/***************************************************************************
 *             __________               __   ___.
 *   Open      \______   \ ____   ____ |  | _\_ |__   _______  ___
 *   Source     |       _//  _ \_/ ___\|  |/ /| __ \ /  _ \  \/  /
 *   Jukebox    |    |   (  <_> )  \___|    < | \_\ (  <_> > <  <
 *   Firmware   |____|_  /\____/ \___  >__|_ \|___  /\____/__/\_ \
 *                     \/            \/     \/    \/            \/
 * $Id$
 *
 * Copyright (C) 2008 by Michael Sevakis
 *
 * 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
 * KIND, either express or implied.
 *
 ****************************************************************************/
#include <stdlib.h>
#include "system.h"
#include "kernel.h"
#include "audio.h"
#include "sound.h"
#include "sdma-imx31.h"
#include "mmu-imx31.h"
#include "pcm-internal.h"

#define DMA_PLAY_CH_NUM 2
#define DMA_REC_CH_NUM 1
#define DMA_PLAY_CH_PRIORITY 6
#define DMA_REC_CH_PRIORITY 6

static struct buffer_descriptor dma_play_bd NOCACHEBSS_ATTR;

static void play_dma_callback(void);
static struct channel_descriptor dma_play_cd =
{
    .bd_count = 1,
    .callback = play_dma_callback,
    .shp_addr = SDMA_PER_ADDR_SSI2_TX1,
    .wml      = SDMA_SSI_TXFIFO_WML*2,
    .per_type = SDMA_PER_SSI_SHP, /* SSI2 shared with SDMA core */
    .tran_type = SDMA_TRAN_EMI_2_PER,
    .event_id1 = SDMA_REQ_SSI2_TX1,
};

/* The pcm locking relies on the fact the interrupt handlers run to completion
 * before lower-priority modes proceed. We don't have to touch hardware
 * registers. Disabling SDMA interrupt would disable DMA callbacks systemwide
 * and that is not something that is desireable.
 *
 * Lock explanation [++.locked]:
 * Trivial, just increment .locked.
 *
 * Unlock explanation [if (--.locked == 0 && .state != 0)]:
 * If int occurred and saw .locked as nonzero, we'll get a pending
 * and it will have taken no action other than to set the flag to the
 * value of .state. If it saw zero for .locked, it will have proceeded
 * normally into the pcm callbacks. If cb set the pending flag, it has
 * to be called to kickstart the callback mechanism and DMA. If the unlock
 * came after a stop, we won't be in the block and DMA will be off. If
 * we're still doing transfers, cb will see 0 for .locked and if pending,
 * it won't be called by DMA again. */
struct dma_data
{
    int locked;
    int callback_pending; /* DMA interrupt happened while locked */
    int state;
};

static struct dma_data dma_play_data =
{
    /* Initialize to an unlocked, stopped state */
    .locked = 0,
    .callback_pending = 0,
    .state = 0
};

static void play_start_dma(const void *addr, size_t size)
{
    commit_dcache_range(addr, size);

    dma_play_bd.buf_addr = (void *)addr_virt_to_phys((unsigned long)addr);
    dma_play_bd.mode.count = size;
    dma_play_bd.mode.command = TRANSFER_16BIT;
    dma_play_bd.mode.status = BD_DONE | BD_WRAP | BD_INTR;

    sdma_channel_run(DMA_PLAY_CH_NUM);
}

static void play_dma_callback(void)
{
    if (dma_play_data.locked != 0)
    {
        /* Callback is locked out */
        dma_play_data.callback_pending = dma_play_data.state;
        return;
    }

    /* Inform of status and get new buffer */
    enum pcm_dma_status status = (dma_play_bd.mode.status & BD_RROR) ?
                  PCM_DMAST_ERR_DMA : PCM_DMAST_OK;
    const void *addr;
    size_t size;

    if (pcm_play_dma_complete_callback(status, &addr, &size))
    {
        play_start_dma(addr, size);
        pcm_play_dma_status_callback(PCM_DMAST_STARTED);
    }
}

void pcm_play_lock(void)
{
    ++dma_play_data.locked;
}

void pcm_play_unlock(void)
{
    if (--dma_play_data.locked == 0 && dma_play_data.state != 0)
    {
        int oldstatus = disable_irq_save();
        int pending = dma_play_data.callback_pending;
        dma_play_data.callback_pending = 0;
        restore_irq(oldstatus);

        if (pending != 0)
            play_dma_callback();
    }
}

void pcm_dma_apply_settings(void)
{
    audiohw_set_frequency(pcm_fsel);
}

void pcm_play_dma_init(void)
{
    /* Init DMA channel information */
    sdma_channel_init(DMA_PLAY_CH_NUM, &dma_play_cd, &dma_play_bd);
    sdma_channel_set_priority(DMA_PLAY_CH_NUM, DMA_PLAY_CH_PRIORITY);

    /* Init audio interfaces */
    audiohw_init();
}

void pcm_play_dma_postinit(void)
{
    audiohw_postinit();
}

static void play_start_pcm(void)
{
    /* Stop transmission (if in progress) */
    SSI_SCR2 &= ~SSI_SCR_TE;

    SSI_SCR2 |= SSI_SCR_SSIEN;   /* Enable SSI */
    SSI_STCR2 |= SSI_STCR_TFEN0; /* Enable TX FIFO */

    dma_play_data.state = 1; /* Check callback on unlock */

    /* Do prefill to prevent swapped channels (see TLSbo61214 in MCIMX31CE).
     * No actual solution was offered but this appears to work. */
    SSI_STX0_2 = 0;
    SSI_STX0_2 = 0;
    SSI_STX0_2 = 0;
    SSI_STX0_2 = 0;

    SSI_SIER2 |= SSI_SIER_TDMAE; /* Enable DMA req. */
    SSI_SCR2 |= SSI_SCR_TE;      /* Start transmitting */
}

static void play_stop_pcm(void)
{
    SSI_SIER2 &= ~SSI_SIER_TDMAE; /* Disable DMA req. */

    /* Set state before pending to prevent race with interrupt */
    dma_play_data.state = 0;

    /* Wait for FIFO to empty */
    while (SSI_SFCSR_TFCNT0 & SSI_SFCSR2);

    SSI_STCR2 &= ~SSI_STCR_TFEN0; /* Disable TX */
    SSI_SCR2 &= ~(SSI_SCR_TE | SSI_SCR_SSIEN); /* Disable transmission, SSI */

    if (pcm_playing)
    {
        /* Stopping: clear buffer info to ensure 0-size readbacks when
         * stopped */
        unsigned long dsa = 0;
        dma_play_bd.buf_addr = NULL;
        dma_play_bd.mode.count = 0;
        discard_dcache_range(&dsa, sizeof(dsa));
        sdma_write_words(&dsa, CHANNEL_CONTEXT_ADDR(DMA_PLAY_CH_NUM)+0x0b, 1);
    }

    /* Clear any pending callback */
    dma_play_data.callback_pending = 0;
}

void pcm_play_dma_start(const void *addr, size_t size)
{
    sdma_channel_stop(DMA_PLAY_CH_NUM);

    /* Disable transmission */
    SSI_STCR2 &= ~SSI_STCR_TFEN0;
    SSI_SCR2 &= ~(SSI_SCR_TE | SSI_SCR_SSIEN);

    if (!sdma_channel_reset(DMA_PLAY_CH_NUM))
        return;

    /* Begin I2S transmission */
    play_start_pcm();

    /* Begin DMA transfer */
    play_start_dma(addr, size);
}

void pcm_play_dma_stop(void)
{
    sdma_channel_stop(DMA_PLAY_CH_NUM);
    play_stop_pcm();
}

/* Return a pointer to the samples and the number of them in *count */
const void * pcm_play_dma_get_peak_buffer(int *count)
{
    static unsigned long dsa NOCACHEBSS_ATTR;
    unsigned long addr;
    long offs, size;
    int oldstatus;

    /* read burst dma source address register in channel context */
    sdma_read_words(&dsa, CHANNEL_CONTEXT_ADDR(DMA_PLAY_CH_NUM)+0x0b, 1);

    oldstatus = disable_irq_save();
    addr = dsa;
    offs = addr - (unsigned long)dma_play_bd.buf_addr;
    size = dma_play_bd.mode.count;
    restore_irq(oldstatus);

    /* Be addresses are coherent (no buffer change during read) */
    if (offs >= 0 && offs < size)
    {
        *count = (size - offs) >> 2;
        return (void *)((addr + 2) & ~3);
    }

    *count = 0;
    return NULL;
}

void * pcm_dma_addr(void *addr)
{
    return (void *)addr_virt_to_phys((unsigned long)addr);
}

#ifdef HAVE_RECORDING
static struct buffer_descriptor dma_rec_bd NOCACHEBSS_ATTR;

static void rec_dma_callback(void);
static struct channel_descriptor dma_rec_cd =
{
    .bd_count = 1,
    .callback = rec_dma_callback,
    .shp_addr = SDMA_PER_ADDR_SSI1_RX1,
    .wml      = SDMA_SSI_RXFIFO_WML*2,
    .per_type = SDMA_PER_SSI,
    .tran_type = SDMA_TRAN_PER_2_EMI,
    .event_id1 = SDMA_REQ_SSI1_RX1,
};

static struct dma_data dma_rec_data =
{
    /* Initialize to an unlocked, stopped state */
    .locked = 0,
    .callback_pending = 0,
    .state = 0
};

static void rec_start_dma(void *addr, size_t size)
{
    discard_dcache_range(addr, size);

    addr = (void *)addr_virt_to_phys((unsigned long)addr);

    dma_rec_bd.buf_addr = addr;
    dma_rec_bd.mode.count = size;
    dma_rec_bd.mode.command = TRANSFER_16BIT;
    dma_rec_bd.mode.status = BD_DONE | BD_WRAP | BD_INTR;

    sdma_channel_run(DMA_REC_CH_NUM);
}

static void rec_dma_callback(void)
{
    if (dma_rec_data.locked != 0)
    {
        dma_rec_data.callback_pending = dma_rec_data.state;
        return; /* Callback is locked out */
    }

    /* Inform middle layer */
    enum pcm_dma_status status = (dma_rec_bd.mode.status & BD_RROR) ?
                                  PCM_DMAST_ERR_DMA : PCM_DMAST_OK;
    void *addr;
    size_t size;

    if (pcm_rec_dma_complete_callback(status, &addr, &size))
    {
        rec_start_dma(addr, size);
        pcm_rec_dma_status_callback(PCM_DMAST_STARTED);
    }
}

void pcm_rec_lock(void)
{
    ++dma_rec_data.locked;
}

void pcm_rec_unlock(void)
{
    if (--dma_rec_data.locked == 0 && dma_rec_data.state != 0)
    {
        int oldstatus = disable_irq_save();
        int pending = dma_rec_data.callback_pending;
        dma_rec_data.callback_pending = 0;
        restore_irq(oldstatus);

        if (pending != 0)
            rec_dma_callback();
    }
}

void pcm_rec_dma_stop(void)
{
    SSI_SIER1 &= ~SSI_SIER_RDMAE; /* Disable DMA req. */

    /* Set state before pending to prevent race with interrupt */
    dma_rec_data.state = 0;

    /* Stop receiving data */
    sdma_channel_stop(DMA_REC_CH_NUM);

    bitclr32(&SSI_SIER1, SSI_SIER_RDMAE);

    SSI_SCR1 &= ~SSI_SCR_RE;      /* Disable RX */
    SSI_SRCR1 &= ~SSI_SRCR_RFEN0; /* Disable RX FIFO */

    if (pcm_recording)
    {
        /* Stopping: clear buffer info to ensure 0-size readbacks when
         * stopped */
        unsigned long pda = 0;
        dma_rec_bd.buf_addr = NULL;
        dma_rec_bd.mode.count = 0;
        discard_dcache_range(&pda, sizeof(pda));
        sdma_write_words(&pda, CHANNEL_CONTEXT_ADDR(DMA_REC_CH_NUM)+0x0a, 1);
    }

    /* Clear any pending callback */
    dma_rec_data.callback_pending = 0;
}

void pcm_rec_dma_start(void *addr, size_t size)
{
    pcm_rec_dma_stop();

    if (!sdma_channel_reset(DMA_REC_CH_NUM))
        return;

    SSI_SRCR1 |= SSI_SRCR_RFEN0; /* Enable RX FIFO */

    /* Ensure clear FIFO */
    while (SSI_SFCSR1 & SSI_SFCSR_RFCNT0)
        SSI_SRX0_1;

    /* Enable receive */
    SSI_SCR1 |= SSI_SCR_RE;
    SSI_SIER1 |= SSI_SIER_RDMAE; /* Enable DMA req. */

    /* Begin DMA transfer */
    rec_start_dma(addr, size);

    dma_rec_data.state = 1; /* Check callback on unlock */
}

void pcm_rec_dma_close(void)
{
    pcm_rec_dma_stop();
    sdma_channel_close(DMA_REC_CH_NUM);
}

void pcm_rec_dma_init(void)
{
    pcm_rec_dma_stop();

    /* Init channel information */
    sdma_channel_init(DMA_REC_CH_NUM, &dma_rec_cd, &dma_rec_bd);
    sdma_channel_set_priority(DMA_REC_CH_NUM, DMA_REC_CH_PRIORITY);
}

const void * pcm_rec_dma_get_peak_buffer(void)
{
    static unsigned long pda NOCACHEBSS_ATTR;
    unsigned long buf, end, bufend;
    int oldstatus;

    /* read burst dma destination address register in channel context */
    sdma_read_words(&pda, CHANNEL_CONTEXT_ADDR(DMA_REC_CH_NUM)+0x0a, 1);

    oldstatus = disable_irq_save();
    end = pda;
    buf = (unsigned long)dma_rec_bd.buf_addr;
    bufend = buf + dma_rec_bd.mode.count;
    restore_irq(oldstatus);

    /* Be addresses are coherent (no buffer change during read) */
    if (end >= buf && end < bufend)
        return (void *)(end & ~3);

    return NULL;
}

#endif /* HAVE_RECORDING */