drivers/platform/msm/sps/sps_dma.c - kernel/msm - Git at Google

 /* Copyright (c) 2011-2013, The Linux Foundation. All rights reserved.
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 and
  * only version 2 as published by the Free Software Foundation.
  *
  * 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.
  */

 /* BAM-DMA Manager. */

 #ifdef CONFIG_SPS_SUPPORT_BAMDMA

 #include <linux/export.h>
 #include <linux/memory.h>	/* memset */

 #include "spsi.h"
 #include "bam.h"
 #include "sps_bam.h"		/* bam_dma_thresh_dma */
 #include "sps_core.h"		/* sps_h2bam() */

 /**
  * registers
  */

 #define DMA_ENBL			(0x00000000)
 #ifdef CONFIG_SPS_SUPPORT_NDP_BAM
 #define DMA_REVISION			(0x00000004)
 #define DMA_CONFIG			(0x00000008)
 #define DMA_CHNL_CONFIG(n)		(0x00001000 + 4096 * (n))
 #else
 #define DMA_CHNL_CONFIG(n)		(0x00000004 + 4 * (n))
 #define DMA_CONFIG			(0x00000040)
 #endif

 /**
  * masks
  */

 /* DMA_CHNL_confign */
 #ifdef CONFIG_SPS_SUPPORT_NDP_BAM
 #define DMA_CHNL_PRODUCER_PIPE_ENABLED	0x40000
 #define DMA_CHNL_CONSUMER_PIPE_ENABLED	0x20000
 #endif
 #define DMA_CHNL_HALT_DONE		0x10000
 #define DMA_CHNL_HALT			0x1000
 #define DMA_CHNL_ENABLE                 0x100
 #define DMA_CHNL_ACT_THRESH             0x30
 #define DMA_CHNL_WEIGHT                 0x7

 /* DMA_CONFIG */
 #define TESTBUS_SELECT                  0x3

 /**
  *
  * Write register with debug info.
  *
  * @base - bam base virtual address.
  * @offset - register offset.
  * @val - value to write.
  *
  */
 static inline void dma_write_reg(void *base, u32 offset, u32 val)
 {
 	iowrite32(val, base + offset);
 	SPS_DBG("sps:bamdma: write reg 0x%x w_val 0x%x.", offset, val);
 }

 /**
  * Write register masked field with debug info.
  *
  * @base - bam base virtual address.
  * @offset - register offset.
  * @mask - register bitmask.
  * @val - value to write.
  *
  */
 static inline void dma_write_reg_field(void *base, u32 offset,
 				       const u32 mask, u32 val)
 {
 	u32 shift = find_first_bit((void *)&mask, 32);
 	u32 tmp = ioread32(base + offset);

 	tmp &= ~mask;		/* clear written bits */
 	val = tmp | (val << shift);
 	iowrite32(val, base + offset);
 	SPS_DBG("sps:bamdma: write reg 0x%x w_val 0x%x.", offset, val);
 }

 /* Round max number of pipes to nearest multiple of 2 */
 #define DMA_MAX_PIPES         ((BAM_MAX_PIPES / 2) * 2)

 /* Maximum number of BAM-DMAs supported */
 #define MAX_BAM_DMA_DEVICES   1

 /* Maximum number of BAMs that will be registered */
 #define MAX_BAM_DMA_BAMS      1

 /* Pipe enable check values */
 #define DMA_PIPES_STATE_DIFF     0
 #define DMA_PIPES_BOTH_DISABLED  1
 #define DMA_PIPES_BOTH_ENABLED   2

 /* Even pipe is tx/dest/input/write, odd pipe is rx/src/output/read */
 #define DMA_PIPE_IS_DEST(p)   (((p) & 1) == 0)
 #define DMA_PIPE_IS_SRC(p)    (((p) & 1) != 0)

 /* BAM DMA pipe state */
 enum bamdma_pipe_state {
 	PIPE_INACTIVE = 0,
 	PIPE_ACTIVE
 };

 /* BAM DMA channel state */
 enum bamdma_chan_state {
 	DMA_CHAN_STATE_FREE = 0,
 	DMA_CHAN_STATE_ALLOC_EXT,	/* Client allocation */
 	DMA_CHAN_STATE_ALLOC_INT	/* Internal (resource mgr) allocation */
 };

 struct bamdma_chan {
 	/* Allocation state */
 	enum bamdma_chan_state state;

 	/* BAM DMA channel configuration parameters */
 	u32 threshold;
 	enum sps_dma_priority priority;

 	/* HWIO channel configuration parameters */
 	enum bam_dma_thresh_dma thresh;
 	enum bam_dma_weight_dma weight;

 };

 /* BAM DMA device state */
 struct bamdma_device {
 	/* BAM-DMA device state */
 	int enabled;
 	int local;

 	/* BAM device state */
 	struct sps_bam *bam;

 	/* BAM handle, for deregistration */
 	unsigned long h;

 	/* BAM DMA device virtual mapping */
 	void *virt_addr;
 	int virtual_mapped;
 	phys_addr_t phys_addr;
 	void *hwio;

 	/* BAM DMA pipe/channel state */
 	u32 num_pipes;
 	enum bamdma_pipe_state pipes[DMA_MAX_PIPES];
 	struct bamdma_chan chans[DMA_MAX_PIPES / 2];

 };

 /* BAM-DMA devices */
 static struct bamdma_device bam_dma_dev[MAX_BAM_DMA_DEVICES];
 static struct mutex bam_dma_lock;

 /*
  * The BAM DMA module registers all BAMs in the BSP properties, but only
  * uses the first BAM-DMA device for allocations.  References to the others
  * are stored in the following data array.
  */
 static int num_bams;
 static unsigned long bam_handles[MAX_BAM_DMA_BAMS];

 /**
  * Find BAM-DMA device
  *
  * This function finds the BAM-DMA device associated with the BAM handle.
  *
  * @h - BAM handle
  *
  * @return - pointer to BAM-DMA device, or NULL on error
  *
  */
 static struct bamdma_device *sps_dma_find_device(unsigned long h)
 {
 	return &bam_dma_dev[0];
 }

 /**
  * BAM DMA device enable
  *
  * This function enables a BAM DMA device and the associated BAM.
  *
  * @dev - pointer to BAM DMA device context
  *
  * @return 0 on success, negative value on error
  *
  */
 static int sps_dma_device_enable(struct bamdma_device *dev)
 {
 	if (dev->enabled)
 		return 0;

 	/*
 	 *  If the BAM-DMA device is locally controlled then enable BAM-DMA
 	 *  device
 	 */
 	if (dev->local)
 		dma_write_reg(dev->virt_addr, DMA_ENBL, 1);

 	/* Enable BAM device */
 	if (sps_bam_enable(dev->bam)) {
 		SPS_ERR("sps:Failed to enable BAM DMA's BAM: %pa",
 			&dev->phys_addr);
 		return SPS_ERROR;
 	}

 	dev->enabled = true;

 	return 0;
 }

 /**
  * BAM DMA device enable
  *
  * This function initializes a BAM DMA device.
  *
  * @dev - pointer to BAM DMA device context
  *
  * @return 0 on success, negative value on error
  *
  */
 static int sps_dma_device_disable(struct bamdma_device *dev)
 {
 	u32 pipe_index;

 	if (!dev->enabled)
 		return 0;

 	/* Do not disable if channels active */
 	for (pipe_index = 0; pipe_index < dev->num_pipes; pipe_index++) {
 		if (dev->pipes[pipe_index] != PIPE_INACTIVE)
 			break;
 	}

 	if (pipe_index < dev->num_pipes) {
 		SPS_ERR("sps:Fail to disable BAM-DMA %pa:channels are active",
 			&dev->phys_addr);
 		return SPS_ERROR;
 	}

 	dev->enabled = false;

 	/* Disable BAM device */
 	if (sps_bam_disable(dev->bam)) {
 		SPS_ERR("sps:Fail to disable BAM-DMA BAM:%pa", &dev->phys_addr);
 		return SPS_ERROR;
 	}

 	/* Is the BAM-DMA device locally controlled? */
 	if (dev->local)
 		/* Disable BAM-DMA device */
 		dma_write_reg(dev->virt_addr, DMA_ENBL, 0);

 	return 0;
 }

 /**
  * Initialize BAM DMA device
  *
  */
 int sps_dma_device_init(unsigned long h)
 {
 	struct bamdma_device *dev;
 	struct sps_bam_props *props;
 	int result = SPS_ERROR;

 	mutex_lock(&bam_dma_lock);

 	/* Find a free BAM-DMA device slot */
 	dev = NULL;
 	if (bam_dma_dev[0].bam != NULL) {
 		SPS_ERR("sps:BAM-DMA BAM device is already initialized.");
 		goto exit_err;
 	} else {
 		dev = &bam_dma_dev[0];
 	}

 	/* Record BAM */
 	memset(dev, 0, sizeof(*dev));
 	dev->h = h;
 	dev->bam = sps_h2bam(h);

 	if (dev->bam == NULL) {
 		SPS_ERR("sps:BAM-DMA BAM device is not found "
 				"from the handle.");
 		goto exit_err;
 	}

 	/* Map the BAM DMA device into virtual space, if necessary */
 	props = &dev->bam->props;
 	dev->phys_addr = props->periph_phys_addr;
 	if (props->periph_virt_addr != NULL) {
 		dev->virt_addr = props->periph_virt_addr;
 		dev->virtual_mapped = false;
 	} else {
 		if (props->periph_virt_size == 0) {
 			SPS_ERR("sps:Unable to map BAM DMA IO memory: %pa %x",
 			 &dev->phys_addr, props->periph_virt_size);
 			goto exit_err;
 		}

 		dev->virt_addr = ioremap(dev->phys_addr,
 					  props->periph_virt_size);
 		if (dev->virt_addr == NULL) {
 			SPS_ERR("sps:Unable to map BAM DMA IO memory: %pa %x",
 				&dev->phys_addr, props->periph_virt_size);
 			goto exit_err;
 		}
 		dev->virtual_mapped = true;
 	}
 	dev->hwio = (void *) dev->virt_addr;

 	/* Is the BAM-DMA device locally controlled? */
 	if ((props->manage & SPS_BAM_MGR_DEVICE_REMOTE) == 0) {
 		SPS_DBG2("sps:BAM-DMA is controlled locally: %pa",
 			&dev->phys_addr);
 		dev->local = true;
 	} else {
 		SPS_DBG2("sps:BAM-DMA is controlled remotely: %pa",
 			&dev->phys_addr);
 		dev->local = false;
 	}

 	/*
 	 * Enable the BAM DMA and determine the number of pipes/channels.
 	 * Leave the BAM-DMA enabled, since it is always a shared device.
 	 */
 	if (sps_dma_device_enable(dev))
 		goto exit_err;

 	dev->num_pipes = dev->bam->props.num_pipes;

 	result = 0;
 exit_err:
 	if (result) {
 		if (dev != NULL) {
 			if (dev->virtual_mapped)
 				iounmap(dev->virt_addr);

 			dev->bam = NULL;
 		}
 	}

 	mutex_unlock(&bam_dma_lock);

 	return result;
 }

 /**
  * De-initialize BAM DMA device
  *
  */
 int sps_dma_device_de_init(unsigned long h)
 {
 	struct bamdma_device *dev;
 	u32 pipe_index;
 	u32 chan;
 	int result = 0;

 	mutex_lock(&bam_dma_lock);

 	dev = sps_dma_find_device(h);
 	if (dev == NULL) {
 		SPS_ERR("sps:BAM-DMA: not registered: %lx", h);
 		result = SPS_ERROR;
 		goto exit_err;
 	}

 	/* Check for channel leaks */
 	for (chan = 0; chan < dev->num_pipes / 2; chan++) {
 		if (dev->chans[chan].state != DMA_CHAN_STATE_FREE) {
 			SPS_ERR("sps:BAM-DMA: channel not free: %d", chan);
 			result = SPS_ERROR;
 			dev->chans[chan].state = DMA_CHAN_STATE_FREE;
 		}
 	}
 	for (pipe_index = 0; pipe_index < dev->num_pipes; pipe_index++) {
 		if (dev->pipes[pipe_index] != PIPE_INACTIVE) {
 			SPS_ERR("sps:BAM-DMA: pipe not inactive: %d",
 					pipe_index);
 			result = SPS_ERROR;
 			dev->pipes[pipe_index] = PIPE_INACTIVE;
 		}
 	}

 	/* Disable BAM and BAM-DMA */
 	if (sps_dma_device_disable(dev))
 		result = SPS_ERROR;

 	dev->h = BAM_HANDLE_INVALID;
 	dev->bam = NULL;
 	if (dev->virtual_mapped)
 		iounmap(dev->virt_addr);

 exit_err:
 	mutex_unlock(&bam_dma_lock);

 	return result;
 }

 /**
  * Initialize BAM DMA module
  *
  */
 int sps_dma_init(const struct sps_bam_props *bam_props)
 {
 	struct sps_bam_props props;
 	const struct sps_bam_props *bam_reg;
 	unsigned long h;

 	/* Init local data */
 	memset(&bam_dma_dev, 0, sizeof(bam_dma_dev));
 	num_bams = 0;
 	memset(bam_handles, 0, sizeof(bam_handles));

 	/* Create a mutex to control access to the BAM-DMA devices */
 	mutex_init(&bam_dma_lock);

 	/* Are there any BAM DMA devices? */
 	if (bam_props == NULL)
 		return 0;

 	/*
 	 * Registers all BAMs in the BSP properties, but only uses the first
 	 * BAM-DMA device for allocations.
 	 */
 	if (bam_props->phys_addr) {
 		/* Force multi-EE option for all BAM-DMAs */
 		bam_reg = bam_props;
 		if ((bam_props->options & SPS_BAM_OPT_BAMDMA) &&
 		    (bam_props->manage & SPS_BAM_MGR_MULTI_EE) == 0) {
 			SPS_DBG("sps:Setting multi-EE options for BAM-DMA: %pa",
 				&bam_props->phys_addr);
 			props = *bam_props;
 			props.manage |= SPS_BAM_MGR_MULTI_EE;
 			bam_reg = &props;
 		}

 		/* Register the BAM */
 		if (sps_register_bam_device(bam_reg, &h)) {
 			SPS_ERR(
 				"sps:Fail to register BAM-DMA BAM device: "
 					"phys %pa", &bam_props->phys_addr);
 			return SPS_ERROR;
 		}

 		/* Record the BAM so that it may be deregistered later */
 		if (num_bams < MAX_BAM_DMA_BAMS) {
 			bam_handles[num_bams] = h;
 			num_bams++;
 		} else {
 			SPS_ERR("sps:BAM-DMA: BAM limit exceeded: %d",
 					num_bams);
 			return SPS_ERROR;
 		}
 	} else {
 		SPS_ERR("sps:BAM-DMA phys_addr is zero.");
 		return SPS_ERROR;
 	}


 	return 0;
 }

 /**
  * De-initialize BAM DMA module
  *
  */
 void sps_dma_de_init(void)
 {
 	int n;

 	/* De-initialize the BAM devices */
 	for (n = 0; n < num_bams; n++)
 		sps_deregister_bam_device(bam_handles[n]);

 	/* Clear local data */
 	memset(&bam_dma_dev, 0, sizeof(bam_dma_dev));
 	num_bams = 0;
 	memset(bam_handles, 0, sizeof(bam_handles));
 }

 /**
  * Allocate a BAM DMA channel
  *
  */
 int sps_alloc_dma_chan(const struct sps_alloc_dma_chan *alloc,
 		       struct sps_dma_chan *chan_info)
 {
 	struct bamdma_device *dev;
 	struct bamdma_chan *chan;
 	u32 pipe_index;
 	enum bam_dma_thresh_dma thresh = (enum bam_dma_thresh_dma) 0;
 	enum bam_dma_weight_dma weight = (enum bam_dma_weight_dma) 0;
 	int result = SPS_ERROR;

 	if (alloc == NULL || chan_info == NULL) {
 		SPS_ERR("sps:sps_alloc_dma_chan. invalid parameters");
 		return SPS_ERROR;
 	}

 	/* Translate threshold and priority to hwio values */
 	if (alloc->threshold != SPS_DMA_THRESHOLD_DEFAULT) {
 		if (alloc->threshold >= 512)
 			thresh = BAM_DMA_THRESH_512;
 		else if (alloc->threshold >= 256)
 			thresh = BAM_DMA_THRESH_256;
 		else if (alloc->threshold >= 128)
 			thresh = BAM_DMA_THRESH_128;
 		else
 			thresh = BAM_DMA_THRESH_64;
 	}

 	weight = alloc->priority;

 	if ((u32)alloc->priority > (u32)BAM_DMA_WEIGHT_HIGH) {
 		SPS_ERR("sps:BAM-DMA: invalid priority: %x", alloc->priority);
 		return SPS_ERROR;
 	}

 	mutex_lock(&bam_dma_lock);

 	dev = sps_dma_find_device(alloc->dev);
 	if (dev == NULL) {
 		SPS_ERR("sps:BAM-DMA: invalid BAM handle: %lx", alloc->dev);
 		goto exit_err;
 	}

 	/* Search for a free set of pipes */
 	for (pipe_index = 0, chan = dev->chans;
 	      pipe_index < dev->num_pipes; pipe_index += 2, chan++) {
 		if (chan->state == DMA_CHAN_STATE_FREE) {
 			/* Just check pipes for safety */
 			if (dev->pipes[pipe_index] != PIPE_INACTIVE ||
 			    dev->pipes[pipe_index + 1] != PIPE_INACTIVE) {
 				SPS_ERR("sps:BAM-DMA: channel %d state "
 					"error:%d %d",
 					pipe_index / 2, dev->pipes[pipe_index],
 				 dev->pipes[pipe_index + 1]);
 				goto exit_err;
 			}
 			break; /* Found free pipe */
 		}
 	}

 	if (pipe_index >= dev->num_pipes) {
 		SPS_ERR("sps:BAM-DMA: no free channel. num_pipes = %d",
 			dev->num_pipes);
 		goto exit_err;
 	}

 	chan->state = DMA_CHAN_STATE_ALLOC_EXT;

 	/* Store config values for use when pipes are activated */
 	chan = &dev->chans[pipe_index / 2];
 	chan->threshold = alloc->threshold;
 	chan->thresh = thresh;
 	chan->priority = alloc->priority;
 	chan->weight = weight;

 	SPS_DBG2("sps:sps_alloc_dma_chan. pipe %d.\n", pipe_index);

 	/* Report allocated pipes to client */
 	chan_info->dev = dev->h;
 	/* Dest/input/write pipex */
 	chan_info->dest_pipe_index = pipe_index;
 	/* Source/output/read pipe */
 	chan_info->src_pipe_index = pipe_index + 1;

 	result = 0;
 exit_err:
 	mutex_unlock(&bam_dma_lock);

 	return result;
 }
 EXPORT_SYMBOL(sps_alloc_dma_chan);

 /**
  * Free a BAM DMA channel
  *
  */
 int sps_free_dma_chan(struct sps_dma_chan *chan)
 {
 	struct bamdma_device *dev;
 	u32 pipe_index;
 	int result = 0;

 	if (chan == NULL) {
 		SPS_ERR("sps:sps_free_dma_chan. chan is NULL");
 		return SPS_ERROR;
 	}

 	mutex_lock(&bam_dma_lock);

 	dev = sps_dma_find_device(chan->dev);
 	if (dev == NULL) {
 		SPS_ERR("sps:BAM-DMA: invalid BAM handle: %lx", chan->dev);
 		result = SPS_ERROR;
 		goto exit_err;
 	}

 	/* Verify the pipe indices */
 	pipe_index = chan->dest_pipe_index;
 	if (pipe_index >= dev->num_pipes || ((pipe_index & 1)) ||
 	    (pipe_index + 1) != chan->src_pipe_index) {
 		SPS_ERR("sps:sps_free_dma_chan. Invalid pipe indices."
 			"num_pipes=%d.dest=%d.src=%d.",
 			dev->num_pipes,
 			chan->dest_pipe_index,
 			chan->src_pipe_index);
 		result = SPS_ERROR;
 		goto exit_err;
 	}

 	/* Are both pipes inactive? */
 	if (dev->chans[pipe_index / 2].state != DMA_CHAN_STATE_ALLOC_EXT ||
 	    dev->pipes[pipe_index] != PIPE_INACTIVE ||
 	    dev->pipes[pipe_index + 1] != PIPE_INACTIVE) {
 		SPS_ERR("sps:BAM-DMA: attempt to free active chan %d: %d %d",
 			pipe_index / 2, dev->pipes[pipe_index],
 			dev->pipes[pipe_index + 1]);
 		result = SPS_ERROR;
 		goto exit_err;
 	}

 	/* Free the channel */
 	dev->chans[pipe_index / 2].state = DMA_CHAN_STATE_FREE;

 exit_err:
 	mutex_unlock(&bam_dma_lock);

 	return result;
 }
 EXPORT_SYMBOL(sps_free_dma_chan);

 /**
  * Activate a BAM DMA pipe
  *
  * This function activates a BAM DMA pipe.
  *
  * @dev - pointer to BAM-DMA device descriptor
  *
  * @pipe_index - pipe index
  *
  * @return 0 on success, negative value on error
  *
  */
 static u32 sps_dma_check_pipes(struct bamdma_device *dev, u32 pipe_index)
 {
 	u32 pipe_in;
 	u32 pipe_out;
 	int enabled_in;
 	int enabled_out;
 	u32 check;

 	pipe_in = pipe_index & ~1;
 	pipe_out = pipe_in + 1;
 	enabled_in = bam_pipe_is_enabled(dev->bam->base, pipe_in);
 	enabled_out = bam_pipe_is_enabled(dev->bam->base, pipe_out);

 	if (!enabled_in && !enabled_out)
 		check = DMA_PIPES_BOTH_DISABLED;
 	else if (enabled_in && enabled_out)
 		check = DMA_PIPES_BOTH_ENABLED;
 	else
 		check = DMA_PIPES_STATE_DIFF;

 	return check;
 }

 /**
  * Allocate a BAM DMA pipe
  *
  */
 int sps_dma_pipe_alloc(void *bam_arg, u32 pipe_index, enum sps_mode dir)
 {
 	struct sps_bam *bam = bam_arg;
 	struct bamdma_device *dev;
 	struct bamdma_chan *chan;
 	u32 channel;
 	int result = SPS_ERROR;

 	if (bam == NULL) {
 		SPS_ERR("sps:BAM context is NULL");
 		return SPS_ERROR;
 	}

 	/* Check pipe direction */
 	if ((DMA_PIPE_IS_DEST(pipe_index) && dir != SPS_MODE_DEST) ||
 	    (DMA_PIPE_IS_SRC(pipe_index) && dir != SPS_MODE_SRC)) {
 		SPS_ERR("sps:BAM-DMA: wrong direction for BAM %pa pipe %d",
 			&bam->props.phys_addr, pipe_index);
 		return SPS_ERROR;
 	}

 	mutex_lock(&bam_dma_lock);

 	dev = sps_dma_find_device((unsigned long) bam);
 	if (dev == NULL) {
 		SPS_ERR("sps:BAM-DMA: invalid BAM: %pa",
 			&bam->props.phys_addr);
 		goto exit_err;
 	}
 	if (pipe_index >= dev->num_pipes) {
 		SPS_ERR("sps:BAM-DMA: BAM %pa invalid pipe: %d",
 			&bam->props.phys_addr, pipe_index);
 		goto exit_err;
 	}
 	if (dev->pipes[pipe_index] != PIPE_INACTIVE) {
 		SPS_ERR("sps:BAM-DMA: BAM %pa pipe %d already active",
 			&bam->props.phys_addr, pipe_index);
 		goto exit_err;
 	}

 	/* Mark pipe active */
 	dev->pipes[pipe_index] = PIPE_ACTIVE;

 	/* If channel is not allocated, make an internal allocation */
 	channel = pipe_index / 2;
 	chan = &dev->chans[channel];
 	if (chan->state != DMA_CHAN_STATE_ALLOC_EXT &&
 	    chan->state != DMA_CHAN_STATE_ALLOC_INT) {
 		chan->state = DMA_CHAN_STATE_ALLOC_INT;
 	}

 	result = 0;
 exit_err:
 	mutex_unlock(&bam_dma_lock);

 	return result;
 }

 /**
  * Enable a BAM DMA pipe
  *
  */
 int sps_dma_pipe_enable(void *bam_arg, u32 pipe_index)
 {
 	struct sps_bam *bam = bam_arg;
 	struct bamdma_device *dev;
 	struct bamdma_chan *chan;
 	u32 channel;
 	int result = SPS_ERROR;

 	SPS_DBG2("sps:sps_dma_pipe_enable.pipe %d", pipe_index);

 	mutex_lock(&bam_dma_lock);

 	dev = sps_dma_find_device((unsigned long) bam);
 	if (dev == NULL) {
 		SPS_ERR("sps:BAM-DMA: invalid BAM");
 		goto exit_err;
 	}
 	if (pipe_index >= dev->num_pipes) {
 		SPS_ERR("sps:BAM-DMA: BAM %pa invalid pipe: %d",
 			&bam->props.phys_addr, pipe_index);
 		goto exit_err;
 	}
 	if (dev->pipes[pipe_index] != PIPE_ACTIVE) {
 		SPS_ERR("sps:BAM-DMA: BAM %pa pipe %d not active",
 			&bam->props.phys_addr, pipe_index);
 		goto exit_err;
 	}

       /*
        * The channel must be enabled when the dest/input/write pipe
        * is enabled
        */
 	if (DMA_PIPE_IS_DEST(pipe_index)) {
 		/* Configure and enable the channel */
 		channel = pipe_index / 2;
 		chan = &dev->chans[channel];

 		if (chan->threshold != SPS_DMA_THRESHOLD_DEFAULT)
 			dma_write_reg_field(dev->virt_addr,
 					    DMA_CHNL_CONFIG(channel),
 					    DMA_CHNL_ACT_THRESH,
 					    chan->thresh);

 		if (chan->priority != SPS_DMA_PRI_DEFAULT)
 			dma_write_reg_field(dev->virt_addr,
 					    DMA_CHNL_CONFIG(channel),
 					    DMA_CHNL_WEIGHT,
 					    chan->weight);

 		dma_write_reg_field(dev->virt_addr,
 				    DMA_CHNL_CONFIG(channel),
 				    DMA_CHNL_ENABLE, 1);
 	}

 	result = 0;
 exit_err:
 	mutex_unlock(&bam_dma_lock);

 	return result;
 }

 /**
  * Deactivate a BAM DMA pipe
  *
  * This function deactivates a BAM DMA pipe.
  *
  * @dev - pointer to BAM-DMA device descriptor
  *
  * @bam - pointer to BAM device descriptor
  *
  * @pipe_index - pipe index
  *
  * @return 0 on success, negative value on error
  *
  */
 static int sps_dma_deactivate_pipe_atomic(struct bamdma_device *dev,
 					  struct sps_bam *bam,
 					  u32 pipe_index)
 {
 	u32 channel;

 	if (dev->bam != bam)
 		return SPS_ERROR;
 	if (pipe_index >= dev->num_pipes)
 		return SPS_ERROR;
 	if (dev->pipes[pipe_index] != PIPE_ACTIVE)
 		return SPS_ERROR;	/* Pipe is not active */

 	SPS_DBG2("sps:BAM-DMA: deactivate pipe %d", pipe_index);

 	/* Mark pipe inactive */
 	dev->pipes[pipe_index] = PIPE_INACTIVE;

 	/*
 	 * Channel must be reset when either pipe is disabled, so just always
 	 * reset regardless of other pipe's state
 	 */
 	channel = pipe_index / 2;
 	dma_write_reg_field(dev->virt_addr, DMA_CHNL_CONFIG(channel),
 			    DMA_CHNL_ENABLE, 0);

 	/* If the peer pipe is also inactive, reset the channel */
 	if (sps_dma_check_pipes(dev, pipe_index) == DMA_PIPES_BOTH_DISABLED) {
 		/* Free channel if allocated internally */
 		if (dev->chans[channel].state == DMA_CHAN_STATE_ALLOC_INT)
 			dev->chans[channel].state = DMA_CHAN_STATE_FREE;
 	}

 	return 0;
 }

 /**
  * Free a BAM DMA pipe
  *
  */
 int sps_dma_pipe_free(void *bam_arg, u32 pipe_index)
 {
 	struct bamdma_device *dev;
 	struct sps_bam *bam = bam_arg;
 	int result;

 	mutex_lock(&bam_dma_lock);

 	dev = sps_dma_find_device((unsigned long) bam);
 	if (dev == NULL) {
 		SPS_ERR("sps:BAM-DMA: invalid BAM");
 		result = SPS_ERROR;
 		goto exit_err;
 	}

 	result = sps_dma_deactivate_pipe_atomic(dev, bam, pipe_index);

 exit_err:
 	mutex_unlock(&bam_dma_lock);

 	return result;
 }

 /**
  * Get the BAM handle for BAM-DMA.
  *
  * The BAM handle should be use as source/destination in the sps_connect().
  *
  * @return bam handle on success, zero on error
  */
 unsigned long sps_dma_get_bam_handle(void)
 {
 	return (unsigned long)bam_dma_dev[0].bam;
 }
 EXPORT_SYMBOL(sps_dma_get_bam_handle);

 /**
  * Free the BAM handle for BAM-DMA.
  *
  */
 void sps_dma_free_bam_handle(unsigned long h)
 {
 }
 EXPORT_SYMBOL(sps_dma_free_bam_handle);

 #endif /* CONFIG_SPS_SUPPORT_BAMDMA */
	/* Copyright (c) 2011-2013, The Linux Foundation. All rights reserved.
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 and
	* only version 2 as published by the Free Software Foundation.
	*
	* 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.
	*/

	/* BAM-DMA Manager. */

	#ifdef CONFIG_SPS_SUPPORT_BAMDMA

	#include <linux/export.h>
	#include <linux/memory.h> /* memset */

	#include "spsi.h"
	#include "bam.h"
	#include "sps_bam.h" /* bam_dma_thresh_dma */
	#include "sps_core.h" /* sps_h2bam() */

	/**
	* registers
	*/

	#define DMA_ENBL (0x00000000)
	#ifdef CONFIG_SPS_SUPPORT_NDP_BAM
	#define DMA_REVISION (0x00000004)
	#define DMA_CONFIG (0x00000008)
	#define DMA_CHNL_CONFIG(n) (0x00001000 + 4096 * (n))
	#else
	#define DMA_CHNL_CONFIG(n) (0x00000004 + 4 * (n))
	#define DMA_CONFIG (0x00000040)
	#endif

	/**
	* masks
	*/

	/* DMA_CHNL_confign */
	#ifdef CONFIG_SPS_SUPPORT_NDP_BAM
	#define DMA_CHNL_PRODUCER_PIPE_ENABLED 0x40000
	#define DMA_CHNL_CONSUMER_PIPE_ENABLED 0x20000
	#endif
	#define DMA_CHNL_HALT_DONE 0x10000
	#define DMA_CHNL_HALT 0x1000
	#define DMA_CHNL_ENABLE 0x100
	#define DMA_CHNL_ACT_THRESH 0x30
	#define DMA_CHNL_WEIGHT 0x7

	/* DMA_CONFIG */
	#define TESTBUS_SELECT 0x3

	/**
	*
	* Write register with debug info.
	*
	* @base - bam base virtual address.
	* @offset - register offset.
	* @val - value to write.
	*
	*/
	static inline void dma_write_reg(void *base, u32 offset, u32 val)
	{
	iowrite32(val, base + offset);
	SPS_DBG("sps:bamdma: write reg 0x%x w_val 0x%x.", offset, val);
	}

	/**
	* Write register masked field with debug info.
	*
	* @base - bam base virtual address.
	* @offset - register offset.
	* @mask - register bitmask.
	* @val - value to write.
	*
	*/
	static inline void dma_write_reg_field(void *base, u32 offset,
	const u32 mask, u32 val)
	{
	u32 shift = find_first_bit((void *)&mask, 32);
	u32 tmp = ioread32(base + offset);

	tmp &= ~mask; /* clear written bits */
	val = tmp \| (val << shift);
	iowrite32(val, base + offset);
	SPS_DBG("sps:bamdma: write reg 0x%x w_val 0x%x.", offset, val);
	}

	/* Round max number of pipes to nearest multiple of 2 */
	#define DMA_MAX_PIPES ((BAM_MAX_PIPES / 2) * 2)

	/* Maximum number of BAM-DMAs supported */
	#define MAX_BAM_DMA_DEVICES 1

	/* Maximum number of BAMs that will be registered */
	#define MAX_BAM_DMA_BAMS 1

	/* Pipe enable check values */
	#define DMA_PIPES_STATE_DIFF 0
	#define DMA_PIPES_BOTH_DISABLED 1
	#define DMA_PIPES_BOTH_ENABLED 2

	/* Even pipe is tx/dest/input/write, odd pipe is rx/src/output/read */
	#define DMA_PIPE_IS_DEST(p) (((p) & 1) == 0)
	#define DMA_PIPE_IS_SRC(p) (((p) & 1) != 0)

	/* BAM DMA pipe state */
	enum bamdma_pipe_state {
	PIPE_INACTIVE = 0,
	PIPE_ACTIVE
	};

	/* BAM DMA channel state */
	enum bamdma_chan_state {
	DMA_CHAN_STATE_FREE = 0,
	DMA_CHAN_STATE_ALLOC_EXT, /* Client allocation */
	DMA_CHAN_STATE_ALLOC_INT /* Internal (resource mgr) allocation */
	};

	struct bamdma_chan {
	/* Allocation state */
	enum bamdma_chan_state state;

	/* BAM DMA channel configuration parameters */
	u32 threshold;
	enum sps_dma_priority priority;

	/* HWIO channel configuration parameters */
	enum bam_dma_thresh_dma thresh;
	enum bam_dma_weight_dma weight;

	};

	/* BAM DMA device state */
	struct bamdma_device {
	/* BAM-DMA device state */
	int enabled;
	int local;

	/* BAM device state */
	struct sps_bam *bam;

	/* BAM handle, for deregistration */
	unsigned long h;

	/* BAM DMA device virtual mapping */
	void *virt_addr;
	int virtual_mapped;
	phys_addr_t phys_addr;
	void *hwio;

	/* BAM DMA pipe/channel state */
	u32 num_pipes;
	enum bamdma_pipe_state pipes[DMA_MAX_PIPES];
	struct bamdma_chan chans[DMA_MAX_PIPES / 2];

	};

	/* BAM-DMA devices */
	static struct bamdma_device bam_dma_dev[MAX_BAM_DMA_DEVICES];
	static struct mutex bam_dma_lock;

	/*
	* The BAM DMA module registers all BAMs in the BSP properties, but only
	* uses the first BAM-DMA device for allocations. References to the others
	* are stored in the following data array.
	*/
	static int num_bams;
	static unsigned long bam_handles[MAX_BAM_DMA_BAMS];

	/**
	* Find BAM-DMA device
	*
	* This function finds the BAM-DMA device associated with the BAM handle.
	*
	* @h - BAM handle
	*
	* @return - pointer to BAM-DMA device, or NULL on error
	*
	*/
	static struct bamdma_device *sps_dma_find_device(unsigned long h)
	{
	return &bam_dma_dev[0];
	}

	/**
	* BAM DMA device enable
	*
	* This function enables a BAM DMA device and the associated BAM.
	*
	* @dev - pointer to BAM DMA device context
	*
	* @return 0 on success, negative value on error
	*
	*/
	static int sps_dma_device_enable(struct bamdma_device *dev)
	{
	if (dev->enabled)
	return 0;

	/*
	* If the BAM-DMA device is locally controlled then enable BAM-DMA
	* device
	*/
	if (dev->local)
	dma_write_reg(dev->virt_addr, DMA_ENBL, 1);

	/* Enable BAM device */
	if (sps_bam_enable(dev->bam)) {
	SPS_ERR("sps:Failed to enable BAM DMA's BAM: %pa",
	&dev->phys_addr);
	return SPS_ERROR;
	}

	dev->enabled = true;

	return 0;
	}

	/**
	* BAM DMA device enable
	*
	* This function initializes a BAM DMA device.
	*
	* @dev - pointer to BAM DMA device context
	*
	* @return 0 on success, negative value on error
	*
	*/
	static int sps_dma_device_disable(struct bamdma_device *dev)
	{
	u32 pipe_index;

	if (!dev->enabled)
	return 0;

	/* Do not disable if channels active */
	for (pipe_index = 0; pipe_index < dev->num_pipes; pipe_index++) {
	if (dev->pipes[pipe_index] != PIPE_INACTIVE)
	break;
	}

	if (pipe_index < dev->num_pipes) {
	SPS_ERR("sps:Fail to disable BAM-DMA %pa:channels are active",
	&dev->phys_addr);
	return SPS_ERROR;
	}

	dev->enabled = false;

	/* Disable BAM device */
	if (sps_bam_disable(dev->bam)) {
	SPS_ERR("sps:Fail to disable BAM-DMA BAM:%pa", &dev->phys_addr);
	return SPS_ERROR;
	}

	/* Is the BAM-DMA device locally controlled? */
	if (dev->local)
	/* Disable BAM-DMA device */
	dma_write_reg(dev->virt_addr, DMA_ENBL, 0);

	return 0;
	}

	/**
	* Initialize BAM DMA device
	*
	*/
	int sps_dma_device_init(unsigned long h)
	{
	struct bamdma_device *dev;
	struct sps_bam_props *props;
	int result = SPS_ERROR;

	mutex_lock(&bam_dma_lock);

	/* Find a free BAM-DMA device slot */
	dev = NULL;
	if (bam_dma_dev[0].bam != NULL) {
	SPS_ERR("sps:BAM-DMA BAM device is already initialized.");
	goto exit_err;
	} else {
	dev = &bam_dma_dev[0];
	}

	/* Record BAM */
	memset(dev, 0, sizeof(*dev));
	dev->h = h;
	dev->bam = sps_h2bam(h);

	if (dev->bam == NULL) {
	SPS_ERR("sps:BAM-DMA BAM device is not found "
	"from the handle.");
	goto exit_err;
	}

	/* Map the BAM DMA device into virtual space, if necessary */
	props = &dev->bam->props;
	dev->phys_addr = props->periph_phys_addr;
	if (props->periph_virt_addr != NULL) {
	dev->virt_addr = props->periph_virt_addr;
	dev->virtual_mapped = false;
	} else {
	if (props->periph_virt_size == 0) {
	SPS_ERR("sps:Unable to map BAM DMA IO memory: %pa %x",
	&dev->phys_addr, props->periph_virt_size);
	goto exit_err;
	}

	dev->virt_addr = ioremap(dev->phys_addr,
	props->periph_virt_size);
	if (dev->virt_addr == NULL) {
	SPS_ERR("sps:Unable to map BAM DMA IO memory: %pa %x",
	&dev->phys_addr, props->periph_virt_size);
	goto exit_err;
	}
	dev->virtual_mapped = true;
	}
	dev->hwio = (void *) dev->virt_addr;

	/* Is the BAM-DMA device locally controlled? */
	if ((props->manage & SPS_BAM_MGR_DEVICE_REMOTE) == 0) {
	SPS_DBG2("sps:BAM-DMA is controlled locally: %pa",
	&dev->phys_addr);
	dev->local = true;
	} else {
	SPS_DBG2("sps:BAM-DMA is controlled remotely: %pa",
	&dev->phys_addr);
	dev->local = false;
	}

	/*
	* Enable the BAM DMA and determine the number of pipes/channels.
	* Leave the BAM-DMA enabled, since it is always a shared device.
	*/
	if (sps_dma_device_enable(dev))
	goto exit_err;

	dev->num_pipes = dev->bam->props.num_pipes;

	result = 0;
	exit_err:
	if (result) {
	if (dev != NULL) {
	if (dev->virtual_mapped)
	iounmap(dev->virt_addr);

	dev->bam = NULL;
	}
	}

	mutex_unlock(&bam_dma_lock);

	return result;
	}

	/**
	* De-initialize BAM DMA device
	*
	*/
	int sps_dma_device_de_init(unsigned long h)
	{
	struct bamdma_device *dev;
	u32 pipe_index;
	u32 chan;
	int result = 0;

	mutex_lock(&bam_dma_lock);

	dev = sps_dma_find_device(h);
	if (dev == NULL) {
	SPS_ERR("sps:BAM-DMA: not registered: %lx", h);
	result = SPS_ERROR;
	goto exit_err;
	}

	/* Check for channel leaks */
	for (chan = 0; chan < dev->num_pipes / 2; chan++) {
	if (dev->chans[chan].state != DMA_CHAN_STATE_FREE) {
	SPS_ERR("sps:BAM-DMA: channel not free: %d", chan);
	result = SPS_ERROR;
	dev->chans[chan].state = DMA_CHAN_STATE_FREE;
	}
	}
	for (pipe_index = 0; pipe_index < dev->num_pipes; pipe_index++) {
	if (dev->pipes[pipe_index] != PIPE_INACTIVE) {
	SPS_ERR("sps:BAM-DMA: pipe not inactive: %d",
	pipe_index);
	result = SPS_ERROR;
	dev->pipes[pipe_index] = PIPE_INACTIVE;
	}
	}

	/* Disable BAM and BAM-DMA */
	if (sps_dma_device_disable(dev))
	result = SPS_ERROR;

	dev->h = BAM_HANDLE_INVALID;
	dev->bam = NULL;
	if (dev->virtual_mapped)
	iounmap(dev->virt_addr);

	exit_err:
	mutex_unlock(&bam_dma_lock);

	return result;
	}

	/**
	* Initialize BAM DMA module
	*
	*/
	int sps_dma_init(const struct sps_bam_props *bam_props)
	{
	struct sps_bam_props props;
	const struct sps_bam_props *bam_reg;
	unsigned long h;

	/* Init local data */
	memset(&bam_dma_dev, 0, sizeof(bam_dma_dev));
	num_bams = 0;
	memset(bam_handles, 0, sizeof(bam_handles));

	/* Create a mutex to control access to the BAM-DMA devices */
	mutex_init(&bam_dma_lock);

	/* Are there any BAM DMA devices? */
	if (bam_props == NULL)
	return 0;

	/*
	* Registers all BAMs in the BSP properties, but only uses the first
	* BAM-DMA device for allocations.
	*/
	if (bam_props->phys_addr) {
	/* Force multi-EE option for all BAM-DMAs */
	bam_reg = bam_props;
	if ((bam_props->options & SPS_BAM_OPT_BAMDMA) &&
	(bam_props->manage & SPS_BAM_MGR_MULTI_EE) == 0) {
	SPS_DBG("sps:Setting multi-EE options for BAM-DMA: %pa",
	&bam_props->phys_addr);
	props = *bam_props;
	props.manage \|= SPS_BAM_MGR_MULTI_EE;
	bam_reg = &props;
	}

	/* Register the BAM */
	if (sps_register_bam_device(bam_reg, &h)) {
	SPS_ERR(
	"sps:Fail to register BAM-DMA BAM device: "
	"phys %pa", &bam_props->phys_addr);
	return SPS_ERROR;
	}

	/* Record the BAM so that it may be deregistered later */
	if (num_bams < MAX_BAM_DMA_BAMS) {
	bam_handles[num_bams] = h;
	num_bams++;
	} else {
	SPS_ERR("sps:BAM-DMA: BAM limit exceeded: %d",
	num_bams);
	return SPS_ERROR;
	}
	} else {
	SPS_ERR("sps:BAM-DMA phys_addr is zero.");
	return SPS_ERROR;
	}


	return 0;
	}

	/**
	* De-initialize BAM DMA module
	*
	*/
	void sps_dma_de_init(void)
	{
	int n;

	/* De-initialize the BAM devices */
	for (n = 0; n < num_bams; n++)
	sps_deregister_bam_device(bam_handles[n]);

	/* Clear local data */
	memset(&bam_dma_dev, 0, sizeof(bam_dma_dev));
	num_bams = 0;
	memset(bam_handles, 0, sizeof(bam_handles));
	}

	/**
	* Allocate a BAM DMA channel
	*
	*/
	int sps_alloc_dma_chan(const struct sps_alloc_dma_chan *alloc,
	struct sps_dma_chan *chan_info)
	{
	struct bamdma_device *dev;
	struct bamdma_chan *chan;
	u32 pipe_index;
	enum bam_dma_thresh_dma thresh = (enum bam_dma_thresh_dma) 0;
	enum bam_dma_weight_dma weight = (enum bam_dma_weight_dma) 0;
	int result = SPS_ERROR;

	if (alloc == NULL \|\| chan_info == NULL) {
	SPS_ERR("sps:sps_alloc_dma_chan. invalid parameters");
	return SPS_ERROR;
	}

	/* Translate threshold and priority to hwio values */
	if (alloc->threshold != SPS_DMA_THRESHOLD_DEFAULT) {
	if (alloc->threshold >= 512)
	thresh = BAM_DMA_THRESH_512;
	else if (alloc->threshold >= 256)
	thresh = BAM_DMA_THRESH_256;
	else if (alloc->threshold >= 128)
	thresh = BAM_DMA_THRESH_128;
	else
	thresh = BAM_DMA_THRESH_64;
	}

	weight = alloc->priority;

	if ((u32)alloc->priority > (u32)BAM_DMA_WEIGHT_HIGH) {
	SPS_ERR("sps:BAM-DMA: invalid priority: %x", alloc->priority);
	return SPS_ERROR;
	}

	mutex_lock(&bam_dma_lock);

	dev = sps_dma_find_device(alloc->dev);
	if (dev == NULL) {
	SPS_ERR("sps:BAM-DMA: invalid BAM handle: %lx", alloc->dev);
	goto exit_err;
	}

	/* Search for a free set of pipes */
	for (pipe_index = 0, chan = dev->chans;
	pipe_index < dev->num_pipes; pipe_index += 2, chan++) {
	if (chan->state == DMA_CHAN_STATE_FREE) {
	/* Just check pipes for safety */
	if (dev->pipes[pipe_index] != PIPE_INACTIVE \|\|
	dev->pipes[pipe_index + 1] != PIPE_INACTIVE) {
	SPS_ERR("sps:BAM-DMA: channel %d state "
	"error:%d %d",
	pipe_index / 2, dev->pipes[pipe_index],
	dev->pipes[pipe_index + 1]);
	goto exit_err;
	}
	break; /* Found free pipe */
	}
	}

	if (pipe_index >= dev->num_pipes) {
	SPS_ERR("sps:BAM-DMA: no free channel. num_pipes = %d",
	dev->num_pipes);
	goto exit_err;
	}

	chan->state = DMA_CHAN_STATE_ALLOC_EXT;

	/* Store config values for use when pipes are activated */
	chan = &dev->chans[pipe_index / 2];
	chan->threshold = alloc->threshold;
	chan->thresh = thresh;
	chan->priority = alloc->priority;
	chan->weight = weight;

	SPS_DBG2("sps:sps_alloc_dma_chan. pipe %d.\n", pipe_index);

	/* Report allocated pipes to client */
	chan_info->dev = dev->h;
	/* Dest/input/write pipex */
	chan_info->dest_pipe_index = pipe_index;
	/* Source/output/read pipe */
	chan_info->src_pipe_index = pipe_index + 1;

	result = 0;
	exit_err:
	mutex_unlock(&bam_dma_lock);

	return result;
	}
	EXPORT_SYMBOL(sps_alloc_dma_chan);

	/**
	* Free a BAM DMA channel
	*
	*/
	int sps_free_dma_chan(struct sps_dma_chan *chan)
	{
	struct bamdma_device *dev;
	u32 pipe_index;
	int result = 0;

	if (chan == NULL) {
	SPS_ERR("sps:sps_free_dma_chan. chan is NULL");
	return SPS_ERROR;
	}

	mutex_lock(&bam_dma_lock);

	dev = sps_dma_find_device(chan->dev);
	if (dev == NULL) {
	SPS_ERR("sps:BAM-DMA: invalid BAM handle: %lx", chan->dev);
	result = SPS_ERROR;
	goto exit_err;
	}

	/* Verify the pipe indices */
	pipe_index = chan->dest_pipe_index;
	if (pipe_index >= dev->num_pipes \|\| ((pipe_index & 1)) \|\|
	(pipe_index + 1) != chan->src_pipe_index) {
	SPS_ERR("sps:sps_free_dma_chan. Invalid pipe indices."
	"num_pipes=%d.dest=%d.src=%d.",
	dev->num_pipes,
	chan->dest_pipe_index,
	chan->src_pipe_index);
	result = SPS_ERROR;
	goto exit_err;
	}

	/* Are both pipes inactive? */
	if (dev->chans[pipe_index / 2].state != DMA_CHAN_STATE_ALLOC_EXT \|\|
	dev->pipes[pipe_index] != PIPE_INACTIVE \|\|
	dev->pipes[pipe_index + 1] != PIPE_INACTIVE) {
	SPS_ERR("sps:BAM-DMA: attempt to free active chan %d: %d %d",
	pipe_index / 2, dev->pipes[pipe_index],
	dev->pipes[pipe_index + 1]);
	result = SPS_ERROR;
	goto exit_err;
	}

	/* Free the channel */
	dev->chans[pipe_index / 2].state = DMA_CHAN_STATE_FREE;

	exit_err:
	mutex_unlock(&bam_dma_lock);

	return result;
	}
	EXPORT_SYMBOL(sps_free_dma_chan);

	/**
	* Activate a BAM DMA pipe
	*
	* This function activates a BAM DMA pipe.
	*
	* @dev - pointer to BAM-DMA device descriptor
	*
	* @pipe_index - pipe index
	*
	* @return 0 on success, negative value on error
	*
	*/
	static u32 sps_dma_check_pipes(struct bamdma_device *dev, u32 pipe_index)
	{
	u32 pipe_in;
	u32 pipe_out;
	int enabled_in;
	int enabled_out;
	u32 check;

	pipe_in = pipe_index & ~1;
	pipe_out = pipe_in + 1;
	enabled_in = bam_pipe_is_enabled(dev->bam->base, pipe_in);
	enabled_out = bam_pipe_is_enabled(dev->bam->base, pipe_out);

	if (!enabled_in && !enabled_out)
	check = DMA_PIPES_BOTH_DISABLED;
	else if (enabled_in && enabled_out)
	check = DMA_PIPES_BOTH_ENABLED;
	else
	check = DMA_PIPES_STATE_DIFF;

	return check;
	}

	/**
	* Allocate a BAM DMA pipe
	*
	*/
	int sps_dma_pipe_alloc(void *bam_arg, u32 pipe_index, enum sps_mode dir)
	{
	struct sps_bam *bam = bam_arg;
	struct bamdma_device *dev;
	struct bamdma_chan *chan;
	u32 channel;
	int result = SPS_ERROR;

	if (bam == NULL) {
	SPS_ERR("sps:BAM context is NULL");
	return SPS_ERROR;
	}

	/* Check pipe direction */
	if ((DMA_PIPE_IS_DEST(pipe_index) && dir != SPS_MODE_DEST) \|\|
	(DMA_PIPE_IS_SRC(pipe_index) && dir != SPS_MODE_SRC)) {
	SPS_ERR("sps:BAM-DMA: wrong direction for BAM %pa pipe %d",
	&bam->props.phys_addr, pipe_index);
	return SPS_ERROR;
	}

	mutex_lock(&bam_dma_lock);

	dev = sps_dma_find_device((unsigned long) bam);
	if (dev == NULL) {
	SPS_ERR("sps:BAM-DMA: invalid BAM: %pa",
	&bam->props.phys_addr);
	goto exit_err;
	}
	if (pipe_index >= dev->num_pipes) {
	SPS_ERR("sps:BAM-DMA: BAM %pa invalid pipe: %d",
	&bam->props.phys_addr, pipe_index);
	goto exit_err;
	}
	if (dev->pipes[pipe_index] != PIPE_INACTIVE) {
	SPS_ERR("sps:BAM-DMA: BAM %pa pipe %d already active",
	&bam->props.phys_addr, pipe_index);
	goto exit_err;
	}

	/* Mark pipe active */
	dev->pipes[pipe_index] = PIPE_ACTIVE;

	/* If channel is not allocated, make an internal allocation */
	channel = pipe_index / 2;
	chan = &dev->chans[channel];
	if (chan->state != DMA_CHAN_STATE_ALLOC_EXT &&
	chan->state != DMA_CHAN_STATE_ALLOC_INT) {
	chan->state = DMA_CHAN_STATE_ALLOC_INT;
	}

	result = 0;
	exit_err:
	mutex_unlock(&bam_dma_lock);

	return result;
	}

	/**
	* Enable a BAM DMA pipe
	*
	*/
	int sps_dma_pipe_enable(void *bam_arg, u32 pipe_index)
	{
	struct sps_bam *bam = bam_arg;
	struct bamdma_device *dev;
	struct bamdma_chan *chan;
	u32 channel;
	int result = SPS_ERROR;

	SPS_DBG2("sps:sps_dma_pipe_enable.pipe %d", pipe_index);

	mutex_lock(&bam_dma_lock);

	dev = sps_dma_find_device((unsigned long) bam);
	if (dev == NULL) {
	SPS_ERR("sps:BAM-DMA: invalid BAM");
	goto exit_err;
	}
	if (pipe_index >= dev->num_pipes) {
	SPS_ERR("sps:BAM-DMA: BAM %pa invalid pipe: %d",
	&bam->props.phys_addr, pipe_index);
	goto exit_err;
	}
	if (dev->pipes[pipe_index] != PIPE_ACTIVE) {
	SPS_ERR("sps:BAM-DMA: BAM %pa pipe %d not active",
	&bam->props.phys_addr, pipe_index);
	goto exit_err;
	}

	/*
	* The channel must be enabled when the dest/input/write pipe
	* is enabled
	*/
	if (DMA_PIPE_IS_DEST(pipe_index)) {
	/* Configure and enable the channel */
	channel = pipe_index / 2;
	chan = &dev->chans[channel];

	if (chan->threshold != SPS_DMA_THRESHOLD_DEFAULT)
	dma_write_reg_field(dev->virt_addr,
	DMA_CHNL_CONFIG(channel),
	DMA_CHNL_ACT_THRESH,
	chan->thresh);

	if (chan->priority != SPS_DMA_PRI_DEFAULT)
	dma_write_reg_field(dev->virt_addr,
	DMA_CHNL_CONFIG(channel),
	DMA_CHNL_WEIGHT,
	chan->weight);

	dma_write_reg_field(dev->virt_addr,
	DMA_CHNL_CONFIG(channel),
	DMA_CHNL_ENABLE, 1);
	}

	result = 0;
	exit_err:
	mutex_unlock(&bam_dma_lock);

	return result;
	}

	/**
	* Deactivate a BAM DMA pipe
	*
	* This function deactivates a BAM DMA pipe.
	*
	* @dev - pointer to BAM-DMA device descriptor
	*
	* @bam - pointer to BAM device descriptor
	*
	* @pipe_index - pipe index
	*
	* @return 0 on success, negative value on error
	*
	*/
	static int sps_dma_deactivate_pipe_atomic(struct bamdma_device *dev,
	struct sps_bam *bam,
	u32 pipe_index)
	{
	u32 channel;

	if (dev->bam != bam)
	return SPS_ERROR;
	if (pipe_index >= dev->num_pipes)
	return SPS_ERROR;
	if (dev->pipes[pipe_index] != PIPE_ACTIVE)
	return SPS_ERROR; /* Pipe is not active */

	SPS_DBG2("sps:BAM-DMA: deactivate pipe %d", pipe_index);

	/* Mark pipe inactive */
	dev->pipes[pipe_index] = PIPE_INACTIVE;

	/*
	* Channel must be reset when either pipe is disabled, so just always
	* reset regardless of other pipe's state
	*/
	channel = pipe_index / 2;
	dma_write_reg_field(dev->virt_addr, DMA_CHNL_CONFIG(channel),
	DMA_CHNL_ENABLE, 0);

	/* If the peer pipe is also inactive, reset the channel */
	if (sps_dma_check_pipes(dev, pipe_index) == DMA_PIPES_BOTH_DISABLED) {
	/* Free channel if allocated internally */
	if (dev->chans[channel].state == DMA_CHAN_STATE_ALLOC_INT)
	dev->chans[channel].state = DMA_CHAN_STATE_FREE;
	}

	return 0;
	}

	/**
	* Free a BAM DMA pipe
	*
	*/
	int sps_dma_pipe_free(void *bam_arg, u32 pipe_index)
	{
	struct bamdma_device *dev;
	struct sps_bam *bam = bam_arg;
	int result;

	mutex_lock(&bam_dma_lock);

	dev = sps_dma_find_device((unsigned long) bam);
	if (dev == NULL) {
	SPS_ERR("sps:BAM-DMA: invalid BAM");
	result = SPS_ERROR;
	goto exit_err;
	}

	result = sps_dma_deactivate_pipe_atomic(dev, bam, pipe_index);

	exit_err:
	mutex_unlock(&bam_dma_lock);

	return result;
	}

	/**
	* Get the BAM handle for BAM-DMA.
	*
	* The BAM handle should be use as source/destination in the sps_connect().
	*
	* @return bam handle on success, zero on error
	*/
	unsigned long sps_dma_get_bam_handle(void)
	{
	return (unsigned long)bam_dma_dev[0].bam;
	}
	EXPORT_SYMBOL(sps_dma_get_bam_handle);

	/**
	* Free the BAM handle for BAM-DMA.
	*
	*/
	void sps_dma_free_bam_handle(unsigned long h)
	{
	}
	EXPORT_SYMBOL(sps_dma_free_bam_handle);

	#endif /* CONFIG_SPS_SUPPORT_BAMDMA */