HDA_CODEC_ALC861, HDA_MATCH_ALL, HDAA_QUIRK_OVREF, 0, 0 }, /*{ ASUS_M2N_SUBVENDOR, HDA_CODEC_AD1988, HDA_MATCH_ALL, HDAA_QUIRK_IVREF80, HDAA_QUIRK_IVREF50 | HDAA_QUIRK_IVREF100, 0 },*/ { MEDION_MD95257_SUBVENDOR, HDA_CODEC_ALC880, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(1) }, { LENOVO_3KN100_SUBVENDOR, HDA_CODEC_AD1986A, HDA_MATCH_ALL, HDAA_QUIRK_EAPDINV | HDAA_QUIRK_SENSEINV, 0, 0 }, { SAMSUNG_Q1_SUBVENDOR, HDA_CODEC_AD1986A, HDA_MATCH_ALL, HDAA_QUIRK_EAPDINV, 0, 0 }, { APPLE_MB3_SUBVENDOR, HDA_CODEC_ALC885, HDA_MATCH_ALL, HDAA_QUIRK_OVREF50, 0, HDAA_GPIO_SET(0) }, { APPLE_INTEL_MAC, HDA_CODEC_STAC9221, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) | HDAA_GPIO_SET(1) }, { APPLE_MACBOOKAIR31, HDA_CODEC_CS4206, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(1) | HDAA_GPIO_SET(3) }, + { HDA_MATCH_ALL, HDA_CODEC_CS4208, APPLE_MACBOOKAIR61, + 0, 0, + HDAA_GPIO_SET(0) }, + { HDA_MATCH_ALL, HDA_CODEC_CS4208, APPLE_MACBOOKAIR62, + 0, 0, + HDAA_GPIO_SET(0) }, { APPLE_MACBOOKPRO55, HDA_CODEC_CS4206, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(1) | HDAA_GPIO_SET(3) }, { APPLE_MACBOOKPRO71, HDA_CODEC_CS4206, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(1) | HDAA_GPIO_SET(3) }, { HDA_INTEL_MACBOOKPRO92, HDA_CODEC_CS4206, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(1) | HDAA_GPIO_SET(3) }, { DELL_D630_SUBVENDOR, HDA_CODEC_STAC9205X, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { DELL_V1400_SUBVENDOR, HDA_CODEC_STAC9228X, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(2) }, { DELL_V1500_SUBVENDOR, HDA_CODEC_STAC9205X, HDA_MATCH_ALL, 0, 0, HDAA_GPIO_SET(0) }, { HDA_MATCH_ALL, HDA_CODEC_AD1988, HDA_MATCH_ALL, HDAA_QUIRK_IVREF80, HDAA_QUIRK_IVREF50 | HDAA_QUIRK_IVREF100, 0 }, { HDA_MATCH_ALL, HDA_CODEC_AD1988B, HDA_MATCH_ALL, HDAA_QUIRK_IVREF80, HDAA_QUIRK_IVREF50 | HDAA_QUIRK_IVREF100, 0 }, { HDA_MATCH_ALL, HDA_CODEC_CX20549, HDA_MATCH_ALL, 0, HDAA_QUIRK_FORCESTEREO, 0 }, /* Mac Pro 1,1 requires ovref for proper volume level. */ { 0x00000000, HDA_CODEC_ALC885, 0x106b0c00, 0, HDAA_QUIRK_OVREF, 0 } }; static struct pin_patch_t * match_pin_patches(int vendor_id, int vendor_subid) { for (int ci = 0; ci < nitems(realtek_model_pin_patches); ci++) { struct hdaa_model_pin_patch_t *p = &realtek_model_pin_patches[ci]; if (vendor_id != p->id) continue; for (struct model_pin_patch_t *pp = p->patches; pp->models; pp++) { for (struct pin_machine_model_t *model = pp->models; model->id != 0; model++) { if (HDA_DEV_MATCH(model->id, vendor_subid)) return (pp->pin_patches); } } } return (0); } static void hdac_pin_patch(struct hdaa_widget *w) { const char *patch_str = NULL; uint32_t config, orig, id, subid; nid_t nid = w->nid; config = orig = w->wclass.pin.config; id = hdaa_codec_id(w->devinfo); subid = hdaa_card_id(w->devinfo); if (id == HDA_CODEC_ALC883 && HDA_DEV_MATCH(ACER_ALL_SUBVENDOR, subid)) { switch (nid) { case 25: config &= ~(HDA_CONFIG_DEFAULTCONF_DEVICE_MASK | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK); config |= (HDA_CONFIG_DEFAULTCONF_DEVICE_MIC_IN | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_FIXED); break; case 28: config &= ~(HDA_CONFIG_DEFAULTCONF_DEVICE_MASK | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK); config |= (HDA_CONFIG_DEFAULTCONF_DEVICE_CD | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_FIXED); break; } } else if (id == HDA_CODEC_CX20549 && subid == HP_V3000_SUBVENDOR) { switch (nid) { case 18: config &= ~HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK; config |= HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_NONE; break; case 20: config &= ~(HDA_CONFIG_DEFAULTCONF_DEVICE_MASK | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK); config |= (HDA_CONFIG_DEFAULTCONF_DEVICE_MIC_IN | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_FIXED); break; case 21: config &= ~(HDA_CONFIG_DEFAULTCONF_DEVICE_MASK | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK); config |= (HDA_CONFIG_DEFAULTCONF_DEVICE_CD | HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_FIXED); break; } } else if (id == HDA_CODEC_CX20551 && subid == HP_DV5000_SUBVENDOR) { switch (nid) { case 20: case 21: config &= ~HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK; config |= HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_NONE; break; } } /* New patches */ if (id == HDA_CODEC_AD1984A && subid == LENOVO_X300_SUBVENDOR) { switch (nid) { case 17: /* Headphones with redirection */ patch_str = "as=1 seq=15"; break; case 20: /* Two mics together */ patch_str = "as=2 seq=15"; break; } } else if (id == HDA_CODEC_AD1986A && (subid == ASUS_M2NPVMX_SUBVENDOR || subid == ASUS_A8NVMCSM_SUBVENDOR || subid == ASUS_P5PL2_SUBVENDOR)) { switch (nid) { case 26: /* Headphones with redirection */ patch_str = "as=1 seq=15"; break; case 28: /* 5.1 out => 2.0 out + 1 input */ patch_str = "device=Line-in as=8 seq=1"; break; case 29: /* Can't use this as input, as the only available mic * preamplifier is busy by front panel mic (nid 31). * If you want to use this rear connector as mic input, * you have to disable the front panel one. */ patch_str = "as=0"; break; case 31: /* Lot of inputs configured with as=15 and unusable */ patch_str = "as=8 seq=3"; break; case 32: patch_str = "as=8 seq=4"; break; case 34: patch_str = "as=8 seq=5"; break; case 36: patch_str = "as=8 seq=6"; break; } } else if (id == HDA_CODEC_CX20561 && subid == LENOVO_B450_SUBVENDOR) { switch (nid) { case 22: patch_str = "as=1 seq=15"; break; } } else if (id == HDA_CODEC_CX20561 && subid == LENOVO_T400_SUBVENDOR) { switch (nid) { case 22: patch_str = "as=1 seq=15"; break; case 26: patch_str = "as=1 seq=0"; break; } } else if (id == HDA_CODEC_CX20590 && (subid == LENOVO_X1_SUBVENDOR || subid == LENOVO_X220_SUBVENDOR || subid == LENOVO_T420_SUBVENDOR || subid == LENOVO_T520_SUBVENDOR || subid == LENOVO_G580_SUBVENDOR)) { switch (nid) { case 25: patch_str = "as=1 seq=15"; break; /* * Group onboard mic and headphone mic * together. Fixes onboard mic. */ case 27: patch_str = "as=2 seq=15"; break; case 35: patch_str = "as=2"; break; } } else if (id == HDA_CODEC_ALC235 && subid == ASUS_GL553VE_SUBVENDOR) { switch (nid) { case 33: patch_str = "as=1 seq=15"; break; } } else if (id == HDA_CODEC_ALC256 && (subid == DELL_I7577_SUBVENDOR || subid == DELL_L7480_SUBVENDOR)) { switch (nid) { case 20: patch_str = "as=1 seq=0"; break; case 33: patch_str = "as=1 seq=15"; break; } } else if (id == HDA_CODEC_ALC257 && (subid == LENOVO_L5AMD_SUBVENDOR || subid == LENOVO_L5INTEL_SUBVENDOR || subid == LENOVO_IDEAPAD3_SUBVENDOR)) { switch (nid) { case 20: patch_str = "as=1 seq=0"; break; case 33: patch_str = "as=1 seq=15"; break; } } else if (id == HDA_CODEC_IDT92HD95B && (subid == FRAMEWORK_LAPTOP_0001_SUBVENDOR || subid == FRAMEWORK_LAPTOP_0002_SUBVENDOR || subid == FRAMEWORK_LAPTOP_0003_SUBVENDOR)) { switch (nid) { case 10: patch_str = "as=1 seq=15 color=Black loc=Left"; break; case 11: patch_str = "as=3 seq=15 color=Black loc=Left"; break; } } else if (id == HDA_CODEC_ALC295 && subid == FRAMEWORK_LAPTOP_0006_SUBVENDOR) { switch (nid) { case 33: patch_str = "as=1 seq=15 color=Black loc=Left"; break; } } else if (id == HDA_CODEC_ALC230 && subid == LENOVO_IDEAPAD330_SUBVENDOR) { switch (nid) { case 20: patch_str = "as=1 seq=0 device=Speaker"; break; case 33: patch_str = "as=1 seq=15 device=Headphones"; break; } } else if (id == HDA_CODEC_ALC269 && subid == LENOVO_X230_SUBVENDOR) { switch (nid) { case 21: patch_str = "as=1 seq=15"; break; case 24: patch_str = "as=4 seq=15"; break; } } else if (id == HDA_CODEC_ALC294 && subid == ASUS_UX331_SUBVENDOR) { switch (nid) { case 25: /* XXX You are not expected to understand this. */ config = 0x01a1103c; break; case 33: patch_str = "as=1 seq=15"; break; } } else { /* * loop over hdaa_model_pin_patch */ struct pin_patch_t *pin_patches = NULL; pin_patches = match_pin_patches(id, subid); if (pin_patches != NULL) { for (struct pin_patch_t *patch = pin_patches; patch->type; patch++) { if (nid == patch->nid) { switch (patch->type) { case PIN_PATCH_TYPE_STRING: patch_str = patch->patch.string; break; case PIN_PATCH_TYPE_MASK: config &= ~patch->patch.mask[0]; config |= patch->patch.mask[1]; break; case PIN_PATCH_TYPE_OVERRIDE: config = patch->patch.override; break; default: /* should panic hard */ break; } break; } } } } if (patch_str != NULL) config = hdaa_widget_pin_patch(config, patch_str); HDA_BOOTVERBOSE( if (config != orig) device_printf(w->devinfo->dev, "Patching pin config nid=%u 0x%08x -> 0x%08x\n", nid, orig, config); ); w->wclass.pin.config = config; } static void hdaa_widget_patch(struct hdaa_widget *w) { struct hdaa_devinfo *devinfo = w->devinfo; uint32_t orig; nid_t beeper = -1; orig = w->param.widget_cap; /* On some codecs beeper is an input pin, but it is not recordable alone. Also most of BIOSes does not declare beeper pin. Change beeper pin node type to beeper to help parser. */ switch (hdaa_codec_id(devinfo)) { case HDA_CODEC_AD1882: case HDA_CODEC_AD1883: case HDA_CODEC_AD1984: case HDA_CODEC_AD1984A: case HDA_CODEC_AD1984B: case HDA_CODEC_AD1987: case HDA_CODEC_AD1988: case HDA_CODEC_AD1988B: case HDA_CODEC_AD1989B: beeper = 26; break; case HDA_CODEC_ALC260: beeper = 23; break; } if (hda_get_vendor_id(devinfo->dev) == REALTEK_VENDORID && hdaa_codec_id(devinfo) != HDA_CODEC_ALC260) beeper = 29; if (w->nid == beeper) { w->param.widget_cap &= ~HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_MASK; w->param.widget_cap |= HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_BEEP_WIDGET << HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_SHIFT; w->waspin = 1; } /* * Clear "digital" flag from digital mic input, as its signal then goes * to "analog" mixer and this separation just limits functionaity. */ if (hdaa_codec_id(devinfo) == HDA_CODEC_AD1984A && w->nid == 23) w->param.widget_cap &= ~HDA_PARAM_AUDIO_WIDGET_CAP_DIGITAL_MASK; HDA_BOOTVERBOSE( if (w->param.widget_cap != orig) { device_printf(w->devinfo->dev, "Patching widget caps nid=%u 0x%08x -> 0x%08x\n", w->nid, orig, w->param.widget_cap); } ); if (w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX) hdac_pin_patch(w); } void hdaa_patch(struct hdaa_devinfo *devinfo) { struct hdaa_widget *w; uint32_t id, subid, subsystemid; int i; id = hdaa_codec_id(devinfo); subid = hdaa_card_id(devinfo); subsystemid = hda_get_subsystem_id(devinfo->dev); /* * Quirks */ for (i = 0; i < nitems(hdac_quirks); i++) { if (!(HDA_DEV_MATCH(hdac_quirks[i].model, subid) && HDA_DEV_MATCH(hdac_quirks[i].id, id) && HDA_DEV_MATCH(hdac_quirks[i].subsystemid, subsystemid))) continue; devinfo->quirks |= hdac_quirks[i].set; devinfo->quirks &= ~(hdac_quirks[i].unset); devinfo->gpio = hdac_quirks[i].gpio; } /* Apply per-widget patch. */ for (i = devinfo->startnode; i < devinfo->endnode; i++) { w = hdaa_widget_get(devinfo, i); if (w == NULL) continue; hdaa_widget_patch(w); } switch (id) { case HDA_CODEC_AD1983: /* * This CODEC has several possible usages, but none * fit the parser best. Help parser to choose better. */ /* Disable direct unmixed playback to get pcm volume. */ w = hdaa_widget_get(devinfo, 5); if (w != NULL) w->connsenable[0] = 0; w = hdaa_widget_get(devinfo, 6); if (w != NULL) w->connsenable[0] = 0; w = hdaa_widget_get(devinfo, 11); if (w != NULL) w->connsenable[0] = 0; /* Disable mic and line selectors. */ w = hdaa_widget_get(devinfo, 12); if (w != NULL) w->connsenable[1] = 0; w = hdaa_widget_get(devinfo, 13); if (w != NULL) w->connsenable[1] = 0; /* Disable recording from mono playback mix. */ w = hdaa_widget_get(devinfo, 20); if (w != NULL) w->connsenable[3] = 0; break; case HDA_CODEC_AD1986A: /* * This CODEC has overcomplicated input mixing. * Make some cleaning there. */ /* Disable input mono mixer. Not needed and not supported. */ w = hdaa_widget_get(devinfo, 43); if (w != NULL) w->enable = 0; /* Disable any with any input mixing mesh. Use separately. */ w = hdaa_widget_get(devinfo, 39); if (w != NULL) w->enable = 0; w = hdaa_widget_get(devinfo, 40); if (w != NULL) w->enable = 0; w = hdaa_widget_get(devinfo, 41); if (w != NULL) w->enable = 0; w = hdaa_widget_get(devinfo, 42); if (w != NULL) w->enable = 0; /* Disable duplicate mixer node connector. */ w = hdaa_widget_get(devinfo, 15); if (w != NULL) w->connsenable[3] = 0; /* There is only one mic preamplifier, use it effectively. */ w = hdaa_widget_get(devinfo, 31); if (w != NULL) { if ((w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK) == HDA_CONFIG_DEFAULTCONF_DEVICE_MIC_IN) { w = hdaa_widget_get(devinfo, 16); if (w != NULL) w->connsenable[2] = 0; } else { w = hdaa_widget_get(devinfo, 15); if (w != NULL) w->connsenable[0] = 0; } } w = hdaa_widget_get(devinfo, 32); if (w != NULL) { if ((w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_DEVICE_MASK) == HDA_CONFIG_DEFAULTCONF_DEVICE_MIC_IN) { w = hdaa_widget_get(devinfo, 16); if (w != NULL) w->connsenable[0] = 0; } else { w = hdaa_widget_get(devinfo, 15); if (w != NULL) w->connsenable[1] = 0; } } if (subid == ASUS_A8X_SUBVENDOR) { /* * This is just plain ridiculous.. There * are several A8 series that share the same * pci id but works differently (EAPD). */ w = hdaa_widget_get(devinfo, 26); if (w != NULL && w->type == HDA_PARAM_AUDIO_WIDGET_CAP_TYPE_PIN_COMPLEX && (w->wclass.pin.config & HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_MASK) != HDA_CONFIG_DEFAULTCONF_CONNECTIVITY_NONE) devinfo->quirks &= ~HDAA_QUIRK_EAPDINV; } break; case HDA_CODEC_AD1981HD: /* * This CODEC has very unusual design with several * points inappropriate for the present parser. */ /* Disable recording from mono playback mix. */ w = hdaa_widget_get(devinfo, 21); if (w != NULL) w->connsenable[3] = 0; /* Disable rear to front mic mixer, use separately. */ w = hdaa_widget_get(devinfo, 31); if (w != NULL) w->enable = 0; /* Disable direct playback, use mixer. */ w = hdaa_widget_get(devinfo, 5); if (w != NULL) w->connsenable[0] = 0; w = hdaa_widget_get(devinfo, 6); if (w != NULL) w->connsenable[0] = 0; w = hdaa_widget_get(devinfo, 9); if (w != NULL) w->connsenable[0] = 0; w = hdaa_widget_get(devinfo, 24); if (w != NULL) w->connsenable[0] = 0; break; case HDA_CODEC_ALC269: /* * ASUS EeePC 1001px has strange variant of ALC269 CODEC, * that mutes speaker if unused mixer at NID 15 is muted. * Probably CODEC incorrectly reports internal connections. * Hide that muter from the driver. There are several CODECs * sharing this ID and I have not enough information about * them to implement more universal solution. */ if (subid == 0x84371043) { w = hdaa_widget_get(devinfo, 15); if (w != NULL) w->param.inamp_cap = 0; } break; case HDA_CODEC_CX20582: case HDA_CODEC_CX20583: case HDA_CODEC_CX20584: case HDA_CODEC_CX20585: case HDA_CODEC_CX20590: /* * These codecs have extra connectivity on record side * too reach for the present parser. */ w = hdaa_widget_get(devinfo, 20); if (w != NULL) w->connsenable[1] = 0; w = hdaa_widget_get(devinfo, 21); if (w != NULL) w->connsenable[1] = 0; w = hdaa_widget_get(devinfo, 22); if (w != NULL) w->connsenable[0] = 0; break; case HDA_CODEC_VT1708S_0: case HDA_CODEC_VT1708S_1: case HDA_CODEC_VT1708S_2: case HDA_CODEC_VT1708S_3: case HDA_CODEC_VT1708S_4: case HDA_CODEC_VT1708S_5: case HDA_CODEC_VT1708S_6: case HDA_CODEC_VT1708S_7: /* * These codecs have hidden mic boost controls. */ w = hdaa_widget_get(devinfo, 26); if (w != NULL) w->param.inamp_cap = (40 << HDA_PARAM_OUTPUT_AMP_CAP_STEPSIZE_SHIFT) | (3 << HDA_PARAM_OUTPUT_AMP_CAP_NUMSTEPS_SHIFT) | (0 << HDA_PARAM_OUTPUT_AMP_CAP_OFFSET_SHIFT); w = hdaa_widget_get(devinfo, 30); if (w != NULL) w->param.inamp_cap = (40 << HDA_PARAM_OUTPUT_AMP_CAP_STEPSIZE_SHIFT) | (3 << HDA_PARAM_OUTPUT_AMP_CAP_NUMSTEPS_SHIFT) | (0 << HDA_PARAM_OUTPUT_AMP_CAP_OFFSET_SHIFT); break; } } static uint32_t hdaa_read_coef(device_t dev, nid_t nid, uint16_t idx) { hda_command(dev, HDA_CMD_SET_COEFF_INDEX(0, nid, idx)); return (hda_command(dev, HDA_CMD_GET_PROCESSING_COEFF(0, nid))); } static uint32_t hdaa_write_coef(device_t dev, nid_t nid, uint16_t idx, uint16_t val) { hda_command(dev, HDA_CMD_SET_COEFF_INDEX(0, nid, idx)); return (hda_command(dev, HDA_CMD_SET_PROCESSING_COEFF(0, nid, val))); } void hdaa_patch_direct(struct hdaa_devinfo *devinfo) { device_t dev = devinfo->dev; uint32_t id, subid, val; id = hdaa_codec_id(devinfo); subid = hdaa_card_id(devinfo); switch (id) { case HDA_CODEC_VT1708S_0: case HDA_CODEC_VT1708S_1: case HDA_CODEC_VT1708S_2: case HDA_CODEC_VT1708S_3: case HDA_CODEC_VT1708S_4: case HDA_CODEC_VT1708S_5: case HDA_CODEC_VT1708S_6: case HDA_CODEC_VT1708S_7: /* Enable Mic Boost Volume controls. */ hda_command(dev, HDA_CMD_12BIT(0, devinfo->nid, 0xf98, 0x01)); /* Fall though */ case HDA_CODEC_VT1818S: /* Don't bypass mixer. */ hda_command(dev, HDA_CMD_12BIT(0, devinfo->nid, 0xf88, 0xc0)); break; case HDA_CODEC_ALC1150: if (subid == 0xd9781462) { /* Too low volume on MSI H170 GAMING M3. */ hdaa_write_coef(dev, 0x20, 0x07, 0x7cb); } break; } if (id == HDA_CODEC_ALC255 || id == HDA_CODEC_ALC256) { val = hdaa_read_coef(dev, 0x20, 0x46); hdaa_write_coef(dev, 0x20, 0x46, val|0x3000); } if (subid == APPLE_INTEL_MAC) hda_command(dev, HDA_CMD_12BIT(0, devinfo->nid, 0x7e7, 0)); if (id == HDA_CODEC_ALC269) { if (subid == 0x16e31043 || subid == 0x831a1043 || subid == 0x834a1043 || subid == 0x83981043 || subid == 0x83ce1043) { /* * The digital mics on some Asus laptops produce * differential signals instead of expected stereo. * That results in silence if downmixing to mono. * To workaround, make codec handle the signal as mono. */ val = hdaa_read_coef(dev, 0x20, 0x07); hdaa_write_coef(dev, 0x20, 0x07, val|0x80); } if (subid == 0x15171043) { /* Increase output amp on ASUS UX31A by +5dB. */ hdaa_write_coef(dev, 0x20, 0x12, 0x2800); } } } diff --git a/sys/dev/sound/pci/hda/hdac.h b/sys/dev/sound/pci/hda/hdac.h index 9b11dcba32a8..231839327530 100644 --- a/sys/dev/sound/pci/hda/hdac.h +++ b/sys/dev/sound/pci/hda/hdac.h @@ -1,1008 +1,1011 @@ /*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2006 Stephane E. Potvin * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifndef _HDAC_H_ #define _HDAC_H_ #include "hdac_if.h" /**************************************************************************** * Miscellaneous defines ****************************************************************************/ /* Controller models */ #define HDA_MODEL_CONSTRUCT(vendor, model) \ (((uint32_t)(model) << 16) | ((vendor##_VENDORID) & 0xffff)) /* Intel */ #define INTEL_VENDORID 0x8086 #define HDA_INTEL_CMLKLP HDA_MODEL_CONSTRUCT(INTEL, 0x02c8) #define HDA_INTEL_CMLKH HDA_MODEL_CONSTRUCT(INTEL, 0x06c8) #define HDA_INTEL_OAK HDA_MODEL_CONSTRUCT(INTEL, 0x080a) #define HDA_INTEL_BAY HDA_MODEL_CONSTRUCT(INTEL, 0x0f04) #define HDA_INTEL_HSW1 HDA_MODEL_CONSTRUCT(INTEL, 0x0a0c) #define HDA_INTEL_HSW2 HDA_MODEL_CONSTRUCT(INTEL, 0x0c0c) #define HDA_INTEL_HSW3 HDA_MODEL_CONSTRUCT(INTEL, 0x0d0c) #define HDA_INTEL_BDW1 HDA_MODEL_CONSTRUCT(INTEL, 0x160c) #define HDA_INTEL_BXTNT HDA_MODEL_CONSTRUCT(INTEL, 0x1a98) #define HDA_INTEL_CPT HDA_MODEL_CONSTRUCT(INTEL, 0x1c20) #define HDA_INTEL_PATSBURG HDA_MODEL_CONSTRUCT(INTEL, 0x1d20) #define HDA_INTEL_PPT1 HDA_MODEL_CONSTRUCT(INTEL, 0x1e20) #define HDA_INTEL_BR HDA_MODEL_CONSTRUCT(INTEL, 0x2284) #define HDA_INTEL_82801F HDA_MODEL_CONSTRUCT(INTEL, 0x2668) #define HDA_INTEL_63XXESB HDA_MODEL_CONSTRUCT(INTEL, 0x269a) #define HDA_INTEL_82801G HDA_MODEL_CONSTRUCT(INTEL, 0x27d8) #define HDA_INTEL_82801H HDA_MODEL_CONSTRUCT(INTEL, 0x284b) #define HDA_INTEL_82801I HDA_MODEL_CONSTRUCT(INTEL, 0x293e) #define HDA_INTEL_GMLK HDA_MODEL_CONSTRUCT(INTEL, 0x3198) #define HDA_INTEL_JLK HDA_MODEL_CONSTRUCT(INTEL, 0x38c8) #define HDA_INTEL_82801JI HDA_MODEL_CONSTRUCT(INTEL, 0x3a3e) #define HDA_INTEL_82801JD HDA_MODEL_CONSTRUCT(INTEL, 0x3a6e) #define HDA_INTEL_PCH HDA_MODEL_CONSTRUCT(INTEL, 0x3b56) #define HDA_INTEL_PCH2 HDA_MODEL_CONSTRUCT(INTEL, 0x3b57) #define HDA_INTEL_ELLK HDA_MODEL_CONSTRUCT(INTEL, 0x4b55) #define HDA_INTEL_JLK2 HDA_MODEL_CONSTRUCT(INTEL, 0x4dc8) #define HDA_INTEL_BXTNP HDA_MODEL_CONSTRUCT(INTEL, 0x5a98) #define HDA_INTEL_MACBOOKPRO92 HDA_MODEL_CONSTRUCT(INTEL, 0x7270) #define HDA_INTEL_ALLK HDA_MODEL_CONSTRUCT(INTEL, 0x7ad0) #define HDA_INTEL_ALLKM HDA_MODEL_CONSTRUCT(INTEL, 0x51cc) #define HDA_INTEL_ALLKN HDA_MODEL_CONSTRUCT(INTEL, 0x54c8) #define HDA_INTEL_ALLKP1 HDA_MODEL_CONSTRUCT(INTEL, 0x51c8) #define HDA_INTEL_ALLKP2 HDA_MODEL_CONSTRUCT(INTEL, 0x51cd) #define HDA_INTEL_ALLKPS HDA_MODEL_CONSTRUCT(INTEL, 0x51c9) #define HDA_INTEL_RPTLK1 HDA_MODEL_CONSTRUCT(INTEL, 0x51ca) #define HDA_INTEL_RPTLK2 HDA_MODEL_CONSTRUCT(INTEL, 0x51cb) #define HDA_INTEL_RPTLK3 HDA_MODEL_CONSTRUCT(INTEL, 0x7a50) #define HDA_INTEL_SCH HDA_MODEL_CONSTRUCT(INTEL, 0x811b) #define HDA_INTEL_LPT1 HDA_MODEL_CONSTRUCT(INTEL, 0x8c20) #define HDA_INTEL_LPT2 HDA_MODEL_CONSTRUCT(INTEL, 0x8c21) #define HDA_INTEL_WCPT HDA_MODEL_CONSTRUCT(INTEL, 0x8ca0) #define HDA_INTEL_WELLS1 HDA_MODEL_CONSTRUCT(INTEL, 0x8d20) #define HDA_INTEL_WELLS2 HDA_MODEL_CONSTRUCT(INTEL, 0x8d21) #define HDA_INTEL_LPTLP1 HDA_MODEL_CONSTRUCT(INTEL, 0x9c20) #define HDA_INTEL_LPTLP2 HDA_MODEL_CONSTRUCT(INTEL, 0x9c21) #define HDA_INTEL_BDW2 HDA_MODEL_CONSTRUCT(INTEL, 0x9ca0) #define HDA_INTEL_SRPTLP HDA_MODEL_CONSTRUCT(INTEL, 0x9d70) #define HDA_INTEL_KBLKLP HDA_MODEL_CONSTRUCT(INTEL, 0x9d71) #define HDA_INTEL_SRPT HDA_MODEL_CONSTRUCT(INTEL, 0xa170) #define HDA_INTEL_KBLK HDA_MODEL_CONSTRUCT(INTEL, 0xa171) #define HDA_INTEL_KBLKH HDA_MODEL_CONSTRUCT(INTEL, 0xa2f0) #define HDA_INTEL_CFLK HDA_MODEL_CONSTRUCT(INTEL, 0xa348) #define HDA_INTEL_CMLKS HDA_MODEL_CONSTRUCT(INTEL, 0xa3f0) #define HDA_INTEL_CNLK HDA_MODEL_CONSTRUCT(INTEL, 0x9dc8) #define HDA_INTEL_ICLK HDA_MODEL_CONSTRUCT(INTEL, 0x34c8) #define HDA_INTEL_TGLK HDA_MODEL_CONSTRUCT(INTEL, 0xa0c8) #define HDA_INTEL_TGLKH HDA_MODEL_CONSTRUCT(INTEL, 0x43c8) #define HDA_INTEL_MTL HDA_MODEL_CONSTRUCT(INTEL, 0x7e28) #define HDA_INTEL_ARLS HDA_MODEL_CONSTRUCT(INTEL, 0x7f50) #define HDA_INTEL_ARL HDA_MODEL_CONSTRUCT(INTEL, 0x7728) #define HDA_INTEL_LNLP HDA_MODEL_CONSTRUCT(INTEL, 0xa828) #define INTEL_A100ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xa100) #define INTEL_D400ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xd400) #define INTEL_D401ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xd401) #define INTEL_D402ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xd402) #define INTEL_E305ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xe305) #define INTEL_E308ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xe308) #define INTEL_E224ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xe224) #define INTEL_E400ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xe400) #define INTEL_E401ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xe401) #define INTEL_E402ID_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xe402) #define HDA_INTEL_ALL HDA_MODEL_CONSTRUCT(INTEL, 0xffff) /* Nvidia */ #define NVIDIA_VENDORID 0x10de #define HDA_NVIDIA_MCP51 HDA_MODEL_CONSTRUCT(NVIDIA, 0x026c) #define HDA_NVIDIA_MCP55 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0371) #define HDA_NVIDIA_MCP61_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x03e4) #define HDA_NVIDIA_MCP61_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x03f0) #define HDA_NVIDIA_MCP65_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x044a) #define HDA_NVIDIA_MCP65_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x044b) #define HDA_NVIDIA_MCP67_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x055c) #define HDA_NVIDIA_MCP67_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x055d) #define HDA_NVIDIA_MCP78_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0774) #define HDA_NVIDIA_MCP78_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0775) #define HDA_NVIDIA_MCP78_3 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0776) #define HDA_NVIDIA_MCP78_4 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0777) #define HDA_NVIDIA_MCP73_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x07fc) #define HDA_NVIDIA_MCP73_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x07fd) #define HDA_NVIDIA_MCP79_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0ac0) #define HDA_NVIDIA_MCP79_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0ac1) #define HDA_NVIDIA_MCP79_3 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0ac2) #define HDA_NVIDIA_MCP79_4 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0ac3) #define HDA_NVIDIA_0BE2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0be2) #define HDA_NVIDIA_0BE3 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0be3) #define HDA_NVIDIA_0BE4 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0be4) #define HDA_NVIDIA_GT100 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0be5) #define HDA_NVIDIA_GT106 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0be9) #define HDA_NVIDIA_GT108 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0bea) #define HDA_NVIDIA_GT104 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0beb) #define HDA_NVIDIA_GT116 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0bee) #define HDA_NVIDIA_MCP89_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0d94) #define HDA_NVIDIA_MCP89_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0d95) #define HDA_NVIDIA_MCP89_3 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0d96) #define HDA_NVIDIA_MCP89_4 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0d97) #define HDA_NVIDIA_GF119 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0e08) #define HDA_NVIDIA_GF110_1 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0e09) #define HDA_NVIDIA_GF110_2 HDA_MODEL_CONSTRUCT(NVIDIA, 0x0e0c) #define HDA_NVIDIA_ALL HDA_MODEL_CONSTRUCT(NVIDIA, 0xffff) /* ATI */ #define ATI_VENDORID 0x1002 #define HDA_ATI_SB450 HDA_MODEL_CONSTRUCT(ATI, 0x437b) #define HDA_ATI_SB600 HDA_MODEL_CONSTRUCT(ATI, 0x4383) #define HDA_ATI_RS600 HDA_MODEL_CONSTRUCT(ATI, 0x793b) #define HDA_ATI_RS690 HDA_MODEL_CONSTRUCT(ATI, 0x7919) #define HDA_ATI_RS780 HDA_MODEL_CONSTRUCT(ATI, 0x960f) #define HDA_ATI_RS880 HDA_MODEL_CONSTRUCT(ATI, 0x970f) #define HDA_ATI_R600 HDA_MODEL_CONSTRUCT(ATI, 0xaa00) #define HDA_ATI_RV630 HDA_MODEL_CONSTRUCT(ATI, 0xaa08) #define HDA_ATI_RV610 HDA_MODEL_CONSTRUCT(ATI, 0xaa10) #define HDA_ATI_RV670 HDA_MODEL_CONSTRUCT(ATI, 0xaa18) #define HDA_ATI_RV635 HDA_MODEL_CONSTRUCT(ATI, 0xaa20) #define HDA_ATI_RV620 HDA_MODEL_CONSTRUCT(ATI, 0xaa28) #define HDA_ATI_RV770 HDA_MODEL_CONSTRUCT(ATI, 0xaa30) #define HDA_ATI_RV730 HDA_MODEL_CONSTRUCT(ATI, 0xaa38) #define HDA_ATI_RV710 HDA_MODEL_CONSTRUCT(ATI, 0xaa40) #define HDA_ATI_RV740 HDA_MODEL_CONSTRUCT(ATI, 0xaa48) #define HDA_ATI_RV870 HDA_MODEL_CONSTRUCT(ATI, 0xaa50) #define HDA_ATI_RV840 HDA_MODEL_CONSTRUCT(ATI, 0xaa58) #define HDA_ATI_RV830 HDA_MODEL_CONSTRUCT(ATI, 0xaa60) #define HDA_ATI_RV810 HDA_MODEL_CONSTRUCT(ATI, 0xaa68) #define HDA_ATI_RV970 HDA_MODEL_CONSTRUCT(ATI, 0xaa80) #define HDA_ATI_RV940 HDA_MODEL_CONSTRUCT(ATI, 0xaa88) #define HDA_ATI_RV930 HDA_MODEL_CONSTRUCT(ATI, 0xaa90) #define HDA_ATI_RV910 HDA_MODEL_CONSTRUCT(ATI, 0xaa98) #define HDA_ATI_R1000 HDA_MODEL_CONSTRUCT(ATI, 0xaaa0) #define HDA_ATI_OLAND HDA_MODEL_CONSTRUCT(ATI, 0xaab0) #define HDA_ATI_KABINI HDA_MODEL_CONSTRUCT(ATI, 0x9840) #define HDA_ATI_TRINITY HDA_MODEL_CONSTRUCT(ATI, 0x9902) #define HDA_ATI_ALL HDA_MODEL_CONSTRUCT(ATI, 0xffff) #define AMD_VENDORID 0x1022 #define HDA_AMD_X370 HDA_MODEL_CONSTRUCT(AMD, 0x1457) #define HDA_AMD_X570 HDA_MODEL_CONSTRUCT(AMD, 0x1487) #define HDA_AMD_STONEY HDA_MODEL_CONSTRUCT(AMD, 0x157a) #define HDA_AMD_RAVEN HDA_MODEL_CONSTRUCT(AMD, 0x15e3) #define HDA_AMD_HUDSON2 HDA_MODEL_CONSTRUCT(AMD, 0x780d) #define HDA_AMD_ALL HDA_MODEL_CONSTRUCT(AMD, 0xffff) /* RDC */ #define RDC_VENDORID 0x17f3 #define HDA_RDC_M3010 HDA_MODEL_CONSTRUCT(RDC, 0x3010) /* Creative */ #define CREATIVE_VENDORID 0x1102 #define HDA_CREATIVE_SB1570 HDA_MODEL_CONSTRUCT(CREATIVE, 0x0012) #define HDA_CREATIVE_ALL HDA_MODEL_CONSTRUCT(CREATIVE, 0xffff) /* VIA */ #define VIA_VENDORID 0x1106 #define HDA_VIA_VT82XX HDA_MODEL_CONSTRUCT(VIA, 0x3288) #define HDA_VIA_ALL HDA_MODEL_CONSTRUCT(VIA, 0xffff) /* VMware */ #define VMWARE_VENDORID 0x15ad #define HDA_VMWARE HDA_MODEL_CONSTRUCT(VMWARE, 0x1977) #define HDA_VMWARE_ALL HDA_MODEL_CONSTRUCT(VMWARE, 0xffff) /* SiS */ #define SIS_VENDORID 0x1039 #define HDA_SIS_966 HDA_MODEL_CONSTRUCT(SIS, 0x7502) #define HDA_SIS_ALL HDA_MODEL_CONSTRUCT(SIS, 0xffff) /* ULI */ #define ULI_VENDORID 0x10b9 #define HDA_ULI_M5461 HDA_MODEL_CONSTRUCT(ULI, 0x5461) #define HDA_ULI_ALL HDA_MODEL_CONSTRUCT(ULI, 0xffff) /* OEM/subvendors */ /* Intel */ #define INTEL_DH87RL_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0x204a) #define INTEL_D101GGC_SUBVENDOR HDA_MODEL_CONSTRUCT(INTEL, 0xd600) /* HP/Compaq */ #define HP_VENDORID 0x103c #define HP_Z200_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x103c) #define HP_225AID_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x225a) #define HP_2272ID_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x2272) #define HP_2273ID_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x2273) #define HP_V3000_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x30b5) #define HP_NX7400_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x30a2) #define HP_NX6310_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x30aa) #define HP_NX6325_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x30b0) #define HP_XW4300_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x3013) #define HP_3010_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x3010) #define HP_DV5000_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x30a5) #define HP_DC7700S_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x2801) #define HP_DC7700_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x2802) #define HP_DC5750_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x280a) #define HP_AF006UR_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0x83a2) #define HP_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(HP, 0xffff) /* What is wrong with XN 2563 anyway? (Got the picture ?) */ #define HP_NX6325_SUBVENDORX 0x103c30b0 /* Dell */ #define DELL_VENDORID 0x1028 #define DELL_D630_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x01f9) #define DELL_D820_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x01cc) #define DELL_V1400_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0227) #define DELL_V1500_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0228) #define DELL_I1300_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x01c9) #define DELL_L7480_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x07a0) #define DELL_XPSM1210_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x01d7) #define DELL_OPLX745_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x01da) #define DELL_05F4ID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x05f4) #define DELL_05F5ID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x05f5) #define DELL_05F6ID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x05f6) #define DELL_V5470_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0615) #define DELL_V5470_1_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0616) #define DELL_064AID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x064a) #define DELL_064BID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x064b) #define DELL_9020M_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0669) #define DELL_V5480_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x069a) #define DELL_06D9ID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x06d9) #define DELL_06DAID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x06da) #define DELL_06DBID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x06db) #define DELL_06DDID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x06dd) #define DELL_06DEID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x06de) #define DELL_06DFID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x06df) #define DELL_06E0ID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x06e0) #define DELL_7559_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0706) #define DELL_7000_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0798) #define DELL_XPS9560_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x07be) #define DELL_E7240_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x05ca) #define DELL_164AID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x164a) #define DELL_164BID_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x164b) #define DELL_I7577_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0x0802) #define DELL_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(DELL, 0xffff) /* Clevo */ #define CLEVO_VENDORID 0x1558 #define CLEVO_D900T_SUBVENDOR HDA_MODEL_CONSTRUCT(CLEVO, 0x0900) #define CLEVO_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(CLEVO, 0xffff) /* Acer */ #define ACER_VENDORID 0x1025 #define ACER_0070ID_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0070) #define ACER_0077ID_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0077) #define ACER_0078ID_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0078) #define ACER_0087ID_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0087) #define ACER_A5050_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x010f) #define ACER_A4520_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0127) #define ACER_A4710_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x012f) #define ACER_A4715_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0133) #define ACER_TM_6293_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0139) #define ACER_3681WXM_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0110) #define ACER_T6292_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x011b) #define ACER_T5320_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x011f) #define ACER_TM_6293_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0139) #define ACER_AC700_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x047c) #define ACER_V5_571G_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x072d) #define ACER_AO725_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0740) #define ACER_AO756_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0742) #define ACER_E1_472_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0762) #define ACER_E1_572_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x0775) #define ACER_V5_573G_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x079b) #define ACER_CB_14_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0x106d) #define ACER_V5_122P_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0xa80d) #define ACER_APFV_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0xa884) #define ACER_E309ID_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0xe309) #define ACER_E310ID_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0xe310) #define ACER_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(ACER, 0xffff) /* Asus */ #define ASUS_VENDORID 0x1043 #define ASUS_X540A_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x103e) #define ASUS_X540SA_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x10c0) #define ASUS_X556UR_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x11c0) #define ASUS_W5A_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x10c3) #define ASUS_X540LA_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x10d0) #define ASUS_A8X_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1153) #define ASUS_U5F_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1263) #define ASUS_W6F_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1263) #define ASUS_X541SA_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x12e0) #define ASUS_X541UV_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x12f0) #define ASUS_A7M_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1323) #define ASUS_F3JC_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1338) #define ASUS_G2K_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1339) #define ASUS_Z550SA_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x13b0) #define ASUS_A7T_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x13c2) #define ASUS_UX331_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x14de) #define ASUS_UX31A_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1517) #define ASUS_GL553VE_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x15e0) #define ASUS_Z71V_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1964) #define ASUS_W2J_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1971) #define ASUS_M5200_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1993) #define ASUS_G73JW_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1a13) #define ASUS_X705UD_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1a30) #define ASUS_Z550MA_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1bbd) #define ASUS_X555UB_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x1ccd) #define ASUS_P5PL2_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x817f) #define ASUS_P1AH2_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x81cb) #define ASUS_M2NPVMX_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x81cb) #define ASUS_M2V_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x81e7) #define ASUS_P5BWD_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x81ec) #define ASUS_M2N_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x8234) #define ASUS_A8NVMCSM_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0xcb84) #define ASUS_X101CH_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0x8516) #define ASUS_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(ASUS, 0xffff) /* IBM / Lenovo */ #define IBM_VENDORID 0x1014 #define IBM_M52_SUBVENDOR HDA_MODEL_CONSTRUCT(IBM, 0x02f6) #define IBM_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(IBM, 0xffff) /* Lenovo */ #define LENOVO_VENDORID 0x17aa #define LENOVO_3KN100_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x2066) #define LENOVO_3KN200_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x384e) #define LENOVO_B450_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x3a0d) #define LENOVO_TCA55_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x1015) #define LENOVO_X1_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21e8) #define LENOVO_X1CRBN_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21f9) #define LENOVO_X120BS_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x2227) #define LENOVO_X120KH_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x225c) #define LENOVO_X120QD_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x2292) #define LENOVO_X220_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21da) #define LENOVO_X300_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x20ac) #define LENOVO_T400_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x20f2) #define LENOVO_T420_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21ce) #define LENOVO_T430_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21f3) #define LENOVO_T430S_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21fb) #define LENOVO_T520_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21cf) #define LENOVO_T530_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21f6) #define LENOVO_X230_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x21fa) #define LENOVO_X230T_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x2203) #define LENOVO_T431S_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x2208) #define LENOVO_X1CRBNG11_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x2315) #define LENOVO_G580_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x3977) #define LENOVO_L5AMD_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x381b) #define LENOVO_L5INTEL_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x380f) #define LENOVO_3000_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x384e) #define LENOVO_IDEAPAD330_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x3808) #define LENOVO_IDEAPAD3_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0x3881) #define LENOVO_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(LENOVO, 0xffff) /* Samsung */ #define SAMSUNG_VENDORID 0x144d #define SAMSUNG_Q1_SUBVENDOR HDA_MODEL_CONSTRUCT(SAMSUNG, 0xc027) #define SAMSUNG_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(SAMSUNG, 0xffff) /* Medion ? */ #define MEDION_VENDORID 0x161f #define MEDION_MD95257_SUBVENDOR HDA_MODEL_CONSTRUCT(MEDION, 0x203d) #define MEDION_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(MEDION, 0xffff) /* Apple Computer Inc. */ #define APPLE_VENDORID 0x106b #define APPLE_MB3_SUBVENDOR HDA_MODEL_CONSTRUCT(APPLE, 0x00a1) /* Sony */ #define SONY_VENDORID 0x104d #define SONY_S5_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x81cc) #define SONY_81A0ID_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x81a0) #define SONY_81D6ID_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x81d6) #define SONY_81BBID_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x81bb) #define SONY_VAIO_TX_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x81e2) #define SONY_VAIO_S13_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x9099) #define SONY_VAIO_P11_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x90b5) #define SONY_VAIO_P13_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0x90b6) #define SONY_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(SONY, 0xffff) /* Tyan? */ #define TYAN_VENDORID 0x10f1 #define TYAN_N6650W_SUBVENDOR HDA_MODEL_CONSTRUCT(TYAN, 0x2915) /* * Apple Intel MacXXXX seems using Sigmatel codec/vendor id * instead of their own, which is beyond my comprehension * (see HDA_CODEC_STAC9221 below). */ #define APPLE_INTEL_MAC 0x76808384 #define APPLE_MACBOOKAIR31 0x0d9410de +#define APPLE_MACBOOKAIR61 0x106b7100 +#define APPLE_MACBOOKAIR62 0x106b7200 #define APPLE_MACBOOKPRO55 0xcb7910de #define APPLE_MACBOOKPRO71 0xcb8910de /* LG Electronics */ #define LG_VENDORID 0x1854 #define LG_LW20_SUBVENDOR HDA_MODEL_CONSTRUCT(LG, 0x0018) #define LG_M1_SUBVENDOR HDA_MODEL_CONSTRUCT(LG, 0x003b) #define LG_P1_SUBVENDOR HDA_MODEL_CONSTRUCT(LG, 0x005f) #define LG_W1_SUBVENDOR HDA_MODEL_CONSTRUCT(LG, 0x0068) #define LG_LW25_SUBVENDOR HDA_MODEL_CONSTRUCT(LG, 0x0077) #define LG_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(LG, 0xffff) /* Fujitsu Siemens */ #define FS_VENDORID 0x1734 #define FS_PA1510_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0x10b8) #define FS_SI1848_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0x10cd) #define FS_AMILO_M1437_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0x107c) #define FS_AMILO_M1451G_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0x1094) #define FS_AMILO_PI1556_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0x10b0) #define FS_AMILO_XI1526_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0x10ac) #define FS_H270_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0x1147) #define FS_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(FS, 0xffff) /* Fujitsu Limited */ #define FL_VENDORID 0x10cf #define FL_S7020D_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0x1326) #define FL_LB_S7110_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0x1397) #define FL_U1010_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0x142d) #define FL_1475ID_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0x1475) #define FL_LB_U904_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0x1845) #define FL_LB_T731_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0x15dc) #define FL_LB_E725_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0x1757) #define FL_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(FL, 0xffff) /* Toshiba */ #define TOSHIBA_VENDORID 0x1179 #define TOSHIBA_U200_SUBVENDOR HDA_MODEL_CONSTRUCT(TOSHIBA, 0x0001) #define TOSHIBA_A135_SUBVENDOR HDA_MODEL_CONSTRUCT(TOSHIBA, 0xff01) #define TOSHIBA_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(TOSHIBA, 0xffff) /* Micro-Star International (MSI) */ #define MSI_VENDORID 0x1462 #define MSI_MS1034_SUBVENDOR HDA_MODEL_CONSTRUCT(MSI, 0x0349) #define MSI_MS034A_SUBVENDOR HDA_MODEL_CONSTRUCT(MSI, 0x034a) #define MSI_1150ID_SUBVENDOR HDA_MODEL_CONSTRUCT(MSI, 0x1150) #define MSI_MS_B120_SUBVENDOR HDA_MODEL_CONSTRUCT(MSI, 0xb120) #define MSI_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(MSI, 0xffff) /* Giga-Byte Technology */ #define GB_VENDORID 0x1458 #define GB_G33S2H_SUBVENDOR HDA_MODEL_CONSTRUCT(GB, 0xa022) #define GB_K8_SUBVENDOR HDA_MODEL_CONSTRUCT(GB, 0xa102) #define GB_BXBT2807_SUBVENDOR HDA_MODEL_CONSTRUCT(GB, 0xfa53) #define GP_ALL_SUBVENDOR HDA_MODEL_CONSTRUCT(GB, 0xffff) /* Uniwill ? */ #define UNIWILL_VENDORID 0x1584 #define UNIWILL_9075_SUBVENDOR HDA_MODEL_CONSTRUCT(UNIWILL, 0x9075) #define UNIWILL_9050_SUBVENDOR HDA_MODEL_CONSTRUCT(UNIWILL, 0x9050) #define UNIWILL_9054_SUBVENDOR HDA_MODEL_CONSTRUCT(UNIWILL, 0x9054) #define UNIWILL_9070_SUBVENDOR HDA_MODEL_CONSTRUCT(UNIWILL, 0x9070) #define UNIWILL_9080_SUBVENDOR HDA_MODEL_CONSTRUCT(UNIWILL, 0x9080) /* Coeus / Elitegroup */ #define COEUS_VENDORID 0x1019 #define COEUS_G610P_SUBVENDOR HDA_MODEL_CONSTRUCT(COEUS, 0x0f69) #define COEUS_A880ID_SUBVENDOR HDA_MODEL_CONSTRUCT(COEUS, 0xa880) /* Arima */ #define ARIMA_VENDORID 0x161f #define ARIMA_W810_SUBVENDOR HDA_MODEL_CONSTRUCT(ARIMA, 0x0f69) /* Shuttle Computer */ #define SHUTTLE_VENDORID 0x1039 #define SHUTTLE_ST20G5_SUBVENDOR HDA_MODEL_CONSTRUCT(SHUTTLE, 0xc790) /* First International Computer */ #define FIC_VENDORID 0x1509 #define FIC_P4M_SUBVENDOR HDA_MODEL_CONSTRUCT(FIC, 0x925d) /* Gateway 2000 */ #define GATEWAY_VENDORID 0x107b #define GATEWAY_3032ID_SUBVENDOR HDA_MODEL_CONSTRUCT(GATEWAY, 0x3032) #define GATEWAY_3033ID_SUBVENDOR HDA_MODEL_CONSTRUCT(GATEWAY, 0x3033) #define GATEWAY_4039ID_SUBVENDOR HDA_MODEL_CONSTRUCT(GATEWAY, 0x4039) /* Biostar */ #define BIOSTAR_VENDORID 0x1565 #define BIOSTAR_8202ID_SUBVENDOR HDA_MODEL_CONSTRUCT(BIOSTAR, 0x8202) /* EPoX Computer Co., Ltd. */ #define EPOX_VENDORID 0x1695 #define EPOX_400DID_SUBVENDOR HDA_MODEL_CONSTRUCT(EPOX, 0x400d) #define EPOX_EP5LDA_SUBVENDOR HDA_MODEL_CONSTRUCT(EPOX, 0x4012) /* AOpen */ #define AOPEN_VENDORID 0xa0a0 #define AOPEN_I915GMMHFS_SUBVENDOR HDA_MODEL_CONSTRUCT(AOPEN, 0x8202) /* Framework */ #define FRAMEWORK_VENDORID 0xf111 #define FRAMEWORK_LAPTOP_0001_SUBVENDOR HDA_MODEL_CONSTRUCT(FRAMEWORK, 0x0001) #define FRAMEWORK_LAPTOP_0002_SUBVENDOR HDA_MODEL_CONSTRUCT(FRAMEWORK, 0x0002) #define FRAMEWORK_LAPTOP_0003_SUBVENDOR HDA_MODEL_CONSTRUCT(FRAMEWORK, 0x0003) #define FRAMEWORK_LAPTOP_0006_SUBVENDOR HDA_MODEL_CONSTRUCT(FRAMEWORK, 0x0006) /* All codecs you can eat... */ #define HDA_CODEC_CONSTRUCT(vendor, id) \ (((uint32_t)(vendor##_VENDORID) << 16) | ((id) & 0xffff)) /* Cirrus Logic */ #define CIRRUSLOGIC_VENDORID 0x1013 #define HDA_CODEC_CS4206 HDA_CODEC_CONSTRUCT(CIRRUSLOGIC, 0x4206) #define HDA_CODEC_CS4207 HDA_CODEC_CONSTRUCT(CIRRUSLOGIC, 0x4207) +#define HDA_CODEC_CS4208 HDA_CODEC_CONSTRUCT(CIRRUSLOGIC, 0x4208) #define HDA_CODEC_CS4210 HDA_CODEC_CONSTRUCT(CIRRUSLOGIC, 0x4210) #define HDA_CODEC_CSXXXX HDA_CODEC_CONSTRUCT(CIRRUSLOGIC, 0xffff) /* Realtek */ #define REALTEK_VENDORID 0x10ec #define HDA_CODEC_ALC215 HDA_CODEC_CONSTRUCT(REALTEK, 0x0215) #define HDA_CODEC_ALC221 HDA_CODEC_CONSTRUCT(REALTEK, 0x0221) #define HDA_CODEC_ALC222 HDA_CODEC_CONSTRUCT(REALTEK, 0x0222) #define HDA_CODEC_ALC225 HDA_CODEC_CONSTRUCT(REALTEK, 0x0225) #define HDA_CODEC_ALC230 HDA_CODEC_CONSTRUCT(REALTEK, 0x0230) #define HDA_CODEC_ALC231 HDA_CODEC_CONSTRUCT(REALTEK, 0x0231) #define HDA_CODEC_ALC233 HDA_CODEC_CONSTRUCT(REALTEK, 0x0233) #define HDA_CODEC_ALC234 HDA_CODEC_CONSTRUCT(REALTEK, 0x0234) #define HDA_CODEC_ALC235 HDA_CODEC_CONSTRUCT(REALTEK, 0x0235) #define HDA_CODEC_ALC236 HDA_CODEC_CONSTRUCT(REALTEK, 0x0236) #define HDA_CODEC_ALC245 HDA_CODEC_CONSTRUCT(REALTEK, 0x0245) #define HDA_CODEC_ALC255 HDA_CODEC_CONSTRUCT(REALTEK, 0x0255) #define HDA_CODEC_ALC256 HDA_CODEC_CONSTRUCT(REALTEK, 0x0256) #define HDA_CODEC_ALC257 HDA_CODEC_CONSTRUCT(REALTEK, 0x0257) #define HDA_CODEC_ALC260 HDA_CODEC_CONSTRUCT(REALTEK, 0x0260) #define HDA_CODEC_ALC262 HDA_CODEC_CONSTRUCT(REALTEK, 0x0262) #define HDA_CODEC_ALC267 HDA_CODEC_CONSTRUCT(REALTEK, 0x0267) #define HDA_CODEC_ALC268 HDA_CODEC_CONSTRUCT(REALTEK, 0x0268) #define HDA_CODEC_ALC269 HDA_CODEC_CONSTRUCT(REALTEK, 0x0269) #define HDA_CODEC_ALC270 HDA_CODEC_CONSTRUCT(REALTEK, 0x0270) #define HDA_CODEC_ALC271 HDA_CODEC_CONSTRUCT(REALTEK, 0x0271) #define HDA_CODEC_ALC272 HDA_CODEC_CONSTRUCT(REALTEK, 0x0272) #define HDA_CODEC_ALC273 HDA_CODEC_CONSTRUCT(REALTEK, 0x0273) #define HDA_CODEC_ALC274 HDA_CODEC_CONSTRUCT(REALTEK, 0x0274) #define HDA_CODEC_ALC275 HDA_CODEC_CONSTRUCT(REALTEK, 0x0275) #define HDA_CODEC_ALC276 HDA_CODEC_CONSTRUCT(REALTEK, 0x0276) #define HDA_CODEC_ALC280 HDA_CODEC_CONSTRUCT(REALTEK, 0x0280) #define HDA_CODEC_ALC282 HDA_CODEC_CONSTRUCT(REALTEK, 0x0282) #define HDA_CODEC_ALC283 HDA_CODEC_CONSTRUCT(REALTEK, 0x0283) #define HDA_CODEC_ALC284 HDA_CODEC_CONSTRUCT(REALTEK, 0x0284) #define HDA_CODEC_ALC285 HDA_CODEC_CONSTRUCT(REALTEK, 0x0285) #define HDA_CODEC_ALC286 HDA_CODEC_CONSTRUCT(REALTEK, 0x0286) #define HDA_CODEC_ALC287 HDA_CODEC_CONSTRUCT(REALTEK, 0x0287) #define HDA_CODEC_ALC288 HDA_CODEC_CONSTRUCT(REALTEK, 0x0288) #define HDA_CODEC_ALC289 HDA_CODEC_CONSTRUCT(REALTEK, 0x0289) #define HDA_CODEC_ALC290 HDA_CODEC_CONSTRUCT(REALTEK, 0x0290) #define HDA_CODEC_ALC292 HDA_CODEC_CONSTRUCT(REALTEK, 0x0292) #define HDA_CODEC_ALC293 HDA_CODEC_CONSTRUCT(REALTEK, 0x0293) #define HDA_CODEC_ALC294 HDA_CODEC_CONSTRUCT(REALTEK, 0x0294) #define HDA_CODEC_ALC295 HDA_CODEC_CONSTRUCT(REALTEK, 0x0295) #define HDA_CODEC_ALC298 HDA_CODEC_CONSTRUCT(REALTEK, 0x0298) #define HDA_CODEC_ALC299 HDA_CODEC_CONSTRUCT(REALTEK, 0x0299) #define HDA_CODEC_ALC300 HDA_CODEC_CONSTRUCT(REALTEK, 0x0300) #define HDA_CODEC_ALC623 HDA_CODEC_CONSTRUCT(REALTEK, 0x0623) #define HDA_CODEC_ALC660 HDA_CODEC_CONSTRUCT(REALTEK, 0x0660) #define HDA_CODEC_ALC662 HDA_CODEC_CONSTRUCT(REALTEK, 0x0662) #define HDA_CODEC_ALC663 HDA_CODEC_CONSTRUCT(REALTEK, 0x0663) #define HDA_CODEC_ALC665 HDA_CODEC_CONSTRUCT(REALTEK, 0x0665) #define HDA_CODEC_ALC670 HDA_CODEC_CONSTRUCT(REALTEK, 0x0670) #define HDA_CODEC_ALC671 HDA_CODEC_CONSTRUCT(REALTEK, 0x0671) #define HDA_CODEC_ALC680 HDA_CODEC_CONSTRUCT(REALTEK, 0x0680) #define HDA_CODEC_ALC700 HDA_CODEC_CONSTRUCT(REALTEK, 0x0700) #define HDA_CODEC_ALC701 HDA_CODEC_CONSTRUCT(REALTEK, 0x0701) #define HDA_CODEC_ALC703 HDA_CODEC_CONSTRUCT(REALTEK, 0x0703) #define HDA_CODEC_ALC861 HDA_CODEC_CONSTRUCT(REALTEK, 0x0861) #define HDA_CODEC_ALC861VD HDA_CODEC_CONSTRUCT(REALTEK, 0x0862) #define HDA_CODEC_ALC880 HDA_CODEC_CONSTRUCT(REALTEK, 0x0880) #define HDA_CODEC_ALC882 HDA_CODEC_CONSTRUCT(REALTEK, 0x0882) #define HDA_CODEC_ALC883 HDA_CODEC_CONSTRUCT(REALTEK, 0x0883) #define HDA_CODEC_ALC885 HDA_CODEC_CONSTRUCT(REALTEK, 0x0885) #define HDA_CODEC_ALC887 HDA_CODEC_CONSTRUCT(REALTEK, 0x0887) #define HDA_CODEC_ALC888 HDA_CODEC_CONSTRUCT(REALTEK, 0x0888) #define HDA_CODEC_ALC889 HDA_CODEC_CONSTRUCT(REALTEK, 0x0889) #define HDA_CODEC_ALC892 HDA_CODEC_CONSTRUCT(REALTEK, 0x0892) #define HDA_CODEC_ALC897 HDA_CODEC_CONSTRUCT(REALTEK, 0x0897) #define HDA_CODEC_ALC898 HDA_CODEC_CONSTRUCT(REALTEK, 0x0898) #define HDA_CODEC_ALC899 HDA_CODEC_CONSTRUCT(REALTEK, 0x0899) #define HDA_CODEC_ALC1150 HDA_CODEC_CONSTRUCT(REALTEK, 0x0900) #define HDA_CODEC_ALCS1200A HDA_CODEC_CONSTRUCT(REALTEK, 0x0b00) #define HDA_CODEC_ALC1220_1 HDA_CODEC_CONSTRUCT(REALTEK, 0x1168) #define HDA_CODEC_ALC1220 HDA_CODEC_CONSTRUCT(REALTEK, 0x1220) #define HDA_CODEC_ALCXXXX HDA_CODEC_CONSTRUCT(REALTEK, 0xffff) /* Motorola */ #define MOTO_VENDORID 0x1057 #define HDA_CODEC_MOTOXXXX HDA_CODEC_CONSTRUCT(MOTO, 0xffff) /* Creative */ #define CREATIVE_VENDORID 0x1102 #define HDA_CODEC_CA0110 HDA_CODEC_CONSTRUCT(CREATIVE, 0x000a) #define HDA_CODEC_CA0110_2 HDA_CODEC_CONSTRUCT(CREATIVE, 0x000b) #define HDA_CODEC_SB0880 HDA_CODEC_CONSTRUCT(CREATIVE, 0x000d) #define HDA_CODEC_CA0132 HDA_CODEC_CONSTRUCT(CREATIVE, 0x0011) #define HDA_CODEC_CAXXXX HDA_CODEC_CONSTRUCT(CREATIVE, 0xffff) /* Analog Devices */ #define ANALOGDEVICES_VENDORID 0x11d4 #define HDA_CODEC_AD1884A HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x184a) #define HDA_CODEC_AD1882 HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1882) #define HDA_CODEC_AD1883 HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1883) #define HDA_CODEC_AD1884 HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1884) #define HDA_CODEC_AD1984A HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x194a) #define HDA_CODEC_AD1984B HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x194b) #define HDA_CODEC_AD1981HD HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1981) #define HDA_CODEC_AD1983 HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1983) #define HDA_CODEC_AD1984 HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1984) #define HDA_CODEC_AD1986A HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1986) #define HDA_CODEC_AD1987 HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1987) #define HDA_CODEC_AD1988 HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x1988) #define HDA_CODEC_AD1988B HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x198b) #define HDA_CODEC_AD1882A HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x882a) #define HDA_CODEC_AD1989A HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x989a) #define HDA_CODEC_AD1989B HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0x989b) #define HDA_CODEC_ADXXXX HDA_CODEC_CONSTRUCT(ANALOGDEVICES, 0xffff) /* CMedia */ #define CMEDIA_VENDORID 0x13f6 #define HDA_CODEC_CMI9880 HDA_CODEC_CONSTRUCT(CMEDIA, 0x9880) #define HDA_CODEC_CMIXXXX HDA_CODEC_CONSTRUCT(CMEDIA, 0xffff) #define CMEDIA2_VENDORID 0x434d #define HDA_CODEC_CMI98802 HDA_CODEC_CONSTRUCT(CMEDIA2, 0x4980) #define HDA_CODEC_CMIXXXX2 HDA_CODEC_CONSTRUCT(CMEDIA2, 0xffff) /* Sigmatel */ #define SIGMATEL_VENDORID 0x8384 #define HDA_CODEC_STAC9230X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7612) #define HDA_CODEC_STAC9230D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7613) #define HDA_CODEC_STAC9229X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7614) #define HDA_CODEC_STAC9229D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7615) #define HDA_CODEC_STAC9228X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7616) #define HDA_CODEC_STAC9228D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7617) #define HDA_CODEC_STAC9227X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7618) #define HDA_CODEC_STAC9227D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7619) #define HDA_CODEC_STAC9274 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7620) #define HDA_CODEC_STAC9274D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7621) #define HDA_CODEC_STAC9273X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7622) #define HDA_CODEC_STAC9273D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7623) #define HDA_CODEC_STAC9272X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7624) #define HDA_CODEC_STAC9272D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7625) #define HDA_CODEC_STAC9271X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7626) #define HDA_CODEC_STAC9271D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7627) #define HDA_CODEC_STAC9274X5NH HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7628) #define HDA_CODEC_STAC9274D5NH HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7629) #define HDA_CODEC_STAC9250 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7634) #define HDA_CODEC_STAC9251 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7636) #define HDA_CODEC_IDT92HD700X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7638) #define HDA_CODEC_IDT92HD700D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7639) #define HDA_CODEC_IDT92HD206X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7645) #define HDA_CODEC_IDT92HD206D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7646) #define HDA_CODEC_CXD9872RDK HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7661) #define HDA_CODEC_STAC9872AK HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7662) #define HDA_CODEC_CXD9872AKD HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7664) #define HDA_CODEC_STAC9221 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7680) #define HDA_CODEC_STAC922XD HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7681) #define HDA_CODEC_STAC9221_A2 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7682) #define HDA_CODEC_STAC9221D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7683) #define HDA_CODEC_STAC9220 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7690) #define HDA_CODEC_STAC9200D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7691) #define HDA_CODEC_IDT92HD005 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7698) #define HDA_CODEC_IDT92HD005D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7699) #define HDA_CODEC_STAC9205X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a0) #define HDA_CODEC_STAC9205D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a1) #define HDA_CODEC_STAC9204X HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a2) #define HDA_CODEC_STAC9204D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a3) #define HDA_CODEC_STAC9255 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a4) #define HDA_CODEC_STAC9255D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a5) #define HDA_CODEC_STAC9254 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a6) #define HDA_CODEC_STAC9254D HDA_CODEC_CONSTRUCT(SIGMATEL, 0x76a7) #define HDA_CODEC_STAC9220_A2 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7880) #define HDA_CODEC_STAC9220_A1 HDA_CODEC_CONSTRUCT(SIGMATEL, 0x7882) #define HDA_CODEC_STACXXXX HDA_CODEC_CONSTRUCT(SIGMATEL, 0xffff) /* IDT / Tempo Semiconductor */ #define IDT_VENDORID 0x111d #define HDA_CODEC_IDT92HD75BX HDA_CODEC_CONSTRUCT(IDT, 0x7603) #define HDA_CODEC_IDT92HD83C1X HDA_CODEC_CONSTRUCT(IDT, 0x7604) #define HDA_CODEC_IDT92HD81B1X HDA_CODEC_CONSTRUCT(IDT, 0x7605) #define HDA_CODEC_IDT92HD75B3 HDA_CODEC_CONSTRUCT(IDT, 0x7608) #define HDA_CODEC_IDT92HD73D1 HDA_CODEC_CONSTRUCT(IDT, 0x7674) #define HDA_CODEC_IDT92HD73C1 HDA_CODEC_CONSTRUCT(IDT, 0x7675) #define HDA_CODEC_IDT92HD73E1 HDA_CODEC_CONSTRUCT(IDT, 0x7676) #define HDA_CODEC_IDT92HD95B HDA_CODEC_CONSTRUCT(IDT, 0x7695) #define HDA_CODEC_IDT92HD71B8 HDA_CODEC_CONSTRUCT(IDT, 0x76b0) #define HDA_CODEC_IDT92HD71B8_2 HDA_CODEC_CONSTRUCT(IDT, 0x76b1) #define HDA_CODEC_IDT92HD71B7 HDA_CODEC_CONSTRUCT(IDT, 0x76b2) #define HDA_CODEC_IDT92HD71B7_2 HDA_CODEC_CONSTRUCT(IDT, 0x76b3) #define HDA_CODEC_IDT92HD71B6 HDA_CODEC_CONSTRUCT(IDT, 0x76b4) #define HDA_CODEC_IDT92HD71B6_2 HDA_CODEC_CONSTRUCT(IDT, 0x76b5) #define HDA_CODEC_IDT92HD71B5 HDA_CODEC_CONSTRUCT(IDT, 0x76b6) #define HDA_CODEC_IDT92HD71B5_2 HDA_CODEC_CONSTRUCT(IDT, 0x76b7) #define HDA_CODEC_IDT92HD89C3 HDA_CODEC_CONSTRUCT(IDT, 0x76c0) #define HDA_CODEC_IDT92HD89C2 HDA_CODEC_CONSTRUCT(IDT, 0x76c1) #define HDA_CODEC_IDT92HD89C1 HDA_CODEC_CONSTRUCT(IDT, 0x76c2) #define HDA_CODEC_IDT92HD89B3 HDA_CODEC_CONSTRUCT(IDT, 0x76c3) #define HDA_CODEC_IDT92HD89B2 HDA_CODEC_CONSTRUCT(IDT, 0x76c4) #define HDA_CODEC_IDT92HD89B1 HDA_CODEC_CONSTRUCT(IDT, 0x76c5) #define HDA_CODEC_IDT92HD89E3 HDA_CODEC_CONSTRUCT(IDT, 0x76c6) #define HDA_CODEC_IDT92HD89E2 HDA_CODEC_CONSTRUCT(IDT, 0x76c7) #define HDA_CODEC_IDT92HD89E1 HDA_CODEC_CONSTRUCT(IDT, 0x76c8) #define HDA_CODEC_IDT92HD89D3 HDA_CODEC_CONSTRUCT(IDT, 0x76c9) #define HDA_CODEC_IDT92HD89D2 HDA_CODEC_CONSTRUCT(IDT, 0x76ca) #define HDA_CODEC_IDT92HD89D1 HDA_CODEC_CONSTRUCT(IDT, 0x76cb) #define HDA_CODEC_IDT92HD89F3 HDA_CODEC_CONSTRUCT(IDT, 0x76cc) #define HDA_CODEC_IDT92HD89F2 HDA_CODEC_CONSTRUCT(IDT, 0x76cd) #define HDA_CODEC_IDT92HD89F1 HDA_CODEC_CONSTRUCT(IDT, 0x76ce) #define HDA_CODEC_IDT92HD87B1_3 HDA_CODEC_CONSTRUCT(IDT, 0x76d1) #define HDA_CODEC_IDT92HD83C1C HDA_CODEC_CONSTRUCT(IDT, 0x76d4) #define HDA_CODEC_IDT92HD81B1C HDA_CODEC_CONSTRUCT(IDT, 0x76d5) #define HDA_CODEC_IDT92HD87B2_4 HDA_CODEC_CONSTRUCT(IDT, 0x76d9) #define HDA_CODEC_IDT92HD93BXX HDA_CODEC_CONSTRUCT(IDT, 0x76df) #define HDA_CODEC_IDT92HD91BXX HDA_CODEC_CONSTRUCT(IDT, 0x76e0) #define HDA_CODEC_IDT92HD98BXX HDA_CODEC_CONSTRUCT(IDT, 0x76e3) #define HDA_CODEC_IDT92HD99BXX HDA_CODEC_CONSTRUCT(IDT, 0x76e5) #define HDA_CODEC_IDT92HD90BXX HDA_CODEC_CONSTRUCT(IDT, 0x76e7) #define HDA_CODEC_IDT92HD66B1X5 HDA_CODEC_CONSTRUCT(IDT, 0x76e8) #define HDA_CODEC_IDT92HD66B2X5 HDA_CODEC_CONSTRUCT(IDT, 0x76e9) #define HDA_CODEC_IDT92HD66B3X5 HDA_CODEC_CONSTRUCT(IDT, 0x76ea) #define HDA_CODEC_IDT92HD66C1X5 HDA_CODEC_CONSTRUCT(IDT, 0x76eb) #define HDA_CODEC_IDT92HD66C2X5 HDA_CODEC_CONSTRUCT(IDT, 0x76ec) #define HDA_CODEC_IDT92HD66C3X5 HDA_CODEC_CONSTRUCT(IDT, 0x76ed) #define HDA_CODEC_IDT92HD66B1X3 HDA_CODEC_CONSTRUCT(IDT, 0x76ee) #define HDA_CODEC_IDT92HD66B2X3 HDA_CODEC_CONSTRUCT(IDT, 0x76ef) #define HDA_CODEC_IDT92HD66B3X3 HDA_CODEC_CONSTRUCT(IDT, 0x76f0) #define HDA_CODEC_IDT92HD66C1X3 HDA_CODEC_CONSTRUCT(IDT, 0x76f1) #define HDA_CODEC_IDT92HD66C2X3 HDA_CODEC_CONSTRUCT(IDT, 0x76f2) #define HDA_CODEC_IDT92HD66C3_65 HDA_CODEC_CONSTRUCT(IDT, 0x76f3) #define HDA_CODEC_IDTXXXX HDA_CODEC_CONSTRUCT(IDT, 0xffff) /* Silicon Image */ #define SII_VENDORID 0x1095 #define HDA_CODEC_SII1390 HDA_CODEC_CONSTRUCT(SII, 0x1390) #define HDA_CODEC_SII1392 HDA_CODEC_CONSTRUCT(SII, 0x1392) #define HDA_CODEC_SIIXXXX HDA_CODEC_CONSTRUCT(SII, 0xffff) /* Lucent/Agere */ #define AGERE_VENDORID 0x11c1 #define HDA_CODEC_AGEREXXXX HDA_CODEC_CONSTRUCT(AGERE, 0xffff) /* Conexant */ #define CONEXANT_VENDORID 0x14f1 #define HDA_CODEC_CX20549 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5045) #define HDA_CODEC_CX20551 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5047) #define HDA_CODEC_CX20561 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5051) #define HDA_CODEC_CX20582 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5066) #define HDA_CODEC_CX20583 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5067) #define HDA_CODEC_CX20584 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5068) #define HDA_CODEC_CX20585 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5069) #define HDA_CODEC_CX20588 HDA_CODEC_CONSTRUCT(CONEXANT, 0x506c) #define HDA_CODEC_CX20590 HDA_CODEC_CONSTRUCT(CONEXANT, 0x506e) #define HDA_CODEC_CX20631 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5097) #define HDA_CODEC_CX20632 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5098) #define HDA_CODEC_CX20641 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50a1) #define HDA_CODEC_CX20642 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50a2) #define HDA_CODEC_CX20651 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50ab) #define HDA_CODEC_CX20652 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50ac) #define HDA_CODEC_CX20664 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50b8) #define HDA_CODEC_CX20665 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50b9) #define HDA_CODEC_CX21722 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50f1) #define HDA_CODEC_CX20722 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50f2) #define HDA_CODEC_CX21724 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50f3) #define HDA_CODEC_CX20724 HDA_CODEC_CONSTRUCT(CONEXANT, 0x50f4) #define HDA_CODEC_CX20751 HDA_CODEC_CONSTRUCT(CONEXANT, 0x510f) #define HDA_CODEC_CX20751_2 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5110) #define HDA_CODEC_CX20753 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5111) #define HDA_CODEC_CX20755 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5113) #define HDA_CODEC_CX20756 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5114) #define HDA_CODEC_CX20757 HDA_CODEC_CONSTRUCT(CONEXANT, 0x5115) #define HDA_CODEC_CX20952 HDA_CODEC_CONSTRUCT(CONEXANT, 0x51d7) #define HDA_CODEC_CXXXXX HDA_CODEC_CONSTRUCT(CONEXANT, 0xffff) /* VIA */ #define HDA_CODEC_VT1708_8 HDA_CODEC_CONSTRUCT(VIA, 0x1708) #define HDA_CODEC_VT1708_9 HDA_CODEC_CONSTRUCT(VIA, 0x1709) #define HDA_CODEC_VT1708_A HDA_CODEC_CONSTRUCT(VIA, 0x170a) #define HDA_CODEC_VT1708_B HDA_CODEC_CONSTRUCT(VIA, 0x170b) #define HDA_CODEC_VT1709_0 HDA_CODEC_CONSTRUCT(VIA, 0xe710) #define HDA_CODEC_VT1709_1 HDA_CODEC_CONSTRUCT(VIA, 0xe711) #define HDA_CODEC_VT1709_2 HDA_CODEC_CONSTRUCT(VIA, 0xe712) #define HDA_CODEC_VT1709_3 HDA_CODEC_CONSTRUCT(VIA, 0xe713) #define HDA_CODEC_VT1709_4 HDA_CODEC_CONSTRUCT(VIA, 0xe714) #define HDA_CODEC_VT1709_5 HDA_CODEC_CONSTRUCT(VIA, 0xe715) #define HDA_CODEC_VT1709_6 HDA_CODEC_CONSTRUCT(VIA, 0xe716) #define HDA_CODEC_VT1709_7 HDA_CODEC_CONSTRUCT(VIA, 0xe717) #define HDA_CODEC_VT1708B_0 HDA_CODEC_CONSTRUCT(VIA, 0xe720) #define HDA_CODEC_VT1708B_1 HDA_CODEC_CONSTRUCT(VIA, 0xe721) #define HDA_CODEC_VT1708B_2 HDA_CODEC_CONSTRUCT(VIA, 0xe722) #define HDA_CODEC_VT1708B_3 HDA_CODEC_CONSTRUCT(VIA, 0xe723) #define HDA_CODEC_VT1708B_4 HDA_CODEC_CONSTRUCT(VIA, 0xe724) #define HDA_CODEC_VT1708B_5 HDA_CODEC_CONSTRUCT(VIA, 0xe725) #define HDA_CODEC_VT1708B_6 HDA_CODEC_CONSTRUCT(VIA, 0xe726) #define HDA_CODEC_VT1708B_7 HDA_CODEC_CONSTRUCT(VIA, 0xe727) #define HDA_CODEC_VT1708S_0 HDA_CODEC_CONSTRUCT(VIA, 0x0397) #define HDA_CODEC_VT1708S_1 HDA_CODEC_CONSTRUCT(VIA, 0x1397) #define HDA_CODEC_VT1708S_2 HDA_CODEC_CONSTRUCT(VIA, 0x2397) #define HDA_CODEC_VT1708S_3 HDA_CODEC_CONSTRUCT(VIA, 0x3397) #define HDA_CODEC_VT1708S_4 HDA_CODEC_CONSTRUCT(VIA, 0x4397) #define HDA_CODEC_VT1708S_5 HDA_CODEC_CONSTRUCT(VIA, 0x5397) #define HDA_CODEC_VT1708S_6 HDA_CODEC_CONSTRUCT(VIA, 0x6397) #define HDA_CODEC_VT1708S_7 HDA_CODEC_CONSTRUCT(VIA, 0x7397) #define HDA_CODEC_VT1702_0 HDA_CODEC_CONSTRUCT(VIA, 0x0398) #define HDA_CODEC_VT1702_1 HDA_CODEC_CONSTRUCT(VIA, 0x1398) #define HDA_CODEC_VT1702_2 HDA_CODEC_CONSTRUCT(VIA, 0x2398) #define HDA_CODEC_VT1702_3 HDA_CODEC_CONSTRUCT(VIA, 0x3398) #define HDA_CODEC_VT1702_4 HDA_CODEC_CONSTRUCT(VIA, 0x4398) #define HDA_CODEC_VT1702_5 HDA_CODEC_CONSTRUCT(VIA, 0x5398) #define HDA_CODEC_VT1702_6 HDA_CODEC_CONSTRUCT(VIA, 0x6398) #define HDA_CODEC_VT1702_7 HDA_CODEC_CONSTRUCT(VIA, 0x7398) #define HDA_CODEC_VT1716S_0 HDA_CODEC_CONSTRUCT(VIA, 0x0433) #define HDA_CODEC_VT1716S_1 HDA_CODEC_CONSTRUCT(VIA, 0xa721) #define HDA_CODEC_VT1718S_0 HDA_CODEC_CONSTRUCT(VIA, 0x0428) #define HDA_CODEC_VT1718S_1 HDA_CODEC_CONSTRUCT(VIA, 0x4428) #define HDA_CODEC_VT1802_0 HDA_CODEC_CONSTRUCT(VIA, 0x0446) #define HDA_CODEC_VT1802_1 HDA_CODEC_CONSTRUCT(VIA, 0x8446) #define HDA_CODEC_VT1812 HDA_CODEC_CONSTRUCT(VIA, 0x0448) #define HDA_CODEC_VT1818S HDA_CODEC_CONSTRUCT(VIA, 0x0440) #define HDA_CODEC_VT1828S HDA_CODEC_CONSTRUCT(VIA, 0x4441) #define HDA_CODEC_VT2002P_0 HDA_CODEC_CONSTRUCT(VIA, 0x0438) #define HDA_CODEC_VT2002P_1 HDA_CODEC_CONSTRUCT(VIA, 0x4438) #define HDA_CODEC_VT2020 HDA_CODEC_CONSTRUCT(VIA, 0x0441) #define HDA_CODEC_VTXXXX HDA_CODEC_CONSTRUCT(VIA, 0xffff) /* VMware */ #define HDA_CODEC_VMWARE HDA_CODEC_CONSTRUCT(VMWARE, 0x1975) #define HDA_CODEC_VMWAREXXXX HDA_CODEC_CONSTRUCT(VMWARE, 0xffff) /* ATI */ #define HDA_CODEC_ATIRS600_1 HDA_CODEC_CONSTRUCT(ATI, 0x793c) #define HDA_CODEC_ATIRS600_2 HDA_CODEC_CONSTRUCT(ATI, 0x7919) #define HDA_CODEC_ATIRS690 HDA_CODEC_CONSTRUCT(ATI, 0x791a) #define HDA_CODEC_ATIR6XX HDA_CODEC_CONSTRUCT(ATI, 0xaa01) #define HDA_CODEC_ATIXXXX HDA_CODEC_CONSTRUCT(ATI, 0xffff) /* NVIDIA */ #define HDA_CODEC_NVIDIAMCP78 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0002) #define HDA_CODEC_NVIDIAMCP78_2 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0003) #define HDA_CODEC_NVIDIAMCP78_3 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0005) #define HDA_CODEC_NVIDIAMCP78_4 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0006) #define HDA_CODEC_NVIDIAMCP7A HDA_CODEC_CONSTRUCT(NVIDIA, 0x0007) #define HDA_CODEC_NVIDIAGT220 HDA_CODEC_CONSTRUCT(NVIDIA, 0x000a) #define HDA_CODEC_NVIDIAGT21X HDA_CODEC_CONSTRUCT(NVIDIA, 0x000b) #define HDA_CODEC_NVIDIAMCP89 HDA_CODEC_CONSTRUCT(NVIDIA, 0x000c) #define HDA_CODEC_NVIDIAGT240 HDA_CODEC_CONSTRUCT(NVIDIA, 0x000d) #define HDA_CODEC_NVIDIAGTS450 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0011) #define HDA_CODEC_NVIDIAGT440 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0014) #define HDA_CODEC_NVIDIAGTX550 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0015) #define HDA_CODEC_NVIDIAGTX570 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0018) #define HDA_CODEC_NVIDIATEGRA30 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0020) #define HDA_CODEC_NVIDIATEGRA114 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0022) #define HDA_CODEC_NVIDIATEGRA124 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0028) #define HDA_CODEC_NVIDIATEGRA210 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0029) #define HDA_CODEC_NVIDIAMCP67 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0067) #define HDA_CODEC_NVIDIAGM204 HDA_CODEC_CONSTRUCT(NVIDIA, 0x0071) #define HDA_CODEC_NVIDIAMCP73 HDA_CODEC_CONSTRUCT(NVIDIA, 0x8001) #define HDA_CODEC_NVIDIAXXXX HDA_CODEC_CONSTRUCT(NVIDIA, 0xffff) /* Chrontel */ #define CHRONTEL_VENDORID 0x17e8 #define HDA_CODEC_CHXXXX HDA_CODEC_CONSTRUCT(CHRONTEL, 0xffff) /* INTEL */ #define HDA_CODEC_INTELIP HDA_CODEC_CONSTRUCT(INTEL, 0x0054) #define HDA_CODEC_INTELGMLK HDA_CODEC_CONSTRUCT(INTEL, 0x2800) #define HDA_CODEC_INTELBL HDA_CODEC_CONSTRUCT(INTEL, 0x2801) #define HDA_CODEC_INTELCA HDA_CODEC_CONSTRUCT(INTEL, 0x2802) #define HDA_CODEC_INTELEL HDA_CODEC_CONSTRUCT(INTEL, 0x2803) #define HDA_CODEC_INTELIP2 HDA_CODEC_CONSTRUCT(INTEL, 0x2804) #define HDA_CODEC_INTELCPT HDA_CODEC_CONSTRUCT(INTEL, 0x2805) #define HDA_CODEC_INTELPPT HDA_CODEC_CONSTRUCT(INTEL, 0x2806) #define HDA_CODEC_INTELHSW HDA_CODEC_CONSTRUCT(INTEL, 0x2807) #define HDA_CODEC_INTELBDW HDA_CODEC_CONSTRUCT(INTEL, 0x2808) #define HDA_CODEC_INTELSKLK HDA_CODEC_CONSTRUCT(INTEL, 0x2809) #define HDA_CODEC_INTELBXTN HDA_CODEC_CONSTRUCT(INTEL, 0x280a) #define HDA_CODEC_INTELKBLK HDA_CODEC_CONSTRUCT(INTEL, 0x280b) #define HDA_CODEC_INTELCNLK HDA_CODEC_CONSTRUCT(INTEL, 0x280c) #define HDA_CODEC_INTELGMLK1 HDA_CODEC_CONSTRUCT(INTEL, 0x280d) #define HDA_CODEC_INTELICLK HDA_CODEC_CONSTRUCT(INTEL, 0x280f) #define HDA_CODEC_INTELTGLK HDA_CODEC_CONSTRUCT(INTEL, 0x2812) #define HDA_CODEC_INTELTGLKH HDA_CODEC_CONSTRUCT(INTEL, 0x2814) #define HDA_CODEC_INTELALLK HDA_CODEC_CONSTRUCT(INTEL, 0x2815) #define HDA_CODEC_INTELJLK HDA_CODEC_CONSTRUCT(INTEL, 0x281a) #define HDA_CODEC_INTELELLK HDA_CODEC_CONSTRUCT(INTEL, 0x281b) #define HDA_CODEC_INTELCT HDA_CODEC_CONSTRUCT(INTEL, 0x2880) #define HDA_CODEC_INTELVV2 HDA_CODEC_CONSTRUCT(INTEL, 0x2882) #define HDA_CODEC_INTELBR HDA_CODEC_CONSTRUCT(INTEL, 0x2883) #define HDA_CODEC_INTELCL HDA_CODEC_CONSTRUCT(INTEL, 0x29fb) #define HDA_CODEC_INTELXXXX HDA_CODEC_CONSTRUCT(INTEL, 0xffff) /**************************************************************************** * Helper Macros ****************************************************************************/ #define HDA_DMA_ALIGNMENT 128 #define HDA_BDL_MIN 2 #define HDA_BDL_MAX 256 #define HDA_BDL_DEFAULT HDA_BDL_MIN #define HDA_BLK_MIN HDA_DMA_ALIGNMENT #define HDA_BLK_ALIGN (~(HDA_BLK_MIN - 1)) #define HDA_BUFSZ_MIN (HDA_BDL_MIN * HDA_BLK_MIN) #define HDA_BUFSZ_MAX 262144 #define HDA_BUFSZ_DEFAULT 65536 #define HDA_GPIO_MAX 8 #define HDA_DEV_MATCH(fl, v) ((fl) == (v) || \ (fl) == 0xffffffff || \ (((fl) & 0xffff0000) == 0xffff0000 && \ ((fl) & 0x0000ffff) == ((v) & 0x0000ffff)) || \ (((fl) & 0x0000ffff) == 0x0000ffff && \ ((fl) & 0xffff0000) == ((v) & 0xffff0000))) #define HDA_MATCH_ALL 0xffffffff #define HDA_INVALID 0xffffffff #define HDA_BOOTVERBOSE(stmt) do { \ if (bootverbose != 0 || snd_verbose > 3) { \ stmt \ } \ } while (0) #define HDA_BOOTHVERBOSE(stmt) do { \ if (snd_verbose > 3) { \ stmt \ } \ } while (0) #define hda_command(dev, verb) \ HDAC_CODEC_COMMAND(device_get_parent(dev), (dev), (verb)) typedef int nid_t; /**************************************************************************** * Simplified Accessors for HDA devices ****************************************************************************/ enum hdac_device_ivars { HDA_IVAR_CODEC_ID, HDA_IVAR_NODE_ID, HDA_IVAR_VENDOR_ID, HDA_IVAR_DEVICE_ID, HDA_IVAR_REVISION_ID, HDA_IVAR_STEPPING_ID, HDA_IVAR_SUBVENDOR_ID, HDA_IVAR_SUBDEVICE_ID, HDA_IVAR_SUBSYSTEM_ID, HDA_IVAR_NODE_TYPE, HDA_IVAR_DMA_NOCACHE, HDA_IVAR_STRIPES_MASK, }; #define HDA_ACCESSOR(var, ivar, type) \ __BUS_ACCESSOR(hda, var, HDA, ivar, type) HDA_ACCESSOR(codec_id, CODEC_ID, uint8_t); HDA_ACCESSOR(node_id, NODE_ID, uint8_t); HDA_ACCESSOR(vendor_id, VENDOR_ID, uint16_t); HDA_ACCESSOR(device_id, DEVICE_ID, uint16_t); HDA_ACCESSOR(revision_id, REVISION_ID, uint8_t); HDA_ACCESSOR(stepping_id, STEPPING_ID, uint8_t); HDA_ACCESSOR(subvendor_id, SUBVENDOR_ID, uint16_t); HDA_ACCESSOR(subdevice_id, SUBDEVICE_ID, uint16_t); HDA_ACCESSOR(subsystem_id, SUBSYSTEM_ID, uint32_t); HDA_ACCESSOR(node_type, NODE_TYPE, uint8_t); HDA_ACCESSOR(dma_nocache, DMA_NOCACHE, uint8_t); HDA_ACCESSOR(stripes_mask, STRIPES_MASK, uint8_t); #define PCIS_MULTIMEDIA_HDA 0x03 #endif diff --git a/sys/dev/sound/pci/hda/hdacc.c b/sys/dev/sound/pci/hda/hdacc.c index b4321a5bf998..4198982c9c2a 100644 --- a/sys/dev/sound/pci/hda/hdacc.c +++ b/sys/dev/sound/pci/hda/hdacc.c @@ -1,802 +1,803 @@ /*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2006 Stephane E. Potvin * Copyright (c) 2006 Ariff Abdullah * Copyright (c) 2008-2012 Alexander Motin * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * Intel High Definition Audio (CODEC) driver for FreeBSD. */ #ifdef HAVE_KERNEL_OPTION_HEADERS #include "opt_snd.h" #endif #include #include #include #include struct hdacc_fg { device_t dev; nid_t nid; uint8_t type; uint32_t subsystem_id; }; struct hdacc_softc { device_t dev; struct mtx *lock; nid_t cad; device_t streams[2][16]; device_t tags[64]; int fgcnt; struct hdacc_fg *fgs; }; #define hdacc_lock(codec) snd_mtxlock((codec)->lock) #define hdacc_unlock(codec) snd_mtxunlock((codec)->lock) #define hdacc_lockassert(codec) snd_mtxassert((codec)->lock) MALLOC_DEFINE(M_HDACC, "hdacc", "HDA CODEC"); /* CODECs */ static const struct { uint32_t id; uint16_t revid; const char *name; } hdacc_codecs[] = { { HDA_CODEC_CS4206, 0, "Cirrus Logic CS4206" }, { HDA_CODEC_CS4207, 0, "Cirrus Logic CS4207" }, + { HDA_CODEC_CS4208, 0, "Cirrus Logic CS4208" }, { HDA_CODEC_CS4210, 0, "Cirrus Logic CS4210" }, { HDA_CODEC_ALC215, 0, "Realtek ALC215" }, { HDA_CODEC_ALC221, 0, "Realtek ALC221" }, { HDA_CODEC_ALC222, 0, "Realtek ALC222" }, { HDA_CODEC_ALC225, 0, "Realtek ALC225" }, { HDA_CODEC_ALC230, 0, "Realtek ALC230" }, { HDA_CODEC_ALC231, 0, "Realtek ALC231" }, { HDA_CODEC_ALC233, 0, "Realtek ALC233" }, { HDA_CODEC_ALC234, 0, "Realtek ALC234" }, { HDA_CODEC_ALC235, 0, "Realtek ALC235" }, { HDA_CODEC_ALC236, 0, "Realtek ALC236" }, { HDA_CODEC_ALC245, 0, "Realtek ALC245" }, { HDA_CODEC_ALC255, 0, "Realtek ALC255" }, { HDA_CODEC_ALC256, 0, "Realtek ALC256" }, { HDA_CODEC_ALC257, 0, "Realtek ALC257" }, { HDA_CODEC_ALC260, 0, "Realtek ALC260" }, { HDA_CODEC_ALC262, 0, "Realtek ALC262" }, { HDA_CODEC_ALC267, 0, "Realtek ALC267" }, { HDA_CODEC_ALC268, 0, "Realtek ALC268" }, { HDA_CODEC_ALC269, 0, "Realtek ALC269" }, { HDA_CODEC_ALC270, 0, "Realtek ALC270" }, { HDA_CODEC_ALC272, 0, "Realtek ALC272" }, { HDA_CODEC_ALC273, 0, "Realtek ALC273" }, { HDA_CODEC_ALC274, 0, "Realtek ALC274" }, { HDA_CODEC_ALC275, 0, "Realtek ALC275" }, { HDA_CODEC_ALC276, 0, "Realtek ALC276" }, { HDA_CODEC_ALC292, 0, "Realtek ALC292" }, { HDA_CODEC_ALC295, 0, "Realtek ALC295" }, { HDA_CODEC_ALC280, 0, "Realtek ALC280" }, { HDA_CODEC_ALC282, 0, "Realtek ALC282" }, { HDA_CODEC_ALC283, 0, "Realtek ALC283" }, { HDA_CODEC_ALC284, 0, "Realtek ALC284" }, { HDA_CODEC_ALC285, 0, "Realtek ALC285" }, { HDA_CODEC_ALC286, 0, "Realtek ALC286" }, { HDA_CODEC_ALC288, 0, "Realtek ALC288" }, { HDA_CODEC_ALC289, 0, "Realtek ALC289" }, { HDA_CODEC_ALC290, 0, "Realtek ALC290" }, { HDA_CODEC_ALC292, 0, "Realtek ALC292" }, { HDA_CODEC_ALC293, 0, "Realtek ALC293" }, { HDA_CODEC_ALC294, 0, "Realtek ALC294" }, { HDA_CODEC_ALC295, 0, "Realtek ALC295" }, { HDA_CODEC_ALC298, 0, "Realtek ALC298" }, { HDA_CODEC_ALC299, 0, "Realtek ALC299" }, { HDA_CODEC_ALC300, 0, "Realtek ALC300" }, { HDA_CODEC_ALC623, 0, "Realtek ALC623" }, { HDA_CODEC_ALC660, 0, "Realtek ALC660-VD" }, { HDA_CODEC_ALC662, 0x0002, "Realtek ALC662 rev2" }, { HDA_CODEC_ALC662, 0x0101, "Realtek ALC662 rev1" }, { HDA_CODEC_ALC662, 0x0300, "Realtek ALC662 rev3" }, { HDA_CODEC_ALC662, 0, "Realtek ALC662" }, { HDA_CODEC_ALC663, 0, "Realtek ALC663" }, { HDA_CODEC_ALC665, 0, "Realtek ALC665" }, { HDA_CODEC_ALC670, 0, "Realtek ALC670" }, { HDA_CODEC_ALC671, 0, "Realtek ALC671" }, { HDA_CODEC_ALC680, 0, "Realtek ALC680" }, { HDA_CODEC_ALC700, 0, "Realtek ALC700" }, { HDA_CODEC_ALC701, 0, "Realtek ALC701" }, { HDA_CODEC_ALC703, 0, "Realtek ALC703" }, { HDA_CODEC_ALC861, 0x0340, "Realtek ALC660" }, { HDA_CODEC_ALC861, 0, "Realtek ALC861" }, { HDA_CODEC_ALC861VD, 0, "Realtek ALC861-VD" }, { HDA_CODEC_ALC880, 0, "Realtek ALC880" }, { HDA_CODEC_ALC882, 0, "Realtek ALC882" }, { HDA_CODEC_ALC883, 0, "Realtek ALC883" }, { HDA_CODEC_ALC885, 0x0101, "Realtek ALC889A" }, { HDA_CODEC_ALC885, 0x0103, "Realtek ALC889A" }, { HDA_CODEC_ALC885, 0, "Realtek ALC885" }, { HDA_CODEC_ALC887, 0, "Realtek ALC887" }, { HDA_CODEC_ALC888, 0x0101, "Realtek ALC1200" }, { HDA_CODEC_ALC888, 0, "Realtek ALC888" }, { HDA_CODEC_ALC889, 0, "Realtek ALC889" }, { HDA_CODEC_ALC892, 0, "Realtek ALC892" }, { HDA_CODEC_ALC897, 0, "Realtek ALC897" }, { HDA_CODEC_ALC898, 0, "Realtek ALC898" }, { HDA_CODEC_ALC899, 0, "Realtek ALC899" }, { HDA_CODEC_ALC1150, 0, "Realtek ALC1150" }, { HDA_CODEC_ALCS1200A, 0, "Realtek ALCS1200A" }, { HDA_CODEC_ALC1220_1, 0, "Realtek ALC1220" }, { HDA_CODEC_ALC1220, 0, "Realtek ALC1220" }, { HDA_CODEC_AD1882, 0, "Analog Devices AD1882" }, { HDA_CODEC_AD1882A, 0, "Analog Devices AD1882A" }, { HDA_CODEC_AD1883, 0, "Analog Devices AD1883" }, { HDA_CODEC_AD1884, 0, "Analog Devices AD1884" }, { HDA_CODEC_AD1884A, 0, "Analog Devices AD1884A" }, { HDA_CODEC_AD1981HD, 0, "Analog Devices AD1981HD" }, { HDA_CODEC_AD1983, 0, "Analog Devices AD1983" }, { HDA_CODEC_AD1984, 0, "Analog Devices AD1984" }, { HDA_CODEC_AD1984A, 0, "Analog Devices AD1984A" }, { HDA_CODEC_AD1984B, 0, "Analog Devices AD1984B" }, { HDA_CODEC_AD1986A, 0, "Analog Devices AD1986A" }, { HDA_CODEC_AD1987, 0, "Analog Devices AD1987" }, { HDA_CODEC_AD1988, 0, "Analog Devices AD1988A" }, { HDA_CODEC_AD1988B, 0, "Analog Devices AD1988B" }, { HDA_CODEC_AD1989A, 0, "Analog Devices AD1989A" }, { HDA_CODEC_AD1989B, 0, "Analog Devices AD1989B" }, { HDA_CODEC_CA0110, 0, "Creative CA0110-IBG" }, { HDA_CODEC_CA0110_2, 0, "Creative CA0110-IBG" }, { HDA_CODEC_CA0132, 0, "Creative CA0132" }, { HDA_CODEC_SB0880, 0, "Creative SB0880 X-Fi" }, { HDA_CODEC_CMI9880, 0, "CMedia CMI9880" }, { HDA_CODEC_CMI98802, 0, "CMedia CMI9880" }, { HDA_CODEC_CXD9872RDK, 0, "Sigmatel CXD9872RD/K" }, { HDA_CODEC_CXD9872AKD, 0, "Sigmatel CXD9872AKD" }, { HDA_CODEC_STAC9200D, 0, "Sigmatel STAC9200D" }, { HDA_CODEC_STAC9204X, 0, "Sigmatel STAC9204X" }, { HDA_CODEC_STAC9204D, 0, "Sigmatel STAC9204D" }, { HDA_CODEC_STAC9205X, 0, "Sigmatel STAC9205X" }, { HDA_CODEC_STAC9205D, 0, "Sigmatel STAC9205D" }, { HDA_CODEC_STAC9220, 0, "Sigmatel STAC9220" }, { HDA_CODEC_STAC9220_A1, 0, "Sigmatel STAC9220_A1" }, { HDA_CODEC_STAC9220_A2, 0, "Sigmatel STAC9220_A2" }, { HDA_CODEC_STAC9221, 0, "Sigmatel STAC9221" }, { HDA_CODEC_STAC9221_A2, 0, "Sigmatel STAC9221_A2" }, { HDA_CODEC_STAC9221D, 0, "Sigmatel STAC9221D" }, { HDA_CODEC_STAC922XD, 0, "Sigmatel STAC9220D/9223D" }, { HDA_CODEC_STAC9227X, 0, "Sigmatel STAC9227X" }, { HDA_CODEC_STAC9227D, 0, "Sigmatel STAC9227D" }, { HDA_CODEC_STAC9228X, 0, "Sigmatel STAC9228X" }, { HDA_CODEC_STAC9228D, 0, "Sigmatel STAC9228D" }, { HDA_CODEC_STAC9229X, 0, "Sigmatel STAC9229X" }, { HDA_CODEC_STAC9229D, 0, "Sigmatel STAC9229D" }, { HDA_CODEC_STAC9230X, 0, "Sigmatel STAC9230X" }, { HDA_CODEC_STAC9230D, 0, "Sigmatel STAC9230D" }, { HDA_CODEC_STAC9250, 0, "Sigmatel STAC9250" }, { HDA_CODEC_STAC9251, 0, "Sigmatel STAC9251" }, { HDA_CODEC_STAC9255, 0, "Sigmatel STAC9255" }, { HDA_CODEC_STAC9255D, 0, "Sigmatel STAC9255D" }, { HDA_CODEC_STAC9254, 0, "Sigmatel STAC9254" }, { HDA_CODEC_STAC9254D, 0, "Sigmatel STAC9254D" }, { HDA_CODEC_STAC9271X, 0, "Sigmatel STAC9271X" }, { HDA_CODEC_STAC9271D, 0, "Sigmatel STAC9271D" }, { HDA_CODEC_STAC9272X, 0, "Sigmatel STAC9272X" }, { HDA_CODEC_STAC9272D, 0, "Sigmatel STAC9272D" }, { HDA_CODEC_STAC9273X, 0, "Sigmatel STAC9273X" }, { HDA_CODEC_STAC9273D, 0, "Sigmatel STAC9273D" }, { HDA_CODEC_STAC9274, 0, "Sigmatel STAC9274" }, { HDA_CODEC_STAC9274D, 0, "Sigmatel STAC9274D" }, { HDA_CODEC_STAC9274X5NH, 0, "Sigmatel STAC9274X5NH" }, { HDA_CODEC_STAC9274D5NH, 0, "Sigmatel STAC9274D5NH" }, { HDA_CODEC_STAC9872AK, 0, "Sigmatel STAC9872AK" }, { HDA_CODEC_IDT92HD005, 0, "IDT 92HD005" }, { HDA_CODEC_IDT92HD005D, 0, "IDT 92HD005D" }, { HDA_CODEC_IDT92HD206X, 0, "IDT 92HD206X" }, { HDA_CODEC_IDT92HD206D, 0, "IDT 92HD206D" }, { HDA_CODEC_IDT92HD66B1X5, 0, "IDT 92HD66B1X5" }, { HDA_CODEC_IDT92HD66B2X5, 0, "IDT 92HD66B2X5" }, { HDA_CODEC_IDT92HD66B3X5, 0, "IDT 92HD66B3X5" }, { HDA_CODEC_IDT92HD66C1X5, 0, "IDT 92HD66C1X5" }, { HDA_CODEC_IDT92HD66C2X5, 0, "IDT 92HD66C2X5" }, { HDA_CODEC_IDT92HD66C3X5, 0, "IDT 92HD66C3X5" }, { HDA_CODEC_IDT92HD66B1X3, 0, "IDT 92HD66B1X3" }, { HDA_CODEC_IDT92HD66B2X3, 0, "IDT 92HD66B2X3" }, { HDA_CODEC_IDT92HD66B3X3, 0, "IDT 92HD66B3X3" }, { HDA_CODEC_IDT92HD66C1X3, 0, "IDT 92HD66C1X3" }, { HDA_CODEC_IDT92HD66C2X3, 0, "IDT 92HD66C2X3" }, { HDA_CODEC_IDT92HD66C3_65, 0, "IDT 92HD66C3_65" }, { HDA_CODEC_IDT92HD700X, 0, "IDT 92HD700X" }, { HDA_CODEC_IDT92HD700D, 0, "IDT 92HD700D" }, { HDA_CODEC_IDT92HD71B5, 0, "IDT 92HD71B5" }, { HDA_CODEC_IDT92HD71B5_2, 0, "IDT 92HD71B5" }, { HDA_CODEC_IDT92HD71B6, 0, "IDT 92HD71B6" }, { HDA_CODEC_IDT92HD71B6_2, 0, "IDT 92HD71B6" }, { HDA_CODEC_IDT92HD71B7, 0, "IDT 92HD71B7" }, { HDA_CODEC_IDT92HD71B7_2, 0, "IDT 92HD71B7" }, { HDA_CODEC_IDT92HD71B8, 0, "IDT 92HD71B8" }, { HDA_CODEC_IDT92HD71B8_2, 0, "IDT 92HD71B8" }, { HDA_CODEC_IDT92HD73C1, 0, "IDT 92HD73C1" }, { HDA_CODEC_IDT92HD73D1, 0, "IDT 92HD73D1" }, { HDA_CODEC_IDT92HD73E1, 0, "IDT 92HD73E1" }, { HDA_CODEC_IDT92HD75B3, 0, "IDT 92HD75B3" }, { HDA_CODEC_IDT92HD75BX, 0, "IDT 92HD75BX" }, { HDA_CODEC_IDT92HD81B1C, 0, "IDT 92HD81B1C" }, { HDA_CODEC_IDT92HD81B1X, 0, "IDT 92HD81B1X" }, { HDA_CODEC_IDT92HD83C1C, 0, "IDT 92HD83C1C" }, { HDA_CODEC_IDT92HD83C1X, 0, "IDT 92HD83C1X" }, { HDA_CODEC_IDT92HD87B1_3, 0, "IDT 92HD87B1/3" }, { HDA_CODEC_IDT92HD87B2_4, 0, "IDT 92HD87B2/4" }, { HDA_CODEC_IDT92HD89C3, 0, "IDT 92HD89C3" }, { HDA_CODEC_IDT92HD89C2, 0, "IDT 92HD89C2" }, { HDA_CODEC_IDT92HD89C1, 0, "IDT 92HD89C1" }, { HDA_CODEC_IDT92HD89B3, 0, "IDT 92HD89B3" }, { HDA_CODEC_IDT92HD89B2, 0, "IDT 92HD89B2" }, { HDA_CODEC_IDT92HD89B1, 0, "IDT 92HD89B1" }, { HDA_CODEC_IDT92HD89E3, 0, "IDT 92HD89E3" }, { HDA_CODEC_IDT92HD89E2, 0, "IDT 92HD89E2" }, { HDA_CODEC_IDT92HD89E1, 0, "IDT 92HD89E1" }, { HDA_CODEC_IDT92HD89D3, 0, "IDT 92HD89D3" }, { HDA_CODEC_IDT92HD89D2, 0, "IDT 92HD89D2" }, { HDA_CODEC_IDT92HD89D1, 0, "IDT 92HD89D1" }, { HDA_CODEC_IDT92HD89F3, 0, "IDT 92HD89F3" }, { HDA_CODEC_IDT92HD89F2, 0, "IDT 92HD89F2" }, { HDA_CODEC_IDT92HD89F1, 0, "IDT 92HD89F1" }, { HDA_CODEC_IDT92HD90BXX, 0, "IDT 92HD90BXX" }, { HDA_CODEC_IDT92HD91BXX, 0, "IDT 92HD91BXX" }, { HDA_CODEC_IDT92HD93BXX, 0, "IDT 92HD93BXX" }, { HDA_CODEC_IDT92HD95B, 0, "Tempo 92HD95B" }, { HDA_CODEC_IDT92HD98BXX, 0, "IDT 92HD98BXX" }, { HDA_CODEC_IDT92HD99BXX, 0, "IDT 92HD99BXX" }, { HDA_CODEC_CX20549, 0, "Conexant CX20549 (Venice)" }, { HDA_CODEC_CX20551, 0, "Conexant CX20551 (Waikiki)" }, { HDA_CODEC_CX20561, 0, "Conexant CX20561 (Hermosa)" }, { HDA_CODEC_CX20582, 0, "Conexant CX20582 (Pebble)" }, { HDA_CODEC_CX20583, 0, "Conexant CX20583 (Pebble HSF)" }, { HDA_CODEC_CX20584, 0, "Conexant CX20584" }, { HDA_CODEC_CX20585, 0, "Conexant CX20585" }, { HDA_CODEC_CX20588, 0, "Conexant CX20588" }, { HDA_CODEC_CX20590, 0, "Conexant CX20590" }, { HDA_CODEC_CX20631, 0, "Conexant CX20631" }, { HDA_CODEC_CX20632, 0, "Conexant CX20632" }, { HDA_CODEC_CX20641, 0, "Conexant CX20641" }, { HDA_CODEC_CX20642, 0, "Conexant CX20642" }, { HDA_CODEC_CX20651, 0, "Conexant CX20651" }, { HDA_CODEC_CX20652, 0, "Conexant CX20652" }, { HDA_CODEC_CX20664, 0, "Conexant CX20664" }, { HDA_CODEC_CX20665, 0, "Conexant CX20665" }, { HDA_CODEC_CX21722, 0, "Conexant CX21722" }, { HDA_CODEC_CX20722, 0, "Conexant CX20722" }, { HDA_CODEC_CX21724, 0, "Conexant CX21724" }, { HDA_CODEC_CX20724, 0, "Conexant CX20724" }, { HDA_CODEC_CX20751, 0, "Conexant CX20751/2" }, { HDA_CODEC_CX20751_2, 0, "Conexant CX20751/2" }, { HDA_CODEC_CX20753, 0, "Conexant CX20753/4" }, { HDA_CODEC_CX20755, 0, "Conexant CX20755" }, { HDA_CODEC_CX20756, 0, "Conexant CX20756" }, { HDA_CODEC_CX20757, 0, "Conexant CX20757" }, { HDA_CODEC_CX20952, 0, "Conexant CX20952" }, { HDA_CODEC_VT1708_8, 0, "VIA VT1708_8" }, { HDA_CODEC_VT1708_9, 0, "VIA VT1708_9" }, { HDA_CODEC_VT1708_A, 0, "VIA VT1708_A" }, { HDA_CODEC_VT1708_B, 0, "VIA VT1708_B" }, { HDA_CODEC_VT1709_0, 0, "VIA VT1709_0" }, { HDA_CODEC_VT1709_1, 0, "VIA VT1709_1" }, { HDA_CODEC_VT1709_2, 0, "VIA VT1709_2" }, { HDA_CODEC_VT1709_3, 0, "VIA VT1709_3" }, { HDA_CODEC_VT1709_4, 0, "VIA VT1709_4" }, { HDA_CODEC_VT1709_5, 0, "VIA VT1709_5" }, { HDA_CODEC_VT1709_6, 0, "VIA VT1709_6" }, { HDA_CODEC_VT1709_7, 0, "VIA VT1709_7" }, { HDA_CODEC_VT1708B_0, 0, "VIA VT1708B_0" }, { HDA_CODEC_VT1708B_1, 0, "VIA VT1708B_1" }, { HDA_CODEC_VT1708B_2, 0, "VIA VT1708B_2" }, { HDA_CODEC_VT1708B_3, 0, "VIA VT1708B_3" }, { HDA_CODEC_VT1708B_4, 0, "VIA VT1708B_4" }, { HDA_CODEC_VT1708B_5, 0, "VIA VT1708B_5" }, { HDA_CODEC_VT1708B_6, 0, "VIA VT1708B_6" }, { HDA_CODEC_VT1708B_7, 0, "VIA VT1708B_7" }, { HDA_CODEC_VT1708S_0, 0, "VIA VT1708S_0" }, { HDA_CODEC_VT1708S_1, 0, "VIA VT1708S_1" }, { HDA_CODEC_VT1708S_2, 0, "VIA VT1708S_2" }, { HDA_CODEC_VT1708S_3, 0, "VIA VT1708S_3" }, { HDA_CODEC_VT1708S_4, 0, "VIA VT1708S_4" }, { HDA_CODEC_VT1708S_5, 0, "VIA VT1708S_5" }, { HDA_CODEC_VT1708S_6, 0, "VIA VT1708S_6" }, { HDA_CODEC_VT1708S_7, 0, "VIA VT1708S_7" }, { HDA_CODEC_VT1702_0, 0, "VIA VT1702_0" }, { HDA_CODEC_VT1702_1, 0, "VIA VT1702_1" }, { HDA_CODEC_VT1702_2, 0, "VIA VT1702_2" }, { HDA_CODEC_VT1702_3, 0, "VIA VT1702_3" }, { HDA_CODEC_VT1702_4, 0, "VIA VT1702_4" }, { HDA_CODEC_VT1702_5, 0, "VIA VT1702_5" }, { HDA_CODEC_VT1702_6, 0, "VIA VT1702_6" }, { HDA_CODEC_VT1702_7, 0, "VIA VT1702_7" }, { HDA_CODEC_VT1716S_0, 0, "VIA VT1716S_0" }, { HDA_CODEC_VT1716S_1, 0, "VIA VT1716S_1" }, { HDA_CODEC_VT1718S_0, 0, "VIA VT1718S_0" }, { HDA_CODEC_VT1718S_1, 0, "VIA VT1718S_1" }, { HDA_CODEC_VT1802_0, 0, "VIA VT1802_0" }, { HDA_CODEC_VT1802_1, 0, "VIA VT1802_1" }, { HDA_CODEC_VT1812, 0, "VIA VT1812" }, { HDA_CODEC_VT1818S, 0, "VIA VT1818S" }, { HDA_CODEC_VT1828S, 0, "VIA VT1828S" }, { HDA_CODEC_VT2002P_0, 0, "VIA VT2002P_0" }, { HDA_CODEC_VT2002P_1, 0, "VIA VT2002P_1" }, { HDA_CODEC_VT2020, 0, "VIA VT2020" }, { HDA_CODEC_ATIRS600_1, 0, "ATI RS600" }, { HDA_CODEC_ATIRS600_2, 0, "ATI RS600" }, { HDA_CODEC_ATIRS690, 0, "ATI RS690/780" }, { HDA_CODEC_ATIR6XX, 0, "ATI R6xx" }, { HDA_CODEC_NVIDIAMCP67, 0, "NVIDIA MCP67" }, { HDA_CODEC_NVIDIAMCP73, 0, "NVIDIA MCP73" }, { HDA_CODEC_NVIDIAMCP78, 0, "NVIDIA MCP78" }, { HDA_CODEC_NVIDIAMCP78_2, 0, "NVIDIA MCP78" }, { HDA_CODEC_NVIDIAMCP78_3, 0, "NVIDIA MCP78" }, { HDA_CODEC_NVIDIAMCP78_4, 0, "NVIDIA MCP78" }, { HDA_CODEC_NVIDIAMCP7A, 0, "NVIDIA MCP7A" }, { HDA_CODEC_NVIDIAGM204, 0, "NVIDIA GM204" }, { HDA_CODEC_NVIDIAGT220, 0, "NVIDIA GT220" }, { HDA_CODEC_NVIDIAGT21X, 0, "NVIDIA GT21x" }, { HDA_CODEC_NVIDIAMCP89, 0, "NVIDIA MCP89" }, { HDA_CODEC_NVIDIAGT240, 0, "NVIDIA GT240" }, { HDA_CODEC_NVIDIAGTS450, 0, "NVIDIA GTS450" }, { HDA_CODEC_NVIDIAGT440, 0, "NVIDIA GT440" }, { HDA_CODEC_NVIDIAGTX550, 0, "NVIDIA GTX550" }, { HDA_CODEC_NVIDIAGTX570, 0, "NVIDIA GTX570" }, { HDA_CODEC_NVIDIATEGRA30, 0, "NVIDIA Tegra30" }, { HDA_CODEC_NVIDIATEGRA114, 0, "NVIDIA Tegra114" }, { HDA_CODEC_NVIDIATEGRA124, 0, "NVIDIA Tegra124" }, { HDA_CODEC_NVIDIATEGRA210, 0, "NVIDIA Tegra210" }, { HDA_CODEC_INTELIP, 0, "Intel Ibex Peak" }, { HDA_CODEC_INTELBL, 0, "Intel Bearlake" }, { HDA_CODEC_INTELCA, 0, "Intel Cantiga" }, { HDA_CODEC_INTELEL, 0, "Intel Eaglelake" }, { HDA_CODEC_INTELIP2, 0, "Intel Ibex Peak" }, { HDA_CODEC_INTELCPT, 0, "Intel Cougar Point" }, { HDA_CODEC_INTELPPT, 0, "Intel Panther Point" }, { HDA_CODEC_INTELHSW, 0, "Intel Haswell" }, { HDA_CODEC_INTELBDW, 0, "Intel Broadwell" }, { HDA_CODEC_INTELSKLK, 0, "Intel Skylake" }, { HDA_CODEC_INTELKBLK, 0, "Intel Kaby Lake" }, { HDA_CODEC_INTELJLK, 0, "Intel Jasper Lake" }, { HDA_CODEC_INTELELLK, 0, "Intel Elkhart Lake" }, { HDA_CODEC_INTELCT, 0, "Intel Cedar Trail" }, { HDA_CODEC_INTELVV2, 0, "Intel Valleyview2" }, { HDA_CODEC_INTELBR, 0, "Intel Braswell" }, { HDA_CODEC_INTELCL, 0, "Intel Crestline" }, { HDA_CODEC_INTELBXTN, 0, "Intel Broxton" }, { HDA_CODEC_INTELCNLK, 0, "Intel Cannon Lake" }, { HDA_CODEC_INTELGMLK, 0, "Intel Gemini Lake" }, { HDA_CODEC_INTELGMLK1, 0, "Intel Gemini Lake" }, { HDA_CODEC_INTELICLK, 0, "Intel Ice Lake" }, { HDA_CODEC_INTELTGLK, 0, "Intel Tiger Lake" }, { HDA_CODEC_INTELTGLKH, 0, "Intel Tiger Lake-H" }, { HDA_CODEC_INTELALLK, 0, "Intel Alder Lake" }, { HDA_CODEC_SII1390, 0, "Silicon Image SiI1390" }, { HDA_CODEC_SII1392, 0, "Silicon Image SiI1392" }, { HDA_CODEC_VMWARE, 0, "VMware" }, /* Unknown CODECs */ { HDA_CODEC_ADXXXX, 0, "Analog Devices" }, { HDA_CODEC_AGEREXXXX, 0, "Lucent/Agere Systems" }, { HDA_CODEC_ALCXXXX, 0, "Realtek" }, { HDA_CODEC_ATIXXXX, 0, "ATI" }, { HDA_CODEC_CAXXXX, 0, "Creative" }, { HDA_CODEC_CMIXXXX, 0, "CMedia" }, { HDA_CODEC_CMIXXXX2, 0, "CMedia" }, { HDA_CODEC_CSXXXX, 0, "Cirrus Logic" }, { HDA_CODEC_CXXXXX, 0, "Conexant" }, { HDA_CODEC_CHXXXX, 0, "Chrontel" }, { HDA_CODEC_IDTXXXX, 0, "IDT" }, { HDA_CODEC_INTELXXXX, 0, "Intel" }, { HDA_CODEC_MOTOXXXX, 0, "Motorola" }, { HDA_CODEC_NVIDIAXXXX, 0, "NVIDIA" }, { HDA_CODEC_SIIXXXX, 0, "Silicon Image" }, { HDA_CODEC_STACXXXX, 0, "Sigmatel" }, { HDA_CODEC_VMWAREXXXX, 0, "VMware" }, { HDA_CODEC_VTXXXX, 0, "VIA" }, }; static int hdacc_suspend(device_t dev) { HDA_BOOTHVERBOSE( device_printf(dev, "Suspend...\n"); ); bus_generic_suspend(dev); HDA_BOOTHVERBOSE( device_printf(dev, "Suspend done\n"); ); return (0); } static int hdacc_resume(device_t dev) { HDA_BOOTHVERBOSE( device_printf(dev, "Resume...\n"); ); bus_generic_resume(dev); HDA_BOOTHVERBOSE( device_printf(dev, "Resume done\n"); ); return (0); } static int hdacc_probe(device_t dev) { uint32_t id, revid; char buf[128]; int i; id = ((uint32_t)hda_get_vendor_id(dev) << 16) + hda_get_device_id(dev); revid = ((uint32_t)hda_get_revision_id(dev) << 8) + hda_get_stepping_id(dev); for (i = 0; i < nitems(hdacc_codecs); i++) { if (!HDA_DEV_MATCH(hdacc_codecs[i].id, id)) continue; if (hdacc_codecs[i].revid != 0 && hdacc_codecs[i].revid != revid) continue; break; } if (i < nitems(hdacc_codecs)) { if ((hdacc_codecs[i].id & 0xffff) != 0xffff) strlcpy(buf, hdacc_codecs[i].name, sizeof(buf)); else snprintf(buf, sizeof(buf), "%s (0x%04x)", hdacc_codecs[i].name, hda_get_device_id(dev)); } else snprintf(buf, sizeof(buf), "Generic (0x%04x)", id); device_set_descf(dev, "%s HDA CODEC", buf); return (BUS_PROBE_DEFAULT); } static int hdacc_attach(device_t dev) { struct hdacc_softc *codec = device_get_softc(dev); device_t child; int cad = (intptr_t)device_get_ivars(dev); uint32_t subnode; int startnode; int endnode; int i, n; codec->lock = HDAC_GET_MTX(device_get_parent(dev), dev); codec->dev = dev; codec->cad = cad; hdacc_lock(codec); subnode = hda_command(dev, HDA_CMD_GET_PARAMETER(0, 0x0, HDA_PARAM_SUB_NODE_COUNT)); hdacc_unlock(codec); if (subnode == HDA_INVALID) return (EIO); codec->fgcnt = HDA_PARAM_SUB_NODE_COUNT_TOTAL(subnode); startnode = HDA_PARAM_SUB_NODE_COUNT_START(subnode); endnode = startnode + codec->fgcnt; HDA_BOOTHVERBOSE( device_printf(dev, "Root Node at nid=0: %d subnodes %d-%d\n", HDA_PARAM_SUB_NODE_COUNT_TOTAL(subnode), startnode, endnode - 1); ); codec->fgs = malloc(sizeof(struct hdacc_fg) * codec->fgcnt, M_HDACC, M_ZERO | M_WAITOK); for (i = startnode, n = 0; i < endnode; i++, n++) { codec->fgs[n].nid = i; hdacc_lock(codec); codec->fgs[n].type = HDA_PARAM_FCT_GRP_TYPE_NODE_TYPE(hda_command(dev, HDA_CMD_GET_PARAMETER(0, i, HDA_PARAM_FCT_GRP_TYPE))); codec->fgs[n].subsystem_id = hda_command(dev, HDA_CMD_GET_SUBSYSTEM_ID(0, i)); hdacc_unlock(codec); codec->fgs[n].dev = child = device_add_child(dev, NULL, DEVICE_UNIT_ANY); if (child == NULL) { device_printf(dev, "Failed to add function device\n"); continue; } device_set_ivars(child, &codec->fgs[n]); } bus_attach_children(dev); return (0); } static int hdacc_detach(device_t dev) { struct hdacc_softc *codec = device_get_softc(dev); int error; if ((error = bus_generic_detach(dev)) != 0) return (error); free(codec->fgs, M_HDACC); return (0); } static int hdacc_child_location(device_t dev, device_t child, struct sbuf *sb) { struct hdacc_fg *fg = device_get_ivars(child); sbuf_printf(sb, "nid=%d", fg->nid); return (0); } static int hdacc_child_pnpinfo_method(device_t dev, device_t child, struct sbuf *sb) { struct hdacc_fg *fg = device_get_ivars(child); sbuf_printf(sb, "type=0x%02x subsystem=0x%08x", fg->type, fg->subsystem_id); return (0); } static int hdacc_print_child(device_t dev, device_t child) { struct hdacc_fg *fg = device_get_ivars(child); int retval; retval = bus_print_child_header(dev, child); retval += printf(" at nid %d", fg->nid); retval += bus_print_child_footer(dev, child); return (retval); } static void hdacc_probe_nomatch(device_t dev, device_t child) { struct hdacc_softc *codec = device_get_softc(dev); struct hdacc_fg *fg = device_get_ivars(child); device_printf(child, "<%s %s Function Group> at nid %d on %s " "(no driver attached)\n", device_get_desc(dev), fg->type == HDA_PARAM_FCT_GRP_TYPE_NODE_TYPE_AUDIO ? "Audio" : (fg->type == HDA_PARAM_FCT_GRP_TYPE_NODE_TYPE_MODEM ? "Modem" : "Unknown"), fg->nid, device_get_nameunit(dev)); HDA_BOOTVERBOSE( device_printf(dev, "Subsystem ID: 0x%08x\n", hda_get_subsystem_id(dev)); ); HDA_BOOTHVERBOSE( device_printf(dev, "Power down FG nid=%d to the D3 state...\n", fg->nid); ); hdacc_lock(codec); hda_command(dev, HDA_CMD_SET_POWER_STATE(0, fg->nid, HDA_CMD_POWER_STATE_D3)); hdacc_unlock(codec); } static int hdacc_read_ivar(device_t dev, device_t child, int which, uintptr_t *result) { struct hdacc_fg *fg = device_get_ivars(child); switch (which) { case HDA_IVAR_NODE_ID: *result = fg->nid; break; case HDA_IVAR_NODE_TYPE: *result = fg->type; break; case HDA_IVAR_SUBSYSTEM_ID: *result = fg->subsystem_id; break; default: return(BUS_READ_IVAR(device_get_parent(dev), dev, which, result)); } return (0); } static struct mtx * hdacc_get_mtx(device_t dev, device_t child) { struct hdacc_softc *codec = device_get_softc(dev); return (codec->lock); } static uint32_t hdacc_codec_command(device_t dev, device_t child, uint32_t verb) { return (HDAC_CODEC_COMMAND(device_get_parent(dev), dev, verb)); } static int hdacc_stream_alloc(device_t dev, device_t child, int dir, int format, int stripe, uint32_t **dmapos) { struct hdacc_softc *codec = device_get_softc(dev); int stream; stream = HDAC_STREAM_ALLOC(device_get_parent(dev), dev, dir, format, stripe, dmapos); if (stream > 0) codec->streams[dir][stream] = child; return (stream); } static void hdacc_stream_free(device_t dev, device_t child, int dir, int stream) { struct hdacc_softc *codec = device_get_softc(dev); codec->streams[dir][stream] = NULL; HDAC_STREAM_FREE(device_get_parent(dev), dev, dir, stream); } static int hdacc_stream_start(device_t dev, device_t child, int dir, int stream, bus_addr_t buf, int blksz, int blkcnt) { return (HDAC_STREAM_START(device_get_parent(dev), dev, dir, stream, buf, blksz, blkcnt)); } static void hdacc_stream_stop(device_t dev, device_t child, int dir, int stream) { HDAC_STREAM_STOP(device_get_parent(dev), dev, dir, stream); } static void hdacc_stream_reset(device_t dev, device_t child, int dir, int stream) { HDAC_STREAM_RESET(device_get_parent(dev), dev, dir, stream); } static uint32_t hdacc_stream_getptr(device_t dev, device_t child, int dir, int stream) { return (HDAC_STREAM_GETPTR(device_get_parent(dev), dev, dir, stream)); } static void hdacc_stream_intr(device_t dev, int dir, int stream) { struct hdacc_softc *codec = device_get_softc(dev); device_t child; if ((child = codec->streams[dir][stream]) != NULL) HDAC_STREAM_INTR(child, dir, stream); } static int hdacc_unsol_alloc(device_t dev, device_t child, int wanted) { struct hdacc_softc *codec = device_get_softc(dev); int tag; wanted &= 0x3f; tag = wanted; do { if (codec->tags[tag] == NULL) { codec->tags[tag] = child; HDAC_UNSOL_ALLOC(device_get_parent(dev), dev, tag); return (tag); } tag++; tag &= 0x3f; } while (tag != wanted); return (-1); } static void hdacc_unsol_free(device_t dev, device_t child, int tag) { struct hdacc_softc *codec = device_get_softc(dev); KASSERT(tag >= 0 && tag <= 0x3f, ("Wrong tag value %d\n", tag)); codec->tags[tag] = NULL; HDAC_UNSOL_FREE(device_get_parent(dev), dev, tag); } static void hdacc_unsol_intr(device_t dev, uint32_t resp) { struct hdacc_softc *codec = device_get_softc(dev); device_t child; int tag; tag = resp >> 26; if ((child = codec->tags[tag]) != NULL) HDAC_UNSOL_INTR(child, resp); else device_printf(codec->dev, "Unexpected unsolicited " "response with tag %d: %08x\n", tag, resp); } static void hdacc_pindump(device_t dev) { device_t *devlist; int devcount, i; if (device_get_children(dev, &devlist, &devcount) != 0) return; for (i = 0; i < devcount; i++) HDAC_PINDUMP(devlist[i]); free(devlist, M_TEMP); } static device_method_t hdacc_methods[] = { /* device interface */ DEVMETHOD(device_probe, hdacc_probe), DEVMETHOD(device_attach, hdacc_attach), DEVMETHOD(device_detach, hdacc_detach), DEVMETHOD(device_suspend, hdacc_suspend), DEVMETHOD(device_resume, hdacc_resume), /* Bus interface */ DEVMETHOD(bus_child_location, hdacc_child_location), DEVMETHOD(bus_child_pnpinfo, hdacc_child_pnpinfo_method), DEVMETHOD(bus_print_child, hdacc_print_child), DEVMETHOD(bus_probe_nomatch, hdacc_probe_nomatch), DEVMETHOD(bus_read_ivar, hdacc_read_ivar), DEVMETHOD(hdac_get_mtx, hdacc_get_mtx), DEVMETHOD(hdac_codec_command, hdacc_codec_command), DEVMETHOD(hdac_stream_alloc, hdacc_stream_alloc), DEVMETHOD(hdac_stream_free, hdacc_stream_free), DEVMETHOD(hdac_stream_start, hdacc_stream_start), DEVMETHOD(hdac_stream_stop, hdacc_stream_stop), DEVMETHOD(hdac_stream_reset, hdacc_stream_reset), DEVMETHOD(hdac_stream_getptr, hdacc_stream_getptr), DEVMETHOD(hdac_stream_intr, hdacc_stream_intr), DEVMETHOD(hdac_unsol_alloc, hdacc_unsol_alloc), DEVMETHOD(hdac_unsol_free, hdacc_unsol_free), DEVMETHOD(hdac_unsol_intr, hdacc_unsol_intr), DEVMETHOD(hdac_pindump, hdacc_pindump), DEVMETHOD_END }; static driver_t hdacc_driver = { "hdacc", hdacc_methods, sizeof(struct hdacc_softc), }; DRIVER_MODULE(snd_hda, hdac, hdacc_driver, NULL, NULL);