/* * sound/ad1848.c * * The low level driver for the AD1848/CS4248 codec chip which * is used for example in the MS Sound System. * * The CS4231 which is used in the GUS MAX and some other cards is * upwards compatible with AD1848 and this driver is able to drive it. * * CS4231A and AD1845 are upward compatible with CS4231. However * the new features of these chips are different. * * CS4232 is a PnP audio chip which contains a CS4231A (and SB, MPU). * CS4232A is an improved version of CS4232. */ /* * Copyright (C) by Hannu Savolainen 1993-1997 * * OSS/Free for Linux is distributed under the GNU GENERAL PUBLIC LICENSE (GPL) * Version 2 (June 1991). See the "COPYING" file distributed with this software * for more info. */ #include #include #include #include "soundmodule.h" #define DEB(x) #define DEB1(x) #include "sound_config.h" #ifdef CONFIG_AD1848 #include "ad1848_mixer.h" typedef struct { int base; int irq; int dma1, dma2; int dual_dma; /* 1, when two DMA channels allocated */ unsigned char MCE_bit; unsigned char saved_regs[16]; int debug_flag; int audio_flags; int record_dev, playback_dev; int xfer_count; int audio_mode; int open_mode; int intr_active; char *chip_name, *name; int model; #define MD_1848 1 #define MD_4231 2 #define MD_4231A 3 #define MD_1845 4 #define MD_4232 5 #define MD_C930 6 #define MD_IWAVE 7 /* Mixer parameters */ int recmask; int supported_devices, orig_devices; int supported_rec_devices, orig_rec_devices; int *levels; short mixer_reroute[32]; int dev_no; volatile unsigned long timer_ticks; int timer_running; int irq_ok; mixer_ents *mix_devices; int mixer_output_port; int c930_password_port; } ad1848_info; typedef struct ad1848_port_info { int open_mode; int speed; unsigned char speed_bits; int channels; int audio_format; unsigned char format_bits; } ad1848_port_info; static int nr_ad1848_devs = 0; static volatile char irq2dev[17] = {-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1}; #if defined(CONFIG_SEQUENCER) && !defined(EXCLUDE_TIMERS) static int timer_installed = -1; #endif static int ad_format_mask[8 /*devc->model */ ] = { 0, AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW, AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW | AFMT_S16_BE | AFMT_IMA_ADPCM, AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW | AFMT_S16_BE | AFMT_IMA_ADPCM, AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW, /* AD1845 */ AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW | AFMT_S16_BE | AFMT_IMA_ADPCM, AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW | AFMT_S16_BE | AFMT_IMA_ADPCM, AFMT_U8 | AFMT_S16_LE | AFMT_MU_LAW | AFMT_A_LAW | AFMT_S16_BE | AFMT_IMA_ADPCM }; static ad1848_info adev_info[MAX_AUDIO_DEV]; #define io_Index_Addr(d) ((d)->base) #define io_Indexed_Data(d) ((d)->base+1) #define io_Status(d) ((d)->base+2) #define io_Polled_IO(d) ((d)->base+3) static int ad1848_open(int dev, int mode); static void ad1848_close(int dev); static int ad1848_ioctl(int dev, unsigned int cmd, caddr_t arg); static void ad1848_output_block(int dev, unsigned long buf, int count, int intrflag); static void ad1848_start_input(int dev, unsigned long buf, int count, int intrflag); static int ad1848_prepare_for_output(int dev, int bsize, int bcount); static int ad1848_prepare_for_input(int dev, int bsize, int bcount); static void ad1848_halt(int dev); static void ad1848_halt_input(int dev); static void ad1848_halt_output(int dev); static void ad1848_trigger(int dev, int bits); #if (defined(CONFIG_SEQUENCER) && !defined(EXCLUDE_TIMERS)) || defined(MODULE) static int ad1848_tmr_install(int dev); static void ad1848_tmr_reprogram(int dev); #endif static int ad_read(ad1848_info * devc, int reg) { unsigned long flags; int x; int timeout = 900000; while (timeout > 0 && inb(devc->base) == 0x80) /*Are we initializing */ timeout--; save_flags(flags); cli(); outb(((unsigned char) (reg & 0xff) | devc->MCE_bit), io_Index_Addr(devc)); x = inb(io_Indexed_Data(devc)); /* printk("(%02x<-%02x) ", reg|devc->MCE_bit, x); */ restore_flags(flags); return x; } static void ad_write(ad1848_info * devc, int reg, int data) { unsigned long flags; int timeout = 900000; while (timeout > 0 && inb(devc->base) == 0x80) /*Are we initializing */ timeout--; save_flags(flags); cli(); outb(((unsigned char) (reg & 0xff) | devc->MCE_bit), io_Index_Addr(devc)); outb(((unsigned char) (data & 0xff)), io_Indexed_Data(devc)); /* printk("(%02x->%02x) ", reg|devc->MCE_bit, data); */ restore_flags(flags); } static void wait_for_calibration(ad1848_info * devc) { int timeout = 0; /* * 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. */ timeout = 100000; while (timeout > 0 && inb(devc->base) == 0x80) timeout--; if (inb(devc->base) & 0x80) printk("ad1848: Auto calibration timed out(1).\n"); timeout = 100; while (timeout > 0 && !(ad_read(devc, 11) & 0x20)) timeout--; if (!(ad_read(devc, 11) & 0x20)) return; timeout = 80000; while (timeout > 0 && ad_read(devc, 11) & 0x20) timeout--; if (ad_read(devc, 11) & 0x20) if (devc->model != MD_1845) printk("ad1848: Auto calibration timed out(3).\n"); } static void ad_mute(ad1848_info * devc) { int i; unsigned char prev; /* * Save old register settings and mute output channels */ for (i = 6; i < 8; i++) { prev = devc->saved_regs[i] = ad_read(devc, i); } } static void ad_unmute(ad1848_info * devc) { } static void ad_enter_MCE(ad1848_info * devc) { unsigned long flags; int timeout = 1000; unsigned short prev; while (timeout > 0 && inb(devc->base) == 0x80) /*Are we initializing */ timeout--; save_flags(flags); cli(); devc->MCE_bit = 0x40; prev = inb(io_Index_Addr(devc)); if (prev & 0x40) { restore_flags(flags); return; } outb((devc->MCE_bit), io_Index_Addr(devc)); restore_flags(flags); } static void ad_leave_MCE(ad1848_info * devc) { unsigned long flags; unsigned char prev, acal; int timeout = 1000; while (timeout > 0 && inb(devc->base) == 0x80) /*Are we initializing */ timeout--; save_flags(flags); cli(); acal = ad_read(devc, 9); devc->MCE_bit = 0x00; prev = inb(io_Index_Addr(devc)); outb((0x00), io_Index_Addr(devc)); /* Clear the MCE bit */ if ((prev & 0x40) == 0) /* Not in MCE mode */ { restore_flags(flags); return; } outb((0x00), io_Index_Addr(devc)); /* Clear the MCE bit */ if (acal & 0x08) /* Auto calibration is enabled */ wait_for_calibration(devc); restore_flags(flags); } static int ad1848_set_recmask(ad1848_info * devc, int mask) { unsigned char recdev; int i, n; mask &= devc->supported_rec_devices; /* Rename the mixer bits if necessary */ for (i = 0; i < 32; i++) if (devc->mixer_reroute[i] != i) if (mask & (1 << i)) { mask &= ~(1 << i); mask |= (1 << devc->mixer_reroute[i]); } n = 0; for (i = 0; i < 32; i++) /* Count selected device bits */ if (mask & (1 << i)) n++; if (n == 0) mask = SOUND_MASK_MIC; else if (n != 1) /* Too many devices selected */ { mask &= ~devc->recmask; /* Filter out active settings */ n = 0; for (i = 0; i < 32; i++) /* Count selected device bits */ if (mask & (1 << i)) n++; if (n != 1) mask = SOUND_MASK_MIC; } switch (mask) { case SOUND_MASK_MIC: recdev = 2; break; case SOUND_MASK_LINE: case SOUND_MASK_LINE3: recdev = 0; break; case SOUND_MASK_CD: case SOUND_MASK_LINE1: recdev = 1; break; case SOUND_MASK_IMIX: recdev = 3; break; default: mask = SOUND_MASK_MIC; recdev = 2; } recdev <<= 6; ad_write(devc, 0, (ad_read(devc, 0) & 0x3f) | recdev); ad_write(devc, 1, (ad_read(devc, 1) & 0x3f) | recdev); /* Rename the mixer bits back if necessary */ for (i = 0; i < 32; i++) if (devc->mixer_reroute[i] != i) if (mask & (1 << devc->mixer_reroute[i])) { mask &= ~(1 << devc->mixer_reroute[i]); mask |= (1 << i); } devc->recmask = mask; return mask; } static void change_bits(ad1848_info * devc, unsigned char *regval, int dev, int chn, int newval) { unsigned char mask; int shift; int mute; int mutemask; int set_mute_bit; set_mute_bit = (newval == 0); if (devc->mix_devices[dev][chn].polarity == 1) /* Reverse */ newval = 100 - newval; mask = (1 << devc->mix_devices[dev][chn].nbits) - 1; shift = devc->mix_devices[dev][chn].bitpos; if (devc->mix_devices[dev][chn].mutepos == 8) { /* if there is no mute bit */ mute = 0; /* No mute bit; do nothing special */ mutemask = ~0; /* No mute bit; do nothing special */ } else { mute = (set_mute_bit << devc->mix_devices[dev][chn].mutepos); mutemask = ~(1 << devc->mix_devices[dev][chn].mutepos); } newval = (int) ((newval * mask) + 50) / 100; /* Scale it */ *regval &= (~(mask << shift)) & (mutemask); /* Clear bits */ *regval |= ((newval & mask) << shift) | mute; /* Set new value */ } static int ad1848_mixer_get(ad1848_info * devc, int dev) { if (!((1 << dev) & devc->supported_devices)) return -EINVAL; dev = devc->mixer_reroute[dev]; return devc->levels[dev]; } static int ad1848_mixer_set(ad1848_info * devc, int dev, int value) { int left = value & 0x000000ff; int right = (value & 0x0000ff00) >> 8; int retvol; int regoffs; unsigned char val; if (dev > 31) return -EINVAL; if (!(devc->supported_devices & (1 << dev))) return -EINVAL; dev = devc->mixer_reroute[dev]; if (left > 100) left = 100; if (right > 100) right = 100; if (devc->mix_devices[dev][RIGHT_CHN].nbits == 0) /* Mono control */ right = left; retvol = left | (right << 8); /* Scale volumes */ left = mix_cvt[left]; right = mix_cvt[right]; /* Scale it again */ left = mix_cvt[left]; right = mix_cvt[right]; if (devc->mix_devices[dev][LEFT_CHN].nbits == 0) return -EINVAL; devc->levels[dev] = retvol; /* * Set the left channel */ regoffs = devc->mix_devices[dev][LEFT_CHN].regno; val = ad_read(devc, regoffs); change_bits(devc, &val, dev, LEFT_CHN, left); ad_write(devc, regoffs, val); devc->saved_regs[regoffs] = val; /* * Set the right channel */ if (devc->mix_devices[dev][RIGHT_CHN].nbits == 0) return retvol; /* Was just a mono channel */ regoffs = devc->mix_devices[dev][RIGHT_CHN].regno; val = ad_read(devc, regoffs); change_bits(devc, &val, dev, RIGHT_CHN, right); ad_write(devc, regoffs, val); devc->saved_regs[regoffs] = val; return retvol; } static void ad1848_mixer_reset(ad1848_info * devc) { int i; char name[32]; devc->mix_devices = &(ad1848_mix_devices[0]); sprintf(name, "%s_%d", devc->chip_name, nr_ad1848_devs); for (i = 0; i < 32; i++) devc->mixer_reroute[i] = i; switch (devc->model) { case MD_4231: case MD_4231A: case MD_1845: devc->supported_devices = MODE2_MIXER_DEVICES; break; case MD_C930: devc->supported_devices = C930_MIXER_DEVICES; devc->mix_devices = &(c930_mix_devices[0]); break; case MD_IWAVE: devc->supported_devices = MODE3_MIXER_DEVICES; devc->mix_devices = &(iwave_mix_devices[0]); break; case MD_4232: devc->supported_devices = MODE3_MIXER_DEVICES; break; default: devc->supported_devices = MODE1_MIXER_DEVICES; } devc->supported_rec_devices = MODE1_REC_DEVICES; devc->orig_devices = devc->supported_devices; devc->orig_rec_devices = devc->supported_rec_devices; devc->levels = load_mixer_volumes(name, default_mixer_levels, 1); for (i = 0; i < SOUND_MIXER_NRDEVICES; i++) if (devc->supported_devices & (1 << i)) ad1848_mixer_set(devc, i, devc->levels[i]); ad1848_set_recmask(devc, SOUND_MASK_MIC); devc->mixer_output_port = devc->levels[31] | AUDIO_HEADPHONE | AUDIO_LINE_OUT; if (devc->mixer_output_port & AUDIO_SPEAKER) ad_write(devc, 26, ad_read(devc, 26) & ~0x40); /* Unmute mono out */ else ad_write(devc, 26, ad_read(devc, 26) | 0x40); /* Mute mono out */ } static int ad1848_mixer_ioctl(int dev, unsigned int cmd, caddr_t arg) { ad1848_info *devc = mixer_devs[dev]->devc; if (cmd == SOUND_MIXER_PRIVATE1) { int val; val = *(int *) arg; if (val == 0xffff) return (*(int *) arg = devc->mixer_output_port); val &= (AUDIO_SPEAKER | AUDIO_HEADPHONE | AUDIO_LINE_OUT); devc->mixer_output_port = val; val |= AUDIO_HEADPHONE | AUDIO_LINE_OUT; /* Always on */ devc->mixer_output_port = val; if (val & AUDIO_SPEAKER) ad_write(devc, 26, ad_read(devc, 26) & ~0x40); /* Unmute mono out */ else ad_write(devc, 26, ad_read(devc, 26) | 0x40); /* Mute mono out */ return (*(int *) arg = devc->mixer_output_port); } if (((cmd >> 8) & 0xff) == 'M') { int val; if (_SIOC_DIR(cmd) & _SIOC_WRITE) switch (cmd & 0xff) { case SOUND_MIXER_RECSRC: val = *(int *) arg; return (*(int *) arg = ad1848_set_recmask(devc, val)); break; default: val = *(int *) arg; return (*(int *) arg = ad1848_mixer_set(devc, cmd & 0xff, val)); } else switch (cmd & 0xff) /* * Return parameters */ { case SOUND_MIXER_RECSRC: return (*(int *) arg = devc->recmask); break; case SOUND_MIXER_DEVMASK: return (*(int *) arg = devc->supported_devices); break; case SOUND_MIXER_STEREODEVS: if (devc->model == MD_C930) return (*(int *) arg = devc->supported_devices); else return (*(int *) arg = devc->supported_devices & ~(SOUND_MASK_SPEAKER | SOUND_MASK_IMIX)); break; case SOUND_MIXER_RECMASK: return (*(int *) arg = devc->supported_rec_devices); break; case SOUND_MIXER_CAPS: return (*(int *) arg = SOUND_CAP_EXCL_INPUT); break; default: return (*(int *) arg = ad1848_mixer_get(devc, cmd & 0xff)); } } else return -EINVAL; } static int ad1848_set_speed(int dev, int arg) { ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; /* * The sampling speed is encoded in the least significant nibble 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; unsigned 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 <= 0) return portc->speed; if (devc->model == MD_1845) /* AD1845 has different timer than others */ { if (arg < 4000) arg = 4000; if (arg > 50000) arg = 50000; portc->speed = arg; portc->speed_bits = speed_table[3].bits; return portc->speed; } 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) { printk("ad1848: Can't find speed???\n"); selected = 3; } portc->speed = speed_table[selected].speed; portc->speed_bits = speed_table[selected].bits; return portc->speed; } static short ad1848_set_channels(int dev, short arg) { ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; if (arg != 1 && arg != 2) return portc->channels; portc->channels = arg; return arg; } static unsigned int ad1848_set_bits(int dev, unsigned int arg) { ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; static struct format_tbl { int format; unsigned char bits; } format2bits[] = { { 0, 0 } , { AFMT_MU_LAW, 1 } , { AFMT_A_LAW, 3 } , { AFMT_IMA_ADPCM, 5 } , { AFMT_U8, 0 } , { AFMT_S16_LE, 2 } , { AFMT_S16_BE, 6 } , { AFMT_S8, 0 } , { AFMT_U16_LE, 0 } , { AFMT_U16_BE, 0 } }; int i, n = sizeof(format2bits) / sizeof(struct format_tbl); if (arg == 0) return portc->audio_format; if (!(arg & ad_format_mask[devc->model])) arg = AFMT_U8; portc->audio_format = arg; for (i = 0; i < n; i++) if (format2bits[i].format == arg) { if ((portc->format_bits = format2bits[i].bits) == 0) return portc->audio_format = AFMT_U8; /* Was not supported */ return arg; } /* Still hanging here. Something must be terribly wrong */ portc->format_bits = 0; return portc->audio_format = AFMT_U8; } static struct audio_driver ad1848_audio_driver = { ad1848_open, ad1848_close, ad1848_output_block, ad1848_start_input, ad1848_ioctl, ad1848_prepare_for_input, ad1848_prepare_for_output, ad1848_halt, NULL, NULL, ad1848_halt_input, ad1848_halt_output, ad1848_trigger, ad1848_set_speed, ad1848_set_bits, ad1848_set_channels }; static struct mixer_operations ad1848_mixer_operations = { "SOUNDPORT", "AD1848/CS4248/CS4231", ad1848_mixer_ioctl }; static int ad1848_open(int dev, int mode) { ad1848_info *devc = NULL; ad1848_port_info *portc; unsigned long flags; if (dev < 0 || dev >= num_audiodevs) return -ENXIO; devc = (ad1848_info *) audio_devs[dev]->devc; portc = (ad1848_port_info *) audio_devs[dev]->portc; save_flags(flags); cli(); if (portc->open_mode || (devc->open_mode & mode)) { restore_flags(flags); return -EBUSY; } devc->dual_dma = 0; if (audio_devs[dev]->flags & DMA_DUPLEX) { devc->dual_dma = 1; } devc->intr_active = 0; devc->audio_mode = 0; devc->open_mode |= mode; portc->open_mode = mode; ad1848_trigger(dev, 0); if (mode & OPEN_READ) devc->record_dev = dev; if (mode & OPEN_WRITE) devc->playback_dev = dev; restore_flags(flags); /* * Mute output until the playback really starts. This decreases clicking (hope so). */ ad_mute(devc); return 0; } static void ad1848_close(int dev) { unsigned long flags; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; DEB(printk("ad1848_close(void)\n")); save_flags(flags); cli(); devc->intr_active = 0; ad1848_halt(dev); devc->audio_mode = 0; devc->open_mode &= ~portc->open_mode; portc->open_mode = 0; ad_unmute(devc); restore_flags(flags); } static int ad1848_ioctl(int dev, unsigned int cmd, caddr_t arg) { return -EINVAL; } static void ad1848_output_block(int dev, unsigned long buf, int count, int intrflag) { unsigned long flags, cnt; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; cnt = count; if (portc->audio_format == AFMT_IMA_ADPCM) { cnt /= 4; } else { if (portc->audio_format & (AFMT_S16_LE | AFMT_S16_BE)) /* 16 bit data */ cnt >>= 1; } if (portc->channels > 1) cnt >>= 1; cnt--; if (devc->audio_mode & PCM_ENABLE_OUTPUT && audio_devs[dev]->flags & DMA_AUTOMODE && intrflag && cnt == devc->xfer_count) { devc->audio_mode |= PCM_ENABLE_OUTPUT; devc->intr_active = 1; return; /* * Auto DMA mode on. No need to react */ } save_flags(flags); cli(); ad_write(devc, 15, (unsigned char) (cnt & 0xff)); ad_write(devc, 14, (unsigned char) ((cnt >> 8) & 0xff)); devc->xfer_count = cnt; devc->audio_mode |= PCM_ENABLE_OUTPUT; devc->intr_active = 1; restore_flags(flags); } static void ad1848_start_input(int dev, unsigned long buf, int count, int intrflag) { unsigned long flags, cnt; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; cnt = count; if (portc->audio_format == AFMT_IMA_ADPCM) { cnt /= 4; } else { if (portc->audio_format & (AFMT_S16_LE | AFMT_S16_BE)) /* 16 bit data */ cnt >>= 1; } if (portc->channels > 1) cnt >>= 1; cnt--; if (devc->audio_mode & PCM_ENABLE_INPUT && audio_devs[dev]->flags & DMA_AUTOMODE && intrflag && cnt == devc->xfer_count) { devc->audio_mode |= PCM_ENABLE_INPUT; devc->intr_active = 1; return; /* * Auto DMA mode on. No need to react */ } save_flags(flags); cli(); if (devc->model == MD_1848) { ad_write(devc, 15, (unsigned char) (cnt & 0xff)); ad_write(devc, 14, (unsigned char) ((cnt >> 8) & 0xff)); } else { ad_write(devc, 31, (unsigned char) (cnt & 0xff)); ad_write(devc, 30, (unsigned char) ((cnt >> 8) & 0xff)); } ad_unmute(devc); devc->xfer_count = cnt; devc->audio_mode |= PCM_ENABLE_INPUT; devc->intr_active = 1; restore_flags(flags); } static int ad1848_prepare_for_output(int dev, int bsize, int bcount) { int timeout; unsigned char fs, old_fs, tmp = 0; unsigned long flags; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; ad_mute(devc); save_flags(flags); cli(); fs = portc->speed_bits | (portc->format_bits << 5); if (portc->channels > 1) fs |= 0x10; ad_enter_MCE(devc); /* Enables changes to the format select reg */ if (devc->model == MD_1845) /* Use alternate speed select registers */ { fs &= 0xf0; /* Mask off the rate select bits */ ad_write(devc, 22, (portc->speed >> 8) & 0xff); /* Speed MSB */ ad_write(devc, 23, portc->speed & 0xff); /* Speed LSB */ } old_fs = ad_read(devc, 8); if (devc->model == MD_4232) { tmp = ad_read(devc, 16); ad_write(devc, 16, tmp | 0x30); } if (devc->model == MD_IWAVE) ad_write(devc, 17, 0xc2); /* Disable variable frequency select */ ad_write(devc, 8, fs); /* * Write to I8 starts resynchronization. Wait until it completes. */ timeout = 0; while (timeout < 100 && inb(devc->base) != 0x80) timeout++; timeout = 0; while (timeout < 10000 && inb(devc->base) == 0x80) timeout++; if (devc->model == MD_4232) ad_write(devc, 16, tmp & ~0x30); ad_leave_MCE(devc); /* * Starts the calibration process. */ restore_flags(flags); devc->xfer_count = 0; #if (defined(CONFIG_SEQUENCER) && !defined(EXCLUDE_TIMERS)) || defined(MODULE) if (dev == timer_installed && devc->timer_running) if ((fs & 0x01) != (old_fs & 0x01)) { ad1848_tmr_reprogram(dev); } #endif ad1848_halt_output(dev); return 0; } static int ad1848_prepare_for_input(int dev, int bsize, int bcount) { int timeout; unsigned char fs, old_fs, tmp = 0; unsigned long flags; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; if (devc->audio_mode) return 0; save_flags(flags); cli(); fs = portc->speed_bits | (portc->format_bits << 5); if (portc->channels > 1) fs |= 0x10; ad_enter_MCE(devc); /* Enables changes to the format select reg */ if (devc->model == MD_1845) /* Use alternate speed select registers */ { fs &= 0xf0; /* Mask off the rate select bits */ ad_write(devc, 22, (portc->speed >> 8) & 0xff); /* Speed MSB */ ad_write(devc, 23, portc->speed & 0xff); /* Speed LSB */ } if (devc->model == MD_4232) { tmp = ad_read(devc, 16); ad_write(devc, 16, tmp | 0x30); } if (devc->model == MD_IWAVE) ad_write(devc, 17, 0xc2); /* Disable variable frequency select */ /* * If mode >= 2 (CS4231), set I28. It's the capture format register. */ if (devc->model != MD_1848) { old_fs = ad_read(devc, 28); ad_write(devc, 28, fs); /* * Write to I28 starts resynchronization. Wait until it completes. */ timeout = 0; while (timeout < 100 && inb(devc->base) != 0x80) timeout++; timeout = 0; while (timeout < 10000 && inb(devc->base) == 0x80) timeout++; if (devc->model != MD_1848 && devc->model != MD_1845) { /* * CS4231 compatible devices don't have separate sampling rate selection * register for recording an playback. The I8 register is shared so we have to * set the speed encoding bits of it too. */ unsigned char tmp = portc->speed_bits | (ad_read(devc, 8) & 0xf0); ad_write(devc, 8, tmp); /* * Write to I8 starts resynchronization. Wait until it completes. */ timeout = 0; while (timeout < 100 && inb(devc->base) != 0x80) timeout++; timeout = 0; while (timeout < 10000 && inb(devc->base) == 0x80) timeout++; } } else { /* For AD1848 set I8. */ old_fs = ad_read(devc, 8); ad_write(devc, 8, fs); /* * Write to I8 starts resynchronization. Wait until it completes. */ timeout = 0; while (timeout < 100 && inb(devc->base) != 0x80) timeout++; timeout = 0; while (timeout < 10000 && inb(devc->base) == 0x80) timeout++; } if (devc->model == MD_4232) ad_write(devc, 16, tmp & ~0x30); ad_leave_MCE(devc); /* * Starts the calibration process. */ restore_flags(flags); devc->xfer_count = 0; #if defined(CONFIG_SEQUENCER) && !defined(EXCLUDE_TIMERS) if (dev == timer_installed && devc->timer_running) if ((fs & 0x01) != (old_fs & 0x01)) { ad1848_tmr_reprogram(dev); } #endif ad1848_halt_input(dev); return 0; } static void ad1848_halt(int dev) { ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; unsigned char bits = ad_read(devc, 9); if (bits & 0x01 && portc->open_mode & OPEN_WRITE) ad1848_halt_output(dev); if (bits & 0x02 && portc->open_mode & OPEN_READ) ad1848_halt_input(dev); devc->audio_mode = 0; } static void ad1848_halt_input(int dev) { ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; unsigned long flags; if (!(ad_read(devc, 9) & 0x02)) return; /* Capture not enabled */ save_flags(flags); cli(); ad_mute(devc); { int tmout; disable_dma(audio_devs[dev]->dmap_in->dma); for (tmout = 0; tmout < 100000; tmout++) if (ad_read(devc, 11) & 0x10) break; ad_write(devc, 9, ad_read(devc, 9) & ~0x02); /* Stop capture */ enable_dma(audio_devs[dev]->dmap_in->dma); devc->audio_mode &= ~PCM_ENABLE_INPUT; } outb((0), io_Status(devc)); /* Clear interrupt status */ outb((0), io_Status(devc)); /* Clear interrupt status */ devc->audio_mode &= ~PCM_ENABLE_INPUT; restore_flags(flags); } static void ad1848_halt_output(int dev) { ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; unsigned long flags; if (!(ad_read(devc, 9) & 0x01)) return; /* Playback not enabled */ save_flags(flags); cli(); ad_mute(devc); { int tmout; disable_dma(audio_devs[dev]->dmap_out->dma); for (tmout = 0; tmout < 100000; tmout++) if (ad_read(devc, 11) & 0x10) break; ad_write(devc, 9, ad_read(devc, 9) & ~0x01); /* Stop playback */ enable_dma(audio_devs[dev]->dmap_out->dma); devc->audio_mode &= ~PCM_ENABLE_OUTPUT; } outb((0), io_Status(devc)); /* Clear interrupt status */ outb((0), io_Status(devc)); /* Clear interrupt status */ devc->audio_mode &= ~PCM_ENABLE_OUTPUT; restore_flags(flags); } static void ad1848_trigger(int dev, int state) { ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; ad1848_port_info *portc = (ad1848_port_info *) audio_devs[dev]->portc; unsigned long flags; unsigned char tmp, old; save_flags(flags); cli(); state &= devc->audio_mode; tmp = old = ad_read(devc, 9); if (portc->open_mode & OPEN_READ) { if (state & PCM_ENABLE_INPUT) tmp |= 0x02; else tmp &= ~0x02; } if (portc->open_mode & OPEN_WRITE) { if (state & PCM_ENABLE_OUTPUT) tmp |= 0x01; else tmp &= ~0x01; } /* ad_mute(devc); */ if (tmp != old) { ad_write(devc, 9, tmp); ad_unmute(devc); } restore_flags(flags); } static void ad1848_init_hw(ad1848_info * devc) { int i; /* * Initial values for the indirect registers of CS4248/AD1848. */ static int init_values[] = { 0xa8, 0xa8, 0x08, 0x08, 0x08, 0x08, 0x00, 0x00, 0x00, 0x0c, 0x02, 0x00, 0x8a, 0x01, 0x00, 0x00, /* Positions 16 to 31 just for CS4231/2 and ad1845 */ 0x80, 0x00, 0x10, 0x10, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; for (i = 0; i < 16; i++) ad_write(devc, i, init_values[i]); ad_mute(devc); /* Initialize some variables */ ad_unmute(devc); /* Leave it unmuted now */ if (devc->model > MD_1848) { ad_write(devc, 12, ad_read(devc, 12) | 0x40); /* Mode2 = enabled */ if (devc->model == MD_IWAVE) ad_write(devc, 12, 0x6c); /* Select codec mode 3 */ for (i = 16; i < 32; i++) ad_write(devc, i, init_values[i]); if (devc->model == MD_IWAVE) ad_write(devc, 16, 0x30); /* Playback and capture counters enabled */ } if (devc->model > MD_1848) { if (devc->audio_flags & DMA_DUPLEX) ad_write(devc, 9, ad_read(devc, 9) & ~0x04); /* Dual DMA mode */ else ad_write(devc, 9, ad_read(devc, 9) | 0x04); /* Single DMA mode */ if (devc->model == MD_1845) ad_write(devc, 27, ad_read(devc, 27) | 0x08); /* Alternate freq select enabled */ if (devc->model == MD_IWAVE) { /* Some magic Interwave specific initialization */ ad_write(devc, 12, 0x6c); /* Select codec mode 3 */ ad_write(devc, 16, 0x30); /* Playback and capture counters enabled */ ad_write(devc, 17, 0xc2); /* Alternate feature enable */ } } else { devc->audio_flags &= ~DMA_DUPLEX; ad_write(devc, 9, ad_read(devc, 9) | 0x04); /* Single DMA mode */ } outb((0), io_Status(devc)); /* Clear pending interrupts */ /* * Toggle the MCE bit. It completes the initialization phase. */ ad_enter_MCE(devc); /* In case the bit was off */ ad_leave_MCE(devc); ad1848_mixer_reset(devc); } int ad1848_detect(int io_base, int *ad_flags, int *osp) { unsigned char tmp; ad1848_info *devc = &adev_info[nr_ad1848_devs]; unsigned char tmp1 = 0xff, tmp2 = 0xff; int optiC930 = 0; /* OPTi 82C930 flag */ int interwave = 0; int ad1847_flag = 0; int cs4248_flag = 0; int i; DDB(printk("ad1848_detect(%x)\n", io_base)); if (ad_flags) { if (*ad_flags == 0x12345678) { interwave = 1; *ad_flags = 0; } if (*ad_flags == 0x12345677) { cs4248_flag = 1; *ad_flags = 0; } } if (nr_ad1848_devs >= MAX_AUDIO_DEV) { printk("ad1848 - Too many audio devices\n"); return 0; } if (check_region(io_base, 4)) { printk("ad1848.c: Port %x not free.\n", io_base); return 0; } devc->base = io_base; devc->irq_ok = 0; devc->timer_running = 0; devc->MCE_bit = 0x40; devc->irq = 0; devc->open_mode = 0; devc->chip_name = devc->name = "AD1848"; devc->model = MD_1848; /* AD1848 or CS4248 */ devc->levels = NULL; devc->c930_password_port = 0; devc->debug_flag = 0; /* * Check that the I/O address is in use. * * The bit 0x80 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. */ if (inb(devc->base) == 0xff) { DDB(printk("ad1848_detect: The base I/O address appears to be dead\n")); } /* * Wait for the device to stop initialization */ DDB(printk("ad1848_detect() - step 0\n")); for (i = 0; i < 10000000; i++) { unsigned char x = inb(devc->base); if (x == 0xff || !(x & 0x80)) break; } DDB(printk("ad1848_detect() - step A\n")); if (inb(devc->base) == 0x80) /* Not ready. Let's wait */ ad_leave_MCE(devc); if ((inb(devc->base) & 0x80) != 0x00) /* Not a AD1848 */ { DDB(printk("ad1848 detect error - step A (%02x)\n", (int) inb(devc->base))); 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. */ DDB(printk("ad1848_detect() - step B\n")); ad_write(devc, 0, 0xaa); ad_write(devc, 1, 0x45); /* 0x55 with bit 0x10 clear */ if ((tmp1 = ad_read(devc, 0)) != 0xaa || (tmp2 = ad_read(devc, 1)) != 0x45) if (tmp2 == 0x65) /* AD1847 has couple of bits hardcoded to 1 */ ad1847_flag = 1; else { DDB(printk("ad1848 detect error - step B (%x/%x)\n", tmp1, tmp2)); return 0; } DDB(printk("ad1848_detect() - step C\n")); ad_write(devc, 0, 0x45); ad_write(devc, 1, 0xaa); if ((tmp1 = ad_read(devc, 0)) != 0x45 || (tmp2 = ad_read(devc, 1)) != 0xaa) if (tmp2 == 0x8a) /* AD1847 has few bits hardcoded to 1 */ ad1847_flag = 1; else { DDB(printk("ad1848 detect error - step C (%x/%x)\n", tmp1, tmp2)); return 0; } /* * The indirect register I12 has some read only bits. Lets * try to change them. */ DDB(printk("ad1848_detect() - step D\n")); tmp = ad_read(devc, 12); ad_write(devc, 12, (~tmp) & 0x0f); if ((tmp & 0x0f) != ((tmp1 = ad_read(devc, 12)) & 0x0f)) { DDB(printk("ad1848 detect error - step D (%x)\n", tmp1)); return 0; } /* * NOTE! Last 4 bits of the reg I12 tell the chip revision. * 0x01=RevB and 0x0A=RevC. */ /* * The original AD1848/CS4248 has just 15 indirect registers. This means * that I0 and I16 should return the same value (etc.). * However this doesn't work with CS4248. Actually it seems to be impossible * to detect if the chip is a CS4231 or CS4248. * Ensure that the Mode2 enable bit of I12 is 0. Otherwise this test fails * with CS4231. */ /* * OPTi 82C930 has mode2 control bit in another place. This test will fail * with it. Accept this situation as a possible indication of this chip. */ DDB(printk("ad1848_detect() - step F\n")); ad_write(devc, 12, 0); /* Mode2=disabled */ for (i = 0; i < 16; i++) if ((tmp1 = ad_read(devc, i)) != (tmp2 = ad_read(devc, i + 16))) { DDB(printk("ad1848 detect step F(%d/%x/%x) - OPTi chip???\n", i, tmp1, tmp2)); if (!ad1847_flag) optiC930 = 1; break; } /* * Try to switch the chip to mode2 (CS4231) by setting the MODE2 bit (0x40). * The bit 0x80 is always 1 in CS4248 and CS4231. */ DDB(printk("ad1848_detect() - step G\n")); if (ad_flags && *ad_flags == 400) *ad_flags = 0; else ad_write(devc, 12, 0x40); /* Set mode2, clear 0x80 */ if (ad_flags) *ad_flags = 0; tmp1 = ad_read(devc, 12); if (tmp1 & 0x80) { if (ad_flags) *ad_flags |= AD_F_CS4248; devc->chip_name = "CS4248"; /* Our best knowledge just now */ } if (optiC930 || (tmp1 & 0xc0) == (0x80 | 0x40)) { /* * CS4231 detected - is it? * * Verify that setting I0 doesn't change I16. */ DDB(printk("ad1848_detect() - step H\n")); ad_write(devc, 16, 0); /* Set I16 to known value */ ad_write(devc, 0, 0x45); if ((tmp1 = ad_read(devc, 16)) != 0x45) /* No change -> CS4231? */ { ad_write(devc, 0, 0xaa); if ((tmp1 = ad_read(devc, 16)) == 0xaa) /* Rotten bits? */ { DDB(printk("ad1848 detect error - step H(%x)\n", tmp1)); return 0; } /* * Verify that some bits of I25 are read only. */ DDB(printk("ad1848_detect() - step I\n")); tmp1 = ad_read(devc, 25); /* Original bits */ ad_write(devc, 25, ~tmp1); /* Invert all bits */ if ((ad_read(devc, 25) & 0xe7) == (tmp1 & 0xe7)) { int id, full_id; /* * It's at least CS4231 */ devc->chip_name = "CS4231"; devc->model = MD_4231; /* * 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(devc, 25) & 0xe7; full_id = ad_read(devc, 25); if (id == 0x80) /* Device busy??? */ id = ad_read(devc, 25) & 0xe7; if (id == 0x80) /* Device still busy??? */ id = ad_read(devc, 25) & 0xe7; DDB(printk("ad1848_detect() - step J (%02x/%02x)\n", id, ad_read(devc, 25))); switch (id) { case 0xa0: devc->chip_name = "CS4231A"; devc->model = MD_4231A; break; case 0xa2: devc->chip_name = "CS4232"; devc->model = MD_4232; break; case 0xb2: devc->chip_name = "CS4232A"; devc->model = MD_4232; break; case 0x03: case 0x83: devc->chip_name = "CS4236"; devc->model = MD_4232; break; case 0x41: devc->chip_name = "CS4236B"; devc->model = MD_4232; 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. */ unsigned char tmp = ad_read(devc, 23); ad_write(devc, 23, ~tmp); if (interwave) { devc->model = MD_IWAVE; devc->chip_name = "IWave"; } else if (ad_read(devc, 23) != tmp) /* AD1845 ? */ { devc->chip_name = "AD1845"; devc->model = MD_1845; } else if (cs4248_flag) { if (ad_flags) *ad_flags |= AD_F_CS4248; devc->chip_name = "CS4248"; devc->model = MD_1848; ad_write(devc, 12, ad_read(devc, 12) & ~0x40); /* Mode2 off */ } ad_write(devc, 23, tmp); /* Restore */ } break; default: /* Assume CS4231 or OPTi 82C930 */ DDB(printk("ad1848: I25 = %02x/%02x\n", ad_read(devc, 25), ad_read(devc, 25) & 0xe7)); if (optiC930) { devc->chip_name = "82C930"; devc->model = MD_C930; } else { devc->model = MD_4231; } } } ad_write(devc, 25, tmp1); /* Restore bits */ DDB(printk("ad1848_detect() - step K\n")); } } DDB(printk("ad1848_detect() - step L\n")); if (ad_flags) { if (devc->model != MD_1848) *ad_flags |= AD_F_CS4231; } DDB(printk("ad1848_detect() - Detected OK\n")); if (devc->model == MD_1848 && ad1847_flag) devc->chip_name = "AD1847"; return 1; } int ad1848_init(char *name, int io_base, int irq, int dma_playback, int dma_capture, int share_dma, int *osp) { /* * NOTE! If irq < 0, there is another driver which has allocated the IRQ * so that this driver doesn't need to allocate/deallocate it. * The actually used IRQ is ABS(irq). */ int my_dev; char dev_name[100]; int e; ad1848_info *devc = &adev_info[nr_ad1848_devs]; ad1848_port_info *portc = NULL; devc->irq = (irq > 0) ? irq : 0; devc->open_mode = 0; devc->timer_ticks = 0; devc->dma1 = dma_playback; devc->dma2 = dma_capture; devc->audio_flags = DMA_AUTOMODE; devc->playback_dev = devc->record_dev = 0; if (name != NULL) devc->name = name; if (name != NULL && name[0] != 0) sprintf(dev_name, "%s (%s)", name, devc->chip_name); else sprintf(dev_name, "Generic audio codec (%s)", devc->chip_name); request_region(devc->base, 4, devc->name); conf_printf2(dev_name, devc->base, devc->irq, dma_playback, dma_capture); if (devc->model == MD_1848 || devc->model == MD_C930) devc->audio_flags |= DMA_HARDSTOP; if (devc->model > MD_1848) { if (devc->dma1 == devc->dma2 || devc->dma2 == -1 || devc->dma1 == -1) devc->audio_flags &= ~DMA_DUPLEX; else devc->audio_flags |= DMA_DUPLEX; } if ((my_dev = sound_install_audiodrv(AUDIO_DRIVER_VERSION, dev_name, &ad1848_audio_driver, sizeof(struct audio_driver), devc->audio_flags, ad_format_mask[devc->model], devc, dma_playback, dma_capture)) < 0) { return -1; } portc = (ad1848_port_info *) (sound_mem_blocks[sound_nblocks] = vmalloc(sizeof(ad1848_port_info))); sound_mem_sizes[sound_nblocks] = sizeof(ad1848_port_info); if (sound_nblocks < 1024) sound_nblocks++;; audio_devs[my_dev]->portc = portc; memset((char *) portc, 0, sizeof(*portc)); nr_ad1848_devs++; ad1848_init_hw(devc); if (irq > 0) { irq2dev[irq] = devc->dev_no = my_dev; if (snd_set_irq_handler(devc->irq, adintr, devc->name, NULL) < 0) { printk(KERN_WARNING "ad1848: IRQ in use\n"); } if (devc->model != MD_1848 && devc->model != MD_C930) { int x; unsigned char tmp = ad_read(devc, 16); devc->timer_ticks = 0; ad_write(devc, 21, 0x00); /* Timer MSB */ ad_write(devc, 20, 0x10); /* Timer LSB */ ad_write(devc, 16, tmp | 0x40); /* Enable timer */ for (x = 0; x < 100000 && devc->timer_ticks == 0; x++); ad_write(devc, 16, tmp & ~0x40); /* Disable timer */ if (devc->timer_ticks == 0) printk(KERN_WARNING "ad1848: Interrupt test failed (IRQ%d)\n", devc->irq); else { DDB(printk("Interrupt test OK\n")); devc->irq_ok = 1; } } else devc->irq_ok = 1; /* Couldn't test. assume it's OK */ } else if (irq < 0) irq2dev[-irq] = devc->dev_no = my_dev; #if (defined(CONFIG_SEQUENCER) && !defined(EXCLUDE_TIMERS)) || defined(MODULE) if (devc->model != MD_1848 && devc->model != MD_C930 && devc->irq_ok) ad1848_tmr_install(my_dev); #endif if (!share_dma) { if (sound_alloc_dma(dma_playback, devc->name)) printk("ad1848.c: Can't allocate DMA%d\n", dma_playback); if (dma_capture != dma_playback) if (sound_alloc_dma(dma_capture, devc->name)) printk("ad1848.c: Can't allocate DMA%d\n", dma_capture); } if ((e = sound_install_mixer(MIXER_DRIVER_VERSION, dev_name, &ad1848_mixer_operations, sizeof(struct mixer_operations), devc)) >= 0) { audio_devs[my_dev]->mixer_dev = e; } MOD_INC_USE_COUNT; return my_dev; } void ad1848_control(int cmd, int arg) { ad1848_info *devc; if (nr_ad1848_devs < 1) return; devc = &adev_info[nr_ad1848_devs - 1]; switch (cmd) { case AD1848_SET_XTAL: /* Change clock frequency of AD1845 (only ) */ if (devc->model != MD_1845) return; ad_enter_MCE(devc); ad_write(devc, 29, (ad_read(devc, 29) & 0x1f) | (arg << 5)); ad_leave_MCE(devc); break; case AD1848_MIXER_REROUTE: { int o = (arg >> 8) & 0xff; int n = arg & 0xff; if (n == SOUND_MIXER_NONE) { /* Just hide this control */ ad1848_mixer_set(devc, o, 0); /* Shut up it */ devc->supported_devices &= ~(1 << o); devc->supported_rec_devices &= ~(1 << o); return; } /* Make the mixer control identified by o to appear as n */ if (o < 0 || o > SOUND_MIXER_NRDEVICES) return; if (n < 0 || n > SOUND_MIXER_NRDEVICES) return; if (!(devc->supported_devices & (1 << o))) return; /* Not supported */ devc->mixer_reroute[n] = o; /* Rename the control */ devc->supported_devices &= ~(1 << o); devc->supported_devices |= (1 << n); if (devc->supported_rec_devices & (1 << o)) devc->supported_rec_devices |= (1 << n); devc->supported_rec_devices &= ~(1 << o); } break; } return; } void ad1848_unload(int io_base, int irq, int dma_playback, int dma_capture, int share_dma) { int i, dev = 0; ad1848_info *devc = NULL; for (i = 0; devc == NULL && i < nr_ad1848_devs; i++) if (adev_info[i].base == io_base) { devc = &adev_info[i]; dev = devc->dev_no; } if (devc != NULL) { release_region(devc->base, 4); if (!share_dma) { if (irq > 0) snd_release_irq(devc->irq); sound_free_dma(audio_devs[dev]->dmap_out->dma); if (audio_devs[dev]->dmap_in->dma != audio_devs[dev]->dmap_out->dma) sound_free_dma(audio_devs[dev]->dmap_in->dma); } } else printk("ad1848: Can't find device to be unloaded. Base=%x\n", io_base); MOD_DEC_USE_COUNT; } void adintr(int irq, void *dev_id, struct pt_regs *dummy) { unsigned char status; ad1848_info *devc; int dev; int alt_stat = 0xff; unsigned char c930_stat = 0; int cnt = 0; if (irq < 0 || irq > 15) { dev = -1; } else dev = irq2dev[irq]; if (dev < 0 || dev >= num_audiodevs) { for (irq = 0; irq < 17; irq++) if (irq2dev[irq] != -1) break; if (irq > 15) { /* printk("ad1848.c: Bogus interrupt %d\n", irq); */ return; } dev = irq2dev[irq]; devc = (ad1848_info *) audio_devs[dev]->devc; } else devc = (ad1848_info *) audio_devs[dev]->devc; interrupt_again: /* Jump back here if int status doesn't reset */ status = inb(io_Status(devc)); if (status == 0x80) printk("adintr: Why?\n"); if (devc->model == MD_1848) outb((0), io_Status(devc)); /* Clear interrupt status */ if (status & 0x01) { if (devc->model == MD_C930) { /* 82C930 has interrupt status register in MAD16 register MC11 */ unsigned long flags; save_flags(flags); cli(); alt_stat = 0; if (devc->c930_password_port) outb((0xe4), devc->c930_password_port); /* Password */ outb((11), 0xe0e); c930_stat = inb(0xe0f); if (c930_stat & 0x04) alt_stat |= 0x10; /* Playback intr */ if (c930_stat & 0x08) alt_stat |= 0x20; /* Playback intr */ restore_flags(flags); } else if (devc->model != MD_1848) alt_stat = ad_read(devc, 24); /* Acknowledge the intr before proceeding */ if (devc->model == MD_C930) { /* 82C930 has interrupt status register in MAD16 register MC11 */ unsigned long flags; save_flags(flags); cli(); if (devc->c930_password_port) outb((0xe4), devc->c930_password_port); /* Password */ outb((11), 0xe0e); outb((~c930_stat), 0xe0f); restore_flags(flags); } else if (devc->model != MD_1848) ad_write(devc, 24, ad_read(devc, 24) & ~alt_stat); /* Selective ack */ if (devc->open_mode & OPEN_READ && devc->audio_mode & PCM_ENABLE_INPUT && alt_stat & 0x20) { DMAbuf_inputintr(devc->record_dev); } if (devc->open_mode & OPEN_WRITE && devc->audio_mode & PCM_ENABLE_OUTPUT && alt_stat & 0x10) { DMAbuf_outputintr(devc->playback_dev, 1); } if (devc->model != MD_1848 && alt_stat & 0x40) /* Timer interrupt */ { devc->timer_ticks++; #if (defined(CONFIG_SEQUENCER) && !defined(EXCLUDE_TIMERS)) || defined(MODULE) if (timer_installed == dev && devc->timer_running) sound_timer_interrupt(); #endif } } /* * Sometimes playback or capture interrupts occur while a timer interrupt * is being handled. The interrupt will not be retriggered if we don't * handle it now. Check if an interrupt is still pending and restart * the handler in this case. */ if (inb(io_Status(devc)) & 0x01 && cnt++ < 4) { goto interrupt_again; } } #ifdef DESKPROXL /* * Very experimental initialization sequence for the integrated sound system * of Compaq Deskpro XL. Will be moved somewhere else in future. */ static int init_deskpro(struct address_info *hw_config) { unsigned char tmp; if ((tmp = inb(0xc44)) == 0xff) { DDB(printk("init_deskpro: Dead port 0xc44\n")); return 0; } outb((tmp | 0x04), 0xc44); /* Select bank 1 */ if (inb(0xc44) != 0x04) { DDB(printk("init_deskpro: Invalid bank1 signature in port 0xc44\n")); return 0; } /* * OK. It looks like a Deskpro so let's proceed. */ /* * I/O port 0xc44 Audio configuration register. * * bits 0xc0: Audio revision bits * 0x00 = Compaq Business Audio * 0x40 = MS Sound System Compatible (reset default) * 0x80 = Reserved * 0xc0 = Reserved * bit 0x20: No Wait State Enable * 0x00 = Disabled (reset default, DMA mode) * 0x20 = Enabled (programmed I/O mode) * bit 0x10: MS Sound System Decode Enable * 0x00 = Decoding disabled (reset default) * 0x10 = Decoding enabled * bit 0x08: FM Synthesis Decode Enable * 0x00 = Decoding Disabled (reset default) * 0x08 = Decoding enabled * bit 0x04 Bank select * 0x00 = Bank 0 * 0x04 = Bank 1 * bits 0x03 MSS Base address * 0x00 = 0x530 (reset default) * 0x01 = 0x604 * 0x02 = 0xf40 * 0x03 = 0xe80 */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc44 (before): "); outb((tmp & ~0x04), 0xc44); printk("%02x ", inb(0xc44)); outb((tmp | 0x04), 0xc44); printk("%02x\n", inb(0xc44)); #endif /* Set bank 1 of the register */ tmp = 0x58; /* MSS Mode, MSS&FM decode enabled */ switch (hw_config->io_base) { case 0x530: tmp |= 0x00; break; case 0x604: tmp |= 0x01; break; case 0xf40: tmp |= 0x02; break; case 0xe80: tmp |= 0x03; break; default: DDB(printk("init_deskpro: Invalid MSS port %x\n", hw_config->io_base)); return 0; } outb((tmp & ~0x04), 0xc44); /* Write to bank=0 */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc44 (after): "); outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ printk("%02x ", inb(0xc44)); outb((tmp | 0x04), 0xc44); /* Select bank=1 */ printk("%02x\n", inb(0xc44)); #endif /* * I/O port 0xc45 FM Address Decode/MSS ID Register. * * bank=0, bits 0xfe: FM synthesis Decode Compare bits 7:1 (default=0x88) * bank=0, bit 0x01: SBIC Power Control Bit * 0x00 = Powered up * 0x01 = Powered down * bank=1, bits 0xfc: MSS ID (default=0x40) */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc45 (before): "); outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ printk("%02x ", inb(0xc45)); outb((tmp | 0x04), 0xc44); /* Select bank=1 */ printk("%02x\n", inb(0xc45)); #endif outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ outb((0x88), 0xc45); /* FM base 7:0 = 0x88 */ outb((tmp | 0x04), 0xc44); /* Select bank=1 */ outb((0x10), 0xc45); /* MSS ID = 0x10 (MSS port returns 0x04) */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc45 (after): "); outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ printk("%02x ", inb(0xc45)); outb((tmp | 0x04), 0xc44); /* Select bank=1 */ printk("%02x\n", inb(0xc45)); #endif /* * I/O port 0xc46 FM Address Decode/Address ASIC Revision Register. * * bank=0, bits 0xff: FM synthesis Decode Compare bits 15:8 (default=0x03) * bank=1, bits 0xff: Audio addressing ASIC id */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc46 (before): "); outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ printk("%02x ", inb(0xc46)); outb((tmp | 0x04), 0xc44); /* Select bank=1 */ printk("%02x\n", inb(0xc46)); #endif outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ outb((0x03), 0xc46); /* FM base 15:8 = 0x03 */ outb((tmp | 0x04), 0xc44); /* Select bank=1 */ outb((0x11), 0xc46); /* ASIC ID = 0x11 */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc46 (after): "); outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ printk("%02x ", inb(0xc46)); outb((tmp | 0x04), 0xc44); /* Select bank=1 */ printk("%02x\n", inb(0xc46)); #endif /* * I/O port 0xc47 FM Address Decode Register. * * bank=0, bits 0xff: Decode enable selection for various FM address bits * bank=1, bits 0xff: Reserved */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc47 (before): "); outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ printk("%02x ", inb(0xc47)); outb((tmp | 0x04), 0xc44); /* Select bank=1 */ printk("%02x\n", inb(0xc47)); #endif outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ outb((0x7c), 0xc47); /* FM decode enable bits = 0x7c */ outb((tmp | 0x04), 0xc44); /* Select bank=1 */ outb((0x00), 0xc47); /* Reserved bank1 = 0x00 */ #ifdef DEBUGXL /* Debug printing */ printk("Port 0xc47 (after): "); outb((tmp & ~0x04), 0xc44); /* Select bank=0 */ printk("%02x ", inb(0xc47)); outb((tmp | 0x04), 0xc44); /* Select bank=1 */ printk("%02x\n", inb(0xc47)); #endif /* * I/O port 0xc6f = Audio Disable Function Register */ #ifdef DEBUGXL printk("Port 0xc6f (before) = %02x\n", inb(0xc6f)); #endif outb((0x80), 0xc6f); #ifdef DEBUGXL printk("Port 0xc6f (after) = %02x\n", inb(0xc6f)); #endif return 1; } #endif int probe_ms_sound(struct address_info *hw_config) { unsigned char tmp; DDB(printk("Entered probe_ms_sound(%x, %d)\n", hw_config->io_base, hw_config->card_subtype)); if (check_region(hw_config->io_base, 8)) { printk("MSS: I/O port conflict\n"); return 0; } if (hw_config->card_subtype == 1) /* Has no IRQ/DMA registers */ { /* check_opl3(0x388, hw_config); */ return ad1848_detect(hw_config->io_base + 4, NULL, hw_config->osp); } #ifdef DESKPROXL if (hw_config->card_subtype == 2) /* Compaq Deskpro XL */ { if (!init_deskpro(hw_config)) return 0; } #endif /* * 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. */ if ((tmp = inb(hw_config->io_base + 3)) == 0xff) /* Bus float */ { int ret; DDB(printk("I/O address is inactive (%x)\n", tmp)); if (!(ret = ad1848_detect(hw_config->io_base + 4, NULL, hw_config->osp))) return 0; return 1; } DDB(printk("MSS signature = %x\n", tmp & 0x3f)); if ((tmp & 0x3f) != 0x04 && (tmp & 0x3f) != 0x0f && (tmp & 0x3f) != 0x00) { int ret; MDB(printk("No MSS signature detected on port 0x%x (0x%x)\n", hw_config->io_base, (int) inb(hw_config->io_base + 3))); DDB(printk("Trying to detect codec anyway but IRQ/DMA may not work\n")); if (!(ret = ad1848_detect(hw_config->io_base + 4, NULL, hw_config->osp))) return 0; hw_config->card_subtype = 1; return 1; } if (hw_config->irq > 11) { printk("MSS: Bad IRQ %d\n", hw_config->irq); return 0; } if (hw_config->dma != 0 && hw_config->dma != 1 && hw_config->dma != 3) { printk("MSS: Bad DMA %d\n", hw_config->dma); return 0; } /* * Check that DMA0 is not in use with a 8 bit board. */ if (hw_config->dma == 0 && inb(hw_config->io_base + 3) & 0x80) { printk("MSS: Can't use DMA0 with a 8 bit card/slot\n"); return 0; } if (hw_config->irq > 7 && hw_config->irq != 9 && inb(hw_config->io_base + 3) & 0x80) { printk("MSS: Can't use IRQ%d with a 8 bit card/slot\n", hw_config->irq); return 0; } return ad1848_detect(hw_config->io_base + 4, NULL, hw_config->osp); } void attach_ms_sound(struct address_info *hw_config) { static char interrupt_bits[12] = { -1, -1, -1, -1, -1, -1, -1, 0x08, -1, 0x10, 0x18, 0x20 }; char bits, dma2_bit = 0; static char dma_bits[4] = { 1, 2, 0, 3 }; int config_port = hw_config->io_base + 0; int version_port = hw_config->io_base + 3; int dma = hw_config->dma; int dma2 = hw_config->dma2; if (hw_config->card_subtype == 1) /* Has no IRQ/DMA registers */ { hw_config->slots[0] = ad1848_init("MS Sound System", hw_config->io_base + 4, hw_config->irq, hw_config->dma, hw_config->dma2, 0, hw_config->osp); request_region(hw_config->io_base, 4, "WSS config"); return; } /* * Set the IRQ and DMA addresses. */ bits = interrupt_bits[hw_config->irq]; if (bits == -1) { printk("MSS: Bad IRQ %d\n", hw_config->irq); return; } outb((bits | 0x40), config_port); if ((inb(version_port) & 0x40) == 0) printk("[MSS: IRQ Conflict?]"); /* * Handle the capture DMA channel */ if (dma2 != -1 && dma2 != dma) { if (!((dma == 0 && dma2 == 1) || (dma == 1 && dma2 == 0) || (dma == 3 && dma2 == 0))) { /* Unsupported combination. Try to swap channels */ int tmp = dma; dma = dma2; dma2 = tmp; } if ((dma == 0 && dma2 == 1) || (dma == 1 && dma2 == 0) || (dma == 3 && dma2 == 0)) { dma2_bit = 0x04; /* Enable capture DMA */ } else { printk("MSS: Invalid capture DMA\n"); dma2 = dma; } } else { dma2 = dma; } hw_config->dma = dma; hw_config->dma2 = dma2; outb((bits | dma_bits[dma] | dma2_bit), config_port); /* Write IRQ+DMA setup */ hw_config->slots[0] = ad1848_init("MSS audio codec", hw_config->io_base + 4, hw_config->irq, dma, dma2, 0, hw_config->osp); request_region(hw_config->io_base, 4, "WSS config"); } void unload_ms_sound(struct address_info *hw_config) { int mixer = audio_devs[hw_config->slots[0]]->mixer_dev; ad1848_unload(hw_config->io_base + 4, hw_config->irq, hw_config->dma, hw_config->dma, 0); if(mixer>=0) sound_unload_mixerdev(mixer); sound_unload_audiodev(hw_config->slots[0]); release_region(hw_config->io_base, 4); } #if (defined(CONFIG_SEQUENCER) && !defined(EXCLUDE_TIMERS)) || defined(MODULE) /* * Timer stuff (for /dev/music). */ static unsigned int current_interval = 0; static unsigned int ad1848_tmr_start(int dev, unsigned int usecs) { unsigned long flags; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; unsigned long xtal_nsecs; /* nanoseconds per xtal oscillator tick */ unsigned long divider; save_flags(flags); cli(); /* * Length of the timer interval (in nanoseconds) depends on the * selected crystal oscillator. Check this from bit 0x01 of I8. * * AD1845 has just one oscillator which has cycle time of 10.050 us * (when a 24.576 MHz xtal oscillator is used). * * Convert requested interval to nanoseconds before computing * the timer divider. */ if (devc->model == MD_1845) xtal_nsecs = 10050; else if (ad_read(devc, 8) & 0x01) xtal_nsecs = 9920; else xtal_nsecs = 9969; divider = (usecs * 1000 + xtal_nsecs / 2) / xtal_nsecs; if (divider < 100) /* Don't allow shorter intervals than about 1ms */ divider = 100; if (divider > 65535) /* Overflow check */ divider = 65535; ad_write(devc, 21, (divider >> 8) & 0xff); /* Set upper bits */ ad_write(devc, 20, divider & 0xff); /* Set lower bits */ ad_write(devc, 16, ad_read(devc, 16) | 0x40); /* Start the timer */ devc->timer_running = 1; restore_flags(flags); return current_interval = (divider * xtal_nsecs + 500) / 1000; } static void ad1848_tmr_reprogram(int dev) { /* * Audio driver has changed sampling rate so that a different xtal * oscillator was selected. We have to reprogram the timer rate. */ ad1848_tmr_start(dev, current_interval); sound_timer_syncinterval(current_interval); } static void ad1848_tmr_disable(int dev) { unsigned long flags; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; save_flags(flags); cli(); ad_write(devc, 16, ad_read(devc, 16) & ~0x40); devc->timer_running = 0; restore_flags(flags); } static void ad1848_tmr_restart(int dev) { unsigned long flags; ad1848_info *devc = (ad1848_info *) audio_devs[dev]->devc; if (current_interval == 0) return; save_flags(flags); cli(); ad_write(devc, 16, ad_read(devc, 16) | 0x40); devc->timer_running = 1; restore_flags(flags); } static struct sound_lowlev_timer ad1848_tmr = { 0, 2, ad1848_tmr_start, ad1848_tmr_disable, ad1848_tmr_restart }; static int ad1848_tmr_install(int dev) { if (timer_installed != -1) return 0; /* Don't install another timer */ timer_installed = ad1848_tmr.dev = dev; sound_timer_init(&ad1848_tmr, audio_devs[dev]->name); return 1; } #endif EXPORT_SYMBOL(ad1848_detect); EXPORT_SYMBOL(ad1848_init); EXPORT_SYMBOL(ad1848_unload); EXPORT_SYMBOL(adintr); EXPORT_SYMBOL(probe_ms_sound); EXPORT_SYMBOL(attach_ms_sound); EXPORT_SYMBOL(unload_ms_sound); #ifdef MODULE MODULE_PARM(io, "i"); MODULE_PARM(irq, "i"); MODULE_PARM(dma, "i"); MODULE_PARM(dma2, "i"); MODULE_PARM(type, "i"); int io = -1; int irq = -1; int dma = -1; int dma2 = -1; int type = 0; static int loaded = 0; struct address_info hw_config; int init_module(void) { printk("ad1848/cs4248 codec driver Copyright (C) by Hannu Savolainen 1993-1996\n"); if(io!=-1) { if(irq == -1 || dma == -1) { printk(KERN_WARNING "ad1848: must give I/O , IRQ and DMA.\n"); return -EINVAL; } hw_config.irq = irq; hw_config.io_base = io; hw_config.dma = dma; hw_config.dma2 = dma2; hw_config.card_subtype = type; if(!probe_ms_sound(&hw_config)) return -ENODEV; attach_ms_sound(&hw_config); loaded=1; } SOUND_LOCK; return 0; } void cleanup_module(void) { SOUND_LOCK_END; if(loaded) unload_ms_sound(&hw_config); /* unregister_symtab(&ad1848_syms); */ } #else void export_ad1848_syms(void) { register_symtab(&ad1848_syms); } #endif #endif