FreeBSD/Linux Kernel Cross Reference
sys/arm/freescale/vybrid/vf_sai.c

     /*-
      * Copyright (c) 2014 Ruslan Bukin <br@bsdpad.com>
      * All rights reserved.
      *
      * Redistribution and use in source and binary forms, with or without
      * modification, are permitted provided that the following conditions
      * are met:
      * 1. Redistributions of source code must retain the above copyright
      *    notice, this list of conditions and the following disclaimer.
     * 2. Redistributions in binary form must reproduce the above copyright
     *    notice, this list of conditions and the following disclaimer in the
     *    documentation and/or other materials provided with the distribution.
     *
     * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
     * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
     * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
     * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
     * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
     * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
     * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
     * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
     * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
     * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
     * SUCH DAMAGE.
     */
    
    /*
     * Vybrid Family Synchronous Audio Interface (SAI)
     * Chapter 51, Vybrid Reference Manual, Rev. 5, 07/2013
     */
    
    #include <sys/cdefs.h>
    __FBSDID("$FreeBSD: releng/10.3/sys/arm/freescale/vybrid/vf_sai.c 273652 2014-10-26 01:30:46Z ian $");
    
    #include <sys/param.h>
    #include <sys/systm.h>
    #include <sys/bus.h>
    #include <sys/kernel.h>
    #include <sys/module.h>
    #include <sys/malloc.h>
    #include <sys/rman.h>
    #include <sys/timeet.h>
    #include <sys/timetc.h>
    #include <sys/watchdog.h>
    
    #include <dev/sound/pcm/sound.h>
    #include <dev/sound/chip.h>
    #include <mixer_if.h>
    
    #include <dev/fdt/fdt_common.h>
    #include <dev/ofw/openfirm.h>
    #include <dev/ofw/ofw_bus.h>
    #include <dev/ofw/ofw_bus_subr.h>
    
    #include <machine/bus.h>
    #include <machine/fdt.h>
    #include <machine/cpu.h>
    #include <machine/intr.h>
    
    #include <arm/freescale/vybrid/vf_common.h>
    #include <arm/freescale/vybrid/vf_dmamux.h>
    #include <arm/freescale/vybrid/vf_edma.h>
    
    #define I2S_TCSR        0x00    /* SAI Transmit Control */
    #define I2S_TCR1        0x04    /* SAI Transmit Configuration 1 */
    #define I2S_TCR2        0x08    /* SAI Transmit Configuration 2 */
    #define I2S_TCR3        0x0C    /* SAI Transmit Configuration 3 */
    #define I2S_TCR4        0x10    /* SAI Transmit Configuration 4 */
    #define I2S_TCR5        0x14    /* SAI Transmit Configuration 5 */
    #define I2S_TDR0        0x20    /* SAI Transmit Data */
    #define I2S_TFR0        0x40    /* SAI Transmit FIFO */
    #define I2S_TMR         0x60    /* SAI Transmit Mask */
    #define I2S_RCSR        0x80    /* SAI Receive Control */
    #define I2S_RCR1        0x84    /* SAI Receive Configuration 1 */
    #define I2S_RCR2        0x88    /* SAI Receive Configuration 2 */
    #define I2S_RCR3        0x8C    /* SAI Receive Configuration 3 */
    #define I2S_RCR4        0x90    /* SAI Receive Configuration 4 */
    #define I2S_RCR5        0x94    /* SAI Receive Configuration 5 */
    #define I2S_RDR0        0xA0    /* SAI Receive Data */
    #define I2S_RFR0        0xC0    /* SAI Receive FIFO */
    #define I2S_RMR         0xE0    /* SAI Receive Mask */
    
    #define TCR1_TFW_M      0x1f            /* Transmit FIFO Watermark Mask */
    #define TCR1_TFW_S      0               /* Transmit FIFO Watermark Shift */
    #define TCR2_MSEL_M     0x3             /* MCLK Select Mask*/
    #define TCR2_MSEL_S     26              /* MCLK Select Shift*/
    #define TCR2_BCP        (1 << 25)       /* Bit Clock Polarity */
    #define TCR2_BCD        (1 << 24)       /* Bit Clock Direction */
    #define TCR3_TCE        (1 << 16)       /* Transmit Channel Enable */
    #define TCR4_FRSZ_M     0x1f            /* Frame size Mask */
    #define TCR4_FRSZ_S     16              /* Frame size Shift */
    #define TCR4_SYWD_M     0x1f            /* Sync Width Mask */
    #define TCR4_SYWD_S     8               /* Sync Width Shift */
    #define TCR4_MF         (1 << 4)        /* MSB First */
    #define TCR4_FSE        (1 << 3)        /* Frame Sync Early */
    #define TCR4_FSP        (1 << 1)        /* Frame Sync Polarity Low */
    #define TCR4_FSD        (1 << 0)        /* Frame Sync Direction Master */
    #define TCR5_FBT_M      0x1f            /* First Bit Shifted */
    #define TCR5_FBT_S      8               /* First Bit Shifted */
   #define TCR5_W0W_M      0x1f            /* Word 0 Width */
   #define TCR5_W0W_S      16              /* Word 0 Width */
   #define TCR5_WNW_M      0x1f            /* Word N Width */
   #define TCR5_WNW_S      24              /* Word N Width */
   #define TCSR_TE         (1 << 31)       /* Transmitter Enable */
   #define TCSR_BCE        (1 << 28)       /* Bit Clock Enable */
   #define TCSR_FRDE       (1 << 0)        /* FIFO Request DMA Enable */
   
   #define SAI_NCHANNELS   1
   
   static MALLOC_DEFINE(M_SAI, "sai", "sai audio");
   
   struct sai_rate {
           uint32_t speed;
           uint32_t div; /* Bit Clock Divide. Division value is (div + 1) * 2. */
           uint32_t mfi; /* PLL4 Multiplication Factor Integer */
           uint32_t mfn; /* PLL4 Multiplication Factor Numerator */
           uint32_t mfd; /* PLL4 Multiplication Factor Denominator */
   };
   
   /*
    * Bit clock divider formula
    * (div + 1) * 2 = MCLK/(nch * LRCLK * bits/1000000),
    * where:
    *   MCLK - master clock
    *   nch - number of channels
    *   LRCLK - left right clock
    * e.g. (div + 1) * 2 = 16.9344/(2 * 44100 * 24/1000000)
    *
    * Example for 96khz, 24bit, 18.432 Mhz mclk (192fs)
    * { 96000, 1, 18, 40176000, 93000000 },
    */
   
   static struct sai_rate rate_map[] = {
           { 44100, 7, 33, 80798400, 93000000 }, /* 33.8688 Mhz */
           { 96000, 3, 36, 80352000, 93000000 }, /* 36.864 Mhz */
           { 192000, 1, 36, 80352000, 93000000 }, /* 36.864 Mhz */
           { 0, 0 },
   };
   
   struct sc_info {
           struct resource         *res[2];
           bus_space_tag_t         bst;
           bus_space_handle_t      bsh;
           device_t                dev;
           struct mtx              *lock;
           uint32_t                speed;
           uint32_t                period;
           void                    *ih;
           int                     pos;
           int                     dma_size;
           bus_dma_tag_t           dma_tag;
           bus_dmamap_t            dma_map;
           bus_addr_t              buf_base_phys;
           uint32_t                *buf_base;
           struct tcd_conf         *tcd;
           struct sai_rate         *sr;
           struct edma_softc       *edma_sc;
           int                     edma_chnum;
   };
   
   /* Channel registers */
   struct sc_chinfo {
           struct snd_dbuf         *buffer;
           struct pcm_channel      *channel;
           struct sc_pcminfo       *parent;
   
           /* Channel information */
           uint32_t        dir;
           uint32_t        format;
   
           /* Flags */
           uint32_t        run;
   };
   
   /* PCM device private data */
   struct sc_pcminfo {
           device_t                dev;
           uint32_t                (*ih) (struct sc_pcminfo *scp);
           uint32_t                chnum;
           struct sc_chinfo        chan[SAI_NCHANNELS];
           struct sc_info          *sc;
   };
   
   static struct resource_spec sai_spec[] = {
           { SYS_RES_MEMORY,       0,      RF_ACTIVE },
           { SYS_RES_IRQ,          0,      RF_ACTIVE },
           { -1, 0 }
   };
   
   static int setup_dma(struct sc_pcminfo *scp);
   static void setup_sai(struct sc_info *);
   static void sai_configure_clock(struct sc_info *);
   
   /*
    * Mixer interface.
    */
   
   static int
   saimixer_init(struct snd_mixer *m)
   {
           struct sc_pcminfo *scp;
           struct sc_info *sc;
           int mask;
   
           scp = mix_getdevinfo(m);
           sc = scp->sc;
   
           if (sc == NULL)
                   return -1;
   
           mask = SOUND_MASK_PCM;
   
           snd_mtxlock(sc->lock);
           pcm_setflags(scp->dev, pcm_getflags(scp->dev) | SD_F_SOFTPCMVOL);
           mix_setdevs(m, mask);
           snd_mtxunlock(sc->lock);
   
           return (0);
   }
   
   static int
   saimixer_set(struct snd_mixer *m, unsigned dev,
       unsigned left, unsigned right)
   {
           struct sc_pcminfo *scp;
   
           scp = mix_getdevinfo(m);
   
   #if 0
           device_printf(scp->dev, "saimixer_set() %d %d\n",
               left, right);
   #endif
   
           return (0);
   }
   
   static kobj_method_t saimixer_methods[] = {
           KOBJMETHOD(mixer_init,      saimixer_init),
           KOBJMETHOD(mixer_set,       saimixer_set),
           KOBJMETHOD_END
   };
   MIXER_DECLARE(saimixer);
   
   /*
    * Channel interface.
    */
   
   static void *
   saichan_init(kobj_t obj, void *devinfo, struct snd_dbuf *b,
       struct pcm_channel *c, int dir)
   {
           struct sc_pcminfo *scp;
           struct sc_chinfo *ch;
           struct sc_info *sc;
   
           scp = (struct sc_pcminfo *)devinfo;
           sc = scp->sc;
   
           snd_mtxlock(sc->lock);
           ch = &scp->chan[0];
           ch->dir = dir;
           ch->run = 0;
           ch->buffer = b;
           ch->channel = c;
           ch->parent = scp;
           snd_mtxunlock(sc->lock);
   
           if (sndbuf_setup(ch->buffer, sc->buf_base, sc->dma_size) != 0) {
                   device_printf(scp->dev, "Can't setup sndbuf.\n");
                   return NULL;
           }
   
           return ch;
   }
   
   static int
   saichan_free(kobj_t obj, void *data)
   {
           struct sc_chinfo *ch = data;
           struct sc_pcminfo *scp = ch->parent;
           struct sc_info *sc = scp->sc;
   
   #if 0
           device_printf(scp->dev, "saichan_free()\n");
   #endif
   
           snd_mtxlock(sc->lock);
           /* TODO: free channel buffer */
           snd_mtxunlock(sc->lock);
   
           return (0);
   }
   
   static int
   saichan_setformat(kobj_t obj, void *data, uint32_t format)
   {
           struct sc_chinfo *ch = data;
   
           ch->format = format;
   
           return (0);
   }
   
   static uint32_t
   saichan_setspeed(kobj_t obj, void *data, uint32_t speed)
   {
           struct sc_pcminfo *scp;
           struct sc_chinfo *ch;
           struct sai_rate *sr;
           struct sc_info *sc;
           int threshold;
           int i;
   
           ch = data;
           scp = ch->parent;
           sc = scp->sc;
   
           sr = NULL;
   
           /* First look for equal frequency. */
           for (i = 0; rate_map[i].speed != 0; i++) {
                   if (rate_map[i].speed == speed)
                           sr = &rate_map[i];
           }
   
           /* If no match, just find nearest. */
           if (sr == NULL) {
                   for (i = 0; rate_map[i].speed != 0; i++) {
                           sr = &rate_map[i];
                           threshold = sr->speed + ((rate_map[i + 1].speed != 0) ?
                               ((rate_map[i + 1].speed - sr->speed) >> 1) : 0);
                           if (speed < threshold)
                                   break;
                   }
           }
   
           sc->sr = sr;
   
           sai_configure_clock(sc);
   
           return (sr->speed);
   }
   
   static void
   sai_configure_clock(struct sc_info *sc)
   {
           struct sai_rate *sr;
           int reg;
   
           sr = sc->sr;
   
           /*
            * Manual says that TCR/RCR registers must not be
            * altered when TCSR[TE] is set.
            * We ignore it since we have problem sometimes
            * after re-enabling transmitter (DMA goes stall).
            */
   
           reg = READ4(sc, I2S_TCR2);
           reg &= ~(0xff << 0);
           reg |= (sr->div << 0);
           WRITE4(sc, I2S_TCR2, reg);
   
           pll4_configure_output(sr->mfi, sr->mfn, sr->mfd);
   }
   
   static uint32_t
   saichan_setblocksize(kobj_t obj, void *data, uint32_t blocksize)
   {
           struct sc_chinfo *ch = data;
           struct sc_pcminfo *scp = ch->parent;
           struct sc_info *sc = scp->sc;
   
           sndbuf_resize(ch->buffer, sc->dma_size / blocksize, blocksize);
   
           sc->period = sndbuf_getblksz(ch->buffer);
           return (sc->period);
   }
   
   uint32_t sai_dma_intr(void *arg, int chn);
   uint32_t
   sai_dma_intr(void *arg, int chn)
   {
           struct sc_pcminfo *scp;
           struct sc_chinfo *ch;
           struct sc_info *sc;
           struct tcd_conf *tcd;
   
           scp = arg;
           ch = &scp->chan[0];
   
           sc = scp->sc;
           tcd = sc->tcd;
   
           sc->pos += (tcd->nbytes * tcd->nmajor);
           if (sc->pos >= sc->dma_size)
                   sc->pos -= sc->dma_size;
   
           if (ch->run)
                   chn_intr(ch->channel);
   
           return (0);
   }
   
   static int
   find_edma_controller(struct sc_info *sc)
   {
           struct edma_softc *edma_sc;
           phandle_t node, edma_node;
           int edma_src_transmit;
           int edma_mux_group;
           int edma_device_id;
           device_t edma_dev;
           int dts_value;
           int len;
           int i;
   
           if ((node = ofw_bus_get_node(sc->dev)) == -1)
                   return (ENXIO);
   
           if ((len = OF_getproplen(node, "edma-controller")) <= 0)
                   return (ENXIO);
           if ((len = OF_getproplen(node, "edma-src-transmit")) <= 0)
                   return (ENXIO);
           if ((len = OF_getproplen(node, "edma-mux-group")) <= 0)
                   return (ENXIO);
   
           OF_getprop(node, "edma-src-transmit", &dts_value, len);
           edma_src_transmit = fdt32_to_cpu(dts_value);
           OF_getprop(node, "edma-mux-group", &dts_value, len);
           edma_mux_group = fdt32_to_cpu(dts_value);
           OF_getprop(node, "edma-controller", &dts_value, len);
           edma_node = OF_node_from_xref(fdt32_to_cpu(dts_value));
   
           if ((len = OF_getproplen(edma_node, "device-id")) <= 0) {
                   return (ENXIO);
           };
   
           OF_getprop(edma_node, "device-id", &dts_value, len);
           edma_device_id = fdt32_to_cpu(dts_value);
   
           edma_sc = NULL;
   
           for (i = 0; i < EDMA_NUM_DEVICES; i++) {
                   edma_dev = devclass_get_device(devclass_find("edma"), i);
                   if (edma_dev) {
                           edma_sc = device_get_softc(edma_dev);
                           if (edma_sc->device_id == edma_device_id) {
                                   /* found */
                                   break;
                           };
   
                           edma_sc = NULL;
                   };
           };
   
           if (edma_sc == NULL) {
                   device_printf(sc->dev, "no eDMA. can't operate\n");
                   return (ENXIO);
           };
   
           sc->edma_sc = edma_sc;
   
           sc->edma_chnum = edma_sc->channel_configure(edma_sc, edma_mux_group,
               edma_src_transmit);
           if (sc->edma_chnum < 0) {
                   /* cant setup eDMA */
                   return (ENXIO);
           };
   
           return (0);
   };
   
   static int
   setup_dma(struct sc_pcminfo *scp)
   {
           struct tcd_conf *tcd;
           struct sc_info *sc;
   
           sc = scp->sc;
   
           tcd = malloc(sizeof(struct tcd_conf), M_DEVBUF, M_WAITOK | M_ZERO);
           tcd->channel = sc->edma_chnum;
           tcd->ih = sai_dma_intr;
           tcd->ih_user = scp;
           tcd->saddr = sc->buf_base_phys;
           tcd->daddr = rman_get_start(sc->res[0]) + I2S_TDR0;
   
           /*
            * Bytes to transfer per each minor loop.
            * Hardware FIFO buffer size is 32x32bits.
            */
           tcd->nbytes = 64;
   
           tcd->nmajor = 512;
           tcd->smod = 17; /* dma_size range */
           tcd->dmod = 0;
           tcd->esg = 0;
           tcd->soff = 0x4;
           tcd->doff = 0;
           tcd->ssize = 0x2;
           tcd->dsize = 0x2;
           tcd->slast = 0;
           tcd->dlast_sga = 0;
   
           sc->tcd = tcd;
   
           sc->edma_sc->dma_setup(sc->edma_sc, sc->tcd);
   
           return (0);
   }
   
   static int
   saichan_trigger(kobj_t obj, void *data, int go)
   {
           struct sc_chinfo *ch = data;
           struct sc_pcminfo *scp = ch->parent;
           struct sc_info *sc = scp->sc;
   
           snd_mtxlock(sc->lock);
   
           switch (go) {
           case PCMTRIG_START:
   #if 0
                   device_printf(scp->dev, "trigger start\n");
   #endif
                   ch->run = 1;
                   break;
   
           case PCMTRIG_STOP:
           case PCMTRIG_ABORT:
   #if 0
                   device_printf(scp->dev, "trigger stop or abort\n");
   #endif
                   ch->run = 0;
                   break;
           }
   
           snd_mtxunlock(sc->lock);
   
           return (0);
   }
   
   static uint32_t
   saichan_getptr(kobj_t obj, void *data)
   {
           struct sc_pcminfo *scp;
           struct sc_chinfo *ch;
           struct sc_info *sc;
   
           ch = data;
           scp = ch->parent;
           sc = scp->sc;
   
           return (sc->pos);
   }
   
   static uint32_t sai_pfmt[] = {
           /*
            * eDMA doesn't allow 24-bit coping,
            * so we use 32.
            */
           SND_FORMAT(AFMT_S32_LE, 2, 0),
           0
   };
   
   static struct pcmchan_caps sai_pcaps = {44100, 192000, sai_pfmt, 0};
   
   static struct pcmchan_caps *
   saichan_getcaps(kobj_t obj, void *data)
   {
   
           return (&sai_pcaps);
   }
   
   static kobj_method_t saichan_methods[] = {
           KOBJMETHOD(channel_init,         saichan_init),
           KOBJMETHOD(channel_free,         saichan_free),
           KOBJMETHOD(channel_setformat,    saichan_setformat),
           KOBJMETHOD(channel_setspeed,     saichan_setspeed),
           KOBJMETHOD(channel_setblocksize, saichan_setblocksize),
           KOBJMETHOD(channel_trigger,      saichan_trigger),
           KOBJMETHOD(channel_getptr,       saichan_getptr),
           KOBJMETHOD(channel_getcaps,      saichan_getcaps),
           KOBJMETHOD_END
   };
   CHANNEL_DECLARE(saichan);
   
   static int
   sai_probe(device_t dev)
   {
   
           if (!ofw_bus_status_okay(dev))
                   return (ENXIO);
   
           if (!ofw_bus_is_compatible(dev, "fsl,mvf600-sai"))
                   return (ENXIO);
   
           device_set_desc(dev, "Vybrid Family Synchronous Audio Interface");
           return (BUS_PROBE_DEFAULT);
   }
   
   static void
   sai_intr(void *arg)
   {
           struct sc_pcminfo *scp;
           struct sc_info *sc;
   
           scp = arg;
           sc = scp->sc;
   
           device_printf(sc->dev, "Error I2S_TCSR == 0x%08x\n",
               READ4(sc, I2S_TCSR));
   }
   
   static void
   setup_sai(struct sc_info *sc)
   {
           int reg;
   
           /*
            * TCR/RCR registers must not be altered when TCSR[TE] is set.
            */
   
           reg = READ4(sc, I2S_TCSR);
           reg &= ~(TCSR_BCE | TCSR_TE | TCSR_FRDE);
           WRITE4(sc, I2S_TCSR, reg);
   
           reg = READ4(sc, I2S_TCR3);
           reg &= ~(TCR3_TCE);
           WRITE4(sc, I2S_TCR3, reg);
   
           reg = (64 << TCR1_TFW_S);
           WRITE4(sc, I2S_TCR1, reg);
   
           reg = READ4(sc, I2S_TCR2);
           reg &= ~(TCR2_MSEL_M << TCR2_MSEL_S);
           reg |= (1 << TCR2_MSEL_S);
           reg |= (TCR2_BCP | TCR2_BCD);
           WRITE4(sc, I2S_TCR2, reg);
   
           sai_configure_clock(sc);
   
           reg = READ4(sc, I2S_TCR3);
           reg |= (TCR3_TCE);
           WRITE4(sc, I2S_TCR3, reg);
   
           /* Configure to 32-bit I2S mode */
           reg = READ4(sc, I2S_TCR4);
           reg &= ~(TCR4_FRSZ_M << TCR4_FRSZ_S);
           reg |= (1 << TCR4_FRSZ_S); /* 2 words per frame */
           reg &= ~(TCR4_SYWD_M << TCR4_SYWD_S);
           reg |= (23 << TCR4_SYWD_S);
           reg |= (TCR4_MF | TCR4_FSE | TCR4_FSP | TCR4_FSD);
           WRITE4(sc, I2S_TCR4, reg);
   
           reg = READ4(sc, I2S_TCR5);
           reg &= ~(TCR5_W0W_M << TCR5_W0W_S);
           reg |= (23 << TCR5_W0W_S);
           reg &= ~(TCR5_WNW_M << TCR5_WNW_S);
           reg |= (23 << TCR5_WNW_S);
           reg &= ~(TCR5_FBT_M << TCR5_FBT_S);
           reg |= (31 << TCR5_FBT_S);
           WRITE4(sc, I2S_TCR5, reg);
   
           /* Enable transmitter */
           reg = READ4(sc, I2S_TCSR);
           reg |= (TCSR_BCE | TCSR_TE | TCSR_FRDE);
           reg |= (1 << 10); /* FEIE */
           WRITE4(sc, I2S_TCSR, reg);
   }
   
   
   static void
   sai_dmamap_cb(void *arg, bus_dma_segment_t *segs, int nseg, int err)
   {
           bus_addr_t *addr;
   
           if (err)
                   return;
   
           addr = (bus_addr_t*)arg;
           *addr = segs[0].ds_addr;
   }
   
   static int
   sai_attach(device_t dev)
   {
           char status[SND_STATUSLEN];
           struct sc_pcminfo *scp;
           struct sc_info *sc;
           int err;
   
           sc = malloc(sizeof(*sc), M_DEVBUF, M_WAITOK | M_ZERO);
           sc->dev = dev;
           sc->sr = &rate_map[0];
           sc->pos = 0;
   
           sc->lock = snd_mtxcreate(device_get_nameunit(dev), "sai softc");
           if (sc->lock == NULL) {
                   device_printf(dev, "Cant create mtx\n");
                   return (ENXIO);
           }
   
           if (bus_alloc_resources(dev, sai_spec, sc->res)) {
                   device_printf(dev, "could not allocate resources\n");
                   return (ENXIO);
           }
   
           /* Memory interface */
           sc->bst = rman_get_bustag(sc->res[0]);
           sc->bsh = rman_get_bushandle(sc->res[0]);
   
           /* eDMA */
           if (find_edma_controller(sc)) {
                   device_printf(dev, "could not find active eDMA\n");
                   return (ENXIO);
           }
   
           /* Setup PCM */
           scp = malloc(sizeof(struct sc_pcminfo), M_DEVBUF, M_NOWAIT | M_ZERO);
           scp->sc = sc;
           scp->dev = dev;
   
           /* DMA */
           sc->dma_size = 131072;
   
           /*
            * Must use dma_size boundary as modulo feature required.
            * Modulo feature allows setup circular buffer.
            */
   
           err = bus_dma_tag_create(
               bus_get_dma_tag(sc->dev),
               4, sc->dma_size,            /* alignment, boundary */
               BUS_SPACE_MAXADDR_32BIT,    /* lowaddr */
               BUS_SPACE_MAXADDR,          /* highaddr */
               NULL, NULL,                 /* filter, filterarg */
               sc->dma_size, 1,            /* maxsize, nsegments */
               sc->dma_size, 0,            /* maxsegsize, flags */
               NULL, NULL,                 /* lockfunc, lockarg */
               &sc->dma_tag);
   
           err = bus_dmamem_alloc(sc->dma_tag, (void **)&sc->buf_base,
               BUS_DMA_NOWAIT | BUS_DMA_COHERENT, &sc->dma_map);
           if (err) {
                   device_printf(dev, "cannot allocate framebuffer\n");
                   return (ENXIO);
           }
   
           err = bus_dmamap_load(sc->dma_tag, sc->dma_map, sc->buf_base,
               sc->dma_size, sai_dmamap_cb, &sc->buf_base_phys, BUS_DMA_NOWAIT);
           if (err) {
                   device_printf(dev, "cannot load DMA map\n");
                   return (ENXIO);
           }
   
           bzero(sc->buf_base, sc->dma_size);
   
           /* Setup interrupt handler */
           err = bus_setup_intr(dev, sc->res[1], INTR_MPSAFE | INTR_TYPE_AV,
               NULL, sai_intr, scp, &sc->ih);
           if (err) {
                   device_printf(dev, "Unable to alloc interrupt resource.\n");
                   return (ENXIO);
           }
   
           pcm_setflags(dev, pcm_getflags(dev) | SD_F_MPSAFE);
   
           err = pcm_register(dev, scp, 1, 0);
           if (err) {
                   device_printf(dev, "Can't register pcm.\n");
                   return (ENXIO);
           }
   
           scp->chnum = 0;
           pcm_addchan(dev, PCMDIR_PLAY, &saichan_class, scp);
           scp->chnum++;
   
           snprintf(status, SND_STATUSLEN, "at simplebus");
           pcm_setstatus(dev, status);
   
           mixer_init(dev, &saimixer_class, scp);
   
           setup_dma(scp);
           setup_sai(sc);
   
           return (0);
   }
   
   static device_method_t sai_pcm_methods[] = {
           DEVMETHOD(device_probe,         sai_probe),
           DEVMETHOD(device_attach,        sai_attach),
           { 0, 0 }
   };
   
   static driver_t sai_pcm_driver = {
           "pcm",
           sai_pcm_methods,
           PCM_SOFTC_SIZE,
   };
   
   DRIVER_MODULE(sai, simplebus, sai_pcm_driver, pcm_devclass, 0, 0);
   MODULE_DEPEND(sai, sound, SOUND_MINVER, SOUND_PREFVER, SOUND_MAXVER);
   MODULE_VERSION(sai, 1);

Cache object: 1739274d3b680b1077218b400d143bbb