/* * sound/ad1848.c * * Driver for Microsoft Sound System/Windows Sound System (mss) * -compatible boards. This includes: * * AD1848, CS4248, CS423x, OPTi931, Yamaha OPL/SAx and many others. * * Copyright Luigi Rizzo, 1997,1998 * Copyright by Hannu Savolainen 1994, 1995 * * 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. * * Full data sheets in PDF format for the MSS-compatible chips * are available at * * http://www.crystal.com/ for the CS42XX series, or * http://www.opti.com/ for the OPTi931 */ #include #if NPCM > 0 /* * board-specific include files */ #include /* * prototypes for procedures exported in the device descriptor */ static int mss_probe(struct isa_device *dev); static int mss_attach(struct isa_device *dev); static d_open_t mss_open; static d_close_t mss_close; static d_ioctl_t mss_ioctl; static irq_proc_t mss_intr; static irq_proc_t opti931_intr; static snd_callback_t mss_callback; /* * prototypes for local functions */ static void mss_reinit(snddev_info *d); static int AD_WAIT_INIT(snddev_info *d, int x); static int mss_mixer_set(snddev_info *d, int dev, int value); static int mss_set_recsrc(snddev_info *d, int mask); static void ad1848_mixer_reset(snddev_info *d); static void opti_write(int io_base, u_char reg, u_char data); static u_char opti_read(int io_base, u_char reg); static void ad_write(snddev_info *d, int reg, u_char data); static void ad_write_cnt(snddev_info *d, int reg, u_short data); static int ad_read(snddev_info *d, int reg); /* * device descriptors for the boards supported by this module. */ snddev_info mss_op_desc = { "mss", SNDCARD_MSS, mss_probe, mss_attach, mss_open, mss_close, NULL /* mss_read */, NULL /* mss_write */, mss_ioctl, sndselect /* mss_select */, mss_intr, mss_callback , DSP_BUFFSIZE, /* bufsize */ AFMT_STEREO | AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW, /* audio formats */ /* * the enhanced boards also have AFMT_IMA_ADPCM | AFMT_S16_BE * but we do not use these modes. */ } ; /* * mss_probe() is the probe routine. Note, it is not necessary to * go through this for PnP devices, since they are already * indentified precisely using their PnP id. * * The base address supplied in the device refers to the old MSS * specs where the four 4 registers in io space contain configuration * information. Some boards (as an example, early MSS boards) * has such a block of registers, whereas others (generally CS42xx) * do not. In order to distinguish between the two and do not have * to supply two separate probe routines, the flags entry in isa_device * has a bit to mark this. * */ static int mss_probe(struct isa_device *dev) { u_char tmp; int irq = ffs(dev->id_irq) - 1; bzero(&pcm_info[dev->id_unit], sizeof(pcm_info[dev->id_unit]) ); if (dev->id_iobase == -1) { dev->id_iobase = 0x530; BVDDB(printf("mss_probe: no address supplied, try default 0x%x\n", dev->id_iobase)); } if (snd_conflict(dev->id_iobase)) return 0 ; if ( !(dev->id_flags & DV_F_TRUE_MSS) ) /* Has no IRQ/DMA registers */ goto mss_probe_end; /* * Check if the IO port returns valid signature. The original MS * Sound system returns 0x04 while some cards * (AudioTriX Pro for example) return 0x00 or 0x0f. */ tmp = inb(dev->id_iobase + 3); if (tmp == 0xff) { /* Bus float */ BVDDB(printf("I/O address inactive (%x), try pseudo_mss\n", tmp)); dev->id_flags &= ~DV_F_TRUE_MSS ; goto mss_probe_end; } tmp &= 0x3f ; if (tmp != 0x04 && tmp != 0x0f && tmp != 0x00) { BVDDB(printf("No MSS signature detected on port 0x%x (0x%x)\n", dev->id_iobase, inb(dev->id_iobase + 3))); return 0; } if (irq > 11) { printf("MSS: Bad IRQ %d\n", irq); return 0; } if (dev->id_drq != 0 && dev->id_drq != 1 && dev->id_drq != 3) { printf("MSS: Bad DMA %d\n", dev->id_drq); return 0; } if (inb(dev->id_iobase + 3) & 0x80) { /* 8-bit board: only drq1/3 and irq7/9 */ if (dev->id_drq == 0) { printf("MSS: Can't use DMA0 with a 8 bit card/slot\n"); return 0; } if (irq != 7 && irq != 9) { printf("MSS: Can't use IRQ%d with a 8 bit card/slot\n", irq); return 0; } } mss_probe_end: return mss_detect(dev) ? 8 : 0 ; /* mss uses 8 regs */ } /* * the address passed as io_base for mss_attach is also the old * MSS base address (e.g. 0x530). The codec is four locations ahead. * Note that the attach routine for PnP devices might support * device-specific initializations. */ static int mss_attach(struct isa_device *dev) { snddev_info *d = &(pcm_info[dev->id_unit]); printf("mss_attach <%s>%d at 0x%x irq %d dma %d:%d flags 0x%x\n", d->name, dev->id_unit, d->io_base, d->irq, d->dbuf_out.chan, d->dbuf_in.chan, dev->id_flags); dev->id_alive = 8 ; /* number of io ports */ /* should be already set but just in case... */ if ( dev->id_flags & DV_F_TRUE_MSS ) { /* has IRQ/DMA registers, set IRQ and DMA addr */ static char interrupt_bits[12] = { -1, -1, -1, -1, -1, 0x28, -1, 0x08, -1, 0x10, 0x18, 0x20 }; static char dma_bits[4] = { 1, 2, 0, 3 }; char bits ; if (d->irq == -1 || (bits = interrupt_bits[d->irq]) == -1) { dev->id_irq = 0 ; /* makk invalid irq */ return 0 ; } outb(dev->id_iobase, bits | 0x40); /* config port */ if ((inb(dev->id_iobase + 3) & 0x40) == 0) /* version port */ printf("[IRQ Conflict?]"); /* Write IRQ+DMA setup */ if ( ! FULL_DUPLEX(d) ) /* single chan dma */ outb(dev->id_iobase, bits | dma_bits[d->dbuf_out.chan]); else { if (d->dbuf_out.chan == 0 && d->dbuf_in.chan == 1) bits |= 5 ; else if (d->dbuf_out.chan == 1 && d->dbuf_in.chan == 0) bits |= 6 ; else if (d->dbuf_out.chan == 3 && d->dbuf_in.chan == 0) bits |= 7 ; else { printf("invalid dual dma config %d:%d\n", d->dbuf_out.chan, d->dbuf_in.chan); dev->id_irq = 0 ; dev->id_alive = 0 ; /* this makes attach fail. */ return 0 ; } outb(dev->id_iobase, bits ); } } if (1) { /* machine-specific code for the Toshiba Libretto */ u_char r6, r9; outb( 0x370, 6 /* dma config */ ); outb( 0x371, 0xa9 /* config: DMA-B for rec, DMA-A for play */); r6 = inb( 0x371 /* read */ ); outb( 0x370, 0xa /* version */ ); r9 = inb( 0x371 /* read */ ); DEB(printf("Yamaha: ver 0x%x DMA config 0x%x\n", r6, r9);) /* * yamaha - set volume to max */ outb( 0x370, 7 /* volume left */ ); outb( 0x371, 0 /* max level */ ); outb( 0x370, 8 /* volume right */ ); outb( 0x371, 0 /* max level */ ); } if ( FULL_DUPLEX(d) ) d->audio_fmt |= AFMT_FULLDUPLEX ; if (d->bd_id == MD_YM0020) { DDB(printf("setting up yamaha registers\n")); outb(0x370, 6 /* dma config */ ) ; if (FULL_DUPLEX(d)) outb(0x371, 0xa9 ); /* use both dma chans */ else outb(0x371, 0x8b ); /* use low dma chan */ } mss_reinit(d); ad1848_mixer_reset(d); return 0; } static int mss_open(dev_t dev, int flags, int mode, struct proc * p) { int unit; snddev_info *d; u_long s; dev = minor(dev); unit = dev >> 4 ; dev &= 0xf ; d = &pcm_info[unit] ; s = spltty(); /* * This was meant to support up to 2 open descriptors for the * some device, and check proper device usage on open. * Unfortunately, the kernel will trap all close() calls but * the last one, with the consequence that we cannot really * keep track of which channels are busy. * So, the correct tests cannot be done :( and we must rely * on the locks on concurrent operations of the same type and * on some approximate tests... */ if (dev == SND_DEV_AUDIO) d->flags |= SND_F_BUSY_AUDIO ; else if (dev == SND_DEV_DSP) d->flags |= SND_F_BUSY_DSP ; else if (dev == SND_DEV_DSP16) d->flags |= SND_F_BUSY_DSP16 ; if ( d->flags & SND_F_BUSY ) splx(s); /* device was already set, no need to reinit */ else { /* * device was idle. Do the necessary initialization, * but no need keep interrupts blocked. * will not get them */ splx(s); d->play_speed = d->rec_speed = DSP_DEFAULT_SPEED ; d->flags |= SND_F_BUSY ; d->wsel.si_pid = 0; d->wsel.si_flags = 0; d->rsel.si_pid = 0; d->rsel.si_flags = 0; d->dbuf_out.total = d->dbuf_out.prev_total = 0 ; d->dbuf_in.total = d->dbuf_in.prev_total = 0 ; if (flags & O_NONBLOCK) d->flags |= SND_F_NBIO ; switch (dev) { default : case SND_DEV_AUDIO : d->play_fmt = d->rec_fmt = AFMT_MU_LAW ; break ; case SND_DEV_DSP : d->play_fmt = d->rec_fmt = AFMT_U8 ; break ; case SND_DEV_DSP16 : d->play_fmt = d->rec_fmt = AFMT_S16_LE ; break; } ask_init(d); /* and reset buffers... */ } return 0 ; } static int mss_close(dev_t dev, int flags, int mode, struct proc * p) { int unit; snddev_info *d; u_long s; dev = minor(dev); unit = dev >> 4 ; dev &= 0xf; d = &pcm_info[unit] ; /* * We will only get a single close call when the last reference * to the device is gone. But we must handle ourselves references * through different devices. */ s = spltty(); if (dev == SND_DEV_AUDIO) d->flags &= ~SND_F_BUSY_AUDIO ; else if (dev == SND_DEV_DSP) d->flags &= ~SND_F_BUSY_DSP ; else if (dev == SND_DEV_DSP16) d->flags &= ~SND_F_BUSY_DSP16 ; if ( d->flags & SND_F_BUSY_ANY ) /* still some device open */ splx(s); else { /* last one */ d->flags |= SND_F_CLOSING ; splx(s); /* is this ok here ? */ snd_flush(d); outb(io_Status(d), 0); /* Clear interrupt status */ d->flags = 0 ; } return 0 ; } static int mss_ioctl(dev_t dev, u_long cmd, caddr_t arg, int mode, struct proc * p) { snddev_info *d; int unit; dev = minor(dev); unit = dev >> 4 ; d = &pcm_info[unit] ; /* * handle mixer calls first. Reads are in the default handler, * so do not bother about them. */ if ( (cmd & MIXER_WRITE(0)) == MIXER_WRITE(0) ) { cmd &= 0xff ; if (cmd == SOUND_MIXER_RECSRC) return mss_set_recsrc(d, *(int *)arg) ; else return mss_mixer_set(d, cmd, *(int *)arg) ; } return ENOSYS ; /* fallback to the default ioctl handler */ } /* * the callback routine to handle all dma ops etc. * With the exception of INIT, all other callbacks are invoked * with interrupts disabled. */ static int mss_callback(snddev_info *d, int reason) { u_char m; int retry, wr, cnt; DEB(printf("-- mss_callback reason 0x%03x\n", reason)); wr = reason & SND_CB_WR ; reason &= SND_CB_REASON_MASK ; switch (reason) { case SND_CB_INIT : /* called with int enabled and no pending I/O */ /* * perform all necessary initializations for i/o */ d->rec_fmt = d->play_fmt ; /* no split format on the MSS */ snd_set_blocksize(d); mss_reinit(d); reset_dbuf(& (d->dbuf_in), SND_CHAN_RD ); reset_dbuf(& (d->dbuf_out), SND_CHAN_WR ); return 1 ; break ; case SND_CB_START : cnt = wr ? d->dbuf_out.dl : d->dbuf_in.dl ; if (d->play_fmt == AFMT_S16_LE) cnt /= 2; if (d->flags & SND_F_STEREO) cnt /= 2; cnt-- ; DEB(printf("-- (re)start cnt %d\n", cnt)); m = ad_read(d,9) ; DEB( if (m & 4) printf("OUCH! reg 9 0x%02x\n", m); ); m |= wr ? I9_PEN : I9_CEN ; /* enable DMA */ /* * on the OPTi931 the enable bit seems hard to set... */ for (retry = 10; retry; retry--) { ad_write(d, 9, m ); if (ad_read(d,9) ==m) break; } if (retry == 0) printf("start dma, failed to set bit 0x%02x 0x%02x\n", m, ad_read(d, 9) ) ; if (wr || ! FULL_DUPLEX(d) ) ad_write_cnt(d, 14, cnt); else ad_write_cnt(d, 30, cnt); break ; case SND_CB_STOP : case SND_CB_ABORT : /* XXX check this... */ m = ad_read(d,9) ; m &= wr ? ~I9_PEN : ~I9_CEN ; /* Stop DMA */ /* * on the OPTi931 the enable bit seems hard to set... */ for (retry = 10; retry ; retry-- ) { ad_write(d, 9, m ); if (ad_read(d,9) ==m) break; } if (retry == 0) printf("start dma, failed to clear bit 0x%02x 0x%02x\n", m, ad_read(d, 9) ) ; #if 1 /* * try to disable DMA by clearing count registers. Not sure it * is needed, and it might cause false interrupts when the * DMA is re-enabled later. */ if (wr || ! FULL_DUPLEX(d) ) ad_write_cnt(d, 14, 0); else ad_write_cnt(d, 30, 0); break; #endif } return 0 ; } /* * main irq handler for the CS423x. The OPTi931 code is * a separate one. * The correct way to operate for a device with multiple internal * interrupt sources is to loop on the status register and ack * interrupts until all interrupts are served and none are reported. At * this point the IRQ line to the ISA IRQ controller should go low * and be raised at the next interrupt. * * Since the ISA IRQ controller is sent EOI _before_ passing control * to the isr, it might happen that we serve an interrupt early, in * which case the status register at the next interrupt should just * say that there are no more interrupts... */ static void mss_intr(int unit) { snddev_info *d = &pcm_info[unit]; u_char c, served = 0; int i; DEB(printf("mss_intr\n")); ad_read(d, 11); /* fake read of status bits */ /* * loop until there are interrupts, but no more than 10 times. */ for (i=10 ; i && inb(io_Status(d)) & 1 ; i-- ) { /* get exact reason for full-duplex boards */ c = FULL_DUPLEX(d) ? ad_read(d, 24) : 0x30 ; c &= ~served ; if ( d->dbuf_out.dl && (c & 0x10) ) { served |= 0x10 ; dsp_wrintr(d); } if ( d->dbuf_in.dl && (c & 0x20) ) { served |= 0x20 ; dsp_rdintr(d); } /* * now ack the interrupt */ if ( FULL_DUPLEX(d) ) ad_write(d, 24, ~c); /* ack selectively */ else outb(io_Status(d), 0); /* Clear interrupt status */ } if (served == 0) { printf("How strange... mss_intr with no reason!\n"); /* * this should not happen... I have no idea what to do now. * maybe should do a sanity check and restart dmas ? */ outb(io_Status(d), 0); /* Clear interrupt status */ } } /* * the opti931 seems to miss interrupts when working in full * duplex, so we try some heuristics to catch them. */ static void opti931_intr(int unit) { snddev_info *d = &pcm_info[unit]; u_char masked=0, i11, mc11, c=0; u_char reason; /* b0 = playback, b1 = capture, b2 = timer */ int loops = 10; #if 0 reason = inb(io_Status(d)); if ( ! (reason & 1) ) {/* no int, maybe a shared line ? */ printf("opti931_intr: flag 0, mcir11 0x%02x\n", ad_read(d,11)); return; } #endif i11 = ad_read(d, 11); /* XXX what's for ? */ again: c=mc11 = FULL_DUPLEX(d) ? opti_read(d->conf_base, 11) : 0xc ; mc11 &= 0x0c ; if (c & 0x10) { DEB(printf("Warning: CD interrupt\n");) mc11 |= 0x10 ; } if (c & 0x20) { DEB(printf("Warning: MPU interrupt\n");) mc11 |= 0x20 ; } if (mc11 & masked) printf("irq reset failed, mc11 0x%02x, masked 0x%02x\n", mc11, masked); masked |= mc11 ; /* * the nice OPTi931 sets the IRQ line before setting the bits in * mc11. So, on some occasions I have to retry (max 10 times). */ if ( mc11 == 0 ) { /* perhaps can return ... */ reason = inb(io_Status(d)); if (reason & 1) { DEB(printf("one more try...\n");) if (--loops) goto again; else DDB(printf("opti_intr: irq but mc11 not set!...\n");) } if (loops==10) printf("ouch, intr but nothing in mcir11 0x%02x\n", mc11); return; } if ( d->dbuf_in.dl && (mc11 & 8) ) { dsp_rdintr(d); } if ( d->dbuf_out.dl && (mc11 & 4) ) { dsp_wrintr(d); } opti_write(d->conf_base, 11, ~mc11); /* ack */ if (--loops) goto again; DEB(printf("xxx too many loops\n");) } /* * Second part of the file: functions local to this module. * in this section a few routines to access MSS registers * */ static void opti_write(int io_base, u_char reg, u_char value) { outb(io_base, reg); outb(io_base+1, value); } static u_char opti_read(int io_base, u_char reg) { outb(io_base, reg); return inb(io_base+1); } static void gus_write(int io_base, u_char reg, u_char value) { outb(io_base + 3, reg); outb(io_base + 5, value); } static void gus_writew(int io_base, u_char reg, u_short value) { outb(io_base + 3, reg); outb(io_base + 4, value); } static u_char gus_read(int io_base, u_char reg) { outb(io_base+3, reg); return inb(io_base+5); } static u_short gus_readw(int io_base, u_char reg) { outb(io_base+3, reg); return inw(io_base+4); } /* * AD_WAIT_INIT waits if we are initializing the board and * we cannot modify its settings */ static int AD_WAIT_INIT(snddev_info *d, int x) { int arg=x, n = 0; /* to shut up the compiler... */ for (; x-- ; ) if ( (n=inb(io_Index_Addr(d))) & IA_BUSY) DELAY(10); else return n ; printf("AD_WAIT_INIT FAILED %d 0x%02x\n", arg, n); return n ; } static int ad_read(snddev_info *d, int reg) { u_long flags; int x; flags = spltty(); AD_WAIT_INIT(d, 201); x = inb(io_Index_Addr(d)) & ~IA_AMASK ; outb(io_Index_Addr(d), (u_char) (reg & IA_AMASK) | x ) ; x = inb(io_Indexed_Data(d)); splx(flags); return x; } static void ad_write(snddev_info *d, int reg, u_char data) { u_long flags; int x ; flags = spltty(); AD_WAIT_INIT(d, 1002); x = inb(io_Index_Addr(d)) & ~IA_AMASK ; outb(io_Index_Addr(d), (u_char) (reg & IA_AMASK) | x ) ; outb(io_Indexed_Data(d), data); splx(flags); } static void ad_write_cnt(snddev_info *d, int reg, u_short cnt) { ad_write(d, reg+1, cnt & 0xff ); ad_write(d, reg, cnt >> 8 ); /* upper base must be last */ } static void wait_for_calibration(snddev_info *d) { int n, t; /* * Wait until the auto calibration process has finished. * * 1) Wait until the chip becomes ready (reads don't return 0x80). * 2) Wait until the ACI bit of I11 gets on * 3) Wait until the ACI bit of I11 gets off */ n = AD_WAIT_INIT(d, 1000); if (n & IA_BUSY) printf("mss: Auto calibration timed out(1).\n"); for (t = 100 ; t>0 && (ad_read(d, 11) & 0x20) == 0 ; t--) DELAY(100); for (t = 100 ; t>0 && ad_read(d, 11) & 0x20 ; t--) DELAY(100); } #if 0 /* unused right now... */ static void ad_mute(snddev_info *d) { ad_write(d, 6, ad_read(d,6) | I6_MUTE); ad_write(d, 7, ad_read(d,7) | I6_MUTE); } static void ad_unmute(snddev_info *d) { ad_write(d, 6, ad_read(d,6) & ~I6_MUTE); ad_write(d, 7, ad_read(d,7) & ~I6_MUTE); } #endif static void ad_enter_MCE(snddev_info *d) { int prev; d->bd_flags |= BD_F_MCE_BIT; AD_WAIT_INIT(d, 203); prev = inb(io_Index_Addr(d)); prev &= ~IA_TRD ; outb(io_Index_Addr(d), prev | IA_MCE ) ; } static void ad_leave_MCE(snddev_info *d) { u_long flags; u_char prev; if ( (d->bd_flags & BD_F_MCE_BIT) == 0 ) { printf("--- hey, leave_MCE: MCE bit was not set!\n"); return; } AD_WAIT_INIT(d, 1000); flags = spltty(); d->bd_flags &= ~BD_F_MCE_BIT; prev = inb(io_Index_Addr(d)); prev &= ~IA_TRD ; outb(io_Index_Addr(d), prev & ~IA_MCE ); /* Clear the MCE bit */ wait_for_calibration(d); splx(flags); } /* * only one source can be set... */ static int mss_set_recsrc(snddev_info *d, int mask) { u_char recdev; mask &= d->mix_rec_devs; switch (mask) { case SOUND_MASK_LINE: case SOUND_MASK_LINE3: recdev = 0; break; case SOUND_MASK_CD: case SOUND_MASK_LINE1: recdev = 0x40; break; case SOUND_MASK_IMIX: recdev = 0xc0; break; case SOUND_MASK_MIC: default: mask = SOUND_MASK_MIC; recdev = 0x80; } ad_write(d, 0, (ad_read(d, 0) & 0x3f) | recdev); ad_write(d, 1, (ad_read(d, 1) & 0x3f) | recdev); d->mix_recsrc = mask; return 0; } /* * mixer conversion table: from 0..100 scale to codec values * * I don't understand what's this for... maybe achieve a log-scale * volume control ? */ static char mix_cvt[101] = { 0, 1, 3, 7,10,13,16,19,21,23,26,28,30,32,34,35,37,39,40,42, 43,45,46,47,49,50,51,52,53,55,56,57,58,59,60,61,62,63,64,65, 65,66,67,68,69,70,70,71,72,73,73,74,75,75,76,77,77,78,79,79, 80,81,81,82,82,83,84,84,85,85,86,86,87,87,88,88,89,89,90,90, 91,91,92,92,93,93,94,94,95,95,96,96,96,97,97,98,98,98,99,99, 100 }; /* * there are differences in the mixer depending on the actual sound * card. */ static int mss_mixer_set(snddev_info *d, int dev, int value) { int left = value & 0x000000ff; int right = (value & 0x0000ff00) >> 8; int regoffs; mixer_tab *mix_d = &mix_devices; u_char old, val; if (dev > 31) return EINVAL; if (!(d->mix_devs & (1 << dev))) return EINVAL; if (d->bd_id == MD_OPTI931) mix_d = &(opti931_devices); if ((*mix_d)[dev][LEFT_CHN].nbits == 0) { DEB(printf("nbits = 0 for dev %d\n", dev) ); return EINVAL; } if (left > 100) left = 100; if (right > 100) right = 100; if ( (*mix_d)[dev][RIGHT_CHN].nbits == 0) /* Mono control */ right = left; d->mix_levels[dev] = left | (right << 8); #if 0 /* Scale volumes */ left = mix_cvt[left]; right = mix_cvt[right]; #endif /* * Set the left channel */ regoffs = (*mix_d)[dev][LEFT_CHN].regno; old = val = ad_read(d, regoffs); /* * if volume is 0, mute chan. Otherwise, unmute. */ if (regoffs != 0) /* main input is different */ val = (left == 0 ) ? old | 0x80 : old & 0x7f ; change_bits(mix_d, &val, dev, LEFT_CHN, left); ad_write(d, regoffs, val); DEB(printf("LEFT: dev %d reg %d old 0x%02x new 0x%02x\n", dev, regoffs, old, val)); if ((*mix_d)[dev][RIGHT_CHN].nbits != 0) { /* have stereo */ /* * Set the right channel */ regoffs = (*mix_d)[dev][RIGHT_CHN].regno; old = val = ad_read(d, regoffs); if (regoffs != 1) val = (right == 0 ) ? old | 0x80 : old & 0x7f ; change_bits(mix_d, &val, dev, RIGHT_CHN, right); ad_write(d, regoffs, val); DEB(printf("RIGHT: dev %d reg %d old 0x%02x new 0x%02x\n", dev, regoffs, old, val)); } return 0; /* success */ } static void ad1848_mixer_reset(snddev_info *d) { int i; if (d->bd_id == MD_OPTI931) d->mix_devs = OPTI931_MIXER_DEVICES; else if (d->bd_id != MD_AD1848) d->mix_devs = MODE2_MIXER_DEVICES; else d->mix_devs = MODE1_MIXER_DEVICES; d->mix_rec_devs = MSS_REC_DEVICES; for (i = 0; i < SOUND_MIXER_NRDEVICES; i++) if (d->mix_devs & (1 << i)) mss_mixer_set(d, i, default_mixer_levels[i]); mss_set_recsrc(d, SOUND_MASK_MIC); /* * some device-specific things, mostly mute the mic to * the output mixer so as to avoid hisses. In many cases this * is the default after reset, this code is here mostly as a * reminder that this might be necessary on other boards. */ switch(d->bd_id) { case MD_OPTI931: ad_write(d, 20, 0x88); ad_write(d, 21, 0x88); break; case MD_YM0020: /* set master volume to max */ DDB(printf("set yamaha master volume to max"); ) outb(0x370, 7) ; outb(0x371, 0) ; outb(0x370, 8) ; outb(0x371, 0) ; break; case MD_GUSPNP: /* this is only necessary in mode 3 ... */ ad_write(d, 22, 0x88); ad_write(d, 23, 0x88); } } /* * mss_speed processes the value in play_speed finding the * matching one. As a side effect, it returns the value to * be written in the speed bits of the codec. It does _NOT_ * set the speed of the device (but it should!) */ static int mss_speed(snddev_info *d) { /* * In the CS4231, the low 4 bits of I8 are used to hold the * sample rate. Only a fixed number of values is allowed. This * table lists them. The speed-setting routines scans the table * looking for the closest match. This is the only supported method. * * In the CS4236, there is an alternate metod (which we do not * support yet) which provides almost arbitrary frequency setting. * In the AD1845, it looks like the sample rate can be * almost arbitrary, and written directly to a register. * In the OPTi931, there is a SB command which provides for * almost arbitrary frequency setting. * */ static int speeds[] = { 8000, 5512, 16000, 11025, 27429, 18900, 32000, 22050, -1, 37800, -1, 44100, 48000, 33075, 9600, 6615 }; int arg, i, sel = 0; /* assume entry 0 does not contain -1 */ arg = d->play_speed ; for (i=1; i < 16 ; i++) if (speeds[i] >0 && abs(arg-speeds[i]) < abs(arg-speeds[sel]) ) sel = i ; d->play_speed = d->rec_speed = speeds[sel] ; return sel ; } /* * mss_format checks that the format is supported (or defaults to AFMT_U8) * and returns the bit setting for the 1848 register corresponding to * the desired format. * * fixed lr970724 */ static int mss_format(snddev_info *d) { int i, arg = d->play_fmt ; /* * The data format uses 3 bits (just 2 on the 1848). For each * bit setting, the following array returns the corresponding format. * The code scans the array looking for a suitable format. In * case it is not found, default to AFMT_U8 (not such a good * choice, but let's do it for compatibility...). */ static int fmts[] = { AFMT_U8, AFMT_MU_LAW, AFMT_S16_LE, AFMT_A_LAW, -1, AFMT_IMA_ADPCM, AFMT_U16_BE, -1 }; if ( (arg & d->audio_fmt) == 0 ) /* unsupported fmt, default to AFMT_U8 */ arg = AFMT_U8 ; /* ulaw/alaw seems broken on the opti931... */ if (d->bd_id == MD_OPTI931 || d->bd_id == MD_GUSPNP) { if (arg == AFMT_MU_LAW) { arg = AFMT_U8 ; d->flags |= SND_F_XLAT8 ; } else d->flags &= ~SND_F_XLAT8 ; } /* * check that arg is one of the supported formats in d->format; * otherwise fallback to AFMT_U8 */ for (i=0 ; i<8 ; i++) if (arg == fmts[i]) break; if (i==8) { /* not found, default to AFMT_U8 */ arg = AFMT_U8 ; i = 0 ; } d->play_fmt = d->rec_fmt = arg; return i ; } /* * mss_detect can be used in the probe and the attach routine. * * We store probe information in pcm_info[unit]. This descriptor * is reinitialized just before the attach, so all relevant * information is lost, and mss_detect must be run again in * the attach routine if necessary. */ int mss_detect(struct isa_device *dev) { int i; u_char tmp, tmp1, tmp2 ; snddev_info *d = &(pcm_info[dev->id_unit]); char *name; d->io_base = dev->id_iobase; d->bd_flags |= BD_F_MCE_BIT ; if (d->bd_id != 0) { printf("preselected bd_id 0x%04x -- %s\n", d->bd_id, d->name ? d->name : "???"); return 1; } name = "AD1848" ; d->bd_id = MD_AD1848; /* AD1848 or CS4248 */ /* * Check that the I/O address is in use. * * bit 7 of the base I/O port is known to be 0 after the chip has * performed its power on initialization. Just assume this has * happened before the OS is starting. * * If the I/O address is unused, it typically returns 0xff. */ for (i=0; i<10; i++) if (inb(io_Index_Addr(d)) & IA_BUSY) DELAY(10000); /* maybe busy, wait & retry later */ else break ; if ((inb(io_Index_Addr(d)) & IA_BUSY) != 0x00) { /* Not a AD1848 */ BVDDB(printf("mss_detect error, busy still set (0x%02x)\n", inb(io_Index_Addr(d)))); return 0; } /* * Test if it's possible to change contents of the indirect * registers. Registers 0 and 1 are ADC volume registers. The bit * 0x10 is read only so try to avoid using it. */ ad_write(d, 0, 0xaa); ad_write(d, 1, 0x45);/* 0x55 with bit 0x10 clear */ tmp1 = ad_read(d, 0) ; tmp2 = ad_read(d, 1) ; if ( tmp1 != 0xaa || tmp2 != 0x45) { BVDDB(printf("mss_detect error - IREG (0x%02x/0x%02x) want 0xaa/0x45\n", tmp1, tmp2)); return 0; } ad_write(d, 0, 0x45); ad_write(d, 1, 0xaa); tmp1 = ad_read(d, 0) ; tmp2 = ad_read(d, 1) ; if (tmp1 != 0x45 || tmp2 != 0xaa) { BVDDB(printf("mss_detect error - IREG2 (%x/%x)\n", tmp1, tmp2)); return 0; } /* * The indirect register I12 has some read only bits. Lets try to * change them. */ tmp = ad_read(d, 12); ad_write(d, 12, (~tmp) & 0x0f); tmp1 = ad_read(d, 12); if ((tmp & 0x0f) != (tmp1 & 0x0f)) { BVDDB(printf("mss_detect error - I12 (0x%02x was 0x%02x)\n", tmp1, tmp)); return 0; } /* * NOTE! Last 4 bits of the reg I12 tell the chip revision. * 0x01=RevB * 0x0A=RevC. also CS4231/CS4231A and OPTi931 */ BVDDB(printf("mss_detect - chip revision 0x%02x\n", tmp & 0x0f);) /* * The original AD1848/CS4248 has just 16 indirect registers. This * means that I0 and I16 should return the same value (etc.). Ensure * that the Mode2 enable bit of I12 is 0. Otherwise this test fails * with new parts. */ ad_write(d, 12, 0); /* Mode2=disabled */ for (i = 0; i < 16; i++) if ((tmp1 = ad_read(d, i)) != (tmp2 = ad_read(d, i + 16))) { BVDDB(printf("mss_detect warning - I%d: 0x%02x/0x%02x\n", i, tmp1, tmp2)); /* * note - this seems to fail on the 4232 on I11. So we just break * rather than fail. */ break ; /* return 0; */ } /* * Try to switch the chip to mode2 (CS4231) by setting the MODE2 bit * (0x40). The bit 0x80 is always 1 in CS4248 and CS4231. * * On the OPTi931, however, I12 is readonly and only contains the * chip revision ID (as in the CS4231A). The upper bits return 0. */ ad_write(d, 12, 0x40); /* Set mode2, clear 0x80 */ tmp1 = ad_read(d, 12); if (tmp1 & 0x80) { name = "CS4248" ; /* Our best knowledge just now */ } if ((tmp1 & 0xf0) == 0x00) { BVDDB(printf("this should be an OPTi931\n");) } else if ((tmp1 & 0xc0) == 0xC0) { /* * The 4231 has bit7=1 always, and bit6 we just set to 1. * We want to check that this is really a CS4231 * Verify that setting I0 doesn't change I16. */ ad_write(d, 16, 0); /* Set I16 to known value */ ad_write(d, 0, 0x45); if ((tmp1 = ad_read(d, 16)) != 0x45) { /* No change -> CS4231? */ ad_write(d, 0, 0xaa); if ((tmp1 = ad_read(d, 16)) == 0xaa) { /* Rotten bits? */ BVDDB(printf("mss_detect error - step H(%x)\n", tmp1)); return 0; } /* * Verify that some bits of I25 are read only. */ tmp1 = ad_read(d, 25); /* Original bits */ ad_write(d, 25, ~tmp1); /* Invert all bits */ if ((ad_read(d, 25) & 0xe7) == (tmp1 & 0xe7)) { int id; /* * It's at least CS4231 */ name = "CS4231" ; d->bd_id = MD_CS4231; /* * It could be an AD1845 or CS4231A as well. * CS4231 and AD1845 report the same revision info in I25 * while the CS4231A reports different. */ id = ad_read(d, 25) & 0xe7; /* * b7-b5 = version number; * 100 : all CS4231 * 101 : CS4231A * * b2-b0 = chip id; */ switch (id) { case 0xa0: name = "CS4231A" ; d->bd_id = MD_CS4231A; break; case 0xa2: name = "CS4232" ; d->bd_id = MD_CS4232; break; case 0xb2: /* strange: the 4231 data sheet says b4-b3 are XX * so this should be the same as 0xa2 */ name = "CS4232A" ; d->bd_id = MD_CS4232A; break; case 0x80: /* * It must be a CS4231 or AD1845. The register I23 * of CS4231 is undefined and it appears to be read * only. AD1845 uses I23 for setting sample rate. * Assume the chip is AD1845 if I23 is changeable. */ tmp = ad_read(d, 23); ad_write(d, 23, ~tmp); if (ad_read(d, 23) != tmp) { /* AD1845 ? */ name = "AD1845" ; d->bd_id = MD_AD1845; } ad_write(d, 23, tmp); /* Restore */ DDB(printf("... try to identify the yamaha\n") ;) tmp = inb(0x370) ; outb(0x370, 6 /* dma config */ ) ; if (inb(0x370) != 6 ) /* not a yamaha... restore. */ outb(0x370, tmp ) ; else d->bd_id = MD_YM0020 ; break; case 0x83: /* CS4236 */ case 0x03: /* CS4236 on Intel PR440FX motherboard XXX */ name = "CS4236"; d->bd_id = MD_CS4236; break ; default: /* Assume CS4231 */ BVDDB(printf("unknown id 0x%02x, assuming CS4231\n", id);) d->bd_id = MD_CS4231; } } ad_write(d, 25, tmp1); /* Restore bits */ } } BVDDB(printf("mss_detect() - Detected %s\n", name)); strcpy(d->name, name); dev->id_flags &= ~DV_F_DEV_MASK ; dev->id_flags |= (d->bd_id << DV_F_DEV_SHIFT) & DV_F_DEV_MASK ; return 1; } /* * mss_reinit resets registers of the codec */ static void mss_reinit(snddev_info *d) { u_char r; r = mss_speed(d) ; r |= (mss_format(d) << 5) ; if (d->flags & SND_F_STEREO) r |= 0x10 ; /* XXX check if MCE is necessary... */ ad_enter_MCE(d); /* * perhaps this is not the place to set mode2, should be done * only once at attach time... */ if ( FULL_DUPLEX(d) && d->bd_id != MD_OPTI931) /* * set mode2 bit for dual dma op. This bit is not implemented * on the OPTi931 */ ad_write(d, 12, ad_read(d, 12) | 0x40 /* mode 2 on the CS42xx */ ); /* * XXX this should really go into mss-speed... */ if (d->bd_id == MD_AD1845) { /* Use alternate speed select regs */ r &= 0xf0; /* Mask off the rate select bits */ ad_write(d, 22, (d->play_speed >> 8) & 0xff); /* Speed MSB */ ad_write(d, 23, d->play_speed & 0xff); /* Speed LSB */ /* * XXX must also do something in I27 for the ad1845 */ } ad_write(d, 8, r) ; if ( FULL_DUPLEX(d) ) { #if 0 if (d->bd_id == MD_GUSPNP && d->play_fmt == AFMT_MU_LAW) { printf("warning, cannot do ulaw rec + play on the GUS\n"); r = 0 ; /* move to U8 */ } #endif ad_write(d, 28, r & 0xf0 ) ; /* capture mode */ ad_write(d, 9, 0 /* no capture, no playback, dual dma */) ; } else ad_write(d, 9, 4 /* no capture, no playback, single dma */) ; ad_leave_MCE(d); /* * not sure if this is really needed... */ ad_write_cnt(d, 14, 0 ); /* playback count */ if ( FULL_DUPLEX(d) ) ad_write_cnt(d, 30, 0 ); /* rec. count on dual dma */ ad_write(d, 10, 2 /* int enable */) ; outb(io_Status(d), 0); /* Clear interrupt status */ /* the following seem required on the CS4232 */ ad_write(d, 6, ad_read(d,6) & ~I6_MUTE); ad_write(d, 7, ad_read(d,7) & ~I6_MUTE); snd_set_blocksize(d); /* update blocksize if user did not force it */ } /* * here we have support for PnP cards * */ #if NPNP > 0 static char * cs423x_probe(u_long csn, u_long vend_id); static void cs423x_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev); static struct pnp_device cs423x = { "CS423x/Yamaha", cs423x_probe, cs423x_attach, &nsnd, /* use this for all sound cards */ &tty_imask /* imask */ }; DATA_SET (pnpdevice_set, cs423x); static char * cs423x_probe(u_long csn, u_long vend_id) { char *s = NULL ; u_long id = vend_id & 0xff00ffff; if ( id == 0x3700630e ) s = "CS4237" ; if ( id == 0x2500630e ) s = "CS4235" ; else if ( id == 0x3500630e || id == 0x3600630e ) s = "CS4236" ; else if ( id == 0x3500630e ) s = "CS4236B" ; else if ( id == 0x3200630e) s = "CS4232" ; else if ( id == 0x2000a865) s = "Yamaha SA2"; else if ( id == 0x3000a865) s = "Yamaha SA3"; else if (vend_id == 0x0000a865) s = "Yamaha YMF719 OPL-SA3"; else if (vend_id == 0x8140d315) s = "SoundscapeVIVO"; if (s) { struct pnp_cinfo d; read_pnp_parms(&d, 0); if (d.enable == 0) { printf("This is a %s, but LDN 0 is disabled\n", s); return NULL ; } return s; } return NULL ; } extern snddev_info sb_op_desc; static void cs423x_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev) { struct pnp_cinfo d ; snddev_info tmp_d ; /* patched copy of the basic snddev_info */ int ldn = 0 ; if (read_pnp_parms ( &d , ldn ) == 0 ) { printf("failed to read pnp parms\n"); return ; } snddev_last_probed = &tmp_d; if (d.flags & DV_PNP_SBCODEC) { /*** use sb-compatible codec ***/ dev->id_alive = 16 ; /* number of io ports ? */ tmp_d = sb_op_desc ; if (vend_id==0x2000a865 || vend_id==0x3000a865 || vend_id==0x0008a865 || vend_id==0x8140d315) { /* Yamaha SA2/SA3 or ENSONIQ SoundscapeVIVO ENS4081 */ dev->id_iobase = d.port[0] ; tmp_d.alt_base = d.port[1] ; d.irq[1] = 0 ; /* only needed for the VIVO */ } else { dev->id_iobase = d.port[2] ; tmp_d.alt_base = d.port[0] - 4; } d.drq[1] = 4 ; /* disable, it is not used ... */ } else { /* mss-compatible codec */ dev->id_alive = 8 ; /* number of io ports ? */ tmp_d = mss_op_desc ; dev->id_iobase = d.port[0] -4 ; /* XXX old mss have 4 bytes before... */ tmp_d.alt_base = d.port[2]; switch (vend_id & 0xff00ffff) { case 0x2000a865: /* Yamaha SA2 */ case 0x3000a865: /* Yamaha SA3 */ case 0x0000a865: /* Yamaha TMF719 SA3 */ dev->id_iobase = d.port[1]; tmp_d.alt_base = d.port[0]; tmp_d.conf_base = d.port[4]; tmp_d.bd_id = MD_YM0020 ; break; case 0x8100d315: /* ENSONIQ SoundscapeVIVO */ dev->id_iobase = d.port[1]; tmp_d.alt_base = d.port[0]; tmp_d.bd_id = MD_VIVO ; d.irq[1] = 0 ; break; case 0x3700630e: /* CS4237 */ tmp_d.bd_id = MD_CS4237 ; break; case 0x2500630e: /* AOpen AW37 */ tmp_d.bd_id = MD_CS4237 ; break ; case 0x3500630e: /* CS4236B */ case 0x3600630e: /* CS4236 */ tmp_d.bd_id = MD_CS4236 ; break; default: tmp_d.bd_id = MD_CS4232 ; /* to short-circuit the detect routine */ break; } strcpy(tmp_d.name, name); tmp_d.audio_fmt |= AFMT_FULLDUPLEX ; } write_pnp_parms( &d, ldn ); enable_pnp_card(); if ( (vend_id & 0x0000ffff) == 0x0000a865 ) { /* special volume setting for the Yamaha... */ outb(tmp_d.conf_base, 7 /* volume, left */); outb(tmp_d.conf_base+1, 0 ); outb(tmp_d.conf_base, 8 /* volume, right */); outb(tmp_d.conf_base+1, 0 ); } dev->id_drq = d.drq[0] ; /* primary dma */ dev->id_irq = (1 << d.irq[0] ) ; dev->id_intr = pcmintr ; dev->id_flags = DV_F_DUAL_DMA | (d.drq[1] ) ; tmp_d.synth_base = d.port[1]; /* XXX check this for yamaha */ pcmattach(dev); } static char *opti931_probe(u_long csn, u_long vend_id); static void opti931_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev); static struct pnp_device opti931 = { "OPTi931", opti931_probe, opti931_attach, &nsnd, /* use this for all sound cards */ &tty_imask /* imask */ }; DATA_SET (pnpdevice_set, opti931); static char * opti931_probe(u_long csn, u_long vend_id) { if (vend_id == 0x3109143e) { struct pnp_cinfo d; read_pnp_parms(&d, 1); if (d.enable == 0) { printf("This is an OPTi931, but LDN 1 is disabled\n"); return NULL ; } return "OPTi931" ; } return NULL ; } static void opti931_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev) { struct pnp_cinfo d ; snddev_info tmp_d ; /* patched copy of the basic snddev_info */ int p; read_pnp_parms ( &d , 3 ); /* free resources taken by LDN 3 */ d.irq[0]=0; /* free irq... */ d.port[0]=0; /* free address... */ d.enable = 0 ; write_pnp_parms ( &d , 3 ); read_pnp_parms ( &d , 2 ); /* disable LDN 2 */ d.enable = 0 ; write_pnp_parms ( &d , 2 ); read_pnp_parms ( &d , 1 ) ; write_pnp_parms( &d, 1 ); enable_pnp_card(); snddev_last_probed = &tmp_d; tmp_d = d.flags & DV_PNP_SBCODEC ? sb_op_desc : mss_op_desc ; strcpy(tmp_d.name, name); /* * My MED3931 v.1.0 allocates 3 bytes for the config space, * whereas v.2.0 allocates 4 bytes. What I know for sure is that the * upper two ports must be used, and they should end on a boundary * of 4 bytes. So I need the following trick... */ p = tmp_d.conf_base = (d.port[3] & ~3) + 2; /* config port */ /* * now set default values for both modes. */ dev->id_iobase = d.port[0] - 4 ; /* old mss have 4 bytes before... */ tmp_d.io_base = dev->id_iobase; /* needed for ad_write to work... */ tmp_d.alt_base = d.port[2]; tmp_d.synth_base = d.port[1]; opti_write(p, 4, 0xd6 /* fifo empty, OPL3, audio enable, SB3.2 */ ); ad_write (&tmp_d, 10, 2); /* enable interrupts */ if (d.flags & DV_PNP_SBCODEC) { /* sb-compatible codec */ /* * the 931 is not a real SB, it has important pieces of * hardware controlled by both the MSS and the SB port... */ printf("--- opti931 in sb mode ---\n"); opti_write(p, 6, 1); /* MCIR6 mss disable, sb enable */ /* * swap the main and alternate iobase address since we want * to work in sb mode. */ dev->id_iobase = d.port[2] ; tmp_d.alt_base = d.port[0] - 4; dev->id_flags = DV_F_DUAL_DMA | d.drq[1] ; } else { /* mss-compatible codec */ tmp_d.bd_id = MD_OPTI931 ; /* to short-circuit the detect routine */ opti_write(p, 6 , 2); /* MCIR6: mss enable, sb disable */ opti_write(p, 5, 0x28); /* MCIR5: codec in exp. mode,fifo */ dev->id_flags = DV_F_DUAL_DMA | d.drq[1] ; tmp_d.audio_fmt |= AFMT_FULLDUPLEX ; /* not really well... */ tmp_d.isr = opti931_intr; } dev->id_drq = d.drq[0] ; /* primary dma */ dev->id_irq = (1 << d.irq[0] ) ; dev->id_intr = pcmintr ; pcmattach(dev); } static char *opti925_probe(u_long csn, u_long vend_id); static void opti925_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev); static struct pnp_device opti925 = { "opti925", opti925_probe, opti925_attach, &nsnd, /* use this for all sound cards */ &tty_imask /* imask */ }; DATA_SET (pnpdevice_set, opti925); static char * opti925_probe(u_long csn, u_long vend_id) { if (vend_id == 0x2509143e) { struct pnp_cinfo d ; read_pnp_parms ( &d , 1 ) ; if (d.enable == 0) { printf("This is an OPTi925, but LDN 1 is disabled\n"); return NULL; } return "OPTi925" ; } return NULL ; } static void opti925_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev) { struct pnp_cinfo d ; snddev_info tmp_d ; /* patched copy of the basic snddev_info */ int the_irq = 0 ; tmp_d = mss_op_desc; snddev_last_probed = &tmp_d; read_pnp_parms ( &d , 3 ); /* disable LDN 3 */ the_irq = d.irq[0]; d.port[0] = 0 ; d.enable = 0 ; write_pnp_parms ( &d , 3 ); read_pnp_parms ( &d , 2 ); /* disable LDN 2 */ d.port[0] = 0 ; d.enable = 0 ; write_pnp_parms ( &d , 2 ); read_pnp_parms ( &d , 1 ) ; d.irq[0] = the_irq ; dev->id_iobase = d.port[1]; tmp_d.alt_base = d.port[0]; write_pnp_parms ( &d , 1 ); enable_pnp_card(); tmp_d.conf_base = d.port[3]; dev->id_drq = d.drq[0] ; /* primary dma */ dev->id_irq = (1 << d.irq[0] ) ; dev->id_intr = pcmintr ; dev->id_flags = DV_F_DUAL_DMA | d.drq[1] ; tmp_d.audio_fmt |= AFMT_FULLDUPLEX ; snddev_last_probed->probe(dev); /* not really necessary but doesn't harm */ pcmattach(dev); } static void gus_mem_cfg(snddev_info *tmp); static char *guspnp_probe(u_long csn, u_long vend_id); static void guspnp_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev); static struct pnp_device guspnp = { "GusPnP", guspnp_probe, guspnp_attach, &nsnd, /* use this for all sound cards */ &tty_imask /* imask */ }; DATA_SET (pnpdevice_set, guspnp); static char * guspnp_probe(u_long csn, u_long vend_id) { if (vend_id == 0x0100561e) { struct pnp_cinfo d; read_pnp_parms(&d, 0); if (d.enable == 0) { printf("This is a GusPnP, but LDN 0 is disabled\n"); return NULL ; } return "GusPnP" ; } return NULL ; } static void guspnp_attach(u_long csn, u_long vend_id, char *name, struct isa_device *dev) { struct pnp_cinfo d ; snddev_info tmp_d ; /* patched copy of the basic snddev_info */ u_char tmp; read_pnp_parms ( &d , 0 ) ; /* d.irq[1] = d.irq[0] ; */ pnp_write ( 0xf2, 0xff ); /* enable power on the guspnp */ write_pnp_parms ( &d , 0 ); enable_pnp_card(); tmp_d = mss_op_desc ; snddev_last_probed = &tmp_d; dev->id_iobase = d.port[2] - 4 ; /* room for 4 mss registers */ dev->id_drq = d.drq[1] ; /* XXX PLAY dma */ dev->id_irq = (1 << d.irq[0] ) ; dev->id_intr = pcmintr ; dev->id_flags = DV_F_DUAL_DMA | d.drq[0] ; /* REC dma */ tmp_d.io_base = d.port[2] - 4; tmp_d.alt_base = d.port[0]; /* 0x220 */ tmp_d.conf_base = d.port[1]; /* gus control block... */ tmp_d.bd_id = MD_GUSPNP ; /* reset */ gus_write(tmp_d.conf_base, 0x4c /* _URSTI */, 0 );/* Pull reset */ DELAY(1000 * 30); /* release reset and enable DAC */ gus_write(tmp_d.conf_base, 0x4c /* _URSTI */, 3 ); DELAY(1000 * 30); /* end of reset */ outb( tmp_d.alt_base, 0xC ); /* enable int and dma */ /* * unmute left & right line. Need to go in mode3, unmute, * and back to mode 2 */ tmp = ad_read(&tmp_d, 0x0c); ad_write(&tmp_d, 0x0c, 0x6c ); /* special value to enter mode 3 */ ad_write(&tmp_d, 0x19, 0 ); /* unmute left */ ad_write(&tmp_d, 0x1b, 0 ); /* unmute right */ ad_write(&tmp_d, 0x0c, tmp ); /* restore old mode */ /* send codec interrupts on irq1 and only use that one */ gus_write(tmp_d.conf_base, 0x5a , 0x4f ); /* enable access to hidden regs */ tmp = gus_read(tmp_d.conf_base, 0x5b /* IVERI */ ); gus_write(tmp_d.conf_base, 0x5b , tmp | 1 ); BVDDB(printf("GUS: silicon rev %c\n", 'A' + ( ( tmp & 0xf ) >> 4) );) strcpy(tmp_d.name, name); pcmattach(dev); } #if 0 int gus_mem_write(snddev_info *d, int addr, u_char data) { gus_writew(d->conf_base, 0x43 , addr & 0xffff ); gus_write(d->conf_base, 0x44 , (addr>>16) & 0xff ); outb(d->conf_base + 7, data); } u_char gus_mem_read(snddev_info *d, int addr) { gus_writew(d->conf_base, 0x43 , addr & 0xffff ); gus_write(d->conf_base, 0x44 , (addr>>16) & 0xff ); return inb(d->conf_base + 7); } void gus_mem_cfg(snddev_info *d) { int base; u_char old; u_char a, b; printf("configuring gus memory...\n"); gus_writew(d->conf_base, 0x52 /* LMCFI */, 1 /* 512K*/); old = gus_read(d->conf_base, 0x19); gus_write(d->conf_base, 0x19, old | 1); /* enable enhaced mode */ for (base = 0; base < 1024; base++) { a=gus_mem_read(d, base*1024); a = ~a ; gus_mem_write(d, base*1024, a); b=gus_mem_read(d, base*1024); if ( b != a ) break ; } printf("Have found %d KB ( 0x%x != 0x%x)\n", base, a, b); } #endif /* gus mem cfg... */ #endif /* NPNP > 0 */ #endif /* NPCM > 0 */