/* $OpenBSD: auich.c,v 1.37 2003/10/10 04:38:56 jason Exp $ */ /* * Copyright (c) 2000,2001 Michael Shalayeff * 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 ``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 HIS RELATIVES 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 MIND, 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. */ /* #define AUICH_DEBUG */ /* * AC'97 audio found on Intel 810/815/820/440MX chipsets. * http://developer.intel.com/design/chipsets/datashts/290655.htm * http://developer.intel.com/design/chipsets/manuals/298028.htm * http://www.intel.com/design/chipsets/datashts/290716.htm * http://www.intel.com/design/chipsets/datashts/290744.htm */ #include #include #include #include #include #include #include #include #include #include #include #include #include /* 12.1.10 NAMBAR - native audio mixer base address register */ #define AUICH_NAMBAR 0x10 /* 12.1.11 NABMBAR - native audio bus mastering base address register */ #define AUICH_NABMBAR 0x14 /* table 12-3. native audio bus master control registers */ #define AUICH_BDBAR 0x00 /* 8-byte aligned address */ #define AUICH_CIV 0x04 /* 5 bits current index value */ #define AUICH_LVI 0x05 /* 5 bits last valid index value */ #define AUICH_LVI_MASK 0x1f #define AUICH_STS 0x06 /* 16 bits status */ #define AUICH_FIFOE 0x10 /* fifo error */ #define AUICH_BCIS 0x08 /* r- buf cmplt int sts; wr ack */ #define AUICH_LVBCI 0x04 /* r- last valid bci, wr ack */ #define AUICH_CELV 0x02 /* current equals last valid */ #define AUICH_DCH 0x01 /* dma halted */ #define AUICH_ISTS_BITS "\020\01dch\02celv\03lvbci\04bcis\05fifoe" #define AUICH_PICB 0x08 /* 16 bits */ #define AUICH_PIV 0x0a /* 5 bits prefetched index value */ #define AUICH_CTRL 0x0b /* control */ #define AUICH_IOCE 0x10 /* int on completion enable */ #define AUICH_FEIE 0x08 /* fifo error int enable */ #define AUICH_LVBIE 0x04 /* last valid buf int enable */ #define AUICH_RR 0x02 /* 1 - reset regs */ #define AUICH_RPBM 0x01 /* 1 - run, 0 - pause */ #define AUICH_PCMI 0x00 #define AUICH_PCMO 0x10 #define AUICH_MICI 0x20 #define AUICH_GCTRL 0x2c #define AUICH_SSM_78 0x40000000 /* S/PDIF slots 7 and 8 */ #define AUICH_SSM_69 0x80000000 /* S/PDIF slots 6 and 9 */ #define AUICH_SSM_1011 0xc0000000 /* S/PDIF slots 10 and 11 */ #define AUICH_POM16 0x000000 /* PCM out precision 16bit */ #define AUICH_POM20 0x400000 /* PCM out precision 20bit */ #define AUICH_PCM246_MASK 0x300000 #define AUICH_PCM2 0x000000 /* 2ch output */ #define AUICH_PCM4 0x100000 /* 4ch output */ #define AUICH_PCM6 0x200000 /* 6ch output */ #define AUICH_S2RIE 0x40 /* int when tertiary codec resume */ #define AUICH_SRIE 0x20 /* int when 2ndary codec resume */ #define AUICH_PRIE 0x10 /* int when primary codec resume */ #define AUICH_ACLSO 0x08 /* aclink shut off */ #define AUICH_WRESET 0x04 /* warm reset */ #define AUICH_CRESET 0x02 /* cold reset */ #define AUICH_GIE 0x01 /* gpi int enable */ #define AUICH_GSTS 0x30 #define AUICH_MD3 0x20000 /* pwr-dn semaphore for modem */ #define AUICH_AD3 0x10000 /* pwr-dn semaphore for audio */ #define AUICH_RCS 0x08000 /* read completion status */ #define AUICH_B3S12 0x04000 /* bit 3 of slot 12 */ #define AUICH_B2S12 0x02000 /* bit 2 of slot 12 */ #define AUICH_B1S12 0x01000 /* bit 1 of slot 12 */ #define AUICH_SRI 0x00800 /* secondary resume int */ #define AUICH_PRI 0x00400 /* primary resume int */ #define AUICH_SCR 0x00200 /* secondary codec ready */ #define AUICH_PCR 0x00100 /* primary codec ready */ #define AUICH_MINT 0x00080 /* mic in int */ #define AUICH_POINT 0x00040 /* pcm out int */ #define AUICH_PIINT 0x00020 /* pcm in int */ #define AUICH_MOINT 0x00004 /* modem out int */ #define AUICH_MIINT 0x00002 /* modem in int */ #define AUICH_GSCI 0x00001 /* gpi status change */ #define AUICH_GSTS_BITS "\020\01gsci\02miict\03moint\06piint\07point\010mint\011pcr\012scr\013pri\014sri\015b1s12\016b2s12\017b3s12\020rcs\021ad3\022md3" #define AUICH_CAS 0x34 /* 1/8 bit */ #define AUICH_SEMATIMO 1000 /* us */ #define AUICH_RESETIMO 500000 /* us */ /* * according to the dev/audiovar.h AU_RING_SIZE is 2^16, what fits * in our limits perfectly, i.e. setting it to higher value * in your kernel config would improve perfomance, still 2^21 is the max */ #define AUICH_DMALIST_MAX 32 #define AUICH_DMASEG_MAX (65536*2) /* 64k samples, 2x16 bit samples */ struct auich_dmalist { u_int32_t base; u_int32_t len; #define AUICH_DMAF_IOC 0x80000000 /* 1-int on complete */ #define AUICH_DMAF_BUP 0x40000000 /* 0-retrans last, 1-transmit 0 */ }; #define AUICH_FIXED_RATE 48000 struct auich_dma { bus_dmamap_t map; caddr_t addr; bus_dma_segment_t segs[AUICH_DMALIST_MAX]; int nsegs; size_t size; struct auich_dma *next; }; struct auich_softc { struct device sc_dev; void *sc_ih; audio_device_t sc_audev; bus_space_tag_t iot; bus_space_handle_t mix_ioh; bus_space_handle_t aud_ioh; bus_dma_tag_t dmat; struct ac97_codec_if *codec_if; struct ac97_host_if host_if; /* dma scatter-gather buffer lists, aligned to 8 bytes */ struct auich_dmalist *dmalist_pcmo, *dmap_pcmo, dmasto_pcmo[AUICH_DMALIST_MAX+1]; struct auich_dmalist *dmalist_pcmi, *dmap_pcmi, dmasto_pcmi[AUICH_DMALIST_MAX+1]; struct auich_dmalist *dmalist_mici, *dmap_mici, dmasto_mici[AUICH_DMALIST_MAX+1]; /* i/o buffer pointers */ u_int32_t pcmo_start, pcmo_p, pcmo_end; int pcmo_blksize, pcmo_fifoe; u_int32_t pcmi_start, pcmi_p, pcmi_end; int pcmi_blksize, pcmi_fifoe; u_int32_t mici_start, mici_p, mici_end; int mici_blksize, mici_fifoe; struct auich_dma *sc_dmas; void (*sc_pintr)(void *); void *sc_parg; void (*sc_rintr)(void *); void *sc_rarg; void *powerhook; int suspend; u_int16_t ext_ctrl; int sc_sample_size; int sc_sts_reg; int sc_ignore_codecready; int flags; int sc_ac97rate; }; #ifdef AUICH_DEBUG #define DPRINTF(l,x) do { if (auich_debug & (l)) printf x; } while(0) int auich_debug = 0xfffe; #define AUICH_DEBUG_CODECIO 0x0001 #define AUICH_DEBUG_DMA 0x0002 #define AUICH_DEBUG_PARAM 0x0004 #else #define DPRINTF(x,y) /* nothing */ #endif struct cfdriver auich_cd = { NULL, "auich", DV_DULL }; int auich_match(struct device *, void *, void *); void auich_attach(struct device *, struct device *, void *); int auich_intr(void *); struct cfattach auich_ca = { sizeof(struct auich_softc), auich_match, auich_attach }; static const struct auich_devtype { int vendor; int product; int options; char name[8]; } auich_devices[] = { { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_82801AA_ACA, 0, "ICH" }, { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_82801AB_ACA, 0, "ICH0" }, { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_82801BA_ACA, 0, "ICH2" }, { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_82801CA_ACA, 0, "ICH3" }, { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_82801DB_ACA, 0, "ICH4" }, { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_82801EB_ACA, 0, "ICH5" }, { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_82440MX_ACA, 0, "440MX" }, { PCI_VENDOR_SIS, PCI_PRODUCT_SIS_7012_ACA, 0, "SiS7012" }, { PCI_VENDOR_NVIDIA, PCI_PRODUCT_NVIDIA_NFORCE_ACA, 0, "nForce" }, { PCI_VENDOR_NVIDIA, PCI_PRODUCT_NVIDIA_NFORCE2_ACA, 0, "nForce2" }, { PCI_VENDOR_AMD, PCI_PRODUCT_AMD_PBC768_ACA, 0, "AMD768" }, { PCI_VENDOR_AMD, PCI_PRODUCT_AMD_8111_ACA, 0, "AMD8111" }, }; int auich_open(void *, int); void auich_close(void *); int auich_query_encoding(void *, struct audio_encoding *); int auich_set_params(void *, int, int, struct audio_params *, struct audio_params *); int auich_round_blocksize(void *, int); int auich_halt_output(void *); int auich_halt_input(void *); int auich_getdev(void *, struct audio_device *); int auich_set_port(void *, mixer_ctrl_t *); int auich_get_port(void *, mixer_ctrl_t *); int auich_query_devinfo(void *, mixer_devinfo_t *); void *auich_allocm(void *, int, size_t, int, int); void auich_freem(void *, void *, int); size_t auich_round_buffersize(void *, int, size_t); paddr_t auich_mappage(void *, void *, off_t, int); int auich_get_props(void *); int auich_trigger_output(void *, void *, void *, int, void (*)(void *), void *, struct audio_params *); int auich_trigger_input(void *, void *, void *, int, void (*)(void *), void *, struct audio_params *); void auich_powerhook(int, void *); struct audio_hw_if auich_hw_if = { auich_open, auich_close, NULL, /* drain */ auich_query_encoding, auich_set_params, auich_round_blocksize, NULL, /* commit_setting */ NULL, /* init_output */ NULL, /* init_input */ NULL, /* start_output */ NULL, /* start_input */ auich_halt_output, auich_halt_input, NULL, /* speaker_ctl */ auich_getdev, NULL, /* getfd */ auich_set_port, auich_get_port, auich_query_devinfo, auich_allocm, auich_freem, auich_round_buffersize, auich_mappage, auich_get_props, auich_trigger_output, auich_trigger_input }; int auich_attach_codec(void *, struct ac97_codec_if *); int auich_read_codec(void *, u_int8_t, u_int16_t *); int auich_write_codec(void *, u_int8_t, u_int16_t); void auich_reset_codec(void *); enum ac97_host_flags auich_flags_codec(void *); unsigned int auich_calibrate(struct auich_softc *); int auich_match(parent, match, aux) struct device *parent; void *match; void *aux; { struct pci_attach_args *pa = aux; int i; for (i = sizeof(auich_devices)/sizeof(auich_devices[0]); i--;) if (PCI_VENDOR(pa->pa_id) == auich_devices[i].vendor && PCI_PRODUCT(pa->pa_id) == auich_devices[i].product) return 1; return 0; } void auich_attach(parent, self, aux) struct device *parent, *self; void *aux; { struct auich_softc *sc = (struct auich_softc *)self; struct pci_attach_args *pa = aux; pci_intr_handle_t ih; bus_size_t mix_size, aud_size; pcireg_t csr; const char *intrstr; u_int32_t status; int i; /* SiS 7012 needs special handling */ if (PCI_VENDOR(pa->pa_id) == PCI_VENDOR_SIS && PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_SIS_7012_ACA) { sc->sc_sts_reg = AUICH_PICB; sc->sc_sample_size = 1; } else { sc->sc_sts_reg = AUICH_STS; sc->sc_sample_size = 2; } if (pci_mapreg_map(pa, AUICH_NAMBAR, PCI_MAPREG_TYPE_IO, 0, &sc->iot, &sc->mix_ioh, NULL, &mix_size, 0)) { printf(": can't map codec i/o space\n"); return; } if (pci_mapreg_map(pa, AUICH_NABMBAR, PCI_MAPREG_TYPE_IO, 0, &sc->iot, &sc->aud_ioh, NULL, &aud_size, 0)) { printf(": can't map device i/o space\n"); bus_space_unmap(sc->iot, sc->mix_ioh, mix_size); return; } sc->dmat = pa->pa_dmat; /* enable bus mastering (should not it be mi?) */ csr = pci_conf_read(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG); pci_conf_write(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG, csr | PCI_COMMAND_MASTER_ENABLE); if (pci_intr_map(pa, &ih)) { printf(": can't map interrupt\n"); bus_space_unmap(sc->iot, sc->aud_ioh, aud_size); bus_space_unmap(sc->iot, sc->mix_ioh, mix_size); return; } intrstr = pci_intr_string(pa->pa_pc, ih); sc->sc_ih = pci_intr_establish(pa->pa_pc, ih, IPL_AUDIO, auich_intr, sc, sc->sc_dev.dv_xname); if (!sc->sc_ih) { printf(": can't establish interrupt"); if (intrstr) printf(" at %s", intrstr); printf("\n"); bus_space_unmap(sc->iot, sc->aud_ioh, aud_size); bus_space_unmap(sc->iot, sc->mix_ioh, mix_size); return; } for (i = sizeof(auich_devices)/sizeof(auich_devices[0]); i--;) if (PCI_PRODUCT(pa->pa_id) == auich_devices[i].product) break; snprintf(sc->sc_audev.name, sizeof sc->sc_audev.name, "%s AC97", auich_devices[i].name); snprintf(sc->sc_audev.version, sizeof sc->sc_audev.version, "0x%02x", PCI_REVISION(pa->pa_class)); strlcpy(sc->sc_audev.config, sc->sc_dev.dv_xname, sizeof sc->sc_audev.config); printf(": %s, %s\n", intrstr, sc->sc_audev.name); /* allocate dma lists */ #define a(a) (void *)(((u_long)(a) + sizeof(*(a)) - 1) & ~(sizeof(*(a))-1)) sc->dmalist_pcmo = sc->dmap_pcmo = a(sc->dmasto_pcmo); sc->dmalist_pcmi = sc->dmap_pcmi = a(sc->dmasto_pcmi); sc->dmalist_mici = sc->dmap_mici = a(sc->dmasto_mici); #undef a DPRINTF(AUICH_DEBUG_DMA, ("auich_attach: lists %p %p %p\n", sc->dmalist_pcmo, sc->dmalist_pcmi, sc->dmalist_mici)); /* Reset codec and AC'97 */ auich_reset_codec(sc); status = bus_space_read_4(sc->iot, sc->aud_ioh, AUICH_GSTS); if (!(status & AUICH_PCR)) { /* reset failure */ if (PCI_VENDOR(pa->pa_id) == PCI_VENDOR_INTEL && PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_INTEL_82801DB_ACA) { /* MSI 845G Max never return AUICH_PCR */ sc->sc_ignore_codecready = 1; } else return; } sc->host_if.arg = sc; sc->host_if.attach = auich_attach_codec; sc->host_if.read = auich_read_codec; sc->host_if.write = auich_write_codec; sc->host_if.reset = auich_reset_codec; sc->host_if.flags = auich_flags_codec; if (sc->sc_dev.dv_cfdata->cf_flags & 0x0001) sc->flags = AC97_HOST_SWAPPED_CHANNELS; if (ac97_attach(&sc->host_if) != 0) { pci_intr_disestablish(pa->pa_pc, sc->sc_ih); bus_space_unmap(sc->iot, sc->aud_ioh, aud_size); bus_space_unmap(sc->iot, sc->mix_ioh, mix_size); return; } audio_attach_mi(&auich_hw_if, sc, &sc->sc_dev); /* Watch for power changes */ sc->suspend = PWR_RESUME; sc->powerhook = powerhook_establish(auich_powerhook, sc); sc->sc_ac97rate = auich_calibrate(sc); } int auich_read_codec(v, reg, val) void *v; u_int8_t reg; u_int16_t *val; { struct auich_softc *sc = v; int i; /* wait for an access semaphore */ for (i = AUICH_SEMATIMO; i-- && bus_space_read_1(sc->iot, sc->aud_ioh, AUICH_CAS) & 1; DELAY(1)); if (!sc->sc_ignore_codecready && i < 0) { DPRINTF(AUICH_DEBUG_CODECIO, ("%s: read_codec timeout\n", sc->sc_dev.dv_xname)); return (-1); } *val = bus_space_read_2(sc->iot, sc->mix_ioh, reg); DPRINTF(AUICH_DEBUG_CODECIO, ("%s: read_codec(%x, %x)\n", sc->sc_dev.dv_xname, reg, *val)); return (0); } int auich_write_codec(v, reg, val) void *v; u_int8_t reg; u_int16_t val; { struct auich_softc *sc = v; int i; /* wait for an access semaphore */ for (i = AUICH_SEMATIMO; i-- && bus_space_read_1(sc->iot, sc->aud_ioh, AUICH_CAS) & 1; DELAY(1)); if (sc->sc_ignore_codecready || i >= 0) { DPRINTF(AUICH_DEBUG_CODECIO, ("%s: write_codec(%x, %x)\n", sc->sc_dev.dv_xname, reg, val)); bus_space_write_2(sc->iot, sc->mix_ioh, reg, val); return (0); } else { DPRINTF(AUICH_DEBUG_CODECIO, ("%s: write_codec timeout\n", sc->sc_dev.dv_xname)); return (-1); } } int auich_attach_codec(v, cif) void *v; struct ac97_codec_if *cif; { struct auich_softc *sc = v; sc->codec_if = cif; return 0; } void auich_reset_codec(v) void *v; { struct auich_softc *sc = v; u_int32_t control; int i; control = bus_space_read_4(sc->iot, sc->aud_ioh, AUICH_GCTRL); control &= ~(AUICH_ACLSO | AUICH_PCM246_MASK); control |= (control & AUICH_CRESET) ? AUICH_WRESET : AUICH_CRESET; bus_space_write_4(sc->iot, sc->aud_ioh, AUICH_GCTRL, AUICH_CRESET); for (i = AUICH_RESETIMO; i-- && !(bus_space_read_4(sc->iot, sc->aud_ioh, AUICH_GSTS) & AUICH_PCR); DELAY(1)); if (i < 0) DPRINTF(AUICH_DEBUG_CODECIO, ("%s: reset_codec timeout\n", sc->sc_dev.dv_xname)); } enum ac97_host_flags auich_flags_codec(void *v) { struct auich_softc *sc = v; return (sc->flags); } int auich_open(v, flags) void *v; int flags; { return 0; } void auich_close(v) void *v; { } int auich_query_encoding(v, aep) void *v; struct audio_encoding *aep; { switch (aep->index) { case 0: strlcpy(aep->name, AudioEulinear, sizeof aep->name); aep->encoding = AUDIO_ENCODING_ULINEAR; aep->precision = 8; aep->flags = 0; return (0); case 1: strlcpy(aep->name, AudioEmulaw, sizeof aep->name); aep->encoding = AUDIO_ENCODING_ULAW; aep->precision = 8; aep->flags = AUDIO_ENCODINGFLAG_EMULATED; return (0); case 2: strlcpy(aep->name, AudioEalaw, sizeof aep->name); aep->encoding = AUDIO_ENCODING_ALAW; aep->precision = 8; aep->flags = AUDIO_ENCODINGFLAG_EMULATED; return (0); case 3: strlcpy(aep->name, AudioEslinear, sizeof aep->name); aep->encoding = AUDIO_ENCODING_SLINEAR; aep->precision = 8; aep->flags = AUDIO_ENCODINGFLAG_EMULATED; return (0); case 4: strlcpy(aep->name, AudioEslinear_le, sizeof aep->name); aep->encoding = AUDIO_ENCODING_SLINEAR_LE; aep->precision = 16; aep->flags = 0; return (0); case 5: strlcpy(aep->name, AudioEulinear_le, sizeof aep->name); aep->encoding = AUDIO_ENCODING_ULINEAR_LE; aep->precision = 16; aep->flags = AUDIO_ENCODINGFLAG_EMULATED; return (0); case 6: strlcpy(aep->name, AudioEslinear_be, sizeof aep->name); aep->encoding = AUDIO_ENCODING_SLINEAR_BE; aep->precision = 16; aep->flags = AUDIO_ENCODINGFLAG_EMULATED; return (0); case 7: strlcpy(aep->name, AudioEulinear_be, sizeof aep->name); aep->encoding = AUDIO_ENCODING_ULINEAR_BE; aep->precision = 16; aep->flags = AUDIO_ENCODINGFLAG_EMULATED; return (0); default: return (EINVAL); } } int auich_set_params(v, setmode, usemode, play, rec) void *v; int setmode, usemode; struct audio_params *play, *rec; { struct auich_softc *sc = v; int error; u_int orate; if (setmode & AUMODE_PLAY) { play->factor = 1; play->sw_code = NULL; switch(play->encoding) { case AUDIO_ENCODING_ULAW: switch (play->channels) { case 1: play->factor = 4; play->sw_code = mulaw_to_slinear16_mts; break; case 2: play->factor = 2; play->sw_code = mulaw_to_slinear16; break; default: return (EINVAL); } break; case AUDIO_ENCODING_SLINEAR_LE: switch (play->precision) { case 8: switch (play->channels) { case 1: play->factor = 4; play->sw_code = linear8_to_linear16_mts; break; case 2: play->factor = 2; play->sw_code = linear8_to_linear16; break; default: return (EINVAL); } break; case 16: switch (play->channels) { case 1: play->factor = 2; play->sw_code = noswap_bytes_mts; break; case 2: break; default: return (EINVAL); } break; default: return (EINVAL); } break; case AUDIO_ENCODING_ULINEAR_LE: switch (play->precision) { case 8: switch (play->channels) { case 1: play->factor = 4; play->sw_code = ulinear8_to_linear16_mts; break; case 2: play->factor = 2; play->sw_code = ulinear8_to_linear16; break; default: return (EINVAL); } break; case 16: switch (play->channels) { case 1: play->factor = 2; play->sw_code = change_sign16_mts; break; case 2: play->sw_code = change_sign16; break; default: return (EINVAL); } break; default: return (EINVAL); } break; case AUDIO_ENCODING_ALAW: switch (play->channels) { case 1: play->factor = 4; play->sw_code = alaw_to_slinear16_mts; case 2: play->factor = 2; play->sw_code = alaw_to_slinear16; default: return (EINVAL); } break; case AUDIO_ENCODING_SLINEAR_BE: switch (play->precision) { case 8: switch (play->channels) { case 1: play->factor = 4; play->sw_code = linear8_to_linear16_mts; break; case 2: play->factor = 2; play->sw_code = linear8_to_linear16; break; default: return (EINVAL); } break; case 16: switch (play->channels) { case 1: play->factor = 2; play->sw_code = swap_bytes_mts; break; case 2: play->sw_code = swap_bytes; break; default: return (EINVAL); } break; default: return (EINVAL); } break; case AUDIO_ENCODING_ULINEAR_BE: switch (play->precision) { case 8: switch (play->channels) { case 1: play->factor = 4; play->sw_code = ulinear8_to_linear16_mts; break; case 2: play->factor = 2; play->sw_code = ulinear8_to_linear16; break; default: return (EINVAL); } break; case 16: switch (play->channels) { case 1: play->factor = 2; play->sw_code = change_sign16_swap_bytes_mts; break; case 2: play->sw_code = change_sign16_swap_bytes; break; default: return (EINVAL); } break; default: return (EINVAL); } break; default: return (EINVAL); } orate = play->sample_rate; if (sc->sc_ac97rate != 0) play->sample_rate = orate * AUICH_FIXED_RATE / sc->sc_ac97rate; error = ac97_set_rate(sc->codec_if, play, AUMODE_PLAY); play->sample_rate = orate; if (error) return (error); } if (setmode & AUMODE_RECORD) { rec->factor = 1; rec->sw_code = 0; switch(rec->encoding) { case AUDIO_ENCODING_ULAW: rec->sw_code = ulinear8_to_mulaw; break; case AUDIO_ENCODING_SLINEAR_LE: if (rec->precision == 8) rec->sw_code = change_sign8; break; case AUDIO_ENCODING_ULINEAR_LE: if (rec->precision == 16) rec->sw_code = change_sign16; break; case AUDIO_ENCODING_ALAW: rec->sw_code = ulinear8_to_alaw; break; case AUDIO_ENCODING_SLINEAR_BE: if (rec->precision == 16) rec->sw_code = swap_bytes; else rec->sw_code = change_sign8; break; case AUDIO_ENCODING_ULINEAR_BE: if (rec->precision == 16) rec->sw_code = swap_bytes_change_sign16; break; default: return (EINVAL); } orate = rec->sample_rate; if (sc->sc_ac97rate != 0) rec->sample_rate = orate * AUICH_FIXED_RATE / sc->sc_ac97rate; error = ac97_set_rate(sc->codec_if, rec, AUMODE_RECORD); rec->sample_rate = orate; if (error) return (error); } return (0); } int auich_round_blocksize(v, blk) void *v; int blk; { return blk & ~0x3f; } int auich_halt_output(v) void *v; { struct auich_softc *sc = v; DPRINTF(AUICH_DEBUG_DMA, ("%s: halt_output\n", sc->sc_dev.dv_xname)); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMO + AUICH_CTRL, AUICH_RR); return 0; } int auich_halt_input(v) void *v; { struct auich_softc *sc = v; DPRINTF(AUICH_DEBUG_DMA, ("%s: halt_input\n", sc->sc_dev.dv_xname)); /* XXX halt both unless known otherwise */ bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_CTRL, AUICH_RR); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_MICI + AUICH_CTRL, AUICH_RR); return 0; } int auich_getdev(v, adp) void *v; struct audio_device *adp; { struct auich_softc *sc = v; *adp = sc->sc_audev; return 0; } int auich_set_port(v, cp) void *v; mixer_ctrl_t *cp; { struct auich_softc *sc = v; return sc->codec_if->vtbl->mixer_set_port(sc->codec_if, cp); } int auich_get_port(v, cp) void *v; mixer_ctrl_t *cp; { struct auich_softc *sc = v; return sc->codec_if->vtbl->mixer_get_port(sc->codec_if, cp); } int auich_query_devinfo(v, dp) void *v; mixer_devinfo_t *dp; { struct auich_softc *sc = v; return sc->codec_if->vtbl->query_devinfo(sc->codec_if, dp); } void * auich_allocm(v, direction, size, pool, flags) void *v; int direction; size_t size; int pool, flags; { struct auich_softc *sc = v; struct auich_dma *p; int error; if (size > AUICH_DMALIST_MAX * AUICH_DMASEG_MAX) return NULL; p = malloc(sizeof(*p), pool, flags); if (!p) return NULL; bzero(p, sizeof(*p)); p->size = size; if ((error = bus_dmamem_alloc(sc->dmat, p->size, NBPG, 0, p->segs, 1, &p->nsegs, BUS_DMA_NOWAIT)) != 0) { printf("%s: unable to allocate dma, error = %d\n", sc->sc_dev.dv_xname, error); free(p, pool); return NULL; } if ((error = bus_dmamem_map(sc->dmat, p->segs, p->nsegs, p->size, &p->addr, BUS_DMA_NOWAIT | BUS_DMA_COHERENT)) != 0) { printf("%s: unable to map dma, error = %d\n", sc->sc_dev.dv_xname, error); bus_dmamem_free(sc->dmat, p->segs, p->nsegs); free(p, pool); return NULL; } if ((error = bus_dmamap_create(sc->dmat, p->size, 1, p->size, 0, BUS_DMA_NOWAIT, &p->map)) != 0) { printf("%s: unable to create dma map, error = %d\n", sc->sc_dev.dv_xname, error); bus_dmamem_unmap(sc->dmat, p->addr, size); bus_dmamem_free(sc->dmat, p->segs, p->nsegs); free(p, pool); return NULL; } if ((error = bus_dmamap_load(sc->dmat, p->map, p->addr, p->size, NULL, BUS_DMA_NOWAIT)) != 0) { printf("%s: unable to load dma map, error = %d\n", sc->sc_dev.dv_xname, error); bus_dmamap_destroy(sc->dmat, p->map); bus_dmamem_unmap(sc->dmat, p->addr, size); bus_dmamem_free(sc->dmat, p->segs, p->nsegs); free(p, pool); return NULL; } p->next = sc->sc_dmas; sc->sc_dmas = p; return p->addr; } void auich_freem(v, ptr, pool) void *v; void *ptr; int pool; { struct auich_softc *sc = v; struct auich_dma *p; for (p = sc->sc_dmas; p->addr != ptr; p = p->next) if (p->next == NULL) { printf("auich_freem: trying to free not allocated memory"); return; } bus_dmamap_unload(sc->dmat, p->map); bus_dmamap_destroy(sc->dmat, p->map); bus_dmamem_unmap(sc->dmat, p->addr, p->size); bus_dmamem_free(sc->dmat, p->segs, p->nsegs); free(p, pool); } size_t auich_round_buffersize(v, direction, size) void *v; int direction; size_t size; { if (size > AUICH_DMALIST_MAX * AUICH_DMASEG_MAX) size = AUICH_DMALIST_MAX * AUICH_DMASEG_MAX; return size; } paddr_t auich_mappage(v, mem, off, prot) void *v; void *mem; off_t off; int prot; { struct auich_softc *sc = v; struct auich_dma *p; if (off < 0) return -1; for (p = sc->sc_dmas; p && p->addr != mem; p = p->next); if (!p) return -1; return bus_dmamem_mmap(sc->dmat, p->segs, p->nsegs, off, prot, BUS_DMA_WAITOK); } int auich_get_props(v) void *v; { return AUDIO_PROP_MMAP | AUDIO_PROP_INDEPENDENT | AUDIO_PROP_FULLDUPLEX; } int auich_intr(v) void *v; { struct auich_softc *sc = v; int ret = 0, sts, gsts, i; gsts = bus_space_read_2(sc->iot, sc->aud_ioh, AUICH_GSTS); DPRINTF(AUICH_DEBUG_DMA, ("auich_intr: gsts=%b\n", gsts, AUICH_GSTS_BITS)); if (gsts & AUICH_POINT) { sts = bus_space_read_2(sc->iot, sc->aud_ioh, AUICH_PCMO + sc->sc_sts_reg); DPRINTF(AUICH_DEBUG_DMA, ("auich_intr: osts=%b\n", sts, AUICH_ISTS_BITS)); if (sts & AUICH_FIFOE) { printf("%s: fifo underrun # %u\n", sc->sc_dev.dv_xname, ++sc->pcmo_fifoe); } i = bus_space_read_1(sc->iot, sc->aud_ioh, AUICH_PCMO + AUICH_CIV); if (sts & (AUICH_LVBCI | AUICH_CELV)) { struct auich_dmalist *q, *qe; q = sc->dmap_pcmo; qe = &sc->dmalist_pcmo[i]; while (q != qe) { q->base = sc->pcmo_p; q->len = (sc->pcmo_blksize / sc->sc_sample_size) | AUICH_DMAF_IOC; DPRINTF(AUICH_DEBUG_DMA, ("auich_intr: %p, %p = %x @ %p\n", qe, q, sc->pcmo_blksize / sc->sc_sample_size, sc->pcmo_p)); sc->pcmo_p += sc->pcmo_blksize; if (sc->pcmo_p >= sc->pcmo_end) sc->pcmo_p = sc->pcmo_start; if (++q == &sc->dmalist_pcmo[AUICH_DMALIST_MAX]) q = sc->dmalist_pcmo; } sc->dmap_pcmo = q; bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMO + AUICH_LVI, (sc->dmap_pcmo - sc->dmalist_pcmo - 1) & AUICH_LVI_MASK); } if (sts & AUICH_BCIS && sc->sc_pintr) sc->sc_pintr(sc->sc_parg); /* int ack */ bus_space_write_2(sc->iot, sc->aud_ioh, AUICH_PCMO + sc->sc_sts_reg, sts & (AUICH_LVBCI | AUICH_CELV | AUICH_BCIS | AUICH_FIFOE)); bus_space_write_2(sc->iot, sc->aud_ioh, AUICH_GSTS, AUICH_POINT); ret++; } if (gsts & AUICH_PIINT) { sts = bus_space_read_2(sc->iot, sc->aud_ioh, AUICH_PCMI + sc->sc_sts_reg); DPRINTF(AUICH_DEBUG_DMA, ("auich_intr: ists=%b\n", sts, AUICH_ISTS_BITS)); if (sts & AUICH_FIFOE) { printf("%s: in fifo overrun # %u\n", sc->sc_dev.dv_xname, ++sc->pcmi_fifoe); } i = bus_space_read_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_CIV); if (sts & (AUICH_LVBCI | AUICH_CELV)) { struct auich_dmalist *q, *qe; q = sc->dmap_pcmi; qe = &sc->dmalist_pcmi[i]; while (q != qe) { q->base = sc->pcmi_p; q->len = (sc->pcmi_blksize / sc->sc_sample_size) | AUICH_DMAF_IOC; DPRINTF(AUICH_DEBUG_DMA, ("auich_intr: %p, %p = %x @ %p\n", qe, q, sc->pcmi_blksize / sc->sc_sample_size, sc->pcmi_p)); sc->pcmi_p += sc->pcmi_blksize; if (sc->pcmi_p >= sc->pcmi_end) sc->pcmi_p = sc->pcmi_start; if (++q == &sc->dmalist_pcmi[AUICH_DMALIST_MAX]) q = sc->dmalist_pcmi; } sc->dmap_pcmi = q; bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_LVI, (sc->dmap_pcmi - sc->dmalist_pcmi - 1) & AUICH_LVI_MASK); } if (sts & AUICH_BCIS && sc->sc_rintr) sc->sc_rintr(sc->sc_rarg); /* int ack */ bus_space_write_2(sc->iot, sc->aud_ioh, AUICH_PCMI + sc->sc_sts_reg, sts & (AUICH_LVBCI | AUICH_CELV | AUICH_BCIS | AUICH_FIFOE)); bus_space_write_2(sc->iot, sc->aud_ioh, AUICH_GSTS, AUICH_POINT); ret++; } if (gsts & AUICH_MIINT) { sts = bus_space_read_2(sc->iot, sc->aud_ioh, AUICH_MICI + sc->sc_sts_reg); DPRINTF(AUICH_DEBUG_DMA, ("auich_intr: ists=%b\n", sts, AUICH_ISTS_BITS)); if (sts & AUICH_FIFOE) printf("%s: mic fifo overrun\n", sc->sc_dev.dv_xname); /* TODO mic input dma */ bus_space_write_2(sc->iot, sc->aud_ioh, AUICH_GSTS, AUICH_MIINT); } return ret; } int auich_trigger_output(v, start, end, blksize, intr, arg, param) void *v; void *start, *end; int blksize; void (*intr)(void *); void *arg; struct audio_params *param; { struct auich_softc *sc = v; struct auich_dmalist *q; struct auich_dma *p; DPRINTF(AUICH_DEBUG_DMA, ("auich_trigger_output(%x, %x, %d, %p, %p, %p)\n", start, end, blksize, intr, arg, param)); for (p = sc->sc_dmas; p && p->addr != start; p = p->next); if (!p) return -1; sc->sc_pintr = intr; sc->sc_parg = arg; /* * The logic behind this is: * setup one buffer to play, then LVI dump out the rest * to the scatter-gather chain. */ sc->pcmo_start = p->segs->ds_addr; sc->pcmo_p = sc->pcmo_start + blksize; sc->pcmo_end = sc->pcmo_start + (end - start); sc->pcmo_blksize = blksize; q = sc->dmap_pcmo = sc->dmalist_pcmo; q->base = sc->pcmo_start; q->len = (blksize / sc->sc_sample_size) | AUICH_DMAF_IOC; if (++q == &sc->dmalist_pcmo[AUICH_DMALIST_MAX]) q = sc->dmalist_pcmo; sc->dmap_pcmo = q; bus_space_write_4(sc->iot, sc->aud_ioh, AUICH_PCMO + AUICH_BDBAR, kvtop((caddr_t)sc->dmalist_pcmo)); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMO + AUICH_CTRL, AUICH_IOCE | AUICH_FEIE | AUICH_LVBIE | AUICH_RPBM); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMO + AUICH_LVI, (sc->dmap_pcmo - 1 - sc->dmalist_pcmo) & AUICH_LVI_MASK); return 0; } int auich_trigger_input(v, start, end, blksize, intr, arg, param) void *v; void *start, *end; int blksize; void (*intr)(void *); void *arg; struct audio_params *param; { struct auich_softc *sc = v; struct auich_dmalist *q; struct auich_dma *p; DPRINTF(AUICH_DEBUG_DMA, ("auich_trigger_input(%x, %x, %d, %p, %p, %p)\n", start, end, blksize, intr, arg, param)); for (p = sc->sc_dmas; p && p->addr != start; p = p->next); if (!p) return -1; sc->sc_rintr = intr; sc->sc_rarg = arg; /* * The logic behind this is: * setup one buffer to play, then LVI dump out the rest * to the scatter-gather chain. */ sc->pcmi_start = p->segs->ds_addr; sc->pcmi_p = sc->pcmi_start + blksize; sc->pcmi_end = sc->pcmi_start + (end - start); sc->pcmi_blksize = blksize; q = sc->dmap_pcmi = sc->dmalist_pcmi; q->base = sc->pcmi_start; q->len = (blksize / sc->sc_sample_size) | AUICH_DMAF_IOC; if (++q == &sc->dmalist_pcmi[AUICH_DMALIST_MAX]) q = sc->dmalist_pcmi; sc->dmap_pcmi = q; bus_space_write_4(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_BDBAR, kvtop((caddr_t)sc->dmalist_pcmi)); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_CTRL, AUICH_IOCE | AUICH_FEIE | AUICH_LVBIE | AUICH_RPBM); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_LVI, (sc->dmap_pcmi - 1 - sc->dmalist_pcmi) & AUICH_LVI_MASK); return 0; } void auich_powerhook(why, self) int why; void *self; { struct auich_softc *sc = (struct auich_softc *)self; if (why != PWR_RESUME) { /* Power down */ DPRINTF(1, ("auich: power down\n")); sc->suspend = why; auich_read_codec(sc, AC97_REG_EXT_AUDIO_CTRL, &sc->ext_ctrl); } else { /* Wake up */ DPRINTF(1, ("auich: power resume\n")); if (sc->suspend == PWR_RESUME) { printf("%s: resume without suspend?\n", sc->sc_dev.dv_xname); sc->suspend = why; return; } sc->suspend = why; auich_reset_codec(sc); DELAY(1000); (sc->codec_if->vtbl->restore_ports)(sc->codec_if); auich_write_codec(sc, AC97_REG_EXT_AUDIO_CTRL, sc->ext_ctrl); } } /* -------------------------------------------------------------------- */ /* Calibrate card (some boards are overclocked and need scaling) */ unsigned int auich_calibrate(struct auich_softc *sc) { struct timeval t1, t2; u_int8_t ociv, nciv; u_int32_t wait_us, actual_48k_rate, bytes, ac97rate; void *temp_buffer; struct auich_dma *p; int i; ac97rate = AUICH_FIXED_RATE; /* * Grab audio from input for fixed interval and compare how * much we actually get with what we expect. Interval needs * to be sufficiently short that no interrupts are * generated. */ /* Setup a buffer */ bytes = 16000; temp_buffer = auich_allocm(sc, AUMODE_RECORD, bytes, M_DEVBUF, M_NOWAIT); if (temp_buffer == NULL) return (ac97rate); for (p = sc->sc_dmas; p && p->addr != temp_buffer; p = p->next) ; if (p == NULL) { printf("auich_calibrate: bad address %p\n", temp_buffer); return (ac97rate); } for (i = 0; i < AUICH_DMALIST_MAX; i++) { sc->dmalist_pcmi[i].base = p->map->dm_segs[0].ds_addr; sc->dmalist_pcmi[i].len = bytes / sc->sc_sample_size; } /* * our data format is stereo, 16 bit so each sample is 4 bytes. * assuming we get 48000 samples per second, we get 192000 bytes/sec. * we're going to start recording with interrupts disabled and measure * the time taken for one block to complete. we know the block size, * we know the time in microseconds, we calculate the sample rate: * * actual_rate [bps] = bytes / (time [s] * 4) * actual_rate [bps] = (bytes * 1000000) / (time [us] * 4) * actual_rate [Hz] = (bytes * 250000) / time [us] */ /* prepare */ ociv = bus_space_read_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_CIV); nciv = ociv; bus_space_write_4(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_BDBAR, kvtop((caddr_t)sc->dmalist_pcmi)); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_LVI, (0 - 1) & AUICH_LVI_MASK); /* start */ microtime(&t1); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_CTRL, AUICH_RPBM); /* wait */ while (nciv == ociv) { microtime(&t2); if (t2.tv_sec - t1.tv_sec > 1) break; nciv = bus_space_read_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_CIV); } microtime(&t2); /* reset */ bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_PCMI + AUICH_CTRL, AUICH_RR); bus_space_write_1(sc->iot, sc->aud_ioh, AUICH_MICI + AUICH_CTRL, AUICH_RR); DELAY(100); /* turn time delta into us */ wait_us = ((t2.tv_sec - t1.tv_sec) * 1000000) + t2.tv_usec - t1.tv_usec; #if 0 auich_freem(sc, temp_buffer, M_DEVBUF); #endif if (nciv == ociv) { printf("%s: ac97 link rate calibration timed out after %d us\n", sc->sc_dev.dv_xname, wait_us); return (ac97rate); } actual_48k_rate = (bytes * 250000) / wait_us; if (actual_48k_rate <= 48500) ac97rate = AUICH_FIXED_RATE; else ac97rate = actual_48k_rate; printf("%s: measured ac97 link rate at %d Hz", sc->sc_dev.dv_xname, actual_48k_rate); if (ac97rate != actual_48k_rate) printf(", will use %d Hz", ac97rate); printf("\n"); return (ac97rate); }