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1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857 1858 1859 1860 1861 1862 1863 1864 1865 1866 1867 1868 1869 1870 1871 1872 1873 1874 1875 1876 1877 1878 1879 1880 1881 1882 1883 1884 1885 1886 1887 1888 1889 1890 1891 1892 1893 1894 1895 1896 1897 1898 1899 1900 1901 1902 1903 1904 1905 1906 1907 1908 1909 1910 1911 1912 1913 1914 1915 1916 1917 1918 1919 1920 1921 1922 1923 1924 1925 1926 1927 1928 1929 1930 1931 1932 1933 1934 1935 1936 1937 1938 1939 1940 1941 1942 1943 1944 1945 1946 1947 1948 1949 1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 1970 1971 | /* * * Implementation of primary alsa driver code base for Intel HD Audio. * * Copyright(c) 2004 Intel Corporation. All rights reserved. * * Copyright (c) 2004 Takashi Iwai <tiwai@suse.de> * PeiSen Hou <pshou@realtek.com.tw> * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the Free * Software Foundation; either version 2 of the License, or (at your option) * any later version. * * This program is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for * more details. * * */ #include <linux/clocksource.h> #include <linux/delay.h> #include <linux/interrupt.h> #include <linux/kernel.h> #include <linux/module.h> #include <linux/pm_runtime.h> #include <linux/slab.h> #include <linux/reboot.h> #include <sound/core.h> #include <sound/initval.h> #include "hda_priv.h" #include "hda_controller.h" #define CREATE_TRACE_POINTS #include "hda_intel_trace.h" /* DSP lock helpers */ #ifdef CONFIG_SND_HDA_DSP_LOADER #define dsp_lock_init(dev) mutex_init(&(dev)->dsp_mutex) #define dsp_lock(dev) mutex_lock(&(dev)->dsp_mutex) #define dsp_unlock(dev) mutex_unlock(&(dev)->dsp_mutex) #define dsp_is_locked(dev) ((dev)->locked) #else #define dsp_lock_init(dev) do {} while (0) #define dsp_lock(dev) do {} while (0) #define dsp_unlock(dev) do {} while (0) #define dsp_is_locked(dev) 0 #endif /* * AZX stream operations. */ /* start a stream */ static void azx_stream_start(struct azx *chip, struct azx_dev *azx_dev) { /* * Before stream start, initialize parameter */ azx_dev->insufficient = 1; /* enable SIE */ azx_writel(chip, INTCTL, azx_readl(chip, INTCTL) | (1 << azx_dev->index)); /* set DMA start and interrupt mask */ azx_sd_writeb(chip, azx_dev, SD_CTL, azx_sd_readb(chip, azx_dev, SD_CTL) | SD_CTL_DMA_START | SD_INT_MASK); } /* stop DMA */ static void azx_stream_clear(struct azx *chip, struct azx_dev *azx_dev) { azx_sd_writeb(chip, azx_dev, SD_CTL, azx_sd_readb(chip, azx_dev, SD_CTL) & ~(SD_CTL_DMA_START | SD_INT_MASK)); azx_sd_writeb(chip, azx_dev, SD_STS, SD_INT_MASK); /* to be sure */ } /* stop a stream */ void azx_stream_stop(struct azx *chip, struct azx_dev *azx_dev) { azx_stream_clear(chip, azx_dev); /* disable SIE */ azx_writel(chip, INTCTL, azx_readl(chip, INTCTL) & ~(1 << azx_dev->index)); } EXPORT_SYMBOL_GPL(azx_stream_stop); /* reset stream */ static void azx_stream_reset(struct azx *chip, struct azx_dev *azx_dev) { unsigned char val; int timeout; azx_stream_clear(chip, azx_dev); azx_sd_writeb(chip, azx_dev, SD_CTL, azx_sd_readb(chip, azx_dev, SD_CTL) | SD_CTL_STREAM_RESET); udelay(3); timeout = 300; while (!((val = azx_sd_readb(chip, azx_dev, SD_CTL)) & SD_CTL_STREAM_RESET) && --timeout) ; val &= ~SD_CTL_STREAM_RESET; azx_sd_writeb(chip, azx_dev, SD_CTL, val); udelay(3); timeout = 300; /* waiting for hardware to report that the stream is out of reset */ while (((val = azx_sd_readb(chip, azx_dev, SD_CTL)) & SD_CTL_STREAM_RESET) && --timeout) ; /* reset first position - may not be synced with hw at this time */ *azx_dev->posbuf = 0; } /* * set up the SD for streaming */ static int azx_setup_controller(struct azx *chip, struct azx_dev *azx_dev) { unsigned int val; /* make sure the run bit is zero for SD */ azx_stream_clear(chip, azx_dev); /* program the stream_tag */ val = azx_sd_readl(chip, azx_dev, SD_CTL); val = (val & ~SD_CTL_STREAM_TAG_MASK) | (azx_dev->stream_tag << SD_CTL_STREAM_TAG_SHIFT); if (!azx_snoop(chip)) val |= SD_CTL_TRAFFIC_PRIO; azx_sd_writel(chip, azx_dev, SD_CTL, val); /* program the length of samples in cyclic buffer */ azx_sd_writel(chip, azx_dev, SD_CBL, azx_dev->bufsize); /* program the stream format */ /* this value needs to be the same as the one programmed */ azx_sd_writew(chip, azx_dev, SD_FORMAT, azx_dev->format_val); /* program the stream LVI (last valid index) of the BDL */ azx_sd_writew(chip, azx_dev, SD_LVI, azx_dev->frags - 1); /* program the BDL address */ /* lower BDL address */ azx_sd_writel(chip, azx_dev, SD_BDLPL, (u32)azx_dev->bdl.addr); /* upper BDL address */ azx_sd_writel(chip, azx_dev, SD_BDLPU, upper_32_bits(azx_dev->bdl.addr)); /* enable the position buffer */ if (chip->get_position[0] != azx_get_pos_lpib || chip->get_position[1] != azx_get_pos_lpib) { if (!(azx_readl(chip, DPLBASE) & AZX_DPLBASE_ENABLE)) azx_writel(chip, DPLBASE, (u32)chip->posbuf.addr | AZX_DPLBASE_ENABLE); } /* set the interrupt enable bits in the descriptor control register */ azx_sd_writel(chip, azx_dev, SD_CTL, azx_sd_readl(chip, azx_dev, SD_CTL) | SD_INT_MASK); return 0; } /* assign a stream for the PCM */ static inline struct azx_dev * azx_assign_device(struct azx *chip, struct snd_pcm_substream *substream) { int dev, i, nums; struct azx_dev *res = NULL; /* make a non-zero unique key for the substream */ int key = (substream->pcm->device << 16) | (substream->number << 2) | (substream->stream + 1); if (substream->stream == SNDRV_PCM_STREAM_PLAYBACK) { dev = chip->playback_index_offset; nums = chip->playback_streams; } else { dev = chip->capture_index_offset; nums = chip->capture_streams; } for (i = 0; i < nums; i++, dev++) { struct azx_dev *azx_dev = &chip->azx_dev[dev]; dsp_lock(azx_dev); if (!azx_dev->opened && !dsp_is_locked(azx_dev)) { if (azx_dev->assigned_key == key) { azx_dev->opened = 1; azx_dev->assigned_key = key; dsp_unlock(azx_dev); return azx_dev; } if (!res || (chip->driver_caps & AZX_DCAPS_REVERSE_ASSIGN)) res = azx_dev; } dsp_unlock(azx_dev); } if (res) { dsp_lock(res); res->opened = 1; res->assigned_key = key; dsp_unlock(res); } return res; } /* release the assigned stream */ static inline void azx_release_device(struct azx_dev *azx_dev) { azx_dev->opened = 0; } static cycle_t azx_cc_read(const struct cyclecounter *cc) { struct azx_dev *azx_dev = container_of(cc, struct azx_dev, azx_cc); struct snd_pcm_substream *substream = azx_dev->substream; struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct azx *chip = apcm->chip; return azx_readl(chip, WALLCLK); } static void azx_timecounter_init(struct snd_pcm_substream *substream, bool force, cycle_t last) { struct azx_dev *azx_dev = get_azx_dev(substream); struct timecounter *tc = &azx_dev->azx_tc; struct cyclecounter *cc = &azx_dev->azx_cc; u64 nsec; cc->read = azx_cc_read; cc->mask = CLOCKSOURCE_MASK(32); /* * Converting from 24 MHz to ns means applying a 125/3 factor. * To avoid any saturation issues in intermediate operations, * the 125 factor is applied first. The division is applied * last after reading the timecounter value. * Applying the 1/3 factor as part of the multiplication * requires at least 20 bits for a decent precision, however * overflows occur after about 4 hours or less, not a option. */ cc->mult = 125; /* saturation after 195 years */ cc->shift = 0; nsec = 0; /* audio time is elapsed time since trigger */ timecounter_init(tc, cc, nsec); if (force) /* * force timecounter to use predefined value, * used for synchronized starts */ tc->cycle_last = last; } static u64 azx_adjust_codec_delay(struct snd_pcm_substream *substream, u64 nsec) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct hda_pcm_stream *hinfo = apcm->hinfo[substream->stream]; u64 codec_frames, codec_nsecs; if (!hinfo->ops.get_delay) return nsec; codec_frames = hinfo->ops.get_delay(hinfo, apcm->codec, substream); codec_nsecs = div_u64(codec_frames * 1000000000LL, substream->runtime->rate); if (substream->stream == SNDRV_PCM_STREAM_CAPTURE) return nsec + codec_nsecs; return (nsec > codec_nsecs) ? nsec - codec_nsecs : 0; } /* * set up a BDL entry */ static int setup_bdle(struct azx *chip, struct snd_dma_buffer *dmab, struct azx_dev *azx_dev, u32 **bdlp, int ofs, int size, int with_ioc) { u32 *bdl = *bdlp; while (size > 0) { dma_addr_t addr; int chunk; if (azx_dev->frags >= AZX_MAX_BDL_ENTRIES) return -EINVAL; addr = snd_sgbuf_get_addr(dmab, ofs); /* program the address field of the BDL entry */ bdl[0] = cpu_to_le32((u32)addr); bdl[1] = cpu_to_le32(upper_32_bits(addr)); /* program the size field of the BDL entry */ chunk = snd_sgbuf_get_chunk_size(dmab, ofs, size); /* one BDLE cannot cross 4K boundary on CTHDA chips */ if (chip->driver_caps & AZX_DCAPS_4K_BDLE_BOUNDARY) { u32 remain = 0x1000 - (ofs & 0xfff); if (chunk > remain) chunk = remain; } bdl[2] = cpu_to_le32(chunk); /* program the IOC to enable interrupt * only when the whole fragment is processed */ size -= chunk; bdl[3] = (size || !with_ioc) ? 0 : cpu_to_le32(0x01); bdl += 4; azx_dev->frags++; ofs += chunk; } *bdlp = bdl; return ofs; } /* * set up BDL entries */ static int azx_setup_periods(struct azx *chip, struct snd_pcm_substream *substream, struct azx_dev *azx_dev) { u32 *bdl; int i, ofs, periods, period_bytes; int pos_adj = 0; /* reset BDL address */ azx_sd_writel(chip, azx_dev, SD_BDLPL, 0); azx_sd_writel(chip, azx_dev, SD_BDLPU, 0); period_bytes = azx_dev->period_bytes; periods = azx_dev->bufsize / period_bytes; /* program the initial BDL entries */ bdl = (u32 *)azx_dev->bdl.area; ofs = 0; azx_dev->frags = 0; if (chip->bdl_pos_adj) pos_adj = chip->bdl_pos_adj[chip->dev_index]; if (!azx_dev->no_period_wakeup && pos_adj > 0) { struct snd_pcm_runtime *runtime = substream->runtime; int pos_align = pos_adj; pos_adj = (pos_adj * runtime->rate + 47999) / 48000; if (!pos_adj) pos_adj = pos_align; else pos_adj = ((pos_adj + pos_align - 1) / pos_align) * pos_align; pos_adj = frames_to_bytes(runtime, pos_adj); if (pos_adj >= period_bytes) { dev_warn(chip->card->dev,"Too big adjustment %d\n", pos_adj); pos_adj = 0; } else { ofs = setup_bdle(chip, snd_pcm_get_dma_buf(substream), azx_dev, &bdl, ofs, pos_adj, true); if (ofs < 0) goto error; } } else pos_adj = 0; for (i = 0; i < periods; i++) { if (i == periods - 1 && pos_adj) ofs = setup_bdle(chip, snd_pcm_get_dma_buf(substream), azx_dev, &bdl, ofs, period_bytes - pos_adj, 0); else ofs = setup_bdle(chip, snd_pcm_get_dma_buf(substream), azx_dev, &bdl, ofs, period_bytes, !azx_dev->no_period_wakeup); if (ofs < 0) goto error; } return 0; error: dev_err(chip->card->dev, "Too many BDL entries: buffer=%d, period=%d\n", azx_dev->bufsize, period_bytes); return -EINVAL; } /* * PCM ops */ static int azx_pcm_close(struct snd_pcm_substream *substream) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct hda_pcm_stream *hinfo = apcm->hinfo[substream->stream]; struct azx *chip = apcm->chip; struct azx_dev *azx_dev = get_azx_dev(substream); unsigned long flags; mutex_lock(&chip->open_mutex); spin_lock_irqsave(&chip->reg_lock, flags); azx_dev->substream = NULL; azx_dev->running = 0; spin_unlock_irqrestore(&chip->reg_lock, flags); azx_release_device(azx_dev); hinfo->ops.close(hinfo, apcm->codec, substream); snd_hda_power_down(apcm->codec); mutex_unlock(&chip->open_mutex); return 0; } static int azx_pcm_hw_params(struct snd_pcm_substream *substream, struct snd_pcm_hw_params *hw_params) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct azx *chip = apcm->chip; int ret; dsp_lock(get_azx_dev(substream)); if (dsp_is_locked(get_azx_dev(substream))) { ret = -EBUSY; goto unlock; } ret = chip->ops->substream_alloc_pages(chip, substream, params_buffer_bytes(hw_params)); unlock: dsp_unlock(get_azx_dev(substream)); return ret; } static int azx_pcm_hw_free(struct snd_pcm_substream *substream) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct azx_dev *azx_dev = get_azx_dev(substream); struct azx *chip = apcm->chip; struct hda_pcm_stream *hinfo = apcm->hinfo[substream->stream]; int err; /* reset BDL address */ dsp_lock(azx_dev); if (!dsp_is_locked(azx_dev)) { azx_sd_writel(chip, azx_dev, SD_BDLPL, 0); azx_sd_writel(chip, azx_dev, SD_BDLPU, 0); azx_sd_writel(chip, azx_dev, SD_CTL, 0); azx_dev->bufsize = 0; azx_dev->period_bytes = 0; azx_dev->format_val = 0; } snd_hda_codec_cleanup(apcm->codec, hinfo, substream); err = chip->ops->substream_free_pages(chip, substream); azx_dev->prepared = 0; dsp_unlock(azx_dev); return err; } static int azx_pcm_prepare(struct snd_pcm_substream *substream) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct azx *chip = apcm->chip; struct azx_dev *azx_dev = get_azx_dev(substream); struct hda_pcm_stream *hinfo = apcm->hinfo[substream->stream]; struct snd_pcm_runtime *runtime = substream->runtime; unsigned int bufsize, period_bytes, format_val, stream_tag; int err; struct hda_spdif_out *spdif = snd_hda_spdif_out_of_nid(apcm->codec, hinfo->nid); unsigned short ctls = spdif ? spdif->ctls : 0; dsp_lock(azx_dev); if (dsp_is_locked(azx_dev)) { err = -EBUSY; goto unlock; } azx_stream_reset(chip, azx_dev); format_val = snd_hda_calc_stream_format(apcm->codec, runtime->rate, runtime->channels, runtime->format, hinfo->maxbps, ctls); if (!format_val) { dev_err(chip->card->dev, "invalid format_val, rate=%d, ch=%d, format=%d\n", runtime->rate, runtime->channels, runtime->format); err = -EINVAL; goto unlock; } bufsize = snd_pcm_lib_buffer_bytes(substream); period_bytes = snd_pcm_lib_period_bytes(substream); dev_dbg(chip->card->dev, "azx_pcm_prepare: bufsize=0x%x, format=0x%x\n", bufsize, format_val); if (bufsize != azx_dev->bufsize || period_bytes != azx_dev->period_bytes || format_val != azx_dev->format_val || runtime->no_period_wakeup != azx_dev->no_period_wakeup) { azx_dev->bufsize = bufsize; azx_dev->period_bytes = period_bytes; azx_dev->format_val = format_val; azx_dev->no_period_wakeup = runtime->no_period_wakeup; err = azx_setup_periods(chip, substream, azx_dev); if (err < 0) goto unlock; } /* when LPIB delay correction gives a small negative value, * we ignore it; currently set the threshold statically to * 64 frames */ if (runtime->period_size > 64) azx_dev->delay_negative_threshold = -frames_to_bytes(runtime, 64); else azx_dev->delay_negative_threshold = 0; /* wallclk has 24Mhz clock source */ azx_dev->period_wallclk = (((runtime->period_size * 24000) / runtime->rate) * 1000); azx_setup_controller(chip, azx_dev); if (substream->stream == SNDRV_PCM_STREAM_PLAYBACK) azx_dev->fifo_size = azx_sd_readw(chip, azx_dev, SD_FIFOSIZE) + 1; else azx_dev->fifo_size = 0; stream_tag = azx_dev->stream_tag; /* CA-IBG chips need the playback stream starting from 1 */ if ((chip->driver_caps & AZX_DCAPS_CTX_WORKAROUND) && stream_tag > chip->capture_streams) stream_tag -= chip->capture_streams; err = snd_hda_codec_prepare(apcm->codec, hinfo, stream_tag, azx_dev->format_val, substream); unlock: if (!err) azx_dev->prepared = 1; dsp_unlock(azx_dev); return err; } static int azx_pcm_trigger(struct snd_pcm_substream *substream, int cmd) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct azx *chip = apcm->chip; struct azx_dev *azx_dev; struct snd_pcm_substream *s; int rstart = 0, start, nsync = 0, sbits = 0; int nwait, timeout; azx_dev = get_azx_dev(substream); trace_azx_pcm_trigger(chip, azx_dev, cmd); if (dsp_is_locked(azx_dev) || !azx_dev->prepared) return -EPIPE; switch (cmd) { case SNDRV_PCM_TRIGGER_START: rstart = 1; case SNDRV_PCM_TRIGGER_PAUSE_RELEASE: case SNDRV_PCM_TRIGGER_RESUME: start = 1; break; case SNDRV_PCM_TRIGGER_PAUSE_PUSH: case SNDRV_PCM_TRIGGER_SUSPEND: case SNDRV_PCM_TRIGGER_STOP: start = 0; break; default: return -EINVAL; } snd_pcm_group_for_each_entry(s, substream) { if (s->pcm->card != substream->pcm->card) continue; azx_dev = get_azx_dev(s); sbits |= 1 << azx_dev->index; nsync++; snd_pcm_trigger_done(s, substream); } spin_lock(&chip->reg_lock); /* first, set SYNC bits of corresponding streams */ if (chip->driver_caps & AZX_DCAPS_OLD_SSYNC) azx_writel(chip, OLD_SSYNC, azx_readl(chip, OLD_SSYNC) | sbits); else azx_writel(chip, SSYNC, azx_readl(chip, SSYNC) | sbits); snd_pcm_group_for_each_entry(s, substream) { if (s->pcm->card != substream->pcm->card) continue; azx_dev = get_azx_dev(s); if (start) { azx_dev->start_wallclk = azx_readl(chip, WALLCLK); if (!rstart) azx_dev->start_wallclk -= azx_dev->period_wallclk; azx_stream_start(chip, azx_dev); } else { azx_stream_stop(chip, azx_dev); } azx_dev->running = start; } spin_unlock(&chip->reg_lock); if (start) { /* wait until all FIFOs get ready */ for (timeout = 5000; timeout; timeout--) { nwait = 0; snd_pcm_group_for_each_entry(s, substream) { if (s->pcm->card != substream->pcm->card) continue; azx_dev = get_azx_dev(s); if (!(azx_sd_readb(chip, azx_dev, SD_STS) & SD_STS_FIFO_READY)) nwait++; } if (!nwait) break; cpu_relax(); } } else { /* wait until all RUN bits are cleared */ for (timeout = 5000; timeout; timeout--) { nwait = 0; snd_pcm_group_for_each_entry(s, substream) { if (s->pcm->card != substream->pcm->card) continue; azx_dev = get_azx_dev(s); if (azx_sd_readb(chip, azx_dev, SD_CTL) & SD_CTL_DMA_START) nwait++; } if (!nwait) break; cpu_relax(); } } spin_lock(&chip->reg_lock); /* reset SYNC bits */ if (chip->driver_caps & AZX_DCAPS_OLD_SSYNC) azx_writel(chip, OLD_SSYNC, azx_readl(chip, OLD_SSYNC) & ~sbits); else azx_writel(chip, SSYNC, azx_readl(chip, SSYNC) & ~sbits); if (start) { azx_timecounter_init(substream, 0, 0); if (nsync > 1) { cycle_t cycle_last; /* same start cycle for master and group */ azx_dev = get_azx_dev(substream); cycle_last = azx_dev->azx_tc.cycle_last; snd_pcm_group_for_each_entry(s, substream) { if (s->pcm->card != substream->pcm->card) continue; azx_timecounter_init(s, 1, cycle_last); } } } spin_unlock(&chip->reg_lock); return 0; } unsigned int azx_get_pos_lpib(struct azx *chip, struct azx_dev *azx_dev) { return azx_sd_readl(chip, azx_dev, SD_LPIB); } EXPORT_SYMBOL_GPL(azx_get_pos_lpib); unsigned int azx_get_pos_posbuf(struct azx *chip, struct azx_dev *azx_dev) { return le32_to_cpu(*azx_dev->posbuf); } EXPORT_SYMBOL_GPL(azx_get_pos_posbuf); unsigned int azx_get_position(struct azx *chip, struct azx_dev *azx_dev) { struct snd_pcm_substream *substream = azx_dev->substream; unsigned int pos; int stream = substream->stream; int delay = 0; if (chip->get_position[stream]) pos = chip->get_position[stream](chip, azx_dev); else /* use the position buffer as default */ pos = azx_get_pos_posbuf(chip, azx_dev); if (pos >= azx_dev->bufsize) pos = 0; if (substream->runtime) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct hda_pcm_stream *hinfo = apcm->hinfo[stream]; if (chip->get_delay[stream]) delay += chip->get_delay[stream](chip, azx_dev, pos); if (hinfo->ops.get_delay) delay += hinfo->ops.get_delay(hinfo, apcm->codec, substream); substream->runtime->delay = delay; } trace_azx_get_position(chip, azx_dev, pos, delay); return pos; } EXPORT_SYMBOL_GPL(azx_get_position); static snd_pcm_uframes_t azx_pcm_pointer(struct snd_pcm_substream *substream) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct azx *chip = apcm->chip; struct azx_dev *azx_dev = get_azx_dev(substream); return bytes_to_frames(substream->runtime, azx_get_position(chip, azx_dev)); } static int azx_get_wallclock_tstamp(struct snd_pcm_substream *substream, struct timespec *ts) { struct azx_dev *azx_dev = get_azx_dev(substream); u64 nsec; nsec = timecounter_read(&azx_dev->azx_tc); nsec = div_u64(nsec, 3); /* can be optimized */ nsec = azx_adjust_codec_delay(substream, nsec); *ts = ns_to_timespec(nsec); return 0; } static struct snd_pcm_hardware azx_pcm_hw = { .info = (SNDRV_PCM_INFO_MMAP | SNDRV_PCM_INFO_INTERLEAVED | SNDRV_PCM_INFO_BLOCK_TRANSFER | SNDRV_PCM_INFO_MMAP_VALID | /* No full-resume yet implemented */ /* SNDRV_PCM_INFO_RESUME |*/ SNDRV_PCM_INFO_PAUSE | SNDRV_PCM_INFO_SYNC_START | SNDRV_PCM_INFO_HAS_WALL_CLOCK | SNDRV_PCM_INFO_NO_PERIOD_WAKEUP), .formats = SNDRV_PCM_FMTBIT_S16_LE, .rates = SNDRV_PCM_RATE_48000, .rate_min = 48000, .rate_max = 48000, .channels_min = 2, .channels_max = 2, .buffer_bytes_max = AZX_MAX_BUF_SIZE, .period_bytes_min = 128, .period_bytes_max = AZX_MAX_BUF_SIZE / 2, .periods_min = 2, .periods_max = AZX_MAX_FRAG, .fifo_size = 0, }; static int azx_pcm_open(struct snd_pcm_substream *substream) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct hda_pcm_stream *hinfo = apcm->hinfo[substream->stream]; struct azx *chip = apcm->chip; struct azx_dev *azx_dev; struct snd_pcm_runtime *runtime = substream->runtime; unsigned long flags; int err; int buff_step; mutex_lock(&chip->open_mutex); azx_dev = azx_assign_device(chip, substream); if (azx_dev == NULL) { mutex_unlock(&chip->open_mutex); return -EBUSY; } runtime->hw = azx_pcm_hw; runtime->hw.channels_min = hinfo->channels_min; runtime->hw.channels_max = hinfo->channels_max; runtime->hw.formats = hinfo->formats; runtime->hw.rates = hinfo->rates; snd_pcm_limit_hw_rates(runtime); snd_pcm_hw_constraint_integer(runtime, SNDRV_PCM_HW_PARAM_PERIODS); /* avoid wrap-around with wall-clock */ snd_pcm_hw_constraint_minmax(runtime, SNDRV_PCM_HW_PARAM_BUFFER_TIME, 20, 178000000); if (chip->align_buffer_size) /* constrain buffer sizes to be multiple of 128 bytes. This is more efficient in terms of memory access but isn't required by the HDA spec and prevents users from specifying exact period/buffer sizes. For example for 44.1kHz, a period size set to 20ms will be rounded to 19.59ms. */ buff_step = 128; else /* Don't enforce steps on buffer sizes, still need to be multiple of 4 bytes (HDA spec). Tested on Intel HDA controllers, may not work on all devices where option needs to be disabled */ buff_step = 4; snd_pcm_hw_constraint_step(runtime, 0, SNDRV_PCM_HW_PARAM_BUFFER_BYTES, buff_step); snd_pcm_hw_constraint_step(runtime, 0, SNDRV_PCM_HW_PARAM_PERIOD_BYTES, buff_step); snd_hda_power_up_d3wait(apcm->codec); err = hinfo->ops.open(hinfo, apcm->codec, substream); if (err < 0) { azx_release_device(azx_dev); snd_hda_power_down(apcm->codec); mutex_unlock(&chip->open_mutex); return err; } snd_pcm_limit_hw_rates(runtime); /* sanity check */ if (snd_BUG_ON(!runtime->hw.channels_min) || snd_BUG_ON(!runtime->hw.channels_max) || snd_BUG_ON(!runtime->hw.formats) || snd_BUG_ON(!runtime->hw.rates)) { azx_release_device(azx_dev); hinfo->ops.close(hinfo, apcm->codec, substream); snd_hda_power_down(apcm->codec); mutex_unlock(&chip->open_mutex); return -EINVAL; } /* disable WALLCLOCK timestamps for capture streams until we figure out how to handle digital inputs */ if (substream->stream == SNDRV_PCM_STREAM_CAPTURE) runtime->hw.info &= ~SNDRV_PCM_INFO_HAS_WALL_CLOCK; spin_lock_irqsave(&chip->reg_lock, flags); azx_dev->substream = substream; azx_dev->running = 0; spin_unlock_irqrestore(&chip->reg_lock, flags); runtime->private_data = azx_dev; snd_pcm_set_sync(substream); mutex_unlock(&chip->open_mutex); return 0; } static int azx_pcm_mmap(struct snd_pcm_substream *substream, struct vm_area_struct *area) { struct azx_pcm *apcm = snd_pcm_substream_chip(substream); struct azx *chip = apcm->chip; if (chip->ops->pcm_mmap_prepare) chip->ops->pcm_mmap_prepare(substream, area); return snd_pcm_lib_default_mmap(substream, area); } static struct snd_pcm_ops azx_pcm_ops = { .open = azx_pcm_open, .close = azx_pcm_close, .ioctl = snd_pcm_lib_ioctl, .hw_params = azx_pcm_hw_params, .hw_free = azx_pcm_hw_free, .prepare = azx_pcm_prepare, .trigger = azx_pcm_trigger, .pointer = azx_pcm_pointer, .wall_clock = azx_get_wallclock_tstamp, .mmap = azx_pcm_mmap, .page = snd_pcm_sgbuf_ops_page, }; static void azx_pcm_free(struct snd_pcm *pcm) { struct azx_pcm *apcm = pcm->private_data; if (apcm) { list_del(&apcm->list); kfree(apcm); } } #define MAX_PREALLOC_SIZE (32 * 1024 * 1024) static int azx_attach_pcm_stream(struct hda_bus *bus, struct hda_codec *codec, struct hda_pcm *cpcm) { struct azx *chip = bus->private_data; struct snd_pcm *pcm; struct azx_pcm *apcm; int pcm_dev = cpcm->device; unsigned int size; int s, err; list_for_each_entry(apcm, &chip->pcm_list, list) { if (apcm->pcm->device == pcm_dev) { dev_err(chip->card->dev, "PCM %d already exists\n", pcm_dev); return -EBUSY; } } err = snd_pcm_new(chip->card, cpcm->name, pcm_dev, cpcm->stream[SNDRV_PCM_STREAM_PLAYBACK].substreams, cpcm->stream[SNDRV_PCM_STREAM_CAPTURE].substreams, &pcm); if (err < 0) return err; strlcpy(pcm->name, cpcm->name, sizeof(pcm->name)); apcm = kzalloc(sizeof(*apcm), GFP_KERNEL); if (apcm == NULL) return -ENOMEM; apcm->chip = chip; apcm->pcm = pcm; apcm->codec = codec; pcm->private_data = apcm; pcm->private_free = azx_pcm_free; if (cpcm->pcm_type == HDA_PCM_TYPE_MODEM) pcm->dev_class = SNDRV_PCM_CLASS_MODEM; list_add_tail(&apcm->list, &chip->pcm_list); cpcm->pcm = pcm; for (s = 0; s < 2; s++) { apcm->hinfo[s] = &cpcm->stream[s]; if (cpcm->stream[s].substreams) snd_pcm_set_ops(pcm, s, &azx_pcm_ops); } /* buffer pre-allocation */ size = CONFIG_SND_HDA_PREALLOC_SIZE * 1024; if (size > MAX_PREALLOC_SIZE) size = MAX_PREALLOC_SIZE; snd_pcm_lib_preallocate_pages_for_all(pcm, SNDRV_DMA_TYPE_DEV_SG, chip->card->dev, size, MAX_PREALLOC_SIZE); /* link to codec */ pcm->dev = &codec->dev; return 0; } /* * CORB / RIRB interface */ static int azx_alloc_cmd_io(struct azx *chip) { int err; /* single page (at least 4096 bytes) must suffice for both ringbuffes */ err = chip->ops->dma_alloc_pages(chip, SNDRV_DMA_TYPE_DEV, PAGE_SIZE, &chip->rb); if (err < 0) dev_err(chip->card->dev, "cannot allocate CORB/RIRB\n"); return err; } static void azx_init_cmd_io(struct azx *chip) { int timeout; spin_lock_irq(&chip->reg_lock); /* CORB set up */ chip->corb.addr = chip->rb.addr; chip->corb.buf = (u32 *)chip->rb.area; azx_writel(chip, CORBLBASE, (u32)chip->corb.addr); azx_writel(chip, CORBUBASE, upper_32_bits(chip->corb.addr)); /* set the corb size to 256 entries (ULI requires explicitly) */ azx_writeb(chip, CORBSIZE, 0x02); /* set the corb write pointer to 0 */ azx_writew(chip, CORBWP, 0); /* reset the corb hw read pointer */ azx_writew(chip, CORBRP, AZX_CORBRP_RST); if (!(chip->driver_caps & AZX_DCAPS_CORBRP_SELF_CLEAR)) { for (timeout = 1000; timeout > 0; timeout--) { if ((azx_readw(chip, CORBRP) & AZX_CORBRP_RST) == AZX_CORBRP_RST) break; udelay(1); } if (timeout <= 0) dev_err(chip->card->dev, "CORB reset timeout#1, CORBRP = %d\n", azx_readw(chip, CORBRP)); azx_writew(chip, CORBRP, 0); for (timeout = 1000; timeout > 0; timeout--) { if (azx_readw(chip, CORBRP) == 0) break; udelay(1); } if (timeout <= 0) dev_err(chip->card->dev, "CORB reset timeout#2, CORBRP = %d\n", azx_readw(chip, CORBRP)); } /* enable corb dma */ azx_writeb(chip, CORBCTL, AZX_CORBCTL_RUN); /* RIRB set up */ chip->rirb.addr = chip->rb.addr + 2048; chip->rirb.buf = (u32 *)(chip->rb.area + 2048); chip->rirb.wp = chip->rirb.rp = 0; memset(chip->rirb.cmds, 0, sizeof(chip->rirb.cmds)); azx_writel(chip, RIRBLBASE, (u32)chip->rirb.addr); azx_writel(chip, RIRBUBASE, upper_32_bits(chip->rirb.addr)); /* set the rirb size to 256 entries (ULI requires explicitly) */ azx_writeb(chip, RIRBSIZE, 0x02); /* reset the rirb hw write pointer */ azx_writew(chip, RIRBWP, AZX_RIRBWP_RST); /* set N=1, get RIRB response interrupt for new entry */ if (chip->driver_caps & AZX_DCAPS_CTX_WORKAROUND) azx_writew(chip, RINTCNT, 0xc0); else azx_writew(chip, RINTCNT, 1); /* enable rirb dma and response irq */ azx_writeb(chip, RIRBCTL, AZX_RBCTL_DMA_EN | AZX_RBCTL_IRQ_EN); spin_unlock_irq(&chip->reg_lock); } static void azx_free_cmd_io(struct azx *chip) { spin_lock_irq(&chip->reg_lock); /* disable ringbuffer DMAs */ azx_writeb(chip, RIRBCTL, 0); azx_writeb(chip, CORBCTL, 0); spin_unlock_irq(&chip->reg_lock); } static unsigned int azx_command_addr(u32 cmd) { unsigned int addr = cmd >> 28; if (addr >= AZX_MAX_CODECS) { snd_BUG(); addr = 0; } return addr; } /* send a command */ static int azx_corb_send_cmd(struct hda_bus *bus, u32 val) { struct azx *chip = bus->private_data; unsigned int addr = azx_command_addr(val); unsigned int wp, rp; spin_lock_irq(&chip->reg_lock); /* add command to corb */ wp = azx_readw(chip, CORBWP); if (wp == 0xffff) { /* something wrong, controller likely turned to D3 */ spin_unlock_irq(&chip->reg_lock); return -EIO; } wp++; wp %= AZX_MAX_CORB_ENTRIES; rp = azx_readw(chip, CORBRP); if (wp == rp) { /* oops, it's full */ spin_unlock_irq(&chip->reg_lock); return -EAGAIN; } chip->rirb.cmds[addr]++; chip->corb.buf[wp] = cpu_to_le32(val); azx_writew(chip, CORBWP, wp); spin_unlock_irq(&chip->reg_lock); return 0; } #define AZX_RIRB_EX_UNSOL_EV (1<<4) /* retrieve RIRB entry - called from interrupt handler */ static void azx_update_rirb(struct azx *chip) { unsigned int rp, wp; unsigned int addr; u32 res, res_ex; wp = azx_readw(chip, RIRBWP); if (wp == 0xffff) { /* something wrong, controller likely turned to D3 */ return; } if (wp == chip->rirb.wp) return; chip->rirb.wp = wp; while (chip->rirb.rp != wp) { chip->rirb.rp++; chip->rirb.rp %= AZX_MAX_RIRB_ENTRIES; rp = chip->rirb.rp << 1; /* an RIRB entry is 8-bytes */ res_ex = le32_to_cpu(chip->rirb.buf[rp + 1]); res = le32_to_cpu(chip->rirb.buf[rp]); addr = res_ex & 0xf; if ((addr >= AZX_MAX_CODECS) || !(chip->codec_mask & (1 << addr))) { dev_err(chip->card->dev, "spurious response %#x:%#x, rp = %d, wp = %d", res, res_ex, chip->rirb.rp, wp); snd_BUG(); } else if (res_ex & AZX_RIRB_EX_UNSOL_EV) snd_hda_queue_unsol_event(chip->bus, res, res_ex); else if (chip->rirb.cmds[addr]) { chip->rirb.res[addr] = res; smp_wmb(); chip->rirb.cmds[addr]--; } else if (printk_ratelimit()) { dev_err(chip->card->dev, "spurious response %#x:%#x, last cmd=%#08x\n", res, res_ex, chip->last_cmd[addr]); } } } /* receive a response */ static unsigned int azx_rirb_get_response(struct hda_bus *bus, unsigned int addr) { struct azx *chip = bus->private_data; unsigned long timeout; unsigned long loopcounter; int do_poll = 0; again: timeout = jiffies + msecs_to_jiffies(1000); for (loopcounter = 0;; loopcounter++) { if (chip->polling_mode || do_poll) { spin_lock_irq(&chip->reg_lock); azx_update_rirb(chip); spin_unlock_irq(&chip->reg_lock); } if (!chip->rirb.cmds[addr]) { smp_rmb(); bus->rirb_error = 0; if (!do_poll) chip->poll_count = 0; return chip->rirb.res[addr]; /* the last value */ } if (time_after(jiffies, timeout)) break; if (bus->needs_damn_long_delay || loopcounter > 3000) msleep(2); /* temporary workaround */ else { udelay(10); cond_resched(); } } if (bus->no_response_fallback) return -1; if (!chip->polling_mode && chip->poll_count < 2) { dev_dbg(chip->card->dev, "azx_get_response timeout, polling the codec once: last cmd=0x%08x\n", chip->last_cmd[addr]); do_poll = 1; chip->poll_count++; goto again; } if (!chip->polling_mode) { dev_warn(chip->card->dev, "azx_get_response timeout, switching to polling mode: last cmd=0x%08x\n", chip->last_cmd[addr]); chip->polling_mode = 1; goto again; } if (chip->msi) { dev_warn(chip->card->dev, "No response from codec, disabling MSI: last cmd=0x%08x\n", chip->last_cmd[addr]); if (chip->ops->disable_msi_reset_irq(chip) && chip->ops->disable_msi_reset_irq(chip) < 0) { bus->rirb_error = 1; return -1; } goto again; } if (chip->probing) { /* If this critical timeout happens during the codec probing * phase, this is likely an access to a non-existing codec * slot. Better to return an error and reset the system. */ return -1; } /* a fatal communication error; need either to reset or to fallback * to the single_cmd mode */ bus->rirb_error = 1; if (bus->allow_bus_reset && !bus->response_reset && !bus->in_reset) { bus->response_reset = 1; return -1; /* give a chance to retry */ } dev_err(chip->card->dev, "azx_get_response timeout, switching to single_cmd mode: last cmd=0x%08x\n", chip->last_cmd[addr]); chip->single_cmd = 1; bus->response_reset = 0; /* release CORB/RIRB */ azx_free_cmd_io(chip); /* disable unsolicited responses */ azx_writel(chip, GCTL, azx_readl(chip, GCTL) & ~AZX_GCTL_UNSOL); return -1; } /* * Use the single immediate command instead of CORB/RIRB for simplicity * * Note: according to Intel, this is not preferred use. The command was * intended for the BIOS only, and may get confused with unsolicited * responses. So, we shouldn't use it for normal operation from the * driver. * I left the codes, however, for debugging/testing purposes. */ /* receive a response */ static int azx_single_wait_for_response(struct azx *chip, unsigned int addr) { int timeout = 50; while (timeout--) { /* check IRV busy bit */ if (azx_readw(chip, IRS) & AZX_IRS_VALID) { /* reuse rirb.res as the response return value */ chip->rirb.res[addr] = azx_readl(chip, IR); return 0; } udelay(1); } if (printk_ratelimit()) dev_dbg(chip->card->dev, "get_response timeout: IRS=0x%x\n", azx_readw(chip, IRS)); chip->rirb.res[addr] = -1; return -EIO; } /* send a command */ static int azx_single_send_cmd(struct hda_bus *bus, u32 val) { struct azx *chip = bus->private_data; unsigned int addr = azx_command_addr(val); int timeout = 50; bus->rirb_error = 0; while (timeout--) { /* check ICB busy bit */ if (!((azx_readw(chip, IRS) & AZX_IRS_BUSY))) { /* Clear IRV valid bit */ azx_writew(chip, IRS, azx_readw(chip, IRS) | AZX_IRS_VALID); azx_writel(chip, IC, val); azx_writew(chip, IRS, azx_readw(chip, IRS) | AZX_IRS_BUSY); return azx_single_wait_for_response(chip, addr); } udelay(1); } if (printk_ratelimit()) dev_dbg(chip->card->dev, "send_cmd timeout: IRS=0x%x, val=0x%x\n", azx_readw(chip, IRS), val); return -EIO; } /* receive a response */ static unsigned int azx_single_get_response(struct hda_bus *bus, unsigned int addr) { struct azx *chip = bus->private_data; return chip->rirb.res[addr]; } /* * The below are the main callbacks from hda_codec. * * They are just the skeleton to call sub-callbacks according to the * current setting of chip->single_cmd. */ /* send a command */ static int azx_send_cmd(struct hda_bus *bus, unsigned int val) { struct azx *chip = bus->private_data; if (chip->disabled) return 0; chip->last_cmd[azx_command_addr(val)] = val; if (chip->single_cmd) return azx_single_send_cmd(bus, val); else return azx_corb_send_cmd(bus, val); } /* get a response */ static unsigned int azx_get_response(struct hda_bus *bus, unsigned int addr) { struct azx *chip = bus->private_data; if (chip->disabled) return 0; if (chip->single_cmd) return azx_single_get_response(bus, addr); else return azx_rirb_get_response(bus, addr); } #ifdef CONFIG_SND_HDA_DSP_LOADER /* * DSP loading code (e.g. for CA0132) */ /* use the first stream for loading DSP */ static struct azx_dev * azx_get_dsp_loader_dev(struct azx *chip) { return &chip->azx_dev[chip->playback_index_offset]; } static int azx_load_dsp_prepare(struct hda_bus *bus, unsigned int format, unsigned int byte_size, struct snd_dma_buffer *bufp) { u32 *bdl; struct azx *chip = bus->private_data; struct azx_dev *azx_dev; int err; azx_dev = azx_get_dsp_loader_dev(chip); dsp_lock(azx_dev); spin_lock_irq(&chip->reg_lock); if (azx_dev->running || azx_dev->locked) { spin_unlock_irq(&chip->reg_lock); err = -EBUSY; goto unlock; } azx_dev->prepared = 0; chip->saved_azx_dev = *azx_dev; azx_dev->locked = 1; spin_unlock_irq(&chip->reg_lock); err = chip->ops->dma_alloc_pages(chip, SNDRV_DMA_TYPE_DEV_SG, byte_size, bufp); if (err < 0) goto err_alloc; azx_dev->bufsize = byte_size; azx_dev->period_bytes = byte_size; azx_dev->format_val = format; azx_stream_reset(chip, azx_dev); /* reset BDL address */ azx_sd_writel(chip, azx_dev, SD_BDLPL, 0); azx_sd_writel(chip, azx_dev, SD_BDLPU, 0); azx_dev->frags = 0; bdl = (u32 *)azx_dev->bdl.area; err = setup_bdle(chip, bufp, azx_dev, &bdl, 0, byte_size, 0); if (err < 0) goto error; azx_setup_controller(chip, azx_dev); dsp_unlock(azx_dev); return azx_dev->stream_tag; error: chip->ops->dma_free_pages(chip, bufp); err_alloc: spin_lock_irq(&chip->reg_lock); if (azx_dev->opened) *azx_dev = chip->saved_azx_dev; azx_dev->locked = 0; spin_unlock_irq(&chip->reg_lock); unlock: dsp_unlock(azx_dev); return err; } static void azx_load_dsp_trigger(struct hda_bus *bus, bool start) { struct azx *chip = bus->private_data; struct azx_dev *azx_dev = azx_get_dsp_loader_dev(chip); if (start) azx_stream_start(chip, azx_dev); else azx_stream_stop(chip, azx_dev); azx_dev->running = start; } static void azx_load_dsp_cleanup(struct hda_bus *bus, struct snd_dma_buffer *dmab) { struct azx *chip = bus->private_data; struct azx_dev *azx_dev = azx_get_dsp_loader_dev(chip); if (!dmab->area || !azx_dev->locked) return; dsp_lock(azx_dev); /* reset BDL address */ azx_sd_writel(chip, azx_dev, SD_BDLPL, 0); azx_sd_writel(chip, azx_dev, SD_BDLPU, 0); azx_sd_writel(chip, azx_dev, SD_CTL, 0); azx_dev->bufsize = 0; azx_dev->period_bytes = 0; azx_dev->format_val = 0; chip->ops->dma_free_pages(chip, dmab); dmab->area = NULL; spin_lock_irq(&chip->reg_lock); if (azx_dev->opened) *azx_dev = chip->saved_azx_dev; azx_dev->locked = 0; spin_unlock_irq(&chip->reg_lock); dsp_unlock(azx_dev); } #endif /* CONFIG_SND_HDA_DSP_LOADER */ int azx_alloc_stream_pages(struct azx *chip) { int i, err; struct snd_card *card = chip->card; for (i = 0; i < chip->num_streams; i++) { dsp_lock_init(&chip->azx_dev[i]); /* allocate memory for the BDL for each stream */ err = chip->ops->dma_alloc_pages(chip, SNDRV_DMA_TYPE_DEV, BDL_SIZE, &chip->azx_dev[i].bdl); if (err < 0) { dev_err(card->dev, "cannot allocate BDL\n"); return -ENOMEM; } } /* allocate memory for the position buffer */ err = chip->ops->dma_alloc_pages(chip, SNDRV_DMA_TYPE_DEV, chip->num_streams * 8, &chip->posbuf); if (err < 0) { dev_err(card->dev, "cannot allocate posbuf\n"); return -ENOMEM; } /* allocate CORB/RIRB */ err = azx_alloc_cmd_io(chip); if (err < 0) return err; return 0; } EXPORT_SYMBOL_GPL(azx_alloc_stream_pages); void azx_free_stream_pages(struct azx *chip) { int i; if (chip->azx_dev) { for (i = 0; i < chip->num_streams; i++) if (chip->azx_dev[i].bdl.area) chip->ops->dma_free_pages( chip, &chip->azx_dev[i].bdl); } if (chip->rb.area) chip->ops->dma_free_pages(chip, &chip->rb); if (chip->posbuf.area) chip->ops->dma_free_pages(chip, &chip->posbuf); } EXPORT_SYMBOL_GPL(azx_free_stream_pages); /* * Lowlevel interface */ /* enter link reset */ void azx_enter_link_reset(struct azx *chip) { unsigned long timeout; /* reset controller */ azx_writel(chip, GCTL, azx_readl(chip, GCTL) & ~AZX_GCTL_RESET); timeout = jiffies + msecs_to_jiffies(100); while ((azx_readb(chip, GCTL) & AZX_GCTL_RESET) && time_before(jiffies, timeout)) usleep_range(500, 1000); } EXPORT_SYMBOL_GPL(azx_enter_link_reset); /* exit link reset */ static void azx_exit_link_reset(struct azx *chip) { unsigned long timeout; azx_writeb(chip, GCTL, azx_readb(chip, GCTL) | AZX_GCTL_RESET); timeout = jiffies + msecs_to_jiffies(100); while (!azx_readb(chip, GCTL) && time_before(jiffies, timeout)) usleep_range(500, 1000); } /* reset codec link */ static int azx_reset(struct azx *chip, bool full_reset) { if (!full_reset) goto __skip; /* clear STATESTS */ azx_writew(chip, STATESTS, STATESTS_INT_MASK); /* reset controller */ azx_enter_link_reset(chip); /* delay for >= 100us for codec PLL to settle per spec * Rev 0.9 section 5.5.1 */ usleep_range(500, 1000); /* Bring controller out of reset */ azx_exit_link_reset(chip); /* Brent Chartrand said to wait >= 540us for codecs to initialize */ usleep_range(1000, 1200); __skip: /* check to see if controller is ready */ if (!azx_readb(chip, GCTL)) { dev_dbg(chip->card->dev, "azx_reset: controller not ready!\n"); return -EBUSY; } /* Accept unsolicited responses */ if (!chip->single_cmd) azx_writel(chip, GCTL, azx_readl(chip, GCTL) | AZX_GCTL_UNSOL); /* detect codecs */ if (!chip->codec_mask) { chip->codec_mask = azx_readw(chip, STATESTS); dev_dbg(chip->card->dev, "codec_mask = 0x%x\n", chip->codec_mask); } return 0; } /* enable interrupts */ static void azx_int_enable(struct azx *chip) { /* enable controller CIE and GIE */ azx_writel(chip, INTCTL, azx_readl(chip, INTCTL) | AZX_INT_CTRL_EN | AZX_INT_GLOBAL_EN); } /* disable interrupts */ static void azx_int_disable(struct azx *chip) { int i; /* disable interrupts in stream descriptor */ for (i = 0; i < chip->num_streams; i++) { struct azx_dev *azx_dev = &chip->azx_dev[i]; azx_sd_writeb(chip, azx_dev, SD_CTL, azx_sd_readb(chip, azx_dev, SD_CTL) & ~SD_INT_MASK); } /* disable SIE for all streams */ azx_writeb(chip, INTCTL, 0); /* disable controller CIE and GIE */ azx_writel(chip, INTCTL, azx_readl(chip, INTCTL) & ~(AZX_INT_CTRL_EN | AZX_INT_GLOBAL_EN)); } /* clear interrupts */ static void azx_int_clear(struct azx *chip) { int i; /* clear stream status */ for (i = 0; i < chip->num_streams; i++) { struct azx_dev *azx_dev = &chip->azx_dev[i]; azx_sd_writeb(chip, azx_dev, SD_STS, SD_INT_MASK); } /* clear STATESTS */ azx_writew(chip, STATESTS, STATESTS_INT_MASK); /* clear rirb status */ azx_writeb(chip, RIRBSTS, RIRB_INT_MASK); /* clear int status */ azx_writel(chip, INTSTS, AZX_INT_CTRL_EN | AZX_INT_ALL_STREAM); } /* * reset and start the controller registers */ void azx_init_chip(struct azx *chip, bool full_reset) { if (chip->initialized) return; /* reset controller */ azx_reset(chip, full_reset); /* initialize interrupts */ azx_int_clear(chip); azx_int_enable(chip); /* initialize the codec command I/O */ if (!chip->single_cmd) azx_init_cmd_io(chip); /* program the position buffer */ azx_writel(chip, DPLBASE, (u32)chip->posbuf.addr); azx_writel(chip, DPUBASE, upper_32_bits(chip->posbuf.addr)); chip->initialized = 1; } EXPORT_SYMBOL_GPL(azx_init_chip); void azx_stop_chip(struct azx *chip) { if (!chip->initialized) return; /* disable interrupts */ azx_int_disable(chip); azx_int_clear(chip); /* disable CORB/RIRB */ azx_free_cmd_io(chip); /* disable position buffer */ azx_writel(chip, DPLBASE, 0); azx_writel(chip, DPUBASE, 0); chip->initialized = 0; } EXPORT_SYMBOL_GPL(azx_stop_chip); /* * interrupt handler */ irqreturn_t azx_interrupt(int irq, void *dev_id) { struct azx *chip = dev_id; struct azx_dev *azx_dev; u32 status; u8 sd_status; int i; #ifdef CONFIG_PM_RUNTIME if (chip->driver_caps & AZX_DCAPS_PM_RUNTIME) if (!pm_runtime_active(chip->card->dev)) return IRQ_NONE; #endif spin_lock(&chip->reg_lock); if (chip->disabled) { spin_unlock(&chip->reg_lock); return IRQ_NONE; } status = azx_readl(chip, INTSTS); if (status == 0 || status == 0xffffffff) { spin_unlock(&chip->reg_lock); return IRQ_NONE; } for (i = 0; i < chip->num_streams; i++) { azx_dev = &chip->azx_dev[i]; if (status & azx_dev->sd_int_sta_mask) { sd_status = azx_sd_readb(chip, azx_dev, SD_STS); azx_sd_writeb(chip, azx_dev, SD_STS, SD_INT_MASK); if (!azx_dev->substream || !azx_dev->running || !(sd_status & SD_INT_COMPLETE)) continue; /* check whether this IRQ is really acceptable */ if (!chip->ops->position_check || chip->ops->position_check(chip, azx_dev)) { spin_unlock(&chip->reg_lock); snd_pcm_period_elapsed(azx_dev->substream); spin_lock(&chip->reg_lock); } } } /* clear rirb int */ status = azx_readb(chip, RIRBSTS); if (status & RIRB_INT_MASK) { if (status & RIRB_INT_RESPONSE) { if (chip->driver_caps & AZX_DCAPS_RIRB_PRE_DELAY) udelay(80); azx_update_rirb(chip); } azx_writeb(chip, RIRBSTS, RIRB_INT_MASK); } spin_unlock(&chip->reg_lock); return IRQ_HANDLED; } EXPORT_SYMBOL_GPL(azx_interrupt); /* * Codec initerface */ /* * Probe the given codec address */ static int probe_codec(struct azx *chip, int addr) { unsigned int cmd = (addr << 28) | (AC_NODE_ROOT << 20) | (AC_VERB_PARAMETERS << 8) | AC_PAR_VENDOR_ID; unsigned int res; mutex_lock(&chip->bus->cmd_mutex); chip->probing = 1; azx_send_cmd(chip->bus, cmd); res = azx_get_response(chip->bus, addr); chip->probing = 0; mutex_unlock(&chip->bus->cmd_mutex); if (res == -1) return -EIO; dev_dbg(chip->card->dev, "codec #%d probed OK\n", addr); return 0; } static void azx_bus_reset(struct hda_bus *bus) { struct azx *chip = bus->private_data; bus->in_reset = 1; azx_stop_chip(chip); azx_init_chip(chip, true); #ifdef CONFIG_PM if (chip->initialized) { struct azx_pcm *p; list_for_each_entry(p, &chip->pcm_list, list) snd_pcm_suspend_all(p->pcm); snd_hda_suspend(chip->bus); snd_hda_resume(chip->bus); } #endif bus->in_reset = 0; } #ifdef CONFIG_PM /* power-up/down the controller */ static void azx_power_notify(struct hda_bus *bus, bool power_up) { struct azx *chip = bus->private_data; if (!(chip->driver_caps & AZX_DCAPS_PM_RUNTIME)) return; if (power_up) pm_runtime_get_sync(chip->card->dev); else pm_runtime_put_sync(chip->card->dev); } #endif static int get_jackpoll_interval(struct azx *chip) { int i; unsigned int j; if (!chip->jackpoll_ms) return 0; i = chip->jackpoll_ms[chip->dev_index]; if (i == 0) return 0; if (i < 50 || i > 60000) j = 0; else j = msecs_to_jiffies(i); if (j == 0) dev_warn(chip->card->dev, "jackpoll_ms value out of range: %d\n", i); return j; } /* Codec initialization */ int azx_codec_create(struct azx *chip, const char *model, unsigned int max_slots, int *power_save_to) { struct hda_bus_template bus_temp; int c, codecs, err; memset(&bus_temp, 0, sizeof(bus_temp)); bus_temp.private_data = chip; bus_temp.modelname = model; bus_temp.pci = chip->pci; bus_temp.ops.command = azx_send_cmd; bus_temp.ops.get_response = azx_get_response; bus_temp.ops.attach_pcm = azx_attach_pcm_stream; bus_temp.ops.bus_reset = azx_bus_reset; #ifdef CONFIG_PM bus_temp.power_save = power_save_to; bus_temp.ops.pm_notify = azx_power_notify; #endif #ifdef CONFIG_SND_HDA_DSP_LOADER bus_temp.ops.load_dsp_prepare = azx_load_dsp_prepare; bus_temp.ops.load_dsp_trigger = azx_load_dsp_trigger; bus_temp.ops.load_dsp_cleanup = azx_load_dsp_cleanup; #endif err = snd_hda_bus_new(chip->card, &bus_temp, &chip->bus); if (err < 0) return err; if (chip->driver_caps & AZX_DCAPS_RIRB_DELAY) { dev_dbg(chip->card->dev, "Enable delay in RIRB handling\n"); chip->bus->needs_damn_long_delay = 1; } codecs = 0; if (!max_slots) max_slots = AZX_DEFAULT_CODECS; /* First try to probe all given codec slots */ for (c = 0; c < max_slots; c++) { if ((chip->codec_mask & (1 << c)) & chip->codec_probe_mask) { if (probe_codec(chip, c) < 0) { /* Some BIOSen give you wrong codec addresses * that don't exist */ dev_warn(chip->card->dev, "Codec #%d probe error; disabling it...\n", c); chip->codec_mask &= ~(1 << c); /* More badly, accessing to a non-existing * codec often screws up the controller chip, * and disturbs the further communications. * Thus if an error occurs during probing, * better to reset the controller chip to * get back to the sanity state. */ azx_stop_chip(chip); azx_init_chip(chip, true); } } } /* AMD chipsets often cause the communication stalls upon certain * sequence like the pin-detection. It seems that forcing the synced * access works around the stall. Grrr... */ if (chip->driver_caps & AZX_DCAPS_SYNC_WRITE) { dev_dbg(chip->card->dev, "Enable sync_write for stable communication\n"); chip->bus->sync_write = 1; chip->bus->allow_bus_reset = 1; } /* Then create codec instances */ for (c = 0; c < max_slots; c++) { if ((chip->codec_mask & (1 << c)) & chip->codec_probe_mask) { struct hda_codec *codec; err = snd_hda_codec_new(chip->bus, c, &codec); if (err < 0) continue; codec->jackpoll_interval = get_jackpoll_interval(chip); codec->beep_mode = chip->beep_mode; codecs++; } } if (!codecs) { dev_err(chip->card->dev, "no codecs initialized\n"); return -ENXIO; } return 0; } EXPORT_SYMBOL_GPL(azx_codec_create); /* configure each codec instance */ int azx_codec_configure(struct azx *chip) { struct hda_codec *codec; list_for_each_entry(codec, &chip->bus->codec_list, list) { snd_hda_codec_configure(codec); } return 0; } EXPORT_SYMBOL_GPL(azx_codec_configure); /* mixer creation - all stuff is implemented in hda module */ int azx_mixer_create(struct azx *chip) { return snd_hda_build_controls(chip->bus); } EXPORT_SYMBOL_GPL(azx_mixer_create); /* initialize SD streams */ int azx_init_stream(struct azx *chip) { int i; /* initialize each stream (aka device) * assign the starting bdl address to each stream (device) * and initialize */ for (i = 0; i < chip->num_streams; i++) { struct azx_dev *azx_dev = &chip->azx_dev[i]; azx_dev->posbuf = (u32 __iomem *)(chip->posbuf.area + i * 8); /* offset: SDI0=0x80, SDI1=0xa0, ... SDO3=0x160 */ azx_dev->sd_addr = chip->remap_addr + (0x20 * i + 0x80); /* int mask: SDI0=0x01, SDI1=0x02, ... SDO3=0x80 */ azx_dev->sd_int_sta_mask = 1 << i; /* stream tag: must be non-zero and unique */ azx_dev->index = i; azx_dev->stream_tag = i + 1; } return 0; } EXPORT_SYMBOL_GPL(azx_init_stream); /* * reboot notifier for hang-up problem at power-down */ static int azx_halt(struct notifier_block *nb, unsigned long event, void *buf) { struct azx *chip = container_of(nb, struct azx, reboot_notifier); snd_hda_bus_reboot_notify(chip->bus); azx_stop_chip(chip); return NOTIFY_OK; } void azx_notifier_register(struct azx *chip) { chip->reboot_notifier.notifier_call = azx_halt; register_reboot_notifier(&chip->reboot_notifier); } EXPORT_SYMBOL_GPL(azx_notifier_register); void azx_notifier_unregister(struct azx *chip) { if (chip->reboot_notifier.notifier_call) unregister_reboot_notifier(&chip->reboot_notifier); } EXPORT_SYMBOL_GPL(azx_notifier_unregister); MODULE_LICENSE("GPL"); MODULE_DESCRIPTION("Common HDA driver funcitons"); |