/* * sound/oss/sb_audio.c * * Audio routines for Sound Blaster compatible cards. * * * 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. * * Changes * Alan Cox : Formatting and clean ups * * Status * Mostly working. Weird uart bug causing irq storms * * Daniel J. Rodriksson: Changes to make sb16 work full duplex. * Maybe other 16 bit cards in this code could behave * the same. * Chris Rankin: Use spinlocks instead of CLI/STI */ #include <linux/spinlock.h> #include "sound_config.h" #include "sb_mixer.h" #include "sb.h" #include "sb_ess.h" int sb_audio_open(int dev, int mode) { sb_devc *devc = audio_devs[dev]->devc; unsigned long flags; if (devc == NULL) { printk(KERN_ERR "Sound Blaster: incomplete initialization.\n"); return -ENXIO; } if (devc->caps & SB_NO_RECORDING && mode & OPEN_READ) { if (mode == OPEN_READ) return -EPERM; } spin_lock_irqsave(&devc->lock, flags); if (devc->opened) { spin_unlock_irqrestore(&devc->lock, flags); return -EBUSY; } if (devc->dma16 != -1 && devc->dma16 != devc->dma8 && !devc->duplex) { if (sound_open_dma(devc->dma16, "Sound Blaster 16 bit")) { spin_unlock_irqrestore(&devc->lock, flags); return -EBUSY; } } devc->opened = mode; spin_unlock_irqrestore(&devc->lock, flags); devc->irq_mode = IMODE_NONE; devc->irq_mode_16 = IMODE_NONE; devc->fullduplex = devc->duplex && ((mode & OPEN_READ) && (mode & OPEN_WRITE)); sb_dsp_reset(devc); /* At first glance this check isn't enough, some ESS chips might not * have a RECLEV. However if they don't common_mixer_set will refuse * cause devc->iomap has no register mapping for RECLEV */ if (devc->model == MDL_ESS) ess_mixer_reload (devc, SOUND_MIXER_RECLEV); /* The ALS007 seems to require that the DSP be removed from the output */ /* in order for recording to be activated properly. This is done by */ /* setting the appropriate bits of the output control register 4ch to */ /* zero. This code assumes that the output control registers are not */ /* used anywhere else and therefore the DSP bits are *always* ON for */ /* output and OFF for sampling. */ if (devc->submodel == SUBMDL_ALS007) { if (mode & OPEN_READ) sb_setmixer(devc,ALS007_OUTPUT_CTRL2, sb_getmixer(devc,ALS007_OUTPUT_CTRL2) & 0xf9); else sb_setmixer(devc,ALS007_OUTPUT_CTRL2, sb_getmixer(devc,ALS007_OUTPUT_CTRL2) | 0x06); } return 0; } void sb_audio_close(int dev) { sb_devc *devc = audio_devs[dev]->devc; /* fix things if mmap turned off fullduplex */ if(devc->duplex && !devc->fullduplex && (devc->opened & OPEN_READ) && (devc->opened & OPEN_WRITE)) { struct dma_buffparms *dmap_temp; dmap_temp = audio_devs[dev]->dmap_out; audio_devs[dev]->dmap_out = audio_devs[dev]->dmap_in; audio_devs[dev]->dmap_in = dmap_temp; } audio_devs[dev]->dmap_out->dma = devc->dma8; audio_devs[dev]->dmap_in->dma = ( devc->duplex ) ? devc->dma16 : devc->dma8; if (devc->dma16 != -1 && devc->dma16 != devc->dma8 && !devc->duplex) sound_close_dma(devc->dma16); /* For ALS007, turn DSP output back on if closing the device for read */ if ((devc->submodel == SUBMDL_ALS007) && (devc->opened & OPEN_READ)) { sb_setmixer(devc,ALS007_OUTPUT_CTRL2, sb_getmixer(devc,ALS007_OUTPUT_CTRL2) | 0x06); } devc->opened = 0; } static void sb_set_output_parms(int dev, unsigned long buf, int nr_bytes, int intrflag) { sb_devc *devc = audio_devs[dev]->devc; if (!devc->fullduplex || devc->bits == AFMT_S16_LE) { devc->trg_buf = buf; devc->trg_bytes = nr_bytes; devc->trg_intrflag = intrflag; devc->irq_mode = IMODE_OUTPUT; } else { devc->trg_buf_16 = buf; devc->trg_bytes_16 = nr_bytes; devc->trg_intrflag_16 = intrflag; devc->irq_mode_16 = IMODE_OUTPUT; } } static void sb_set_input_parms(int dev, unsigned long buf, int count, int intrflag) { sb_devc *devc = audio_devs[dev]->devc; if (!devc->fullduplex || devc->bits != AFMT_S16_LE) { devc->trg_buf = buf; devc->trg_bytes = count; devc->trg_intrflag = intrflag; devc->irq_mode = IMODE_INPUT; } else { devc->trg_buf_16 = buf; devc->trg_bytes_16 = count; devc->trg_intrflag_16 = intrflag; devc->irq_mode_16 = IMODE_INPUT; } } /* * SB1.x compatible routines */ static void sb1_audio_output_block(int dev, unsigned long buf, int nr_bytes, int intrflag) { unsigned long flags; int count = nr_bytes; sb_devc *devc = audio_devs[dev]->devc; /* DMAbuf_start_dma (dev, buf, count, DMA_MODE_WRITE); */ if (audio_devs[dev]->dmap_out->dma > 3) count >>= 1; count--; devc->irq_mode = IMODE_OUTPUT; spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x14)) /* 8 bit DAC using DMA */ { sb_dsp_command(devc, (unsigned char) (count & 0xff)); sb_dsp_command(devc, (unsigned char) ((count >> 8) & 0xff)); } else printk(KERN_WARNING "Sound Blaster: unable to start DAC.\n"); spin_unlock_irqrestore(&devc->lock, flags); devc->intr_active = 1; } static void sb1_audio_start_input(int dev, unsigned long buf, int nr_bytes, int intrflag) { unsigned long flags; int count = nr_bytes; sb_devc *devc = audio_devs[dev]->devc; /* * Start a DMA input to the buffer pointed by dmaqtail */ /* DMAbuf_start_dma (dev, buf, count, DMA_MODE_READ); */ if (audio_devs[dev]->dmap_out->dma > 3) count >>= 1; count--; devc->irq_mode = IMODE_INPUT; spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x24)) /* 8 bit ADC using DMA */ { sb_dsp_command(devc, (unsigned char) (count & 0xff)); sb_dsp_command(devc, (unsigned char) ((count >> 8) & 0xff)); } else printk(KERN_ERR "Sound Blaster: unable to start ADC.\n"); spin_unlock_irqrestore(&devc->lock, flags); devc->intr_active = 1; } static void sb1_audio_trigger(int dev, int bits) { sb_devc *devc = audio_devs[dev]->devc; bits &= devc->irq_mode; if (!bits) sb_dsp_command(devc, 0xd0); /* Halt DMA */ else { switch (devc->irq_mode) { case IMODE_INPUT: sb1_audio_start_input(dev, devc->trg_buf, devc->trg_bytes, devc->trg_intrflag); break; case IMODE_OUTPUT: sb1_audio_output_block(dev, devc->trg_buf, devc->trg_bytes, devc->trg_intrflag); break; } } devc->trigger_bits = bits; } static int sb1_audio_prepare_for_input(int dev, int bsize, int bcount) { sb_devc *devc = audio_devs[dev]->devc; unsigned long flags; spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x40)) sb_dsp_command(devc, devc->tconst); sb_dsp_command(devc, DSP_CMD_SPKOFF); spin_unlock_irqrestore(&devc->lock, flags); devc->trigger_bits = 0; return 0; } static int sb1_audio_prepare_for_output(int dev, int bsize, int bcount) { sb_devc *devc = audio_devs[dev]->devc; unsigned long flags; spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x40)) sb_dsp_command(devc, devc->tconst); sb_dsp_command(devc, DSP_CMD_SPKON); spin_unlock_irqrestore(&devc->lock, flags); devc->trigger_bits = 0; return 0; } static int sb1_audio_set_speed(int dev, int speed) { int max_speed = 23000; sb_devc *devc = audio_devs[dev]->devc; int tmp; if (devc->opened & OPEN_READ) max_speed = 13000; if (speed > 0) { if (speed < 4000) speed = 4000; if (speed > max_speed) speed = max_speed; devc->tconst = (256 - ((1000000 + speed / 2) / speed)) & 0xff; tmp = 256 - devc->tconst; speed = (1000000 + tmp / 2) / tmp; devc->speed = speed; } return devc->speed; } static short sb1_audio_set_channels(int dev, short channels) { sb_devc *devc = audio_devs[dev]->devc; return devc->channels = 1; } static unsigned int sb1_audio_set_bits(int dev, unsigned int bits) { sb_devc *devc = audio_devs[dev]->devc; return devc->bits = 8; } static void sb1_audio_halt_xfer(int dev) { unsigned long flags; sb_devc *devc = audio_devs[dev]->devc; spin_lock_irqsave(&devc->lock, flags); sb_dsp_reset(devc); spin_unlock_irqrestore(&devc->lock, flags); } /* * SB 2.0 and SB 2.01 compatible routines */ static void sb20_audio_output_block(int dev, unsigned long buf, int nr_bytes, int intrflag) { unsigned long flags; int count = nr_bytes; sb_devc *devc = audio_devs[dev]->devc; unsigned char cmd; /* DMAbuf_start_dma (dev, buf, count, DMA_MODE_WRITE); */ if (audio_devs[dev]->dmap_out->dma > 3) count >>= 1; count--; devc->irq_mode = IMODE_OUTPUT; spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x48)) /* DSP Block size */ { sb_dsp_command(devc, (unsigned char) (count & 0xff)); sb_dsp_command(devc, (unsigned char) ((count >> 8) & 0xff)); if (devc->speed * devc->channels <= 23000) cmd = 0x1c; /* 8 bit PCM output */ else cmd = 0x90; /* 8 bit high speed PCM output (SB2.01/Pro) */ if (!sb_dsp_command(devc, cmd)) printk(KERN_ERR "Sound Blaster: unable to start DAC.\n"); } else printk(KERN_ERR "Sound Blaster: unable to start DAC.\n"); spin_unlock_irqrestore(&devc->lock, flags); devc->intr_active = 1; } static void sb20_audio_start_input(int dev, unsigned long buf, int nr_bytes, int intrflag) { unsigned long flags; int count = nr_bytes; sb_devc *devc = audio_devs[dev]->devc; unsigned char cmd; /* * Start a DMA input to the buffer pointed by dmaqtail */ /* DMAbuf_start_dma (dev, buf, count, DMA_MODE_READ); */ if (audio_devs[dev]->dmap_out->dma > 3) count >>= 1; count--; devc->irq_mode = IMODE_INPUT; spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x48)) /* DSP Block size */ { sb_dsp_command(devc, (unsigned char) (count & 0xff)); sb_dsp_command(devc, (unsigned char) ((count >> 8) & 0xff)); if (devc->speed * devc->channels <= (devc->major == 3 ? 23000 : 13000)) cmd = 0x2c; /* 8 bit PCM input */ else cmd = 0x98; /* 8 bit high speed PCM input (SB2.01/Pro) */ if (!sb_dsp_command(devc, cmd)) printk(KERN_ERR "Sound Blaster: unable to start ADC.\n"); } else printk(KERN_ERR "Sound Blaster: unable to start ADC.\n"); spin_unlock_irqrestore(&devc->lock, flags); devc->intr_active = 1; } static void sb20_audio_trigger(int dev, int bits) { sb_devc *devc = audio_devs[dev]->devc; bits &= devc->irq_mode; if (!bits) sb_dsp_command(devc, 0xd0); /* Halt DMA */ else { switch (devc->irq_mode) { case IMODE_INPUT: sb20_audio_start_input(dev, devc->trg_buf, devc->trg_bytes, devc->trg_intrflag); break; case IMODE_OUTPUT: sb20_audio_output_block(dev, devc->trg_buf, devc->trg_bytes, devc->trg_intrflag); break; } } devc->trigger_bits = bits; } /* * SB2.01 specific speed setup */ static int sb201_audio_set_speed(int dev, int speed) { sb_devc *devc = audio_devs[dev]->devc; int tmp; int s; if (speed > 0) { if (speed < 4000) speed = 4000; if (speed > 44100) speed = 44100; if (devc->opened & OPEN_READ && speed > 15000) speed = 15000; s = speed * devc->channels; devc->tconst = (256 - ((1000000 + s / 2) / s)) & 0xff; tmp = 256 - devc->tconst; speed = ((1000000 + tmp / 2) / tmp) / devc->channels; devc->speed = speed; } return devc->speed; } /* * SB Pro specific routines */ static int sbpro_audio_prepare_for_input(int dev, int bsize, int bcount) { /* For SB Pro and Jazz16 */ sb_devc *devc = audio_devs[dev]->devc; unsigned long flags; unsigned char bits = 0; if (devc->dma16 >= 0 && devc->dma16 != devc->dma8) audio_devs[dev]->dmap_out->dma = audio_devs[dev]->dmap_in->dma = devc->bits == 16 ? devc->dma16 : devc->dma8; if (devc->model == MDL_JAZZ || devc->model == MDL_SMW) if (devc->bits == AFMT_S16_LE) bits = 0x04; /* 16 bit mode */ spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x40)) sb_dsp_command(devc, devc->tconst); sb_dsp_command(devc, DSP_CMD_SPKOFF); if (devc->channels == 1) sb_dsp_command(devc, 0xa0 | bits); /* Mono input */ else sb_dsp_command(devc, 0xa8 | bits); /* Stereo input */ spin_unlock_irqrestore(&devc->lock, flags); devc->trigger_bits = 0; return 0; } static int sbpro_audio_prepare_for_output(int dev, int bsize, int bcount) { /* For SB Pro and Jazz16 */ sb_devc *devc = audio_devs[dev]->devc; unsigned long flags; unsigned char tmp; unsigned char bits = 0; if (devc->dma16 >= 0 && devc->dma16 != devc->dma8) audio_devs[dev]->dmap_out->dma = audio_devs[dev]->dmap_in->dma = devc->bits == 16 ? devc->dma16 : devc->dma8; if (devc->model == MDL_SBPRO) sb_mixer_set_stereo(devc, devc->channels == 2); spin_lock_irqsave(&devc->lock, flags); if (sb_dsp_command(devc, 0x40)) sb_dsp_command(devc, devc->tconst); sb_dsp_command(devc, DSP_CMD_SPKON); if (devc->model == MDL_JAZZ || devc->model == MDL_SMW) { if (devc->bits == AFMT_S16_LE) bits = 0x04; /* 16 bit mode */ if (devc->channels == 1) sb_dsp_command(devc, 0xa0 | bits); /* Mono output */ else sb_dsp_command(devc, 0xa8 | bits); /* Stereo output */ spin_unlock_irqrestore(&devc->lock, flags); } else { spin_unlock_irqrestore(&devc->lock, flags); tmp = sb_getmixer(devc, 0x0e); if (devc->channels == 1) tmp &= ~0x02; else tmp |= 0x02; sb_setmixer(devc, 0x0e, tmp); } devc->trigger_bits = 0; return 0; } static int sbpro_audio_set_speed(int dev, int speed) { sb_devc *devc = audio_devs[dev]->devc; if (speed > 0) { if (speed < 4000) speed = 4000; if (speed > 44100) speed = 44100; if (devc->channels > 1 && speed > 22050) speed = 22050; sb201_audio_set_speed(dev, speed); } return devc->speed; } static short sbpro_audio_set_channels(int dev, short channels) { sb_devc *devc = audio_devs[dev]->devc; if (channels == 1 || channels == 2) { if (channels != devc->channels) { devc->channels = channels; if (devc->model == MDL_SBPRO && devc->channels == 2) sbpro_audio_set_speed(dev, devc->speed); } } return devc->channels; } static int jazz16_audio_set_speed(int dev, int speed) { sb_devc *devc = audio_devs[dev]->devc; if (speed > 0) { int tmp; int s; if (speed < 5000) speed = 5000; if (speed > 44100) speed = 44100; s = speed * devc->channels; devc->tconst = (256 - ((1000000 + s / 2) / s)) & 0xff; tmp = 256 - devc->tconst; speed = ((1000000 + tmp / 2) / tmp) / devc->channels; devc->speed = speed; } return devc->speed; } /* * SB16 specific routines */ static int sb16_audio_set_speed(int dev, int speed) { sb_devc *devc = audio_devs[dev]->devc; int max_speed = devc->submodel == SUBMDL_ALS100 ? 48000 : 44100; if (speed > 0) { if (speed < 5000) speed = 5000; if (speed > max_speed) speed = max_speed; devc->speed = speed; } return devc->speed; } static unsigned int sb16_audio_set_bits(int dev, unsigned int bits) { sb_devc *devc = audio_devs[dev]->devc; if (bits != 0) { if (bits == AFMT_U8 || bits == AFMT_S16_LE) devc->bits = bits; else devc->bits = AFMT_U8; } return devc->bits; } static int sb16_audio_prepare_for_input(int dev, int bsize, int bcount) { sb_devc *devc = audio_devs[dev]->devc; if (!devc->fullduplex) { audio_devs[dev]->dmap_out->dma = audio_devs[dev]->dmap_in->dma = devc->bits == AFMT_S16_LE ? devc->dma16 : devc->dma8; } else if (devc->bits == AFMT_S16_LE) { audio_devs[dev]->dmap_out->dma = devc->dma8; audio_devs[dev]->dmap_in->dma = devc->dma16; } else { audio_devs[dev]->dmap_out->dma = devc->dma16; audio_devs[dev]->dmap_in->dma = devc->dma8; } devc->trigger_bits = 0; return 0; } static int sb16_audio_prepare_for_output(int dev, int bsize, int bcount) { sb_devc *devc = audio_devs[dev]->devc; if (!devc->fullduplex) { audio_devs[dev]->dmap_out->dma = audio_devs[dev]->dmap_in->dma = devc->bits == AFMT_S16_LE ? devc->dma16 : devc->dma8; } else if (devc->bits == AFMT_S16_LE) { audio_devs[dev]->dmap_out->dma = devc->dma8; audio_devs[dev]->dmap_in->dma = devc->dma16; } else { audio_devs[dev]->dmap_out->dma = devc->dma16; audio_devs[dev]->dmap_in->dma = devc->dma8; } devc->trigger_bits = 0; return 0; } static void sb16_audio_output_block(int dev, unsigned long buf, int count, int intrflag) { unsigned long flags, cnt; sb_devc *devc = audio_devs[dev]->devc; unsigned long bits; if (!devc->fullduplex || devc->bits == AFMT_S16_LE) { devc->irq_mode = IMODE_OUTPUT; devc->intr_active = 1; } else { devc->irq_mode_16 = IMODE_OUTPUT; devc->intr_active_16 = 1; } /* save value */ spin_lock_irqsave(&devc->lock, flags); bits = devc->bits; if (devc->fullduplex) devc->bits = (devc->bits == AFMT_S16_LE) ? AFMT_U8 : AFMT_S16_LE; spin_unlock_irqrestore(&devc->lock, flags); cnt = count; if (devc->bits == AFMT_S16_LE) cnt >>= 1; cnt--; spin_lock_irqsave(&devc->lock, flags); /* DMAbuf_start_dma (dev, buf, count, DMA_MODE_WRITE); */ sb_dsp_command(devc, 0x41); sb_dsp_command(devc, (unsigned char) ((devc->speed >> 8) & 0xff)); sb_dsp_command(devc, (unsigned char) (devc->speed & 0xff)); sb_dsp_command(devc, (devc->bits == AFMT_S16_LE ? 0xb6 : 0xc6)); sb_dsp_command(devc, ((devc->channels == 2 ? 0x20 : 0) + (devc->bits == AFMT_S16_LE ? 0x10 : 0))); sb_dsp_command(devc, (unsigned char) (cnt & 0xff)); sb_dsp_command(devc, (unsigned char) (cnt >> 8)); /* restore real value after all programming */ devc->bits = bits; spin_unlock_irqrestore(&devc->lock, flags); } /* * This fails on the Cyrix MediaGX. If you don't have the DMA enabled * before the first sample arrives it locks up. However even if you * do enable the DMA in time you just get DMA timeouts and missing * interrupts and stuff, so for now I've not bothered fixing this either. */ static void sb16_audio_start_input(int dev, unsigned long buf, int count, int intrflag) { unsigned long flags, cnt; sb_devc *devc = audio_devs[dev]->devc; if (!devc->fullduplex || devc->bits != AFMT_S16_LE) { devc->irq_mode = IMODE_INPUT; devc->intr_active = 1; } else { devc->irq_mode_16 = IMODE_INPUT; devc->intr_active_16 = 1; } cnt = count; if (devc->bits == AFMT_S16_LE) cnt >>= 1; cnt--; spin_lock_irqsave(&devc->lock, flags); /* DMAbuf_start_dma (dev, buf, count, DMA_MODE_READ); */ sb_dsp_command(devc, 0x42); sb_dsp_command(devc, (unsigned char) ((devc->speed >> 8) & 0xff)); sb_dsp_command(devc, (unsigned char) (devc->speed & 0xff)); sb_dsp_command(devc, (devc->bits == AFMT_S16_LE ? 0xbe : 0xce)); sb_dsp_command(devc, ((devc->channels == 2 ? 0x20 : 0) + (devc->bits == AFMT_S16_LE ? 0x10 : 0))); sb_dsp_command(devc, (unsigned char) (cnt & 0xff)); sb_dsp_command(devc, (unsigned char) (cnt >> 8)); spin_unlock_irqrestore(&devc->lock, flags); } static void sb16_audio_trigger(int dev, int bits) { sb_devc *devc = audio_devs[dev]->devc; int bits_16 = bits & devc->irq_mode_16; bits &= devc->irq_mode; if (!bits && !bits_16) sb_dsp_command(devc, 0xd0); /* Halt DMA */ else { if (bits) { switch (devc->irq_mode) { case IMODE_INPUT: sb16_audio_start_input(dev, devc->trg_buf, devc->trg_bytes, devc->trg_intrflag); break; case IMODE_OUTPUT: sb16_audio_output_block(dev, devc->trg_buf, devc->trg_bytes, devc->trg_intrflag); break; } } if (bits_16) { switch (devc->irq_mode_16) { case IMODE_INPUT: sb16_audio_start_input(dev, devc->trg_buf_16, devc->trg_bytes_16, devc->trg_intrflag_16); break; case IMODE_OUTPUT: sb16_audio_output_block(dev, devc->trg_buf_16, devc->trg_bytes_16, devc->trg_intrflag_16); break; } } } devc->trigger_bits = bits | bits_16; } static unsigned char lbuf8[2048]; static signed short *lbuf16 = (signed short *)lbuf8; #define LBUFCOPYSIZE 1024 static void sb16_copy_from_user(int dev, char *localbuf, int localoffs, const char __user *userbuf, int useroffs, int max_in, int max_out, int *used, int *returned, int len) { sb_devc *devc = audio_devs[dev]->devc; int i, c, p, locallen; unsigned char *buf8; signed short *buf16; /* if not duplex no conversion */ if (!devc->fullduplex) { if (copy_from_user(localbuf + localoffs, userbuf + useroffs, len)) return; *used = len; *returned = len; } else if (devc->bits == AFMT_S16_LE) { /* 16 -> 8 */ /* max_in >> 1, max number of samples in ( 16 bits ) */ /* max_out, max number of samples out ( 8 bits ) */ /* len, number of samples that will be taken ( 16 bits )*/ /* c, count of samples remaining in buffer ( 16 bits )*/ /* p, count of samples already processed ( 16 bits )*/ len = ( (max_in >> 1) > max_out) ? max_out : (max_in >> 1); c = len; p = 0; buf8 = (unsigned char *)(localbuf + localoffs); while (c) { locallen = (c >= LBUFCOPYSIZE ? LBUFCOPYSIZE : c); /* << 1 in order to get 16 bit samples */ if (copy_from_user(lbuf16, userbuf + useroffs + (p << 1), locallen << 1)) return; for (i = 0; i < locallen; i++) { buf8[p+i] = ~((lbuf16[i] >> 8) & 0xff) ^ 0x80; } c -= locallen; p += locallen; } /* used = ( samples * 16 bits size ) */ *used = max_in > ( max_out << 1) ? (max_out << 1) : max_in; /* returned = ( samples * 8 bits size ) */ *returned = len; } else { /* 8 -> 16 */ /* max_in, max number of samples in ( 8 bits ) */ /* max_out >> 1, max number of samples out ( 16 bits ) */ /* len, number of samples that will be taken ( 8 bits )*/ /* c, count of samples remaining in buffer ( 8 bits )*/ /* p, count of samples already processed ( 8 bits )*/ len = max_in > (max_out >> 1) ? (max_out >> 1) : max_in; c = len; p = 0; buf16 = (signed short *)(localbuf + localoffs); while (c) { locallen = (c >= LBUFCOPYSIZE ? LBUFCOPYSIZE : c); if (copy_from_user(lbuf8, userbuf+useroffs + p, locallen)) return; for (i = 0; i < locallen; i++) { buf16[p+i] = (~lbuf8[i] ^ 0x80) << 8; } c -= locallen; p += locallen; } /* used = ( samples * 8 bits size ) */ *used = len; /* returned = ( samples * 16 bits size ) */ *returned = len << 1; } } static void sb16_audio_mmap(int dev) { sb_devc *devc = audio_devs[dev]->devc; devc->fullduplex = 0; } static struct audio_driver sb1_audio_driver = /* SB1.x */ { .owner = THIS_MODULE, .open = sb_audio_open, .close = sb_audio_close, .output_block = sb_set_output_parms, .start_input = sb_set_input_parms, .prepare_for_input = sb1_audio_prepare_for_input, .prepare_for_output = sb1_audio_prepare_for_output, .halt_io = sb1_audio_halt_xfer, .trigger = sb1_audio_trigger, .set_speed = sb1_audio_set_speed, .set_bits = sb1_audio_set_bits, .set_channels = sb1_audio_set_channels }; static struct audio_driver sb20_audio_driver = /* SB2.0 */ { .owner = THIS_MODULE, .open = sb_audio_open, .close = sb_audio_close, .output_block = sb_set_output_parms, .start_input = sb_set_input_parms, .prepare_for_input = sb1_audio_prepare_for_input, .prepare_for_output = sb1_audio_prepare_for_output, .halt_io = sb1_audio_halt_xfer, .trigger = sb20_audio_trigger, .set_speed = sb1_audio_set_speed, .set_bits = sb1_audio_set_bits, .set_channels = sb1_audio_set_channels }; static struct audio_driver sb201_audio_driver = /* SB2.01 */ { .owner = THIS_MODULE, .open = sb_audio_open, .close = sb_audio_close, .output_block = sb_set_output_parms, .start_input = sb_set_input_parms, .prepare_for_input = sb1_audio_prepare_for_input, .prepare_for_output = sb1_audio_prepare_for_output, .halt_io = sb1_audio_halt_xfer, .trigger = sb20_audio_trigger, .set_speed = sb201_audio_set_speed, .set_bits = sb1_audio_set_bits, .set_channels = sb1_audio_set_channels }; static struct audio_driver sbpro_audio_driver = /* SB Pro */ { .owner = THIS_MODULE, .open = sb_audio_open, .close = sb_audio_close, .output_block = sb_set_output_parms, .start_input = sb_set_input_parms, .prepare_for_input = sbpro_audio_prepare_for_input, .prepare_for_output = sbpro_audio_prepare_for_output, .halt_io = sb1_audio_halt_xfer, .trigger = sb20_audio_trigger, .set_speed = sbpro_audio_set_speed, .set_bits = sb1_audio_set_bits, .set_channels = sbpro_audio_set_channels }; static struct audio_driver jazz16_audio_driver = /* Jazz16 and SM Wave */ { .owner = THIS_MODULE, .open = sb_audio_open, .close = sb_audio_close, .output_block = sb_set_output_parms, .start_input = sb_set_input_parms, .prepare_for_input = sbpro_audio_prepare_for_input, .prepare_for_output = sbpro_audio_prepare_for_output, .halt_io = sb1_audio_halt_xfer, .trigger = sb20_audio_trigger, .set_speed = jazz16_audio_set_speed, .set_bits = sb16_audio_set_bits, .set_channels = sbpro_audio_set_channels }; static struct audio_driver sb16_audio_driver = /* SB16 */ { .owner = THIS_MODULE, .open = sb_audio_open, .close = sb_audio_close, .output_block = sb_set_output_parms, .start_input = sb_set_input_parms, .prepare_for_input = sb16_audio_prepare_for_input, .prepare_for_output = sb16_audio_prepare_for_output, .halt_io = sb1_audio_halt_xfer, .copy_user = sb16_copy_from_user, .trigger = sb16_audio_trigger, .set_speed = sb16_audio_set_speed, .set_bits = sb16_audio_set_bits, .set_channels = sbpro_audio_set_channels, .mmap = sb16_audio_mmap }; void sb_audio_init(sb_devc * devc, char *name, struct module *owner) { int audio_flags = 0; int format_mask = AFMT_U8; struct audio_driver *driver = &sb1_audio_driver; switch (devc->model) { case MDL_SB1: /* SB1.0 or SB 1.5 */ DDB(printk("Will use standard SB1.x driver\n")); audio_flags = DMA_HARDSTOP; break; case MDL_SB2: DDB(printk("Will use SB2.0 driver\n")); audio_flags = DMA_AUTOMODE; driver = &sb20_audio_driver; break; case MDL_SB201: DDB(printk("Will use SB2.01 (high speed) driver\n")); audio_flags = DMA_AUTOMODE; driver = &sb201_audio_driver; break; case MDL_JAZZ: case MDL_SMW: DDB(printk("Will use Jazz16 driver\n")); audio_flags = DMA_AUTOMODE; format_mask |= AFMT_S16_LE; driver = &jazz16_audio_driver; break; case MDL_ESS: DDB(printk("Will use ESS ES688/1688 driver\n")); driver = ess_audio_init (devc, &audio_flags, &format_mask); break; case MDL_SB16: DDB(printk("Will use SB16 driver\n")); audio_flags = DMA_AUTOMODE; format_mask |= AFMT_S16_LE; if (devc->dma8 != devc->dma16 && devc->dma16 != -1) { audio_flags |= DMA_DUPLEX; devc->duplex = 1; } driver = &sb16_audio_driver; break; default: DDB(printk("Will use SB Pro driver\n")); audio_flags = DMA_AUTOMODE; driver = &sbpro_audio_driver; } if (owner) driver->owner = owner; if ((devc->dev = sound_install_audiodrv(AUDIO_DRIVER_VERSION, name,driver, sizeof(struct audio_driver), audio_flags, format_mask, devc, devc->dma8, devc->duplex ? devc->dma16 : devc->dma8)) < 0) { printk(KERN_ERR "Sound Blaster: unable to install audio.\n"); return; } audio_devs[devc->dev]->mixer_dev = devc->my_mixerdev; audio_devs[devc->dev]->min_fragment = 5; }