/* $NetBSD: ad1848.c,v 1.9 1996/03/01 04:08:24 mycroft Exp $ */ /* * Copyright (c) 1994 John Brezak * Copyright (c) 1991-1993 Regents of the University of California. * 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. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the Computer Systems * Engineering Group at Lawrence Berkeley Laboratory. * 4. Neither the name of the University nor of the Laboratory may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 REGENTS 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. * */ /* * Copyright by Hannu Savolainen 1994 * * 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. * */ /* * Portions of this code are from the VOXware support for the ad1848 * by Hannu Savolainen * * Portions also supplied from the SoundBlaster driver for NetBSD. */ /* * Todo: * - Need datasheet for CS4231 (for use with GUS MAX) * - Use fast audio_dma */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef AUDIO_DEBUG extern void Dprintf __P((const char *, ...)); #define DPRINTF(x) if (ad1848debug) Dprintf x int ad1848debug = 0; #else #define DPRINTF(x) #endif /* * Initial values for the indirect registers of CS4248/AD1848. */ static int ad1848_init_values[] = { /* Left Input Control */ GAIN_12|INPUT_MIC_GAIN_ENABLE, /* Right Input Control */ GAIN_12|INPUT_MIC_GAIN_ENABLE, ATTEN_12, /* Left Aux #1 Input Control */ ATTEN_12, /* Right Aux #1 Input Control */ ATTEN_12, /* Left Aux #2 Input Control */ ATTEN_12, /* Right Aux #2 Input Control */ /* bits 5-0 are attenuation select */ 0x19, /* Left DAC output Control */ 0x19, /* Right DAC output Control */ /* Clock and Data Format */ CLOCK_XTAL1|FMT_PCM8|AUTO_CAL_ENABLE, /* Interface Config */ SINGLE_DMA, INTERRUPT_ENABLE, /* Pin control */ 0x00, /* Test and Init */ 0xca, /* Misc control */ ATTEN_0<<2, /* Digital Mix Control */ 0, /* Upper base Count */ 0, /* Lower base Count */ /* Thse are for CS4231 only (additional registers): */ 0, /* Alt feature 1 */ 0, /* Alt feature 2 */ ATTEN_12, /* Left line in */ ATTEN_12, /* Right line in */ 0, /* Timer low */ 0, /* Timer high */ 0, /* unused */ 0, /* unused */ 0, /* IRQ status */ 0, /* unused */ /* Mono input (mic) Control */ MONO_INPUT_MUTE|ATTEN_6, /* mute mic by default */ 0, /* unused */ 0, /* record format */ 0, /* upper record count */ 0, /* lower record count */ }; int ad1848_probe(); void ad1848_attach(); void ad1848_reset __P((struct ad1848_softc *)); int ad1848_set_speed __P((struct ad1848_softc *, int)); static int ad_read(sc, reg) struct ad1848_softc *sc; int reg; { int x; outb(sc->sc_iobase+AD1848_IADDR, (u_char) (reg & 0xff) | sc->MCE_bit); x = inb(sc->sc_iobase+AD1848_IDATA); /* printf("(%02x<-%02x) ", reg|sc->MCE_bit, x); */ return x; } static __inline__ void ad_write(sc, reg, data) struct ad1848_softc *sc; int reg; int data; { outb(sc->sc_iobase+AD1848_IADDR, (u_char) (reg & 0xff) | sc->MCE_bit); outb(sc->sc_iobase+AD1848_IDATA, (u_char) (data & 0xff)); /* printf("(%02x->%02x) ", reg|sc->MCE_bit, data); */ } static void ad_set_MCE(sc, state) struct ad1848_softc *sc; int state; { if (state) sc->MCE_bit = MODE_CHANGE_ENABLE; else sc->MCE_bit = 0; outb(sc->sc_iobase+AD1848_IADDR, sc->MCE_bit); } static void wait_for_calibration(sc) struct ad1848_softc *sc; { int timeout = 100000; DPRINTF(("ad1848: Auto calibration started.\n")); /* * 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 and then off. */ while (timeout > 0 && inb(sc->sc_iobase+AD1848_IADDR) == SP_IN_INIT) timeout--; if (inb(sc->sc_iobase+AD1848_IADDR) == SP_IN_INIT) DPRINTF(("ad1848: Auto calibration timed out(1).\n")); outb(sc->sc_iobase+AD1848_IADDR, SP_TEST_AND_INIT); timeout = 100000; while (timeout > 0 && inb(sc->sc_iobase+AD1848_IADDR) != SP_TEST_AND_INIT) timeout--; if (inb(sc->sc_iobase+AD1848_IADDR) == SP_TEST_AND_INIT) DPRINTF(("ad1848: Auto calibration timed out(1.5).\n")); if (!(ad_read(sc, SP_TEST_AND_INIT) & AUTO_CAL_IN_PROG)) { timeout = 100000; while (timeout > 0 && !(ad_read(sc, SP_TEST_AND_INIT) & AUTO_CAL_IN_PROG)) timeout--; if (!(ad_read(sc, SP_TEST_AND_INIT) & AUTO_CAL_IN_PROG)) DPRINTF(("ad1848: Auto calibration timed out(2).\n")); } timeout = 100000; while (timeout > 0 && ad_read(sc, SP_TEST_AND_INIT) & AUTO_CAL_IN_PROG) timeout--; if (ad_read(sc, SP_TEST_AND_INIT) & AUTO_CAL_IN_PROG) DPRINTF(("ad1848: Auto calibration timed out(3).\n")); } #ifdef AUDIO_DEBUG void ad1848_dump_regs(sc) struct ad1848_softc *sc; { int i; u_char r; printf("ad1848 status=%x", inb(sc->sc_iobase+AD1848_STATUS)); printf(" regs: "); for (i = 0; i < 16; i++) { r = ad_read(sc, i); printf("%x ", r); } if (sc->mode == 2) for (i = 16; i < 32; i++) { r = ad_read(sc, i); printf("%x ", r); } printf("\n"); } #endif #ifdef NEWCONFIG void ad1848_forceintr(sc) struct ad1848_softc *sc; { static char dmabuf; /* * Set up a DMA read of one byte. * XXX Note that at this point we haven't called * at_setup_dmachan(). This is okay because it just * allocates a buffer in case it needs to make a copy, * and it won't need to make a copy for a 1 byte buffer. * (I think that calling at_setup_dmachan() should be optional; * if you don't call it, it will be called the first time * it is needed (and you pay the latency). Also, you might * never need the buffer anyway.) */ isa_dmastart(DMAMODE_READ, &dmabuf, 1, sc->sc_drq); ad_write(sc, SP_LOWER_BASE_COUNT, 0); ad_write(sc, SP_UPPER_BASE_COUNT, 0); ad_write(sc, SP_INTERFACE_CONFIG, PLAYBACK_ENABLE); } #endif /* * Probe for the ad1848 chip */ int ad1848_probe(sc) struct ad1848_softc *sc; { register int iobase = sc->sc_iobase; u_char tmp, tmp1 = 0xff, tmp2 = 0xff; int i; if (!AD1848_BASE_VALID(iobase)) { printf("ad1848: configured iobase %x invalid\n", iobase); return 0; } sc->sc_iobase = iobase; /* Is there an ad1848 chip ? */ sc->MCE_bit = MODE_CHANGE_ENABLE; sc->mode = 1; /* MODE 1 = original ad1848/ad1846/cs4248 */ /* * Check that the I/O address is in use. * * The SP_IN_INIT bit 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, inb() typically returns 0xff. */ if (((tmp = inb(iobase+AD1848_IADDR)) & SP_IN_INIT) != 0x00) { /* Not a AD1848 */ DPRINTF(("ad_detect_A %x\n", tmp)); 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(sc, 0, 0xaa); ad_write(sc, 1, 0x45); /* 0x55 with bit 0x10 clear */ if ((tmp1 = ad_read(sc, 0)) != 0xaa || (tmp2 = ad_read(sc, 1)) != 0x45) { DPRINTF(("ad_detect_B (%x/%x)\n", tmp1, tmp2)); return 0; } ad_write(sc, 0, 0x45); ad_write(sc, 1, 0xaa); if ((tmp1 = ad_read(sc, 0)) != 0x45 || (tmp2 = ad_read(sc, 1)) != 0xaa) { DPRINTF(("ad_detect_C (%x/%x)\n", tmp1, tmp2)); return 0; } /* * The indirect register I12 has some read only bits. Lets * try to change them. */ tmp = ad_read(sc, SP_MISC_INFO); ad_write(sc, SP_MISC_INFO, (~tmp) & 0x0f); if ((tmp & 0x0f) != ((tmp1 = ad_read(sc, SP_MISC_INFO)) & 0x0f)) { DPRINTF(("ad_detect_D (%x)\n", tmp1)); return 0; } /* * MSB and 4 LSBs of the reg I12 tell the chip revision. * * A preliminary version of the AD1846 data sheet stated that it * used an ID field of 0x0B. The current version, however, * states that the AD1846 uses ID 0x0A, just like the AD1848K. * * this switch statement will need updating as newer clones arrive.... */ switch (tmp1 & 0x8f) { case 0x09: sc->chip_name = "AD1848J"; break; case 0x0A: sc->chip_name = "AD1848K"; break; #if 0 /* See above */ case 0x0B: sc->chip_name = "AD1846"; break; #endif case 0x81: sc->chip_name = "CS4248revB"; /* or CS4231 rev B; see below */ break; case 0x89: sc->chip_name = "CS4248"; break; case 0x8A: sc->chip_name = "broken"; /* CS4231/AD1845; see below */ break; default: sc->chip_name = "unknown"; DPRINTF(("ad1848: unknown codec version %#02X\n", (tmp1 & 0x8f))); } /* * 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 CS4231, AD1845, etc. */ ad_write(sc, SP_MISC_INFO, 0); /* Mode2 = disabled */ for (i = 0; i < 16; i++) if ((tmp1 = ad_read(sc, i)) != (tmp2 = ad_read(sc, i + 16))) { DPRINTF(("ad_detect_F(%d/%x/%x)\n", i, tmp1, tmp2)); return 0; } /* * Try to switch the chip to mode2 (CS4231) by setting the MODE2 bit * The bit 0x80 is always 1 in CS4248, CS4231, and AD1845. */ ad_write(sc, SP_MISC_INFO, MODE2); /* Set mode2, clear 0x80 */ tmp1 = ad_read(sc, SP_MISC_INFO); if ((tmp1 & 0xc0) == (0x80 | MODE2)) { /* * CS4231 or AD1845 detected - is it? * * Verify that setting I2 doesn't change I18. */ ad_write(sc, 18, 0x88); /* Set I18 to known value */ ad_write(sc, 2, 0x45); if ((tmp2 = ad_read(sc, 18)) != 0x45) { /* No change -> CS4231? */ ad_write(sc, 2, 0xaa); if ((tmp2 = ad_read(sc, 18)) == 0xaa) { /* Rotten bits? */ DPRINTF(("ad_detect_H(%x)\n", tmp2)); return 0; } /* * It's a CS4231, or another clone with 32 registers. * Let's find out which by checking I25. */ if ((tmp1 & 0x8f) == 0x8a) { tmp1 = ad_read(sc, CS_VERSION_ID); switch (tmp1 & 0xe7) { case 0xA0: sc->chip_name = "CS4231A"; break; case 0x80: /* XXX I25 no good, AD1845 same as CS4231 */ sc->chip_name = "CS4231 or AD1845"; break; case 0x82: sc->chip_name = "CS4232"; break; } } sc->mode = 2; } } /* Wait for 1848 to init */ while(inb(sc->sc_iobase+AD1848_IADDR) & SP_IN_INIT); /* Wait for 1848 to autocal */ outb(sc->sc_iobase+AD1848_IADDR, SP_TEST_AND_INIT); while(inb(sc->sc_iobase+AD1848_IDATA) & AUTO_CAL_IN_PROG); return 1; } /* * Attach hardware to driver, attach hardware driver to audio * pseudo-device driver . */ void ad1848_attach(sc) struct ad1848_softc *sc; { register int iobase = sc->sc_iobase; int i; struct ad1848_volume vol_mid = {150, 150}; struct ad1848_volume vol_0 = {0, 0}; sc->sc_locked = 0; /* Initialize the ad1848... */ for (i = 0; i < 16; i++) ad_write(sc, i, ad1848_init_values[i]); /* ...and additional CS4231 stuff too */ if (sc->mode == 2) { #if 0 ad_write(sc, SP_INTERFACE_CONFIG, 0); /* disable SINGLE_DMA feature */ #else /* XXX SINGLE_DMA is cleared in ad1848_reset(), due to #if 0 */ #endif for (i = 0x10; i <= 0x1F; i++) if (ad1848_init_values[i] != 0) ad_write(sc, i, ad1848_init_values[i]); } ad1848_reset(sc); /* Set default encoding (ULAW) */ sc->sc_irate = sc->sc_orate = 8000; sc->precision = 8; sc->channels = 1; sc->encoding = AUDIO_ENCODING_ULAW; (void) ad1848_set_in_sr(sc, sc->sc_irate); (void) ad1848_set_out_sr(sc, sc->sc_orate); /* Set default gains */ (void) ad1848_set_rec_gain(sc, &vol_mid); (void) ad1848_set_out_gain(sc, &vol_mid); (void) ad1848_set_mon_gain(sc, &vol_0); (void) ad1848_set_aux1_gain(sc, &vol_mid); /* CD volume */ if (sc->mode == 2) { /* aux1 was really the DAC output */ (void) ad1848_set_aux2_gain(sc, &vol_mid); /* CD volume */ (void) cs4231_set_linein_gain(sc, &vol_mid); (void) cs4231_set_mono_gain(sc, &vol_0); /* mic */ } else (void) ad1848_set_aux2_gain(sc, &vol_0); /* Set default port */ (void) ad1848_set_rec_port(sc, MIC_IN_PORT); printf(": %s", sc->chip_name); } /* * Various routines to interface to higher level audio driver */ int ad1848_set_rec_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { register u_char reg, gain; DPRINTF(("ad1848_set_rec_gain: %d:%d\n", gp->left, gp->right)); sc->rec_gain = *gp; gain = (gp->left * GAIN_22_5)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_LEFT_INPUT_CONTROL); reg &= INPUT_GAIN_MASK; ad_write(sc, SP_LEFT_INPUT_CONTROL, (gain&0x0f)|reg); gain = (gp->right * GAIN_22_5)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_RIGHT_INPUT_CONTROL); reg &= INPUT_GAIN_MASK; ad_write(sc, SP_RIGHT_INPUT_CONTROL, (gain&0x0f)|reg); return(0); } int ad1848_get_rec_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { *gp = sc->rec_gain; return(0); } int ad1848_set_out_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { u_char reg; u_int atten; DPRINTF(("ad1848_set_out_gain: %d:%d\n", gp->left, gp->right)); sc->out_gain = *gp; atten = ((AUDIO_MAX_GAIN - gp->left) * OUTPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_LEFT_OUTPUT_CONTROL); reg &= OUTPUT_ATTEN_MASK; ad_write(sc, SP_LEFT_OUTPUT_CONTROL, (atten&0x3f)|reg); atten = ((AUDIO_MAX_GAIN - gp->right) * OUTPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_RIGHT_OUTPUT_CONTROL); reg &= OUTPUT_ATTEN_MASK; ad_write(sc, SP_RIGHT_OUTPUT_CONTROL, (atten&0x3f)|reg); return(0); } int ad1848_get_out_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { *gp = sc->out_gain; return(0); } int ad1848_set_mon_gain(sc, gp) /* monitor gain */ register struct ad1848_softc *sc; struct ad1848_volume *gp; { u_char reg; u_int atten; DPRINTF(("ad1848_set_mon_gain: %d\n", gp->left)); sc->mon_gain = *gp; atten = ((AUDIO_MAX_GAIN - gp->left) * OUTPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_DIGITAL_MIX); reg &= MIX_ATTEN_MASK; ad_write(sc, SP_DIGITAL_MIX, (atten&OUTPUT_ATTEN_BITS)|reg); return(0); } int ad1848_get_mon_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { *gp = sc->mon_gain; return(0); } int cs4231_set_mono_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { u_char reg, oreg; u_int atten; DPRINTF(("cs4231_set_mono_gain: %d\n", gp->left)); sc->mono_gain = *gp; atten = ((AUDIO_MAX_GAIN - gp->left) * MONO_INPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; oreg = reg = ad_read(sc, CS_MONO_IO_CONTROL); reg &= MONO_INPUT_ATTEN_MASK; ad_write(sc, CS_MONO_IO_CONTROL, (atten&MONO_INPUT_ATTEN_BITS)|reg); DPRINTF(("cs4231_set_mono_gain: was:%x\n", oreg)); return(0); } int cs4231_get_mono_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { *gp = sc->mono_gain; return(0); } int ad1848_set_mic_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { u_char reg; u_int atten; DPRINTF(("cs4231_set_mic_gain: %d\n", gp->left)); if (gp->left > AUDIO_MAX_GAIN/2) { sc->mic_gain_on = 1; reg = ad_read(sc, SP_LEFT_INPUT_CONTROL); ad_write(sc, SP_LEFT_INPUT_CONTROL, reg | INPUT_MIC_GAIN_ENABLE); } else { sc->mic_gain_on = 0; reg = ad_read(sc, SP_LEFT_INPUT_CONTROL); ad_write(sc, SP_LEFT_INPUT_CONTROL, reg & ~INPUT_MIC_GAIN_ENABLE); } return(0); } int ad1848_get_mic_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { if (sc->mic_gain_on) gp->left = gp->right = AUDIO_MAX_GAIN; else gp->left = gp->right = AUDIO_MIN_GAIN; return(0); } void ad1848_mute_monitor(addr, mute) void *addr; int mute; { register struct ad1848_softc *sc = addr; DPRINTF(("ad1848_mute_monitor: %smuting\n", mute ? "" : "un")); if (sc->mode == 2) { cs4231_mute_monitor(sc, mute); cs4231_mute_mono(sc, mute); cs4231_mute_line(sc, mute); } ad1848_mute_aux1(sc, mute); ad1848_mute_aux2(sc, mute); } void cs4231_mute_monitor(sc, mute) register struct ad1848_softc *sc; int mute; { u_char reg; if (mute) { DPRINTF(("cs4231_mute_monitor: muting\n")); reg = ad_read(sc, SP_LEFT_OUTPUT_CONTROL); ad_write(sc, SP_LEFT_OUTPUT_CONTROL, OUTPUT_MUTE|reg); reg = ad_read(sc, SP_RIGHT_OUTPUT_CONTROL); ad_write(sc, SP_RIGHT_OUTPUT_CONTROL, OUTPUT_MUTE|reg); } else if (!sc->mon_mute) { DPRINTF(("cs4231_mute_monitor: unmuting\n")); reg = ad_read(sc, SP_LEFT_OUTPUT_CONTROL); ad_write(sc, SP_LEFT_OUTPUT_CONTROL, reg & ~OUTPUT_MUTE); reg = ad_read(sc, SP_RIGHT_OUTPUT_CONTROL); ad_write(sc, SP_RIGHT_OUTPUT_CONTROL, reg & ~OUTPUT_MUTE); } } void cs4231_mute_mono(sc, mute) register struct ad1848_softc *sc; int mute; { u_char reg; if (mute) { DPRINTF(("cs4231_mute_mono: muting\n")); reg = ad_read(sc, CS_MONO_IO_CONTROL); ad_write(sc, CS_MONO_IO_CONTROL, MONO_INPUT_MUTE|reg); } else if (!sc->mono_mute) { DPRINTF(("cs4231_mute_mono: unmuting\n")); reg = ad_read(sc, CS_MONO_IO_CONTROL); ad_write(sc, CS_MONO_IO_CONTROL, reg & ~MONO_INPUT_MUTE); } } void cs4231_mute_line(sc, mute) register struct ad1848_softc *sc; int mute; { u_char reg; if (mute) { DPRINTF(("cs4231_mute_line: muting\n")); reg = ad_read(sc, CS_LEFT_LINE_CONTROL); ad_write(sc, CS_LEFT_LINE_CONTROL, LINE_INPUT_MUTE|reg); reg = ad_read(sc, CS_RIGHT_LINE_CONTROL); ad_write(sc, CS_RIGHT_LINE_CONTROL, LINE_INPUT_MUTE|reg); } else if (!sc->line_mute) { DPRINTF(("cs4231_mute_line: unmuting\n")); reg = ad_read(sc, CS_LEFT_LINE_CONTROL); ad_write(sc, CS_LEFT_LINE_CONTROL, reg & ~LINE_INPUT_MUTE); reg = ad_read(sc, CS_RIGHT_LINE_CONTROL); ad_write(sc, CS_RIGHT_LINE_CONTROL, reg & ~LINE_INPUT_MUTE); } } void ad1848_mute_aux1(sc, mute) register struct ad1848_softc *sc; int mute; { u_char reg; if (mute) { DPRINTF(("ad1848_mute_aux1: muting\n")); reg = ad_read(sc, SP_LEFT_AUX1_CONTROL); ad_write(sc, SP_LEFT_AUX1_CONTROL, AUX_INPUT_MUTE|reg); reg = ad_read(sc, SP_RIGHT_AUX1_CONTROL); ad_write(sc, SP_RIGHT_AUX1_CONTROL, AUX_INPUT_MUTE|reg); } else if (!sc->aux1_mute) { DPRINTF(("ad1848_mute_aux1: unmuting\n")); reg = ad_read(sc, SP_LEFT_AUX1_CONTROL); ad_write(sc, SP_LEFT_AUX1_CONTROL, reg & ~AUX_INPUT_MUTE); reg = ad_read(sc, SP_RIGHT_AUX1_CONTROL); ad_write(sc, SP_RIGHT_AUX1_CONTROL, reg & ~AUX_INPUT_MUTE); } } void ad1848_mute_aux2(sc, mute) register struct ad1848_softc *sc; int mute; { u_char reg; if (mute) { DPRINTF(("ad1848_mute_aux2: muting\n")); reg = ad_read(sc, SP_LEFT_AUX2_CONTROL); ad_write(sc, SP_LEFT_AUX2_CONTROL, AUX_INPUT_MUTE|reg); reg = ad_read(sc, SP_RIGHT_AUX2_CONTROL); ad_write(sc, SP_RIGHT_AUX2_CONTROL, AUX_INPUT_MUTE|reg); } else if (!sc->aux2_mute) { DPRINTF(("ad1848_mute_aux2: unmuting\n")); reg = ad_read(sc, SP_LEFT_AUX2_CONTROL); ad_write(sc, SP_LEFT_AUX2_CONTROL, reg & ~AUX_INPUT_MUTE); reg = ad_read(sc, SP_RIGHT_AUX2_CONTROL); ad_write(sc, SP_RIGHT_AUX2_CONTROL, reg & ~AUX_INPUT_MUTE); } } int ad1848_set_aux1_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { u_char reg; u_int atten; DPRINTF(("ad1848_set_aux1_gain: %d:%d\n", gp->left, gp->right)); sc->aux1_gain = *gp; atten = ((AUDIO_MAX_GAIN - gp->left) * AUX_INPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_LEFT_AUX1_CONTROL); reg &= ~(AUX_INPUT_ATTEN_BITS); ad_write(sc, SP_LEFT_AUX1_CONTROL, (atten&0x1f)|reg); atten = ((AUDIO_MAX_GAIN - gp->right) * AUX_INPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_RIGHT_AUX1_CONTROL); reg &= ~(AUX_INPUT_ATTEN_BITS); ad_write(sc, SP_RIGHT_AUX1_CONTROL, (atten&0x1f)|reg); return(0); } int ad1848_get_aux1_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { *gp = sc->aux1_gain; return(0); } int cs4231_set_linein_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { u_char reg, oregl, oregr; u_int atten; DPRINTF(("ad1848_set_linein_gain: %d:%d\n", gp->left, gp->right)); sc->line_gain = *gp; atten = ((AUDIO_MAX_GAIN - gp->left) * LINE_INPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; oregl = reg = ad_read(sc, CS_LEFT_LINE_CONTROL); reg &= ~(LINE_INPUT_ATTEN_BITS); ad_write(sc, CS_LEFT_LINE_CONTROL, (atten&LINE_INPUT_ATTEN_BITS)|reg); atten = ((AUDIO_MAX_GAIN - gp->right) * LINE_INPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; oregr = reg = ad_read(sc, CS_RIGHT_LINE_CONTROL); reg &= ~(LINE_INPUT_ATTEN_BITS); ad_write(sc, CS_RIGHT_LINE_CONTROL, (atten&LINE_INPUT_ATTEN_BITS)|reg); DPRINTF(("ad1848_set_linein_gain: was %x:%x\n", oregl, oregr)); return(0); } int cs4231_get_linein_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { *gp = sc->line_gain; return(0); } int ad1848_set_aux2_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { u_char reg; u_int atten; DPRINTF(("ad1848_set_aux2_gain: %d:%d\n", gp->left, gp->right)); sc->aux2_gain = *gp; atten = ((AUDIO_MAX_GAIN - gp->left) * AUX_INPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_LEFT_AUX2_CONTROL); reg &= ~(AUX_INPUT_ATTEN_BITS); ad_write(sc, SP_LEFT_AUX2_CONTROL, (atten&0x1f)|reg); atten = ((AUDIO_MAX_GAIN - gp->right) * AUX_INPUT_ATTEN_BITS)/AUDIO_MAX_GAIN; reg = ad_read(sc, SP_RIGHT_AUX2_CONTROL); reg &= ~(AUX_INPUT_ATTEN_BITS); ad_write(sc, SP_RIGHT_AUX2_CONTROL, (atten&0x1f)|reg); return(0); } int ad1848_get_aux2_gain(sc, gp) register struct ad1848_softc *sc; struct ad1848_volume *gp; { *gp = sc->aux2_gain; return 0; } int ad1848_set_in_sr(addr, sr) void *addr; u_long sr; { register struct ad1848_softc *sc = addr; DPRINTF(("ad1848_set_in_sr: %d\n", sr)); sc->sc_irate = sc->sc_orate = ad1848_set_speed(sc, sr); return(0); } u_long ad1848_get_in_sr(addr) void *addr; { register struct ad1848_softc *sc = addr; return(sc->sc_irate); } int ad1848_set_out_sr(addr, sr) void *addr; u_long sr; { register struct ad1848_softc *sc = addr; DPRINTF(("ad1848_set_out_sr: %d\n", sr)); sc->sc_irate = sc->sc_orate = ad1848_set_speed(sc, sr); return(0); } u_long ad1848_get_out_sr(addr) void *addr; { register struct ad1848_softc *sc = addr; return(sc->sc_orate); } int ad1848_query_encoding(addr, fp) void *addr; struct audio_encoding *fp; { switch (fp->index) { case 0: strcpy(fp->name, AudioEmulaw); fp->format_id = AUDIO_ENCODING_ULAW; break; case 1: strcpy(fp->name, AudioEalaw); fp->format_id = AUDIO_ENCODING_ALAW; break; case 2: strcpy(fp->name, AudioEpcm16); fp->format_id = AUDIO_ENCODING_PCM16; break; case 3: strcpy(fp->name, AudioEpcm8); fp->format_id = AUDIO_ENCODING_PCM8; break; default: return(EINVAL); /*NOTREACHED*/ } return (0); } int ad1848_set_encoding(addr, enc) void *addr; u_int enc; { register struct ad1848_softc *sc = addr; DPRINTF(("ad1848_set_encoding: %d\n", enc)); if (sc->encoding != AUDIO_ENCODING_PCM8 && sc->encoding != AUDIO_ENCODING_PCM16 && sc->encoding != AUDIO_ENCODING_ALAW && sc->encoding != AUDIO_ENCODING_ULAW) { sc->encoding = AUDIO_ENCODING_PCM8; return (EINVAL); } sc->encoding = ad1848_set_format(sc, enc, sc->precision); if (sc->encoding == -1) { sc->encoding = AUDIO_ENCODING_PCM8; return (EINVAL); } return (0); } int ad1848_get_encoding(addr) void *addr; { register struct ad1848_softc *sc = addr; return(sc->encoding); } int ad1848_set_precision(addr, prec) void *addr; u_int prec; { register struct ad1848_softc *sc = addr; DPRINTF(("ad1848_set_precision: %d\n", prec)); sc->encoding = ad1848_set_format(sc, sc->encoding, prec); if (sc->encoding == -1) { sc->encoding = AUDIO_ENCODING_PCM16; sc->precision = 16; return (EINVAL); } sc->precision = prec; return (0); } int ad1848_get_precision(addr) void *addr; { register struct ad1848_softc *sc = addr; return(sc->precision); } int ad1848_set_channels(addr, chans) void *addr; int chans; { register struct ad1848_softc *sc = addr; int mode; DPRINTF(("ad1848_set_channels: %d\n", chans)); if (chans < 1 || chans > 2) return(EINVAL); sc->channels = chans; return(0); } int ad1848_get_channels(addr) void *addr; { register struct ad1848_softc *sc = addr; return(sc->channels); } int ad1848_set_rec_port(sc, port) register struct ad1848_softc *sc; int port; { u_char inp, reg; DPRINTF(("ad1848_set_rec_port: 0x%x\n", port)); if (port == MIC_IN_PORT) { inp = MIC_INPUT; } else if (port == LINE_IN_PORT) { inp = LINE_INPUT; } else if (port == DAC_IN_PORT) { inp = MIXED_DAC_INPUT; } else if (sc->mode == 2 && port == AUX1_IN_PORT) { inp = AUX_INPUT; } else return(EINVAL); reg = ad_read(sc, SP_LEFT_INPUT_CONTROL); reg &= INPUT_SOURCE_MASK; ad_write(sc, SP_LEFT_INPUT_CONTROL, (inp|reg)); reg = ad_read(sc, SP_RIGHT_INPUT_CONTROL); reg &= INPUT_SOURCE_MASK; ad_write(sc, SP_RIGHT_INPUT_CONTROL, (inp|reg)); sc->rec_port = port; return(0); } int ad1848_get_rec_port(sc) register struct ad1848_softc *sc; { return(sc->rec_port); } int ad1848_round_blocksize(addr, blk) void *addr; int blk; { register struct ad1848_softc *sc = addr; sc->sc_lastcc = -1; /* Higher speeds need bigger blocks to avoid popping and silence gaps. */ if ((sc->sc_orate > 8000 || sc->sc_irate > 8000) && blk < NBPG/2) blk = NBPG/2; /* don't try to DMA too much at once, though. */ if (blk > NBPG) blk = NBPG; if (sc->channels == 2) return (blk & ~1); /* must be even to preserve stereo separation */ else return(blk); /* Anything goes :-) */ } u_int ad1848_get_silence(enc) int enc; { #define ULAW_SILENCE 0x7f #define ALAW_SILENCE 0x55 #define LINEAR_SILENCE 0 u_int auzero; switch (enc) { case AUDIO_ENCODING_ULAW: auzero = ULAW_SILENCE; break; case AUDIO_ENCODING_ALAW: auzero = ALAW_SILENCE; break; case AUDIO_ENCODING_PCM8: case AUDIO_ENCODING_PCM16: default: auzero = LINEAR_SILENCE; break; } return(auzero); } int ad1848_open(sc, dev, flags) struct ad1848_softc *sc; dev_t dev; int flags; { DPRINTF(("ad1848_open: sc=0x%x\n", sc)); sc->sc_intr = 0; sc->sc_lastcc = -1; sc->sc_locked = 0; /* Enable interrupts */ DPRINTF(("ad1848_open: enable intrs\n")); ad_write(sc, SP_PIN_CONTROL, INTERRUPT_ENABLE|ad_read(sc, SP_PIN_CONTROL)); #ifdef AUDIO_DEBUG if (ad1848debug) ad1848_dump_regs(sc); #endif return 0; } /* * Close function is called at splaudio(). */ void ad1848_close(addr) void *addr; { struct ad1848_softc *sc = addr; register u_char r; sc->sc_intr = 0; DPRINTF(("ad1848_close: stop DMA\n")); ad_write(sc, SP_LOWER_BASE_COUNT, (u_char)0); ad_write(sc, SP_UPPER_BASE_COUNT, (u_char)0); /* Disable interrupts */ DPRINTF(("ad1848_close: disable intrs\n")); ad_write(sc, SP_PIN_CONTROL, ad_read(sc, SP_PIN_CONTROL) & ~(INTERRUPT_ENABLE)); DPRINTF(("ad1848_close: disable capture and playback\n")); r = ad_read(sc, SP_INTERFACE_CONFIG); r &= ~(CAPTURE_ENABLE|PLAYBACK_ENABLE); ad_write(sc, SP_INTERFACE_CONFIG, r); #ifdef AUDIO_DEBUG if (ad1848debug) ad1848_dump_regs(sc); #endif } /* * Lower-level routines */ int ad1848_commit_settings(addr) void *addr; { struct ad1848_softc *sc = addr; int timeout; u_char fs; int s = splaudio(); ad1848_mute_monitor(sc, 1); ad_set_MCE(sc, 1); /* Enables changes to the format select reg */ fs = sc->speed_bits | (sc->format_bits << 5); if (sc->channels == 2) fs |= FMT_STEREO; ad_write(sc, SP_CLOCK_DATA_FORMAT, fs); /* * If mode == 2 (CS4231), set I28 also. It's the capture format register. */ if (sc->mode == 2) { /* Gravis Ultrasound MAX SDK sources says something about errata * sheets, with the implication that these inb()s are necessary. */ (void) inb(sc->sc_iobase+AD1848_IDATA); (void) inb(sc->sc_iobase+AD1848_IDATA); /* * Write to I8 starts resyncronization. Wait until it completes. */ timeout = 100000; while (timeout > 0 && inb(sc->sc_iobase+AD1848_IADDR) == SP_IN_INIT) timeout--; ad_write(sc, CS_REC_FORMAT, fs); /* Gravis Ultrasound MAX SDK sources says something about errata * sheets, with the implication that these inb()s are necessary. */ (void) inb(sc->sc_iobase+AD1848_IDATA); (void) inb(sc->sc_iobase+AD1848_IDATA); /* Now wait for resync for capture side of the house */ } /* * Write to I8 starts resyncronization. Wait until it completes. */ timeout = 100000; while (timeout > 0 && inb(sc->sc_iobase+AD1848_IADDR) == SP_IN_INIT) timeout--; if (inb(sc->sc_iobase+AD1848_IADDR) == SP_IN_INIT) printf("ad1848_commit: Auto calibration timed out\n"); /* * Starts the calibration process and * enters playback mode after it. */ ad_set_MCE(sc, 0); wait_for_calibration(sc); ad1848_mute_monitor(sc, 0); sc->sc_lastcc = -1; splx(s); return 0; } void ad1848_reset(sc) register struct ad1848_softc *sc; { u_char r; DPRINTF(("ad1848_reset\n")); /* Clear the PEN and CEN bits */ #if 0 r = ad_read(sc, SP_INTERFACE_CONFIG); r &= ~(CAPTURE_ENABLE|PLAYBACK_ENABLE); ad_write(sc, SP_INTERFACE_CONFIG, r); #else ad_write(sc, SP_INTERFACE_CONFIG, 0); #endif if (sc->mode == 2) { outb(sc->sc_iobase+AD1848_IADDR, CS_IRQ_STATUS); outb(sc->sc_iobase+AD1848_IDATA, 0); } /* Clear interrupt status */ outb(sc->sc_iobase+AD1848_STATUS, 0); #ifdef AUDIO_DEBUG if (ad1848debug) ad1848_dump_regs(sc); #endif } int ad1848_set_speed(sc, arg) register struct ad1848_softc *sc; int arg; { /* * The sampling speed is encoded in the least significant nible of I8. The * LSB selects the clock source (0=24.576 MHz, 1=16.9344 Mhz) and other * three bits select the divisor (indirectly): * * The available speeds are in the following table. Keep the speeds in * the increasing order. */ typedef struct { int speed; u_char bits; } speed_struct; static speed_struct speed_table[] = { {5510, (0 << 1) | 1}, {5510, (0 << 1) | 1}, {6620, (7 << 1) | 1}, {8000, (0 << 1) | 0}, {9600, (7 << 1) | 0}, {11025, (1 << 1) | 1}, {16000, (1 << 1) | 0}, {18900, (2 << 1) | 1}, {22050, (3 << 1) | 1}, {27420, (2 << 1) | 0}, {32000, (3 << 1) | 0}, {33075, (6 << 1) | 1}, {37800, (4 << 1) | 1}, {44100, (5 << 1) | 1}, {48000, (6 << 1) | 0} }; int i, n, selected = -1; n = sizeof(speed_table) / sizeof(speed_struct); if (arg < speed_table[0].speed) selected = 0; if (arg > speed_table[n - 1].speed) selected = n - 1; for (i = 1 /*really*/ ; selected == -1 && i < n; i++) if (speed_table[i].speed == arg) selected = i; else if (speed_table[i].speed > arg) { int diff1, diff2; diff1 = arg - speed_table[i - 1].speed; diff2 = speed_table[i].speed - arg; if (diff1 < diff2) selected = i - 1; else selected = i; } if (selected == -1) { printf("ad1848: Can't find speed???\n"); selected = 3; } sc->speed = speed_table[selected].speed; sc->speed_bits = speed_table[selected].bits; return sc->speed; } int ad1848_set_format(sc, fmt, prec) register struct ad1848_softc *sc; int fmt, prec; { static u_char format2bits[] = { /* AUDIO_ENCODING_ULAW */ FMT_ULAW >> 5, /* AUDIO_ENCODING_ALAW */ FMT_ALAW >> 5, /* AUDIO_ENCODING_PCM16 */ FMT_TWOS_COMP >> 5, /* AUDIO_ENCODING_PCM8 */ FMT_PCM8 >> 5 }; DPRINTF(("ad1848_set_format: fmt=%d prec=%d\n", fmt, prec)); /* If not linear; force prec to 8bits */ if (fmt != AUDIO_ENCODING_PCM16 && prec == 16) prec = 8; if (fmt < AUDIO_ENCODING_ULAW || fmt > AUDIO_ENCODING_PCM8) goto nogood; if (prec != 8 && prec != 16) goto nogood; sc->format_bits = format2bits[fmt-1]; if (fmt == AUDIO_ENCODING_PCM16 && prec == 8) sc->format_bits = FMT_PCM8 >> 5; /* signed vs. unsigned samples? */ DPRINTF(("ad1848_set_format: bits=%x\n", sc->format_bits)); return fmt; nogood: sc->format_bits = 0; return -1; } /* * Halt a DMA in progress. */ int ad1848_halt_out_dma(addr) void *addr; { register struct ad1848_softc *sc = addr; u_char reg; DPRINTF(("ad1848: ad1848_halt_out_dma\n")); reg = ad_read(sc, SP_INTERFACE_CONFIG); ad_write(sc, SP_INTERFACE_CONFIG, (reg & ~PLAYBACK_ENABLE)); sc->sc_locked = 0; return(0); } int ad1848_halt_in_dma(addr) void *addr; { register struct ad1848_softc *sc = addr; u_char reg; DPRINTF(("ad1848: ad1848_halt_in_dma\n")); reg = ad_read(sc, SP_INTERFACE_CONFIG); ad_write(sc, SP_INTERFACE_CONFIG, (reg & ~CAPTURE_ENABLE)); sc->sc_locked = 0; return(0); } int ad1848_cont_out_dma(addr) void *addr; { register struct ad1848_softc *sc = addr; u_char reg; DPRINTF(("ad1848: ad1848_cont_out_dma %s\n", sc->sc_locked?"(locked)":"")); reg = ad_read(sc, SP_INTERFACE_CONFIG); ad_write(sc, SP_INTERFACE_CONFIG, (reg | PLAYBACK_ENABLE)); return(0); } int ad1848_cont_in_dma(addr) void *addr; { register struct ad1848_softc *sc = addr; u_char reg; DPRINTF(("ad1848: ad1848_cont_in_dma %s\n", sc->sc_locked?"(locked)":"")); reg = ad_read(sc, SP_INTERFACE_CONFIG); ad_write(sc, SP_INTERFACE_CONFIG, (reg | CAPTURE_ENABLE)); return(0); } /* * DMA input/output are called at splaudio(). */ int ad1848_dma_input(addr, p, cc, intr, arg) void *addr; void *p; int cc; void (*intr)(); void *arg; { register struct ad1848_softc *sc = addr; register int iobase; register u_char reg; if (sc->sc_locked) { DPRINTF(("ad1848_dma_input: locked\n")); return 0; } #ifdef AUDIO_DEBUG if (ad1848debug > 1) Dprintf("ad1848_dma_input: cc=%d 0x%x (0x%x)\n", cc, intr, arg); #endif sc->sc_locked = 1; sc->sc_intr = intr; sc->sc_arg = arg; sc->sc_dma_flags = DMAMODE_READ; sc->sc_dma_bp = p; sc->sc_dma_cnt = cc; isa_dmastart(DMAMODE_READ, p, cc, sc->sc_recdrq); if (sc->precision == 16) cc >>= 1; if (sc->channels == 2) cc >>= 1; cc--; if (sc->sc_lastcc != cc || sc->sc_mode != AUMODE_RECORD) { ad_write(sc, SP_LOWER_BASE_COUNT, (u_char)(cc & 0xff)); ad_write(sc, SP_UPPER_BASE_COUNT, (u_char)((cc >> 8) & 0xff)); if (sc->mode == 2) { ad_write(sc, CS_LOWER_REC_CNT, (u_char)(cc & 0xff)); ad_write(sc, CS_UPPER_REC_CNT, (u_char)((cc >> 8) & 0xff)); } reg = ad_read(sc, SP_INTERFACE_CONFIG); ad_write(sc, SP_INTERFACE_CONFIG, (CAPTURE_ENABLE|reg)); sc->sc_lastcc = cc; sc->sc_mode = AUMODE_RECORD; } return 0; } int ad1848_dma_output(addr, p, cc, intr, arg) void *addr; void *p; int cc; void (*intr)(); void *arg; { register struct ad1848_softc *sc = addr; register int iobase; register u_char reg; if (sc->sc_locked) { DPRINTF(("ad1848_dma_output: locked\n")); return 0; } #ifdef AUDIO_DEBUG if (ad1848debug > 1) Dprintf("ad1848_dma_output: cc=%d 0x%x (0x%x)\n", cc, intr, arg); #endif sc->sc_locked = 1; sc->sc_intr = intr; sc->sc_arg = arg; sc->sc_dma_flags = DMAMODE_WRITE; sc->sc_dma_bp = p; sc->sc_dma_cnt = cc; isa_dmastart(DMAMODE_WRITE, p, cc, sc->sc_drq); if (sc->precision == 16) cc >>= 1; if (sc->channels == 2) cc >>= 1; cc--; if (sc->sc_lastcc != cc || sc->sc_mode != AUMODE_PLAY) { ad_write(sc, SP_LOWER_BASE_COUNT, (u_char)(cc & 0xff)); ad_write(sc, SP_UPPER_BASE_COUNT, (u_char)((cc >> 8) & 0xff)); reg = ad_read(sc, SP_INTERFACE_CONFIG); ad_write(sc, SP_INTERFACE_CONFIG, (PLAYBACK_ENABLE|reg)); sc->sc_lastcc = cc; sc->sc_mode = AUMODE_PLAY; } return 0; } int ad1848_intr(arg) void *arg; { register struct ad1848_softc *sc = arg; int retval = 0; u_char status; /* Get intr status */ status = inb(sc->sc_iobase+AD1848_STATUS); #ifdef AUDIO_DEBUG if (ad1848debug > 1) Dprintf("ad1848_intr: intr=0x%x status=%x\n", sc->sc_intr, status); #endif sc->sc_locked = 0; sc->sc_interrupts++; /* Handle interrupt */ if (sc->sc_intr && (status & INTERRUPT_STATUS)) { /* ACK DMA read because it may be in a bounce buffer */ /* XXX Do write to mask DMA ? */ if (sc->sc_dma_flags & DMAMODE_READ) isa_dmadone(sc->sc_dma_flags, sc->sc_dma_bp, sc->sc_dma_cnt - 1, sc->sc_recdrq); (*sc->sc_intr)(sc->sc_arg); retval = 1; } /* clear interrupt */ if (status & INTERRUPT_STATUS) outb(sc->sc_iobase+AD1848_STATUS, 0); return(retval); }