/* $OpenBSD: azalia_codec.c,v 1.11 2006/06/16 06:00:46 brad Exp $ */ /* $NetBSD: azalia_codec.c,v 1.8 2006/05/10 11:17:27 kent Exp $ */ /*- * Copyright (c) 2005 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by TAMURA Kent * * 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. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the NetBSD * Foundation, Inc. and its contributors. * 4. Neither the name of The NetBSD Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. 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 FOUNDATION 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. */ #include #ifdef NETBSD_GOOP __KERNEL_RCSID(0, "$NetBSD: azalia_codec.c,v 1.3 2005/09/29 04:14:03 kent Exp $"); #endif #include #include #include #include #include #include #define XNAME(co) (((struct device *)co->az)->dv_xname) #define AZ_CLASS_INPUT 0 #define AZ_CLASS_OUTPUT 1 #define AZ_CLASS_RECORD 2 #define ENUM_OFFON .un.e={2, {{{AudioNoff}, 0}, {{AudioNon}, 1}}} #define ENUM_IO .un.e={2, {{{"input"}, 0}, {{"output"}, 1}}} #ifdef MAX_VOLUME_255 # define MIXER_DELTA(n) (AUDIO_MAX_GAIN / (n)) #else # define MIXER_DELTA(n) (1) #endif int azalia_generic_codec_init_dacgroup(codec_t *); int azalia_generic_codec_add_dacgroup(codec_t *, int, uint32_t); int azalia_generic_codec_find_pin(const codec_t *, int, int, uint32_t); int azalia_generic_codec_find_dac(const codec_t *, int, int); int azalia_generic_mixer_init(codec_t *); int azalia_generic_mixer_fix_indexes(codec_t *); int azalia_generic_mixer_default(codec_t *); int azalia_generic_mixer_delete(codec_t *); int azalia_generic_mixer_ensure_capacity(codec_t *, size_t); int azalia_generic_mixer_get(const codec_t *, nid_t, int, mixer_ctrl_t *); int azalia_generic_mixer_set(codec_t *, nid_t, int, const mixer_ctrl_t *); u_char azalia_generic_mixer_from_device_value (const codec_t *, nid_t, int, uint32_t ); uint32_t azalia_generic_mixer_to_device_value (const codec_t *, nid_t, int, u_char); uint32_t azalia_generic_mixer_max(const codec_t *, nid_t, int); boolean_t azalia_generic_mixer_validate_value (const codec_t *, nid_t, int, u_char); int azalia_generic_set_port(codec_t *, mixer_ctrl_t *); int azalia_generic_get_port(codec_t *, mixer_ctrl_t *); int azalia_alc260_mixer_init(codec_t *); int azalia_alc260_init_dacgroup(codec_t *); int azalia_alc260_set_port(codec_t *, mixer_ctrl_t *); int azalia_alc880_init_dacgroup(codec_t *); int azalia_alc882_init_dacgroup(codec_t *); int azalia_alc882_init_widget(const codec_t *, widget_t *, nid_t); #if 0 int azalia_ad1981hd_init_widget(const codec_t *, widget_t *, nid_t); #endif int azalia_stac9221_init_dacgroup(codec_t *); int azalia_stac9220_mixer_init(codec_t *); int azalia_codec_init_vtbl(codec_t *this) { /** * We can refer this->vid and this->subid. */ DPRINTF(("%s: vid=%08x subid=%08x\n", __func__, this->vid, this->subid)); this->name = NULL; this->init_dacgroup = azalia_generic_codec_init_dacgroup; this->mixer_init = azalia_generic_mixer_init; this->mixer_delete = azalia_generic_mixer_delete; this->set_port = azalia_generic_set_port; this->get_port = azalia_generic_get_port; switch (this->vid) { case 0x10ec0260: this->name = "Realtek ALC260"; this->mixer_init = azalia_alc260_mixer_init; this->init_dacgroup = azalia_alc260_init_dacgroup; this->set_port = azalia_alc260_set_port; break; case 0x10ec0880: this->name = "Realtek ALC880"; this->init_dacgroup = azalia_alc880_init_dacgroup; break; case 0x10ec0882: this->name = "Realtek ALC882"; this->init_dacgroup = azalia_alc882_init_dacgroup; this->init_widget = azalia_alc882_init_widget; break; #if 0 case 0x11d41981: /* http://www.analog.com/en/prod/0,2877,AD1981HD,00.html */ this->name = "Analog Devices AD1981HD"; this->init_widget = azalia_ad1981hd_init_widget; break; #endif case 0x11d41983: /* http://www.analog.com/en/prod/0,2877,AD1983,00.html */ this->name = "Analog Devices AD1983"; break; case 0x83847680: this->name = "Sigmatel STAC9221"; this->init_dacgroup = azalia_stac9221_init_dacgroup; break; case 0x83847683: this->name = "Sigmatel STAC9221D"; this->init_dacgroup = azalia_stac9221_init_dacgroup; break; case 0x83847690: this->name = "Sigmatel STAC9220"; this->mixer_init = azalia_stac9220_mixer_init; break; } return 0; } /* ---------------------------------------------------------------- * functions for generic codecs * ---------------------------------------------------------------- */ int azalia_generic_codec_init_dacgroup(codec_t *this) { int i, j, assoc, group; /* * grouping DACs * [0] the lowest assoc DACs * [1] the lowest assoc digital outputs * [2] the 2nd assoc DACs * : */ this->dacs.ngroups = 0; for (assoc = 0; assoc < CORB_CD_ASSOCIATION_MAX; assoc++) { azalia_generic_codec_add_dacgroup(this, assoc, 0); azalia_generic_codec_add_dacgroup(this, assoc, COP_AWCAP_DIGITAL); } /* find DACs which do not connect with any pins by default */ DPRINTF(("%s: find non-connected DACs\n", __func__)); FOR_EACH_WIDGET(this, i) { boolean_t found; if (this->w[i].type != COP_AWTYPE_AUDIO_OUTPUT) continue; found = FALSE; for (group = 0; group < this->dacs.ngroups; group++) { for (j = 0; j < this->dacs.groups[group].nconv; j++) { if (i == this->dacs.groups[group].conv[j]) { found = TRUE; group = this->dacs.ngroups; break; } } } if (found) continue; if (this->dacs.ngroups >= 32) break; this->dacs.groups[this->dacs.ngroups].nconv = 1; this->dacs.groups[this->dacs.ngroups].conv[0] = i; this->dacs.ngroups++; } this->dacs.cur = 0; /* enumerate ADCs */ this->adcs.ngroups = 0; FOR_EACH_WIDGET(this, i) { if (this->w[i].type != COP_AWTYPE_AUDIO_INPUT) continue; this->adcs.groups[this->adcs.ngroups].nconv = 1; this->adcs.groups[this->adcs.ngroups].conv[0] = i; this->adcs.ngroups++; if (this->adcs.ngroups >= 32) break; } this->adcs.cur = 0; return 0; } int azalia_generic_codec_add_dacgroup(codec_t *this, int assoc, uint32_t digital) { int i, j, n, dac, seq; n = 0; for (seq = 0 ; seq < CORB_CD_SEQUENCE_MAX; seq++) { i = azalia_generic_codec_find_pin(this, assoc, seq, digital); if (i < 0) continue; dac = azalia_generic_codec_find_dac(this, i, 0); if (dac < 0) continue; /* duplication check */ for (j = 0; j < n; j++) { if (this->dacs.groups[this->dacs.ngroups].conv[j] == dac) break; } if (j < n) /* this group already has */ continue; this->dacs.groups[this->dacs.ngroups].conv[n++] = dac; DPRINTF(("%s: assoc=%d seq=%d ==> g=%d n=%d\n", __func__, assoc, seq, this->dacs.ngroups, n-1)); } if (n <= 0) /* no such DACs */ return 0; this->dacs.groups[this->dacs.ngroups].nconv = n; /* check if the same combination is already registered */ for (i = 0; i < this->dacs.ngroups; i++) { if (n != this->dacs.groups[i].nconv) continue; for (j = 0; j < n; j++) { if (this->dacs.groups[this->dacs.ngroups].conv[j] != this->dacs.groups[i].conv[j]) break; } if (j >= n) /* matched */ return 0; } /* found no equivalent group */ this->dacs.ngroups++; return 0; } int azalia_generic_codec_find_pin(const codec_t *this, int assoc, int seq, uint32_t digital) { int i; FOR_EACH_WIDGET(this, i) { if (this->w[i].type != COP_AWTYPE_PIN_COMPLEX) continue; if ((this->w[i].d.pin.cap & COP_PINCAP_OUTPUT) == 0) continue; if ((this->w[i].widgetcap & COP_AWCAP_DIGITAL) != digital) continue; if (this->w[i].d.pin.association != assoc) continue; if (this->w[i].d.pin.sequence == seq) { return i; } } return -1; } int azalia_generic_codec_find_dac(const codec_t *this, int index, int depth) { const widget_t *w; int i, j, ret; w = &this->w[index]; if (w->type == COP_AWTYPE_AUDIO_OUTPUT) { DPRINTF(("%s: DAC: nid=0x%x index=%d\n", __func__, w->nid, index)); return index; } if (++depth > 50) { return -1; } if (w->selected >= 0) { j = w->connections[w->selected]; if (VALID_WIDGET_NID(j, this)) { ret = azalia_generic_codec_find_dac(this, j, depth); if (ret >= 0) { DPRINTF(("%s: DAC path: nid=0x%x index=%d\n", __func__, w->nid, index)); return ret; } } } for (i = 0; i < w->nconnections; i++) { j = w->connections[i]; if (!VALID_WIDGET_NID(j, this)) continue; ret = azalia_generic_codec_find_dac(this, j, depth); if (ret >= 0) { DPRINTF(("%s: DAC path: nid=0x%x index=%d\n", __func__, w->nid, index)); return ret; } } return -1; } /* ---------------------------------------------------------------- * Generic mixer functions * ---------------------------------------------------------------- */ int azalia_generic_mixer_init(codec_t *this) { /* * pin "%2.2x" * audio output "dac%2.2x" * audio input "adc%2.2x" * mixer "mixer%2.2x" * selector "sel%2.2x" */ mixer_item_t *m; int err, i, j, k; this->maxmixers = 10; this->nmixers = 0; this->mixers = malloc(sizeof(mixer_item_t) * this->maxmixers, M_DEVBUF, M_NOWAIT); if (this->mixers == NULL) { printf("%s: out of memory in %s\n", XNAME(this), __func__); return ENOMEM; } bzero(this->mixers, sizeof(mixer_item_t) * this->maxmixers); /* register classes */ DPRINTF(("%s: register classes\n", __func__)); m = &this->mixers[AZ_CLASS_INPUT]; m->devinfo.index = AZ_CLASS_INPUT; strlcpy(m->devinfo.label.name, AudioCinputs, sizeof(m->devinfo.label.name)); m->devinfo.type = AUDIO_MIXER_CLASS; m->devinfo.mixer_class = AZ_CLASS_INPUT; m->devinfo.next = AUDIO_MIXER_LAST; m->devinfo.prev = AUDIO_MIXER_LAST; m->nid = 0; m = &this->mixers[AZ_CLASS_OUTPUT]; m->devinfo.index = AZ_CLASS_OUTPUT; strlcpy(m->devinfo.label.name, AudioCoutputs, sizeof(m->devinfo.label.name)); m->devinfo.type = AUDIO_MIXER_CLASS; m->devinfo.mixer_class = AZ_CLASS_OUTPUT; m->devinfo.next = AUDIO_MIXER_LAST; m->devinfo.prev = AUDIO_MIXER_LAST; m->nid = 0; m = &this->mixers[AZ_CLASS_RECORD]; m->devinfo.index = AZ_CLASS_RECORD; strlcpy(m->devinfo.label.name, AudioCrecord, sizeof(m->devinfo.label.name)); m->devinfo.type = AUDIO_MIXER_CLASS; m->devinfo.mixer_class = AZ_CLASS_RECORD; m->devinfo.next = AUDIO_MIXER_LAST; m->devinfo.prev = AUDIO_MIXER_LAST; m->nid = 0; this->nmixers = AZ_CLASS_RECORD + 1; #define MIXER_REG_PROLOG \ mixer_devinfo_t *d; \ err = azalia_generic_mixer_ensure_capacity(this, this->nmixers + 1); \ if (err) \ return err; \ m = &this->mixers[this->nmixers]; \ d = &m->devinfo; \ m->nid = i FOR_EACH_WIDGET(this, i) { const widget_t *w; w = &this->w[i]; /* selector */ if (w->type != COP_AWTYPE_AUDIO_MIXER && w->nconnections >= 2) { MIXER_REG_PROLOG; DPRINTF(("%s: selector %s\n", __func__, w->name)); snprintf(d->label.name, sizeof(d->label.name), "%s.source", w->name); d->type = AUDIO_MIXER_ENUM; if (w->type == COP_AWTYPE_AUDIO_MIXER) d->mixer_class = AZ_CLASS_RECORD; else if (w->type == COP_AWTYPE_AUDIO_SELECTOR) d->mixer_class = AZ_CLASS_INPUT; else d->mixer_class = AZ_CLASS_OUTPUT; m->target = MI_TARGET_CONNLIST; for (j = 0, k = 0; j < w->nconnections && k < 32; j++) { if (!VALID_WIDGET_NID(w->connections[j], this)) continue; DPRINTF(("%s: selector %d=%s\n", __func__, j, this->w[w->connections[j]].name)); d->un.e.member[k].ord = j; strlcpy(d->un.e.member[k].label.name, this->w[w->connections[j]].name, MAX_AUDIO_DEV_LEN); k++; } d->un.e.num_mem = k; this->nmixers++; } /* output mute */ if (w->widgetcap & COP_AWCAP_OUTAMP && w->outamp_cap & COP_AMPCAP_MUTE) { MIXER_REG_PROLOG; DPRINTF(("%s: output mute %s\n", __func__, w->name)); snprintf(d->label.name, sizeof(d->label.name), "%s.mute", w->name); d->type = AUDIO_MIXER_ENUM; if (w->type == COP_AWTYPE_AUDIO_MIXER) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_AUDIO_SELECTOR) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_PIN_COMPLEX) d->mixer_class = AZ_CLASS_OUTPUT; else d->mixer_class = AZ_CLASS_INPUT; m->target = MI_TARGET_OUTAMP; d->un.e.num_mem = 2; d->un.e.member[0].ord = 0; strlcpy(d->un.e.member[0].label.name, AudioNoff, MAX_AUDIO_DEV_LEN); d->un.e.member[1].ord = 1; strlcpy(d->un.e.member[1].label.name, AudioNon, MAX_AUDIO_DEV_LEN); this->nmixers++; } /* output gain */ if (w->widgetcap & COP_AWCAP_OUTAMP && COP_AMPCAP_NUMSTEPS(w->outamp_cap)) { MIXER_REG_PROLOG; DPRINTF(("%s: output gain %s\n", __func__, w->name)); snprintf(d->label.name, sizeof(d->label.name), "%s", w->name); d->type = AUDIO_MIXER_VALUE; if (w->type == COP_AWTYPE_AUDIO_MIXER) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_AUDIO_SELECTOR) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_PIN_COMPLEX) d->mixer_class = AZ_CLASS_OUTPUT; else d->mixer_class = AZ_CLASS_INPUT; m->target = MI_TARGET_OUTAMP; d->un.v.num_channels = WIDGET_CHANNELS(w); #ifdef MAX_VOLUME_255 d->un.v.units.name[0] = 0; #else snprintf(d->un.v.units.name, sizeof(d->un.v.units.name), "0.25x%ddB", COP_AMPCAP_STEPSIZE(w->outamp_cap)+1); #endif d->un.v.delta = MIXER_DELTA(COP_AMPCAP_NUMSTEPS(w->outamp_cap)); this->nmixers++; } /* input mute */ if (w->widgetcap & COP_AWCAP_INAMP && w->inamp_cap & COP_AMPCAP_MUTE) { DPRINTF(("%s: input mute %s\n", __func__, w->name)); if (w->type != COP_AWTYPE_AUDIO_SELECTOR && w->type != COP_AWTYPE_AUDIO_MIXER) { MIXER_REG_PROLOG; snprintf(d->label.name, sizeof(d->label.name), "%s.mute", w->name); d->type = AUDIO_MIXER_ENUM; if (w->type == COP_AWTYPE_PIN_COMPLEX) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_AUDIO_INPUT) d->mixer_class = AZ_CLASS_RECORD; else d->mixer_class = AZ_CLASS_INPUT; m->target = 0; d->un.e.num_mem = 2; d->un.e.member[0].ord = 0; strlcpy(d->un.e.member[0].label.name, AudioNoff, MAX_AUDIO_DEV_LEN); d->un.e.member[1].ord = 1; strlcpy(d->un.e.member[1].label.name, AudioNon, MAX_AUDIO_DEV_LEN); this->nmixers++; } else { for (j = 0; j < w->nconnections; j++) { MIXER_REG_PROLOG; if (!VALID_WIDGET_NID(w->connections[j], this)) continue; DPRINTF(("%s: input mute %s.%s\n", __func__, w->name, this->w[w->connections[j]].name)); snprintf(d->label.name, sizeof(d->label.name), "%s.%s.mute", w->name, this->w[w->connections[j]].name); d->type = AUDIO_MIXER_ENUM; if (w->type == COP_AWTYPE_PIN_COMPLEX) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_AUDIO_INPUT) d->mixer_class = AZ_CLASS_RECORD; else d->mixer_class = AZ_CLASS_INPUT; m->target = j; d->un.e.num_mem = 2; d->un.e.member[0].ord = 0; strlcpy(d->un.e.member[0].label.name, AudioNoff, MAX_AUDIO_DEV_LEN); d->un.e.member[1].ord = 1; strlcpy(d->un.e.member[1].label.name, AudioNon, MAX_AUDIO_DEV_LEN); this->nmixers++; } } } /* input gain */ if (w->widgetcap & COP_AWCAP_INAMP && COP_AMPCAP_NUMSTEPS(w->inamp_cap)) { DPRINTF(("%s: input gain %s\n", __func__, w->name)); if (w->type != COP_AWTYPE_AUDIO_SELECTOR && w->type != COP_AWTYPE_AUDIO_MIXER) { MIXER_REG_PROLOG; snprintf(d->label.name, sizeof(d->label.name), "%s", w->name); d->type = AUDIO_MIXER_VALUE; if (w->type == COP_AWTYPE_PIN_COMPLEX) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_AUDIO_INPUT) d->mixer_class = AZ_CLASS_RECORD; else d->mixer_class = AZ_CLASS_INPUT; m->target = 0; d->un.v.num_channels = WIDGET_CHANNELS(w); #ifdef MAX_VOLUME_255 d->un.v.units.name[0] = 0; #else snprintf(d->un.v.units.name, sizeof(d->un.v.units.name), "0.25x%ddB", COP_AMPCAP_STEPSIZE(w->inamp_cap)+1); #endif d->un.v.delta = MIXER_DELTA(COP_AMPCAP_NUMSTEPS(w->inamp_cap)); this->nmixers++; } else { for (j = 0; j < w->nconnections; j++) { MIXER_REG_PROLOG; if (!VALID_WIDGET_NID(w->connections[j], this)) continue; DPRINTF(("%s: input gain %s.%s\n", __func__, w->name, this->w[w->connections[j]].name)); snprintf(d->label.name, sizeof(d->label.name), "%s.%s", w->name, this->w[w->connections[j]].name); d->type = AUDIO_MIXER_VALUE; if (w->type == COP_AWTYPE_PIN_COMPLEX) d->mixer_class = AZ_CLASS_OUTPUT; else if (w->type == COP_AWTYPE_AUDIO_INPUT) d->mixer_class = AZ_CLASS_RECORD; else d->mixer_class = AZ_CLASS_INPUT; m->target = j; d->un.v.num_channels = WIDGET_CHANNELS(w); #ifdef MAX_VOLUME_255 d->un.v.units.name[0] = 0; #else snprintf(d->un.v.units.name, sizeof(d->un.v.units.name), "0.25x%ddB", COP_AMPCAP_STEPSIZE(w->inamp_cap)+1); #endif d->un.v.delta = MIXER_DELTA(COP_AMPCAP_NUMSTEPS(w->inamp_cap)); this->nmixers++; } } } /* pin direction */ if (w->type == COP_AWTYPE_PIN_COMPLEX && w->d.pin.cap & COP_PINCAP_OUTPUT && w->d.pin.cap & COP_PINCAP_INPUT) { MIXER_REG_PROLOG; DPRINTF(("%s: pin dir %s\n", __func__, w->name)); snprintf(d->label.name, sizeof(d->label.name), "%s.dir", w->name); d->type = AUDIO_MIXER_ENUM; d->mixer_class = AZ_CLASS_OUTPUT; m->target = MI_TARGET_PINDIR; d->un.e.num_mem = 2; d->un.e.member[0].ord = 0; strlcpy(d->un.e.member[0].label.name, AudioNinput, MAX_AUDIO_DEV_LEN); d->un.e.member[1].ord = 1; strlcpy(d->un.e.member[1].label.name, AudioNoutput, MAX_AUDIO_DEV_LEN); this->nmixers++; } /* pin headphone-boost */ if (w->type == COP_AWTYPE_PIN_COMPLEX && w->d.pin.cap & COP_PINCAP_HEADPHONE) { MIXER_REG_PROLOG; DPRINTF(("%s: hpboost %s\n", __func__, w->name)); snprintf(d->label.name, sizeof(d->label.name), "%s.boost", w->name); d->type = AUDIO_MIXER_ENUM; d->mixer_class = AZ_CLASS_OUTPUT; m->target = MI_TARGET_PINBOOST; d->un.e.num_mem = 2; d->un.e.member[0].ord = 0; strlcpy(d->un.e.member[0].label.name, AudioNoff, MAX_AUDIO_DEV_LEN); d->un.e.member[1].ord = 1; strlcpy(d->un.e.member[1].label.name, AudioNon, MAX_AUDIO_DEV_LEN); this->nmixers++; } /* volume knob */ if (w->type == COP_AWTYPE_VOLUME_KNOB && w->d.volume.cap & COP_VKCAP_DELTA) { MIXER_REG_PROLOG; DPRINTF(("%s: volume knob %s\n", __func__, w->name)); strlcpy(d->label.name, w->name, sizeof(d->label.name)); d->type = AUDIO_MIXER_VALUE; d->mixer_class = AZ_CLASS_OUTPUT; m->target = MI_TARGET_VOLUME; d->un.v.num_channels = 1; d->un.v.units.name[0] = 0; d->un.v.delta = MIXER_DELTA(COP_VKCAP_NUMSTEPS(w->d.volume.cap)); this->nmixers++; } } /* if the codec has multiple DAC groups, create "inputs.usingdac" */ if (this->dacs.ngroups > 1) { MIXER_REG_PROLOG; DPRINTF(("%s: create inputs.usingdac\n", __func__)); strlcpy(d->label.name, "usingdac", sizeof(d->label.name)); d->type = AUDIO_MIXER_ENUM; d->mixer_class = AZ_CLASS_INPUT; m->target = MI_TARGET_DAC; for (i = 0; i < this->dacs.ngroups && i < 32; i++) { d->un.e.member[i].ord = i; for (j = 0; j < this->dacs.groups[i].nconv; j++) { if (j * 2 >= MAX_AUDIO_DEV_LEN) break; snprintf(d->un.e.member[i].label.name + j*2, MAX_AUDIO_DEV_LEN - j*2, "%2.2x", this->dacs.groups[i].conv[j]); } } d->un.e.num_mem = i; this->nmixers++; } /* if the codec has multiple ADC groups, create "record.usingadc" */ if (this->adcs.ngroups > 1) { MIXER_REG_PROLOG; DPRINTF(("%s: create inputs.usingadc\n", __func__)); strlcpy(d->label.name, "usingadc", sizeof(d->label.name)); d->type = AUDIO_MIXER_ENUM; d->mixer_class = AZ_CLASS_RECORD; m->target = MI_TARGET_ADC; for (i = 0; i < this->adcs.ngroups && i < 32; i++) { d->un.e.member[i].ord = i; for (j = 0; j < this->adcs.groups[i].nconv; j++) { if (j * 2 >= MAX_AUDIO_DEV_LEN) break; snprintf(d->un.e.member[i].label.name + j*2, MAX_AUDIO_DEV_LEN - j*2, "%2.2x", this->adcs.groups[i].conv[j]); } } d->un.e.num_mem = i; this->nmixers++; } azalia_generic_mixer_fix_indexes(this); azalia_generic_mixer_default(this); return 0; } int azalia_generic_mixer_ensure_capacity(codec_t *this, size_t newsize) { size_t newmax; void *newbuf; if (this->maxmixers >= newsize) return 0; newmax = this->maxmixers + 10; if (newmax < newsize) newmax = newsize; newbuf = malloc(sizeof(mixer_item_t) * newmax, M_DEVBUF, M_NOWAIT); if (newbuf == NULL) { printf("%s: out of memory in %s\n", XNAME(this), __func__); return ENOMEM; } bzero(newbuf, sizeof(mixer_item_t) * newmax); bcopy(this->mixers, newbuf, this->maxmixers * sizeof(mixer_item_t)); free(this->mixers, M_DEVBUF); this->mixers = newbuf; this->maxmixers = newmax; return 0; } int azalia_generic_mixer_fix_indexes(codec_t *this) { int i; mixer_devinfo_t *d; for (i = 0; i < this->nmixers; i++) { d = &this->mixers[i].devinfo; #ifdef DIAGNOSTIC if (d->index != 0 && d->index != i) printf("%s: index mismatch %d %d\n", __func__, d->index, i); #endif d->index = i; if (d->prev == 0) d->prev = AUDIO_MIXER_LAST; if (d->next == 0) d->next = AUDIO_MIXER_LAST; } return 0; } int azalia_generic_mixer_default(codec_t *this) { int i; mixer_item_t *m; /* unmute all */ DPRINTF(("%s: unmute\n", __func__)); for (i = 0; i < this->nmixers; i++) { mixer_ctrl_t mc; m = &this->mixers[i]; if (!IS_MI_TARGET_INAMP(m->target) && m->target != MI_TARGET_OUTAMP) continue; if (m->devinfo.type != AUDIO_MIXER_ENUM) continue; mc.dev = i; mc.type = AUDIO_MIXER_ENUM; mc.un.ord = 0; azalia_generic_mixer_set(this, m->nid, m->target, &mc); } /* * for bidirectional pins, * green=front, orange=surround, gray=c/lfe, black=side --> output * blue=line-in, pink=mic-in --> input */ DPRINTF(("%s: process bidirectional pins\n", __func__)); for (i = 0; i < this->nmixers; i++) { mixer_ctrl_t mc; m = &this->mixers[i]; if (m->target != MI_TARGET_PINDIR) continue; mc.dev = i; mc.type = AUDIO_MIXER_ENUM; switch (this->w[m->nid].d.pin.color) { case CORB_CD_GREEN: case CORB_CD_ORANGE: case CORB_CD_GRAY: case CORB_CD_BLACK: mc.un.ord = 1; break; default: mc.un.ord = 0; } azalia_generic_mixer_set(this, m->nid, m->target, &mc); } /* set unextreme volume */ DPRINTF(("%s: set volume\n", __func__)); for (i = 0; i < this->nmixers; i++) { mixer_ctrl_t mc; m = &this->mixers[i]; if (!IS_MI_TARGET_INAMP(m->target) && m->target != MI_TARGET_OUTAMP && m->target != MI_TARGET_VOLUME) continue; if (m->devinfo.type != AUDIO_MIXER_VALUE) continue; mc.dev = i; mc.type = AUDIO_MIXER_VALUE; mc.un.value.num_channels = 1; mc.un.value.level[0] = AUDIO_MAX_GAIN / 2; if (m->target != MI_TARGET_VOLUME && WIDGET_CHANNELS(&this->w[m->nid]) == 2) { mc.un.value.num_channels = 2; mc.un.value.level[1] = AUDIO_MAX_GAIN / 2; } azalia_generic_mixer_set(this, m->nid, m->target, &mc); } return 0; } int azalia_generic_mixer_delete(codec_t *this) { if (this->mixers == NULL) return 0; free(this->mixers, M_DEVBUF); this->mixers = NULL; return 0; } /** * @param mc mc->type must be set by the caller before the call */ int azalia_generic_mixer_get(const codec_t *this, nid_t nid, int target, mixer_ctrl_t *mc) { uint32_t result; int err; /* inamp mute */ if (IS_MI_TARGET_INAMP(target) && mc->type == AUDIO_MIXER_ENUM) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT | CORB_GAGM_LEFT | MI_TARGET_INAMP(target), &result); if (err) return err; mc->un.ord = result & CORB_GAGM_MUTE ? 1 : 0; } /* inamp gain */ else if (IS_MI_TARGET_INAMP(target) && mc->type == AUDIO_MIXER_VALUE) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT | CORB_GAGM_LEFT | MI_TARGET_INAMP(target), &result); if (err) return err; mc->un.value.level[0] = azalia_generic_mixer_from_device_value(this, nid, target, CORB_GAGM_GAIN(result)); mc->un.value.num_channels = WIDGET_CHANNELS(&this->w[nid]); if (mc->un.value.num_channels == 2) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT | CORB_GAGM_RIGHT | MI_TARGET_INAMP(target), &result); if (err) return err; mc->un.value.level[1] = azalia_generic_mixer_from_device_value (this, nid, target, CORB_GAGM_GAIN(result)); } } /* outamp mute */ else if (target == MI_TARGET_OUTAMP && mc->type == AUDIO_MIXER_ENUM) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT | CORB_GAGM_LEFT | 0, &result); if (err) return err; mc->un.ord = result & CORB_GAGM_MUTE ? 1 : 0; } /* outamp gain */ else if (target == MI_TARGET_OUTAMP && mc->type == AUDIO_MIXER_VALUE) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT | CORB_GAGM_LEFT | 0, &result); if (err) return err; mc->un.value.level[0] = azalia_generic_mixer_from_device_value(this, nid, target, CORB_GAGM_GAIN(result)); mc->un.value.num_channels = WIDGET_CHANNELS(&this->w[nid]); if (mc->un.value.num_channels == 2) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT | CORB_GAGM_RIGHT | 0, &result); if (err) return err; mc->un.value.level[1] = azalia_generic_mixer_from_device_value (this, nid, target, CORB_GAGM_GAIN(result)); } } /* selection */ else if (target == MI_TARGET_CONNLIST) { err = this->comresp(this, nid, CORB_GET_CONNECTION_SELECT_CONTROL, 0, &result); if (err) return err; result = CORB_CSC_INDEX(result); if (!VALID_WIDGET_NID(this->w[nid].connections[result], this)) mc->un.ord = -1; else mc->un.ord = result; } /* pin I/O */ else if (target == MI_TARGET_PINDIR) { err = this->comresp(this, nid, CORB_GET_PIN_WIDGET_CONTROL, 0, &result); if (err) return err; mc->un.ord = result & CORB_PWC_OUTPUT ? 1 : 0; } /* pin headphone-boost */ else if (target == MI_TARGET_PINBOOST) { err = this->comresp(this, nid, CORB_GET_PIN_WIDGET_CONTROL, 0, &result); if (err) return err; mc->un.ord = result & CORB_PWC_HEADPHONE ? 1 : 0; } /* DAC group selection */ else if (target == MI_TARGET_DAC) { mc->un.ord = this->dacs.cur; } /* ADC selection */ else if (target == MI_TARGET_ADC) { mc->un.ord = this->adcs.cur; } /* Volume knob */ else if (target == MI_TARGET_VOLUME) { err = this->comresp(this, nid, CORB_GET_VOLUME_KNOB, 0, &result); if (err) return err; mc->un.value.level[0] = azalia_generic_mixer_from_device_value(this, nid, target, CORB_VKNOB_VOLUME(result)); mc->un.value.num_channels = 1; } else { printf("%s: internal error in %s: target=%x\n", XNAME(this), __func__, target); return -1; } return 0; } int azalia_generic_mixer_set(codec_t *this, nid_t nid, int target, const mixer_ctrl_t *mc) { uint32_t result, value; int err; /* inamp mute */ if (IS_MI_TARGET_INAMP(target) && mc->type == AUDIO_MIXER_ENUM) { /* We have to set stereo mute separately to keep each gain value. */ err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT | CORB_GAGM_LEFT | MI_TARGET_INAMP(target), &result); if (err) return err; value = CORB_AGM_INPUT | CORB_AGM_LEFT | (target << CORB_AGM_INDEX_SHIFT) | CORB_GAGM_GAIN(result); if (mc->un.ord) value |= CORB_AGM_MUTE; err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; if (WIDGET_CHANNELS(&this->w[nid]) == 2) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT | CORB_GAGM_RIGHT | MI_TARGET_INAMP(target), &result); if (err) return err; value = CORB_AGM_INPUT | CORB_AGM_RIGHT | (target << CORB_AGM_INDEX_SHIFT) | CORB_GAGM_GAIN(result); if (mc->un.ord) value |= CORB_AGM_MUTE; err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; } } /* inamp gain */ else if (IS_MI_TARGET_INAMP(target) && mc->type == AUDIO_MIXER_VALUE) { if (mc->un.value.num_channels < 1) return EINVAL; if (!azalia_generic_mixer_validate_value(this, nid, target, mc->un.value.level[0])) return EINVAL; err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT | CORB_GAGM_LEFT | MI_TARGET_INAMP(target), &result); if (err) return err; value = azalia_generic_mixer_to_device_value(this, nid, target, mc->un.value.level[0]); value = CORB_AGM_INPUT | CORB_AGM_LEFT | (target << CORB_AGM_INDEX_SHIFT) | (result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) | (value & CORB_AGM_GAIN_MASK); err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; if (mc->un.value.num_channels >= 2 && WIDGET_CHANNELS(&this->w[nid]) == 2) { if (!azalia_generic_mixer_validate_value(this, nid, target, mc->un.value.level[1])) return EINVAL; err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT | CORB_GAGM_RIGHT | MI_TARGET_INAMP(target), &result); if (err) return err; value = azalia_generic_mixer_to_device_value(this, nid, target, mc->un.value.level[1]); value = CORB_AGM_INPUT | CORB_AGM_RIGHT | (target << CORB_AGM_INDEX_SHIFT) | (result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) | (value & CORB_AGM_GAIN_MASK); err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; } } /* outamp mute */ else if (target == MI_TARGET_OUTAMP && mc->type == AUDIO_MIXER_ENUM) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT | CORB_GAGM_LEFT, &result); if (err) return err; value = CORB_AGM_OUTPUT | CORB_AGM_LEFT | CORB_GAGM_GAIN(result); if (mc->un.ord) value |= CORB_AGM_MUTE; err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; if (WIDGET_CHANNELS(&this->w[nid]) == 2) { err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT | CORB_GAGM_RIGHT, &result); if (err) return err; value = CORB_AGM_OUTPUT | CORB_AGM_RIGHT | CORB_GAGM_GAIN(result); if (mc->un.ord) value |= CORB_AGM_MUTE; err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; } } /* outamp gain */ else if (target == MI_TARGET_OUTAMP && mc->type == AUDIO_MIXER_VALUE) { if (mc->un.value.num_channels < 1) return EINVAL; if (!azalia_generic_mixer_validate_value(this, nid, target, mc->un.value.level[0])) return EINVAL; err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT | CORB_GAGM_LEFT, &result); if (err) return err; value = azalia_generic_mixer_to_device_value(this, nid, target, mc->un.value.level[0]); value = CORB_AGM_OUTPUT | CORB_AGM_LEFT | (result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) | (value & CORB_AGM_GAIN_MASK); err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; if (mc->un.value.num_channels >= 2 && WIDGET_CHANNELS(&this->w[nid]) == 2) { if (!azalia_generic_mixer_validate_value(this, nid, target, mc->un.value.level[1])) return EINVAL; err = this->comresp(this, nid, CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT | CORB_GAGM_RIGHT, &result); if (err) return err; value = azalia_generic_mixer_to_device_value(this, nid, target, mc->un.value.level[1]); value = CORB_AGM_OUTPUT | CORB_AGM_RIGHT | (result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) | (value & CORB_AGM_GAIN_MASK); err = this->comresp(this, nid, CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result); if (err) return err; } } /* selection */ else if (target == MI_TARGET_CONNLIST) { if (mc->un.ord < 0 || mc->un.ord >= this->w[nid].nconnections || !VALID_WIDGET_NID(this->w[nid].connections[mc->un.ord], this)) return EINVAL; err = this->comresp(this, nid, CORB_SET_CONNECTION_SELECT_CONTROL, mc->un.ord, &result); if (err) return err; } /* pin I/O */ else if (target == MI_TARGET_PINDIR) { if (mc->un.ord >= 2) return EINVAL; err = this->comresp(this, nid, CORB_GET_PIN_WIDGET_CONTROL, 0, &result); if (err) return err; if (mc->un.ord == 0) { result &= ~CORB_PWC_OUTPUT; result |= CORB_PWC_INPUT; } else { result &= ~CORB_PWC_INPUT; result |= CORB_PWC_OUTPUT; } err = this->comresp(this, nid, CORB_SET_PIN_WIDGET_CONTROL, result, &result); if (err) return err; } /* pin headphone-boost */ else if (target == MI_TARGET_PINBOOST) { if (mc->un.ord >= 2) return EINVAL; err = this->comresp(this, nid, CORB_GET_PIN_WIDGET_CONTROL, 0, &result); if (err) return err; if (mc->un.ord == 0) { result &= ~CORB_PWC_HEADPHONE; } else { result |= CORB_PWC_HEADPHONE; } err = this->comresp(this, nid, CORB_SET_PIN_WIDGET_CONTROL, result, &result); if (err) return err; } /* DAC group selection */ else if (target == MI_TARGET_DAC) { if (this->running) return EBUSY; if (mc->un.ord >= this->dacs.ngroups) return EINVAL; return azalia_codec_construct_format(this, mc->un.ord, this->adcs.cur); } /* ADC selection */ else if (target == MI_TARGET_ADC) { if (this->running) return EBUSY; if (mc->un.ord >= this->adcs.ngroups) return EINVAL; return azalia_codec_construct_format(this, this->dacs.cur, mc->un.ord); } /* Volume knob */ else if (target == MI_TARGET_VOLUME) { if (mc->un.value.num_channels != 1) return EINVAL; if (!azalia_generic_mixer_validate_value(this, nid, target, mc->un.value.level[0])) return EINVAL; value = azalia_generic_mixer_to_device_value(this, nid, target, mc->un.value.level[0]) | CORB_VKNOB_DIRECT; err = this->comresp(this, nid, CORB_SET_VOLUME_KNOB, value, &result); if (err) return err; } else { printf("%s: internal error in %s: target=%x\n", XNAME(this), __func__, target); return -1; } return 0; } u_char azalia_generic_mixer_from_device_value(const codec_t *this, nid_t nid, int target, uint32_t dv) { #ifdef MAX_VOLUME_255 uint32_t dmax; if (IS_MI_TARGET_INAMP(target)) dmax = COP_AMPCAP_NUMSTEPS(this->w[nid].inamp_cap); else if (target == MI_TARGET_OUTAMP) dmax = COP_AMPCAP_NUMSTEPS(this->w[nid].outamp_cap); else if (target == MI_TARGET_VOLUME) dmax = COP_VKCAP_NUMSTEPS(this->w[nid].d.volume.cap); else { printf("unknown target: %d\n", target); dmax = 255; } return dv * AUDIO_MAX_GAIN / dmax; #else return dv; #endif } uint32_t azalia_generic_mixer_to_device_value(const codec_t *this, nid_t nid, int target, u_char uv) { #ifdef MAX_VOLUME_255 uint32_t dmax; if (IS_MI_TARGET_INAMP(target)) dmax = COP_AMPCAP_NUMSTEPS(this->w[nid].inamp_cap); else if (target == MI_TARGET_OUTAMP) dmax = COP_AMPCAP_NUMSTEPS(this->w[nid].outamp_cap); else if (target == MI_TARGET_VOLUME) dmax = COP_VKCAP_NUMSTEPS(this->w[nid].d.volume.cap); else { printf("unknown target: %d\n", target); dmax = 255; } return uv * dmax / AUDIO_MAX_GAIN; #else return uv; #endif } uint32_t azalia_generic_mixer_max(const codec_t *this, nid_t nid, int target) { #ifdef MAX_VOLUME_255 return AUDIO_MAX_GAIN; #else uint32_t dmax; if (IS_MI_TARGET_INAMP(target)) dmax = COP_AMPCAP_NUMSTEPS(this->w[nid].inamp_cap); else if (target == MI_TARGET_OUTAMP) dmax = COP_AMPCAP_NUMSTEPS(this->w[nid].outamp_cap); else if (target == MI_TARGET_VOLUME) dmax = COP_VKCAP_NUMSTEPS(this->w[nid].d.volume.cap); return dmax; #endif } boolean_t azalia_generic_mixer_validate_value(const codec_t *this, nid_t nid, int target, u_char uv) { #ifdef MAX_VOLUME_255 return TRUE; #else return uv <= generic_mixer_max(this, nid, target); #endif } int azalia_generic_set_port(codec_t *this, mixer_ctrl_t *mc) { const mixer_item_t *m; if (mc->dev >= this->nmixers) return ENXIO; m = &this->mixers[mc->dev]; if (mc->type != m->devinfo.type) return EINVAL; if (mc->type == AUDIO_MIXER_CLASS) return 0; /* nothing to do */ return azalia_generic_mixer_set(this, m->nid, m->target, mc); } int azalia_generic_get_port(codec_t *this, mixer_ctrl_t *mc) { const mixer_item_t *m; if (mc->dev >= this->nmixers) return ENXIO; m = &this->mixers[mc->dev]; mc->type = m->devinfo.type; if (mc->type == AUDIO_MIXER_CLASS) return 0; /* nothing to do */ return azalia_generic_mixer_get(this, m->nid, m->target, mc); } /* ---------------------------------------------------------------- * Realtek ALC260 * * Fujitsu LOOX T70M/T * Internal Speaker: 0x10 * Front Headphone: 0x14 * Front mic: 0x12 * ---------------------------------------------------------------- */ #define ALC260_FUJITSU_ID 0x132610cf static const mixer_item_t alc260_mixer_items[] = { {{AZ_CLASS_INPUT, {AudioCinputs}, AUDIO_MIXER_CLASS, AZ_CLASS_INPUT, 0, 0}, 0}, {{AZ_CLASS_OUTPUT, {AudioCoutputs}, AUDIO_MIXER_CLASS, AZ_CLASS_OUTPUT, 0, 0}, 0}, {{AZ_CLASS_RECORD, {AudioCrecord}, AUDIO_MIXER_CLASS, AZ_CLASS_RECORD, 0, 0}, 0}, {{0, {AudioNmaster}, AUDIO_MIXER_VALUE, AZ_CLASS_OUTPUT, 0, 0, .un.v={{""}, 2, 3}}, 0x08, MI_TARGET_OUTAMP}, /* and 0x09, 0x0a(mono) */ {{0, {AudioNmaster".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x0f, MI_TARGET_OUTAMP}, {{0, {AudioNheadphone".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x10, MI_TARGET_OUTAMP}, {{0, {AudioNheadphone".boost"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x10, MI_TARGET_PINBOOST}, {{0, {AudioNmono".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x11, MI_TARGET_OUTAMP}, {{0, {"mic1.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x12, MI_TARGET_OUTAMP}, {{0, {"mic1"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_IO}, 0x12, MI_TARGET_PINDIR}, {{0, {"mic2.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x13, MI_TARGET_OUTAMP}, {{0, {"mic2"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_IO}, 0x13, MI_TARGET_PINDIR}, {{0, {"line1.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x14, MI_TARGET_OUTAMP}, {{0, {"line1"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_IO}, 0x14, MI_TARGET_PINDIR}, {{0, {"line2.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x15, MI_TARGET_OUTAMP}, {{0, {"line2"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_IO}, 0x15, MI_TARGET_PINDIR}, {{0, {AudioNdac".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x08, MI_TARGET_INAMP(0)}, /* and 0x09, 0x0a(mono) */ {{0, {"mic1.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(0)}, {{0, {"mic1"}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(0)}, {{0, {"mic2.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(1)}, {{0, {"mic2"}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(1)}, {{0, {"line1.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(2)}, {{0, {"line1"}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, 3}}, 0x07, MI_TARGET_INAMP(2)}, {{0, {"line2.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(3)}, {{0, {"line2"}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(3)}, {{0, {AudioNcd".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(4)}, {{0, {AudioNcd}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(4)}, {{0, {AudioNspeaker".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(5)}, {{0, {AudioNspeaker}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(5)}, {{0, {"adc04.source"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, .un.e={5, {{{"mic1"}, 0}, {{"mic2"}, 1}, {{"line1"}, 2}, {{"line2"}, 3}, {{AudioNcd}, 4}}}}, 0x04, MI_TARGET_CONNLIST}, {{0, {"adc04.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, ENUM_OFFON}, 0x04, MI_TARGET_INAMP(0)}, {{0, {"adc04"}, AUDIO_MIXER_VALUE, AZ_CLASS_RECORD, 0, 0, .un.v={{""}, 2, MIXER_DELTA(35)}}, 0x04, MI_TARGET_INAMP(0)}, {{0, {"adc05.source"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, .un.e={6, {{{"mic1"}, 0}, {{"mic2"}, 1}, {{"line1"}, 2}, {{"line2"}, 3}, {{AudioNcd}, 4}, {{AudioNmixerout}, 5}}}}, 0x05, MI_TARGET_CONNLIST}, {{0, {"adc05.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, ENUM_OFFON}, 0x05, MI_TARGET_INAMP(0)}, {{0, {"adc05"}, AUDIO_MIXER_VALUE, AZ_CLASS_RECORD, 0, 0, .un.v={{""}, 2, MIXER_DELTA(35)}}, 0x05, MI_TARGET_INAMP(0)}, {{0, {"usingdac"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, .un.e={2, {{{"analog"}, 0}, {{"digital"}, 1}}}}, 0, MI_TARGET_DAC}, {{0, {"usingadc"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, .un.e={3, {{{"adc04"}, 0}, {{"adc05"}, 1}, {{"digital"}, 2}}}}, 0, MI_TARGET_ADC}, }; static const mixer_item_t alc260_loox_mixer_items[] = { {{AZ_CLASS_INPUT, {AudioCinputs}, AUDIO_MIXER_CLASS, AZ_CLASS_INPUT, 0, 0}, 0}, {{AZ_CLASS_OUTPUT, {AudioCoutputs}, AUDIO_MIXER_CLASS, AZ_CLASS_OUTPUT, 0, 0}, 0}, {{AZ_CLASS_RECORD, {AudioCrecord}, AUDIO_MIXER_CLASS, AZ_CLASS_RECORD, 0, 0}, 0}, {{0, {AudioNmaster}, AUDIO_MIXER_VALUE, AZ_CLASS_OUTPUT, 0, 0, .un.v={{""}, 2, 3}}, 0x08, MI_TARGET_OUTAMP}, /* and 0x09, 0x0a(mono) */ {{0, {AudioNmaster".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x10, MI_TARGET_OUTAMP}, {{0, {AudioNmaster".boost"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x10, MI_TARGET_PINBOOST}, {{0, {AudioNheadphone".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x14, MI_TARGET_OUTAMP}, {{0, {AudioNheadphone".boost"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x14, MI_TARGET_PINBOOST}, {{0, {AudioNdac".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x08, MI_TARGET_INAMP(0)}, /* and 0x09, 0x0a(mono) */ {{0, {AudioNmicrophone".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(0)}, {{0, {AudioNmicrophone}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(0)}, {{0, {AudioNcd".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(4)}, {{0, {AudioNcd}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(4)}, {{0, {AudioNspeaker".mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, ENUM_OFFON}, 0x07, MI_TARGET_INAMP(5)}, {{0, {AudioNspeaker}, AUDIO_MIXER_VALUE, AZ_CLASS_INPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(65)}}, 0x07, MI_TARGET_INAMP(5)}, {{0, {"adc04.source"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, .un.e={2, {{{AudioNmicrophone}, 0}, {{AudioNcd}, 4}}}}, 0x04, MI_TARGET_CONNLIST}, {{0, {"adc04.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, ENUM_OFFON}, 0x04, MI_TARGET_INAMP(0)}, {{0, {"adc04"}, AUDIO_MIXER_VALUE, AZ_CLASS_RECORD, 0, 0, .un.v={{""}, 2, MIXER_DELTA(35)}}, 0x04, MI_TARGET_INAMP(0)}, {{0, {"adc05.source"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, .un.e={3, {{{AudioNmicrophone}, 0}, {{AudioNcd}, 4}, {{AudioNmixerout}, 5}}}}, 0x05, MI_TARGET_CONNLIST}, {{0, {"adc05.mute"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, ENUM_OFFON}, 0x05, MI_TARGET_INAMP(0)}, {{0, {"adc05"}, AUDIO_MIXER_VALUE, AZ_CLASS_RECORD, 0, 0, .un.v={{""}, 2, MIXER_DELTA(35)}}, 0x05, MI_TARGET_INAMP(0)}, {{0, {"usingdac"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, .un.e={2, {{{"analog"}, 0}, {{"digital"}, 1}}}}, 0, MI_TARGET_DAC}, {{0, {"usingadc"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, .un.e={3, {{{"adc04"}, 0}, {{"adc05"}, 1}, {{"digital"}, 2}}}}, 0, MI_TARGET_ADC}, }; int azalia_alc260_mixer_init(codec_t *this) { const mixer_item_t *mi; mixer_ctrl_t mc; switch (this->subid) { case ALC260_FUJITSU_ID: this->nmixers = sizeof(alc260_loox_mixer_items) / sizeof(mixer_item_t); mi = alc260_loox_mixer_items; break; default: this->nmixers = sizeof(alc260_mixer_items) / sizeof(mixer_item_t); mi = alc260_mixer_items; } this->mixers = malloc(sizeof(mixer_item_t) * this->nmixers, M_DEVBUF, M_NOWAIT); if (this->mixers == NULL) { printf("%s: out of memory in %s\n", XNAME(this), __func__); return ENOMEM; } bzero(this->mixers, sizeof(mixer_item_t) * this->nmixers); memcpy(this->mixers, mi, sizeof(mixer_item_t) * this->nmixers); azalia_generic_mixer_fix_indexes(this); azalia_generic_mixer_default(this); mc.dev = -1; /* no need for generic_mixer_set() */ mc.type = AUDIO_MIXER_ENUM; mc.un.ord = 1; /* pindir: output */ azalia_generic_mixer_set(this, 0x0f, MI_TARGET_PINDIR, &mc); /* lineout */ azalia_generic_mixer_set(this, 0x10, MI_TARGET_PINDIR, &mc); /* headphones */ mc.un.ord = 0; /* pindir: input */ azalia_generic_mixer_set(this, 0x12, MI_TARGET_PINDIR, &mc); /* mic1 */ azalia_generic_mixer_set(this, 0x13, MI_TARGET_PINDIR, &mc); /* mic2 */ azalia_generic_mixer_set(this, 0x14, MI_TARGET_PINDIR, &mc); /* line1 */ azalia_generic_mixer_set(this, 0x15, MI_TARGET_PINDIR, &mc); /* line2 */ mc.un.ord = 0; /* mute: off */ azalia_generic_mixer_set(this, 0x08, MI_TARGET_INAMP(0), &mc); azalia_generic_mixer_set(this, 0x08, MI_TARGET_INAMP(1), &mc); azalia_generic_mixer_set(this, 0x09, MI_TARGET_INAMP(0), &mc); azalia_generic_mixer_set(this, 0x09, MI_TARGET_INAMP(1), &mc); azalia_generic_mixer_set(this, 0x0a, MI_TARGET_INAMP(0), &mc); azalia_generic_mixer_set(this, 0x0a, MI_TARGET_INAMP(1), &mc); if (this->subid == ALC260_FUJITSU_ID) { mc.un.ord = 1; /* pindir: output */ azalia_generic_mixer_set(this, 0x14, MI_TARGET_PINDIR, &mc); /* line1 */ mc.un.ord = 4; /* connlist: cd */ azalia_generic_mixer_set(this, 0x05, MI_TARGET_CONNLIST, &mc); } return 0; } int azalia_alc260_init_dacgroup(codec_t *this) { static const convgroupset_t dacs = { -1, 2, {{1, {0x02}}, /* analog 2ch */ {1, {0x03}}}}; /* digital */ static const convgroupset_t adcs = { -1, 3, {{1, {0x04}}, /* analog 2ch */ {1, {0x05}}, /* analog 2ch */ {1, {0x06}}}}; /* digital */ this->dacs = dacs; this->adcs = adcs; return 0; } int azalia_alc260_set_port(codec_t *this, mixer_ctrl_t *mc) { const mixer_item_t *m; mixer_ctrl_t mc2; int err; if (mc->dev >= this->nmixers) return ENXIO; m = &this->mixers[mc->dev]; if (mc->type != m->devinfo.type) return EINVAL; if (mc->type == AUDIO_MIXER_CLASS) return 0; if (m->nid == 0x08 && m->target == MI_TARGET_OUTAMP) { DPRINTF(("%s: hook for outputs.master\n", __func__)); err = azalia_generic_mixer_set(this, m->nid, m->target, mc); if (!err) { azalia_generic_mixer_set(this, 0x09, m->target, mc); mc2 = *mc; mc2.un.value.num_channels = 1; mc2.un.value.level[0] = (mc2.un.value.level[0] + mc2.un.value.level[1]) / 2; azalia_generic_mixer_set(this, 0x0a, m->target, &mc2); } return err; } else if (m->nid == 0x08 && m->target == MI_TARGET_INAMP(0)) { DPRINTF(("%s: hook for inputs.dac.mute\n", __func__)); err = azalia_generic_mixer_set(this, m->nid, m->target, mc); if (!err) { azalia_generic_mixer_set(this, 0x09, m->target, mc); azalia_generic_mixer_set(this, 0x0a, m->target, mc); } return err; } else if (m->nid == 0x04 && m->target == MI_TARGET_CONNLIST && m->devinfo.un.e.num_mem == 2) { if (1 <= mc->un.ord && mc->un.ord <= 3) return EINVAL; } else if (m->nid == 0x05 && m->target == MI_TARGET_CONNLIST && m->devinfo.un.e.num_mem == 3) { if (1 <= mc->un.ord && mc->un.ord <= 3) return EINVAL; } return azalia_generic_mixer_set(this, m->nid, m->target, mc); } /* ---------------------------------------------------------------- * Realtek ALC880 * ---------------------------------------------------------------- */ int azalia_alc880_init_dacgroup(codec_t *this) { static const convgroupset_t dacs = { -1, 2, {{4, {0x02, 0x03, 0x04, 0x05}}, /* analog 8ch */ {1, {0x06}}}}; /* digital */ static const convgroupset_t adcs = { -1, 2, {{2, {0x08, 0x09}}, /* analog 4ch */ {1, {0x0a}}}}; /* digital */ this->dacs = dacs; this->adcs = adcs; return 0; } /* ---------------------------------------------------------------- * Realtek ALC882 * ---------------------------------------------------------------- */ int azalia_alc882_init_dacgroup(codec_t *this) { static const convgroupset_t dacs = { -1, 3, {{4, {0x02, 0x03, 0x04, 0x05}}, /* analog 8ch */ {1, {0x06}}, /* digital */ {1, {0x25}}}}; /* another analog */ static const convgroupset_t adcs = { -1, 2, {{3, {0x07, 0x08, 0x09}}, /* analog 6ch */ {1, {0x0a}}}}; /* digital */ this->dacs = dacs; this->adcs = adcs; return 0; } int azalia_alc882_init_widget(const codec_t *this, widget_t *w, nid_t nid) { switch (nid) { case 0x14: strlcpy(w->name, "green", sizeof(w->name)); break; case 0x15: strlcpy(w->name, "gray", sizeof(w->name)); break; case 0x16: strlcpy(w->name, "orange", sizeof(w->name)); break; case 0x17: strlcpy(w->name, "black", sizeof(w->name)); break; case 0x18: strlcpy(w->name, "mic1", sizeof(w->name)); break; case 0x19: strlcpy(w->name, "mic2", sizeof(w->name)); break; case 0x1a: strlcpy(w->name, AudioNline, sizeof(w->name)); break; case 0x1b: /* AudioNheadphone is too long */ strlcpy(w->name, "hp", sizeof(w->name)); break; case 0x1c: strlcpy(w->name, AudioNcd, sizeof(w->name)); break; case 0x1d: strlcpy(w->name, AudioNspeaker, sizeof(w->name)); break; } return 0; } /* ---------------------------------------------------------------- * Analog Devices AD1981HD * ---------------------------------------------------------------- */ #if 0 int azalia_ad1981hd_init_widget(const codec_t *this, widget_t *w, nid_t nid) { switch (nid) { case 0x05: strlcpy(w->name, AudioNline "out", sizeof(w->name)); break; case 0x06: strlcpy(w->name, "hp", sizeof(w->name)); break; case 0x07: strlcpy(w->name, AudioNmono, sizeof(w->name)); break; case 0x08: strlcpy(w->name, AudioNmicrophone, sizeof(w->name)); break; case 0x09: strlcpy(w->name, AudioNline "in", sizeof(w->name)); break; case 0x0d: strlcpy(w->name, "beep", sizeof(w->name)); break; case 0x17: strlcpy(w->name, AudioNaux, sizeof(w->name)); break; case 0x18: strlcpy(w->name, AudioNmicrophone "2", sizeof(w->name)); break; case 0x19: strlcpy(w->name, AudioNcd, sizeof(w->name)); break; case 0x1d: strlcpy(w->name, AudioNspeaker, sizeof(w->name)); break; } return 0; } #endif /* ---------------------------------------------------------------- * Sigmatel STAC9221 and STAC9221D * ---------------------------------------------------------------- */ int azalia_stac9221_init_dacgroup(codec_t *this) { static const convgroupset_t dacs = { -1, 3, {{4, {0x02, 0x03, 0x04, 0x05}}, /* analog 8ch */ {1, {0x08}}, /* digital */ {1, {0x1a}}}}; /* another digital? */ static const convgroupset_t adcs = { -1, 2, {{2, {0x06, 0x07}}, /* analog 4ch */ {1, {0x09}}}}; /* digital */ this->dacs = dacs; this->adcs = adcs; return 0; } /* ---------------------------------------------------------------- * Sigmatel STAC9220 * ---------------------------------------------------------------- */ static const mixer_item_t stac9220_mixer_items[] = { {{AZ_CLASS_INPUT, {AudioCinputs}, AUDIO_MIXER_CLASS, AZ_CLASS_INPUT, 0, 0}, 0}, {{AZ_CLASS_OUTPUT, {AudioCoutputs}, AUDIO_MIXER_CLASS, AZ_CLASS_OUTPUT, 0, 0}, 0}, {{AZ_CLASS_RECORD, {AudioCrecord}, AUDIO_MIXER_CLASS, AZ_CLASS_RECORD, 0, 0}, 0}, {{0, {AudioNsource}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, .un.e={3, {{{AudioNdac}, 0}, {{"digital-in"}, 1}, {{"selector"}, 2}}}}, 0x07, MI_TARGET_CONNLIST}, {{0, {"digital."AudioNsource}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, .un.e={2, {{{AudioNdac}, 0}, {{"selector"}, 1}}}}, 0x09, MI_TARGET_CONNLIST}, /* AudioNdac is not accurate name */ {{0, {"selector."AudioNmute}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x0a, MI_TARGET_OUTAMP}, {{0, {"selector"}, AUDIO_MIXER_VALUE, AZ_CLASS_OUTPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(15)}}, 0x0a, MI_TARGET_OUTAMP}, {{0, {AudioNmaster"."AudioNmute}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x0b, MI_TARGET_OUTAMP}, {{0, {AudioNmaster}, AUDIO_MIXER_VALUE, AZ_CLASS_OUTPUT, 0, 0, .un.v={{""}, 2, MIXER_DELTA(31)}}, 0x0b, MI_TARGET_OUTAMP}, {{0, {"selector."AudioNsource}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, .un.e={3, {{{"mic1"}, 0}, {{"mic2"}, 1}, {{AudioNcd}, 4}}}}, 0x0c, MI_TARGET_CONNLIST}, {{0, {AudioNheadphone".boost"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x0d, MI_TARGET_PINBOOST}, {{0, {AudioNspeaker".boost"}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x0e, MI_TARGET_PINBOOST}, {{0, {AudioNmono"."AudioNmute}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x11, MI_TARGET_OUTAMP}, {{0, {AudioNmono}, AUDIO_MIXER_VALUE, AZ_CLASS_OUTPUT, 0, 0, .un.v={{""}, 1, MIXER_DELTA(31)}}, 0x11, MI_TARGET_OUTAMP}, {{0, {"beep."AudioNmute}, AUDIO_MIXER_ENUM, AZ_CLASS_OUTPUT, 0, 0, ENUM_OFFON}, 0x14, MI_TARGET_OUTAMP}, {{0, {"beep"}, AUDIO_MIXER_VALUE, AZ_CLASS_OUTPUT, 0, 0, .un.v={{""}, 1, MIXER_DELTA(3)}}, 0x14, MI_TARGET_OUTAMP}, {{0, {"usingdac"}, AUDIO_MIXER_ENUM, AZ_CLASS_INPUT, 0, 0, .un.e={2, {{{"analog"}, 0}, {{"digital"}, 1}}}}, 0, MI_TARGET_DAC}, {{0, {"usingadc"}, AUDIO_MIXER_ENUM, AZ_CLASS_RECORD, 0, 0, .un.e={2, {{{"analog"}, 0}, {{"digital"}, 1}}}}, 0, MI_TARGET_ADC}, }; int azalia_stac9220_mixer_init(codec_t *this) { mixer_ctrl_t mc; this->nmixers = sizeof(stac9220_mixer_items) / sizeof(mixer_item_t); this->mixers = malloc(sizeof(mixer_item_t) * this->nmixers, M_DEVBUF, M_NOWAIT); if (this->mixers == NULL) { printf("%s: out of memory in %s\n", XNAME(this), __func__); return ENOMEM; } bzero(this->mixers, sizeof(mixer_item_t) * this->maxmixers); memcpy(this->mixers, stac9220_mixer_items, sizeof(mixer_item_t) * this->nmixers); azalia_generic_mixer_fix_indexes(this); azalia_generic_mixer_default(this); mc.dev = -1; /* no need for generic_mixer_set() */ mc.type = AUDIO_MIXER_ENUM; mc.un.ord = 1; /* pindir: output */ azalia_generic_mixer_set(this, 0x0d, MI_TARGET_PINDIR, &mc); /* headphones */ azalia_generic_mixer_set(this, 0x0e, MI_TARGET_PINDIR, &mc); /* speaker */ mc.un.ord = 0; /* pindir: input */ azalia_generic_mixer_set(this, 0x0f, MI_TARGET_PINDIR, &mc); /* mic2 */ azalia_generic_mixer_set(this, 0x10, MI_TARGET_PINDIR, &mc); /* mic1 */ mc.type = AUDIO_MIXER_VALUE; mc.un.value.num_channels = 2; mc.un.value.level[0] = azalia_generic_mixer_max(this, 0x0c, MI_TARGET_OUTAMP); mc.un.value.level[1] = mc.un.value.level[0]; azalia_generic_mixer_set(this, 0x0c, MI_TARGET_OUTAMP, &mc); return 0; }