drivers/gpu/host1x/cdma.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0-only
 /*
  * Tegra host1x Command DMA
  *
  * Copyright (c) 2010-2013, NVIDIA Corporation.
  */


 #include <asm/cacheflush.h>
 #include <linux/device.h>
 #include <linux/dma-mapping.h>
 #include <linux/host1x.h>
 #include <linux/interrupt.h>
 #include <linux/kernel.h>
 #include <linux/kfifo.h>
 #include <linux/slab.h>
 #include <trace/events/host1x.h>

 #include "cdma.h"
 #include "channel.h"
 #include "dev.h"
 #include "debug.h"
 #include "job.h"

 /*
  * push_buffer
  *
  * The push buffer is a circular array of words to be fetched by command DMA.
  * Note that it works slightly differently to the sync queue; fence == pos
  * means that the push buffer is full, not empty.
  */

 /*
  * Typically the commands written into the push buffer are a pair of words. We
  * use slots to represent each of these pairs and to simplify things. Note the
  * strange number of slots allocated here. 512 slots will fit exactly within a
  * single memory page. We also need one additional word at the end of the push
  * buffer for the RESTART opcode that will instruct the CDMA to jump back to
  * the beginning of the push buffer. With 512 slots, this means that we'll use
  * 2 memory pages and waste 4092 bytes of the second page that will never be
  * used.
  */
 #define HOST1X_PUSHBUFFER_SLOTS	511

 /*
  * Clean up push buffer resources
  */
 static void host1x_pushbuffer_destroy(struct push_buffer *pb)
 {
 	struct host1x_cdma *cdma = pb_to_cdma(pb);
 	struct host1x *host1x = cdma_to_host1x(cdma);

 	if (!pb->mapped)
 		return;

 	if (host1x->domain) {
 		iommu_unmap(host1x->domain, pb->dma, pb->alloc_size);
 		free_iova(&host1x->iova, iova_pfn(&host1x->iova, pb->dma));
 	}

 	dma_free_wc(host1x->dev, pb->alloc_size, pb->mapped, pb->phys);

 	pb->mapped = NULL;
 	pb->phys = 0;
 }

 /*
  * Init push buffer resources
  */
 static int host1x_pushbuffer_init(struct push_buffer *pb)
 {
 	struct host1x_cdma *cdma = pb_to_cdma(pb);
 	struct host1x *host1x = cdma_to_host1x(cdma);
 	struct iova *alloc;
 	u32 size;
 	int err;

 	pb->mapped = NULL;
 	pb->phys = 0;
 	pb->size = HOST1X_PUSHBUFFER_SLOTS * 8;

 	size = pb->size + 4;

 	/* initialize buffer pointers */
 	pb->fence = pb->size - 8;
 	pb->pos = 0;

 	if (host1x->domain) {
 		unsigned long shift;

 		size = iova_align(&host1x->iova, size);

 		pb->mapped = dma_alloc_wc(host1x->dev, size, &pb->phys,
 					  GFP_KERNEL);
 		if (!pb->mapped)
 			return -ENOMEM;

 		shift = iova_shift(&host1x->iova);
 		alloc = alloc_iova(&host1x->iova, size >> shift,
 				   host1x->iova_end >> shift, true);
 		if (!alloc) {
 			err = -ENOMEM;
 			goto iommu_free_mem;
 		}

 		pb->dma = iova_dma_addr(&host1x->iova, alloc);
 		err = iommu_map(host1x->domain, pb->dma, pb->phys, size,
 				IOMMU_READ);
 		if (err)
 			goto iommu_free_iova;
 	} else {
 		pb->mapped = dma_alloc_wc(host1x->dev, size, &pb->phys,
 					  GFP_KERNEL);
 		if (!pb->mapped)
 			return -ENOMEM;

 		pb->dma = pb->phys;
 	}

 	pb->alloc_size = size;

 	host1x_hw_pushbuffer_init(host1x, pb);

 	return 0;

 iommu_free_iova:
 	__free_iova(&host1x->iova, alloc);
 iommu_free_mem:
 	dma_free_wc(host1x->dev, size, pb->mapped, pb->phys);

 	return err;
 }

 /*
  * Push two words to the push buffer
  * Caller must ensure push buffer is not full
  */
 static void host1x_pushbuffer_push(struct push_buffer *pb, u32 op1, u32 op2)
 {
 	u32 *p = (u32 *)((void *)pb->mapped + pb->pos);

 	WARN_ON(pb->pos == pb->fence);
 	*(p++) = op1;
 	*(p++) = op2;
 	pb->pos += 8;

 	if (pb->pos >= pb->size)
 		pb->pos -= pb->size;
 }

 /*
  * Pop a number of two word slots from the push buffer
  * Caller must ensure push buffer is not empty
  */
 static void host1x_pushbuffer_pop(struct push_buffer *pb, unsigned int slots)
 {
 	/* Advance the next write position */
 	pb->fence += slots * 8;

 	if (pb->fence >= pb->size)
 		pb->fence -= pb->size;
 }

 /*
  * Return the number of two word slots free in the push buffer
  */
 static u32 host1x_pushbuffer_space(struct push_buffer *pb)
 {
 	unsigned int fence = pb->fence;

 	if (pb->fence < pb->pos)
 		fence += pb->size;

 	return (fence - pb->pos) / 8;
 }

 /*
  * Sleep (if necessary) until the requested event happens
  *   - CDMA_EVENT_SYNC_QUEUE_EMPTY : sync queue is completely empty.
  *     - Returns 1
  *   - CDMA_EVENT_PUSH_BUFFER_SPACE : there is space in the push buffer
  *     - Return the amount of space (> 0)
  * Must be called with the cdma lock held.
  */
 unsigned int host1x_cdma_wait_locked(struct host1x_cdma *cdma,
 				     enum cdma_event event)
 {
 	for (;;) {
 		struct push_buffer *pb = &cdma->push_buffer;
 		unsigned int space;

 		switch (event) {
 		case CDMA_EVENT_SYNC_QUEUE_EMPTY:
 			space = list_empty(&cdma->sync_queue) ? 1 : 0;
 			break;

 		case CDMA_EVENT_PUSH_BUFFER_SPACE:
 			space = host1x_pushbuffer_space(pb);
 			break;

 		default:
 			WARN_ON(1);
 			return -EINVAL;
 		}

 		if (space)
 			return space;

 		trace_host1x_wait_cdma(dev_name(cdma_to_channel(cdma)->dev),
 				       event);

 		/* If somebody has managed to already start waiting, yield */
 		if (cdma->event != CDMA_EVENT_NONE) {
 			mutex_unlock(&cdma->lock);
 			schedule();
 			mutex_lock(&cdma->lock);
 			continue;
 		}

 		cdma->event = event;

 		mutex_unlock(&cdma->lock);
 		wait_for_completion(&cdma->complete);
 		mutex_lock(&cdma->lock);
 	}

 	return 0;
 }

 /*
  * Sleep (if necessary) until the push buffer has enough free space.
  *
  * Must be called with the cdma lock held.
  */
 static int host1x_cdma_wait_pushbuffer_space(struct host1x *host1x,
 					     struct host1x_cdma *cdma,
 					     unsigned int needed)
 {
 	while (true) {
 		struct push_buffer *pb = &cdma->push_buffer;
 		unsigned int space;

 		space = host1x_pushbuffer_space(pb);
 		if (space >= needed)
 			break;

 		trace_host1x_wait_cdma(dev_name(cdma_to_channel(cdma)->dev),
 				       CDMA_EVENT_PUSH_BUFFER_SPACE);

 		host1x_hw_cdma_flush(host1x, cdma);

 		/* If somebody has managed to already start waiting, yield */
 		if (cdma->event != CDMA_EVENT_NONE) {
 			mutex_unlock(&cdma->lock);
 			schedule();
 			mutex_lock(&cdma->lock);
 			continue;
 		}

 		cdma->event = CDMA_EVENT_PUSH_BUFFER_SPACE;

 		mutex_unlock(&cdma->lock);
 		wait_for_completion(&cdma->complete);
 		mutex_lock(&cdma->lock);
 	}

 	return 0;
 }
 /*
  * Start timer that tracks the time spent by the job.
  * Must be called with the cdma lock held.
  */
 static void cdma_start_timer_locked(struct host1x_cdma *cdma,
 				    struct host1x_job *job)
 {
 	struct host1x *host = cdma_to_host1x(cdma);

 	if (cdma->timeout.client) {
 		/* timer already started */
 		return;
 	}

 	cdma->timeout.client = job->client;
 	cdma->timeout.syncpt = host1x_syncpt_get(host, job->syncpt_id);
 	cdma->timeout.syncpt_val = job->syncpt_end;
 	cdma->timeout.start_ktime = ktime_get();

 	schedule_delayed_work(&cdma->timeout.wq,
 			      msecs_to_jiffies(job->timeout));
 }

 /*
  * Stop timer when a buffer submission completes.
  * Must be called with the cdma lock held.
  */
 static void stop_cdma_timer_locked(struct host1x_cdma *cdma)
 {
 	cancel_delayed_work(&cdma->timeout.wq);
 	cdma->timeout.client = NULL;
 }

 /*
  * For all sync queue entries that have already finished according to the
  * current sync point registers:
  *  - unpin & unref their mems
  *  - pop their push buffer slots
  *  - remove them from the sync queue
  * This is normally called from the host code's worker thread, but can be
  * called manually if necessary.
  * Must be called with the cdma lock held.
  */
 static void update_cdma_locked(struct host1x_cdma *cdma)
 {
 	bool signal = false;
 	struct host1x *host1x = cdma_to_host1x(cdma);
 	struct host1x_job *job, *n;

 	/* If CDMA is stopped, queue is cleared and we can return */
 	if (!cdma->running)
 		return;

 	/*
 	 * Walk the sync queue, reading the sync point registers as necessary,
 	 * to consume as many sync queue entries as possible without blocking
 	 */
 	list_for_each_entry_safe(job, n, &cdma->sync_queue, list) {
 		struct host1x_syncpt *sp =
 			host1x_syncpt_get(host1x, job->syncpt_id);

 		/* Check whether this syncpt has completed, and bail if not */
 		if (!host1x_syncpt_is_expired(sp, job->syncpt_end)) {
 			/* Start timer on next pending syncpt */
 			if (job->timeout)
 				cdma_start_timer_locked(cdma, job);

 			break;
 		}

 		/* Cancel timeout, when a buffer completes */
 		if (cdma->timeout.client)
 			stop_cdma_timer_locked(cdma);

 		/* Unpin the memory */
 		host1x_job_unpin(job);

 		/* Pop push buffer slots */
 		if (job->num_slots) {
 			struct push_buffer *pb = &cdma->push_buffer;

 			host1x_pushbuffer_pop(pb, job->num_slots);

 			if (cdma->event == CDMA_EVENT_PUSH_BUFFER_SPACE)
 				signal = true;
 		}

 		list_del(&job->list);
 		host1x_job_put(job);
 	}

 	if (cdma->event == CDMA_EVENT_SYNC_QUEUE_EMPTY &&
 	    list_empty(&cdma->sync_queue))
 		signal = true;

 	if (signal) {
 		cdma->event = CDMA_EVENT_NONE;
 		complete(&cdma->complete);
 	}
 }

 void host1x_cdma_update_sync_queue(struct host1x_cdma *cdma,
 				   struct device *dev)
 {
 	struct host1x *host1x = cdma_to_host1x(cdma);
 	u32 restart_addr, syncpt_incrs, syncpt_val;
 	struct host1x_job *job, *next_job = NULL;

 	syncpt_val = host1x_syncpt_load(cdma->timeout.syncpt);

 	dev_dbg(dev, "%s: starting cleanup (thresh %d)\n",
 		__func__, syncpt_val);

 	/*
 	 * Move the sync_queue read pointer to the first entry that hasn't
 	 * completed based on the current HW syncpt value. It's likely there
 	 * won't be any (i.e. we're still at the head), but covers the case
 	 * where a syncpt incr happens just prior/during the teardown.
 	 */

 	dev_dbg(dev, "%s: skip completed buffers still in sync_queue\n",
 		__func__);

 	list_for_each_entry(job, &cdma->sync_queue, list) {
 		if (syncpt_val < job->syncpt_end) {

 			if (!list_is_last(&job->list, &cdma->sync_queue))
 				next_job = list_next_entry(job, list);

 			goto syncpt_incr;
 		}

 		host1x_job_dump(dev, job);
 	}

 	/* all jobs have been completed */
 	job = NULL;

 syncpt_incr:

 	/*
 	 * Increment with CPU the remaining syncpts of a partially executed job.
 	 *
 	 * CDMA will continue execution starting with the next job or will get
 	 * into idle state.
 	 */
 	if (next_job)
 		restart_addr = next_job->first_get;
 	else
 		restart_addr = cdma->last_pos;

 	/* do CPU increments for the remaining syncpts */
 	if (job) {
 		dev_dbg(dev, "%s: perform CPU incr on pending buffers\n",
 			__func__);

 		/* won't need a timeout when replayed */
 		job->timeout = 0;

 		syncpt_incrs = job->syncpt_end - syncpt_val;
 		dev_dbg(dev, "%s: CPU incr (%d)\n", __func__, syncpt_incrs);

 		host1x_job_dump(dev, job);

 		/* safe to use CPU to incr syncpts */
 		host1x_hw_cdma_timeout_cpu_incr(host1x, cdma, job->first_get,
 						syncpt_incrs, job->syncpt_end,
 						job->num_slots);

 		dev_dbg(dev, "%s: finished sync_queue modification\n",
 			__func__);
 	}

 	/* roll back DMAGET and start up channel again */
 	host1x_hw_cdma_resume(host1x, cdma, restart_addr);
 }

 /*
  * Create a cdma
  */
 int host1x_cdma_init(struct host1x_cdma *cdma)
 {
 	int err;

 	mutex_init(&cdma->lock);
 	init_completion(&cdma->complete);

 	INIT_LIST_HEAD(&cdma->sync_queue);

 	cdma->event = CDMA_EVENT_NONE;
 	cdma->running = false;
 	cdma->torndown = false;

 	err = host1x_pushbuffer_init(&cdma->push_buffer);
 	if (err)
 		return err;

 	return 0;
 }

 /*
  * Destroy a cdma
  */
 int host1x_cdma_deinit(struct host1x_cdma *cdma)
 {
 	struct push_buffer *pb = &cdma->push_buffer;
 	struct host1x *host1x = cdma_to_host1x(cdma);

 	if (cdma->running) {
 		pr_warn("%s: CDMA still running\n", __func__);
 		return -EBUSY;
 	}

 	host1x_pushbuffer_destroy(pb);
 	host1x_hw_cdma_timeout_destroy(host1x, cdma);

 	return 0;
 }

 /*
  * Begin a cdma submit
  */
 int host1x_cdma_begin(struct host1x_cdma *cdma, struct host1x_job *job)
 {
 	struct host1x *host1x = cdma_to_host1x(cdma);

 	mutex_lock(&cdma->lock);

 	if (job->timeout) {
 		/* init state on first submit with timeout value */
 		if (!cdma->timeout.initialized) {
 			int err;

 			err = host1x_hw_cdma_timeout_init(host1x, cdma,
 							  job->syncpt_id);
 			if (err) {
 				mutex_unlock(&cdma->lock);
 				return err;
 			}
 		}
 	}

 	if (!cdma->running)
 		host1x_hw_cdma_start(host1x, cdma);

 	cdma->slots_free = 0;
 	cdma->slots_used = 0;
 	cdma->first_get = cdma->push_buffer.pos;

 	trace_host1x_cdma_begin(dev_name(job->channel->dev));
 	return 0;
 }

 /*
  * Push two words into a push buffer slot
  * Blocks as necessary if the push buffer is full.
  */
 void host1x_cdma_push(struct host1x_cdma *cdma, u32 op1, u32 op2)
 {
 	struct host1x *host1x = cdma_to_host1x(cdma);
 	struct push_buffer *pb = &cdma->push_buffer;
 	u32 slots_free = cdma->slots_free;

 	if (host1x_debug_trace_cmdbuf)
 		trace_host1x_cdma_push(dev_name(cdma_to_channel(cdma)->dev),
 				       op1, op2);

 	if (slots_free == 0) {
 		host1x_hw_cdma_flush(host1x, cdma);
 		slots_free = host1x_cdma_wait_locked(cdma,
 						CDMA_EVENT_PUSH_BUFFER_SPACE);
 	}

 	cdma->slots_free = slots_free - 1;
 	cdma->slots_used++;
 	host1x_pushbuffer_push(pb, op1, op2);
 }

 /*
  * Push four words into two consecutive push buffer slots. Note that extra
  * care needs to be taken not to split the two slots across the end of the
  * push buffer. Otherwise the RESTART opcode at the end of the push buffer
  * that ensures processing will restart at the beginning will break up the
  * four words.
  *
  * Blocks as necessary if the push buffer is full.
  */
 void host1x_cdma_push_wide(struct host1x_cdma *cdma, u32 op1, u32 op2,
 			   u32 op3, u32 op4)
 {
 	struct host1x_channel *channel = cdma_to_channel(cdma);
 	struct host1x *host1x = cdma_to_host1x(cdma);
 	struct push_buffer *pb = &cdma->push_buffer;
 	unsigned int needed = 2, extra = 0, i;
 	unsigned int space = cdma->slots_free;

 	if (host1x_debug_trace_cmdbuf)
 		trace_host1x_cdma_push_wide(dev_name(channel->dev), op1, op2,
 					    op3, op4);

 	/* compute number of extra slots needed for padding */
 	if (pb->pos + 16 > pb->size) {
 		extra = (pb->size - pb->pos) / 8;
 		needed += extra;
 	}

 	host1x_cdma_wait_pushbuffer_space(host1x, cdma, needed);
 	space = host1x_pushbuffer_space(pb);

 	cdma->slots_free = space - needed;
 	cdma->slots_used += needed;

 	/*
 	 * Note that we rely on the fact that this is only used to submit wide
 	 * gather opcodes, which consist of 3 words, and they are padded with
 	 * a NOP to avoid having to deal with fractional slots (a slot always
 	 * represents 2 words). The fourth opcode passed to this function will
 	 * therefore always be a NOP.
 	 *
 	 * This works around a slight ambiguity when it comes to opcodes. For
 	 * all current host1x incarnations the NOP opcode uses the exact same
 	 * encoding (0x20000000), so we could hard-code the value here, but a
 	 * new incarnation may change it and break that assumption.
 	 */
 	for (i = 0; i < extra; i++)
 		host1x_pushbuffer_push(pb, op4, op4);

 	host1x_pushbuffer_push(pb, op1, op2);
 	host1x_pushbuffer_push(pb, op3, op4);
 }

 /*
  * End a cdma submit
  * Kick off DMA, add job to the sync queue, and a number of slots to be freed
  * from the pushbuffer. The handles for a submit must all be pinned at the same
  * time, but they can be unpinned in smaller chunks.
  */
 void host1x_cdma_end(struct host1x_cdma *cdma,
 		     struct host1x_job *job)
 {
 	struct host1x *host1x = cdma_to_host1x(cdma);
 	bool idle = list_empty(&cdma->sync_queue);

 	host1x_hw_cdma_flush(host1x, cdma);

 	job->first_get = cdma->first_get;
 	job->num_slots = cdma->slots_used;
 	host1x_job_get(job);
 	list_add_tail(&job->list, &cdma->sync_queue);

 	/* start timer on idle -> active transitions */
 	if (job->timeout && idle)
 		cdma_start_timer_locked(cdma, job);

 	trace_host1x_cdma_end(dev_name(job->channel->dev));
 	mutex_unlock(&cdma->lock);
 }

 /*
  * Update cdma state according to current sync point values
  */
 void host1x_cdma_update(struct host1x_cdma *cdma)
 {
 	mutex_lock(&cdma->lock);
 	update_cdma_locked(cdma);
 	mutex_unlock(&cdma->lock);
 }
	// SPDX-License-Identifier: GPL-2.0-only
	/*
	* Tegra host1x Command DMA
	*
	* Copyright (c) 2010-2013, NVIDIA Corporation.
	*/


	#include <asm/cacheflush.h>
	#include <linux/device.h>
	#include <linux/dma-mapping.h>
	#include <linux/host1x.h>
	#include <linux/interrupt.h>
	#include <linux/kernel.h>
	#include <linux/kfifo.h>
	#include <linux/slab.h>
	#include <trace/events/host1x.h>

	#include "cdma.h"
	#include "channel.h"
	#include "dev.h"
	#include "debug.h"
	#include "job.h"

	/*
	* push_buffer
	*
	* The push buffer is a circular array of words to be fetched by command DMA.
	* Note that it works slightly differently to the sync queue; fence == pos
	* means that the push buffer is full, not empty.
	*/

	/*
	* Typically the commands written into the push buffer are a pair of words. We
	* use slots to represent each of these pairs and to simplify things. Note the
	* strange number of slots allocated here. 512 slots will fit exactly within a
	* single memory page. We also need one additional word at the end of the push
	* buffer for the RESTART opcode that will instruct the CDMA to jump back to
	* the beginning of the push buffer. With 512 slots, this means that we'll use
	* 2 memory pages and waste 4092 bytes of the second page that will never be
	* used.
	*/
	#define HOST1X_PUSHBUFFER_SLOTS 511

	/*
	* Clean up push buffer resources
	*/
	static void host1x_pushbuffer_destroy(struct push_buffer *pb)
	{
	struct host1x_cdma *cdma = pb_to_cdma(pb);
	struct host1x *host1x = cdma_to_host1x(cdma);

	if (!pb->mapped)
	return;

	if (host1x->domain) {
	iommu_unmap(host1x->domain, pb->dma, pb->alloc_size);
	free_iova(&host1x->iova, iova_pfn(&host1x->iova, pb->dma));
	}

	dma_free_wc(host1x->dev, pb->alloc_size, pb->mapped, pb->phys);

	pb->mapped = NULL;
	pb->phys = 0;
	}

	/*
	* Init push buffer resources
	*/
	static int host1x_pushbuffer_init(struct push_buffer *pb)
	{
	struct host1x_cdma *cdma = pb_to_cdma(pb);
	struct host1x *host1x = cdma_to_host1x(cdma);
	struct iova *alloc;
	u32 size;
	int err;

	pb->mapped = NULL;
	pb->phys = 0;
	pb->size = HOST1X_PUSHBUFFER_SLOTS * 8;

	size = pb->size + 4;

	/* initialize buffer pointers */
	pb->fence = pb->size - 8;
	pb->pos = 0;

	if (host1x->domain) {
	unsigned long shift;

	size = iova_align(&host1x->iova, size);

	pb->mapped = dma_alloc_wc(host1x->dev, size, &pb->phys,
	GFP_KERNEL);
	if (!pb->mapped)
	return -ENOMEM;

	shift = iova_shift(&host1x->iova);
	alloc = alloc_iova(&host1x->iova, size >> shift,
	host1x->iova_end >> shift, true);
	if (!alloc) {
	err = -ENOMEM;
	goto iommu_free_mem;
	}

	pb->dma = iova_dma_addr(&host1x->iova, alloc);
	err = iommu_map(host1x->domain, pb->dma, pb->phys, size,
	IOMMU_READ);
	if (err)
	goto iommu_free_iova;
	} else {
	pb->mapped = dma_alloc_wc(host1x->dev, size, &pb->phys,
	GFP_KERNEL);
	if (!pb->mapped)
	return -ENOMEM;

	pb->dma = pb->phys;
	}

	pb->alloc_size = size;

	host1x_hw_pushbuffer_init(host1x, pb);

	return 0;

	iommu_free_iova:
	__free_iova(&host1x->iova, alloc);
	iommu_free_mem:
	dma_free_wc(host1x->dev, size, pb->mapped, pb->phys);

	return err;
	}

	/*
	* Push two words to the push buffer
	* Caller must ensure push buffer is not full
	*/
	static void host1x_pushbuffer_push(struct push_buffer *pb, u32 op1, u32 op2)
	{
	u32 p = (u32 )((void *)pb->mapped + pb->pos);

	WARN_ON(pb->pos == pb->fence);
	*(p++) = op1;
	*(p++) = op2;
	pb->pos += 8;

	if (pb->pos >= pb->size)
	pb->pos -= pb->size;
	}

	/*
	* Pop a number of two word slots from the push buffer
	* Caller must ensure push buffer is not empty
	*/
	static void host1x_pushbuffer_pop(struct push_buffer *pb, unsigned int slots)
	{
	/* Advance the next write position */
	pb->fence += slots * 8;

	if (pb->fence >= pb->size)
	pb->fence -= pb->size;
	}

	/*
	* Return the number of two word slots free in the push buffer
	*/
	static u32 host1x_pushbuffer_space(struct push_buffer *pb)
	{
	unsigned int fence = pb->fence;

	if (pb->fence < pb->pos)
	fence += pb->size;

	return (fence - pb->pos) / 8;
	}

	/*
	* Sleep (if necessary) until the requested event happens
	* - CDMA_EVENT_SYNC_QUEUE_EMPTY : sync queue is completely empty.
	* - Returns 1
	* - CDMA_EVENT_PUSH_BUFFER_SPACE : there is space in the push buffer
	* - Return the amount of space (> 0)
	* Must be called with the cdma lock held.
	*/
	unsigned int host1x_cdma_wait_locked(struct host1x_cdma *cdma,
	enum cdma_event event)
	{
	for (;;) {
	struct push_buffer *pb = &cdma->push_buffer;
	unsigned int space;

	switch (event) {
	case CDMA_EVENT_SYNC_QUEUE_EMPTY:
	space = list_empty(&cdma->sync_queue) ? 1 : 0;
	break;

	case CDMA_EVENT_PUSH_BUFFER_SPACE:
	space = host1x_pushbuffer_space(pb);
	break;

	default:
	WARN_ON(1);
	return -EINVAL;
	}

	if (space)
	return space;

	trace_host1x_wait_cdma(dev_name(cdma_to_channel(cdma)->dev),
	event);

	/* If somebody has managed to already start waiting, yield */
	if (cdma->event != CDMA_EVENT_NONE) {
	mutex_unlock(&cdma->lock);
	schedule();
	mutex_lock(&cdma->lock);
	continue;
	}

	cdma->event = event;

	mutex_unlock(&cdma->lock);
	wait_for_completion(&cdma->complete);
	mutex_lock(&cdma->lock);
	}

	return 0;
	}

	/*
	* Sleep (if necessary) until the push buffer has enough free space.
	*
	* Must be called with the cdma lock held.
	*/
	static int host1x_cdma_wait_pushbuffer_space(struct host1x *host1x,
	struct host1x_cdma *cdma,
	unsigned int needed)
	{
	while (true) {
	struct push_buffer *pb = &cdma->push_buffer;
	unsigned int space;

	space = host1x_pushbuffer_space(pb);
	if (space >= needed)
	break;

	trace_host1x_wait_cdma(dev_name(cdma_to_channel(cdma)->dev),
	CDMA_EVENT_PUSH_BUFFER_SPACE);

	host1x_hw_cdma_flush(host1x, cdma);

	/* If somebody has managed to already start waiting, yield */
	if (cdma->event != CDMA_EVENT_NONE) {
	mutex_unlock(&cdma->lock);
	schedule();
	mutex_lock(&cdma->lock);
	continue;
	}

	cdma->event = CDMA_EVENT_PUSH_BUFFER_SPACE;

	mutex_unlock(&cdma->lock);
	wait_for_completion(&cdma->complete);
	mutex_lock(&cdma->lock);
	}

	return 0;
	}
	/*
	* Start timer that tracks the time spent by the job.
	* Must be called with the cdma lock held.
	*/
	static void cdma_start_timer_locked(struct host1x_cdma *cdma,
	struct host1x_job *job)
	{
	struct host1x *host = cdma_to_host1x(cdma);

	if (cdma->timeout.client) {
	/* timer already started */
	return;
	}

	cdma->timeout.client = job->client;
	cdma->timeout.syncpt = host1x_syncpt_get(host, job->syncpt_id);
	cdma->timeout.syncpt_val = job->syncpt_end;
	cdma->timeout.start_ktime = ktime_get();

	schedule_delayed_work(&cdma->timeout.wq,
	msecs_to_jiffies(job->timeout));
	}

	/*
	* Stop timer when a buffer submission completes.
	* Must be called with the cdma lock held.
	*/
	static void stop_cdma_timer_locked(struct host1x_cdma *cdma)
	{
	cancel_delayed_work(&cdma->timeout.wq);
	cdma->timeout.client = NULL;
	}

	/*
	* For all sync queue entries that have already finished according to the
	* current sync point registers:
	* - unpin & unref their mems
	* - pop their push buffer slots
	* - remove them from the sync queue
	* This is normally called from the host code's worker thread, but can be
	* called manually if necessary.
	* Must be called with the cdma lock held.
	*/
	static void update_cdma_locked(struct host1x_cdma *cdma)
	{
	bool signal = false;
	struct host1x *host1x = cdma_to_host1x(cdma);
	struct host1x_job job, n;

	/* If CDMA is stopped, queue is cleared and we can return */
	if (!cdma->running)
	return;

	/*
	* Walk the sync queue, reading the sync point registers as necessary,
	* to consume as many sync queue entries as possible without blocking
	*/
	list_for_each_entry_safe(job, n, &cdma->sync_queue, list) {
	struct host1x_syncpt *sp =
	host1x_syncpt_get(host1x, job->syncpt_id);

	/* Check whether this syncpt has completed, and bail if not */
	if (!host1x_syncpt_is_expired(sp, job->syncpt_end)) {
	/* Start timer on next pending syncpt */
	if (job->timeout)
	cdma_start_timer_locked(cdma, job);

	break;
	}

	/* Cancel timeout, when a buffer completes */
	if (cdma->timeout.client)
	stop_cdma_timer_locked(cdma);

	/* Unpin the memory */
	host1x_job_unpin(job);

	/* Pop push buffer slots */
	if (job->num_slots) {
	struct push_buffer *pb = &cdma->push_buffer;

	host1x_pushbuffer_pop(pb, job->num_slots);

	if (cdma->event == CDMA_EVENT_PUSH_BUFFER_SPACE)
	signal = true;
	}

	list_del(&job->list);
	host1x_job_put(job);
	}

	if (cdma->event == CDMA_EVENT_SYNC_QUEUE_EMPTY &&
	list_empty(&cdma->sync_queue))
	signal = true;

	if (signal) {
	cdma->event = CDMA_EVENT_NONE;
	complete(&cdma->complete);
	}
	}

	void host1x_cdma_update_sync_queue(struct host1x_cdma *cdma,
	struct device *dev)
	{
	struct host1x *host1x = cdma_to_host1x(cdma);
	u32 restart_addr, syncpt_incrs, syncpt_val;
	struct host1x_job job, next_job = NULL;

	syncpt_val = host1x_syncpt_load(cdma->timeout.syncpt);

	dev_dbg(dev, "%s: starting cleanup (thresh %d)\n",
	__func__, syncpt_val);

	/*
	* Move the sync_queue read pointer to the first entry that hasn't
	* completed based on the current HW syncpt value. It's likely there
	* won't be any (i.e. we're still at the head), but covers the case
	* where a syncpt incr happens just prior/during the teardown.
	*/

	dev_dbg(dev, "%s: skip completed buffers still in sync_queue\n",
	__func__);

	list_for_each_entry(job, &cdma->sync_queue, list) {
	if (syncpt_val < job->syncpt_end) {

	if (!list_is_last(&job->list, &cdma->sync_queue))
	next_job = list_next_entry(job, list);

	goto syncpt_incr;
	}

	host1x_job_dump(dev, job);
	}

	/* all jobs have been completed */
	job = NULL;

	syncpt_incr:

	/*
	* Increment with CPU the remaining syncpts of a partially executed job.
	*
	* CDMA will continue execution starting with the next job or will get
	* into idle state.
	*/
	if (next_job)
	restart_addr = next_job->first_get;
	else
	restart_addr = cdma->last_pos;

	/* do CPU increments for the remaining syncpts */
	if (job) {
	dev_dbg(dev, "%s: perform CPU incr on pending buffers\n",
	__func__);

	/* won't need a timeout when replayed */
	job->timeout = 0;

	syncpt_incrs = job->syncpt_end - syncpt_val;
	dev_dbg(dev, "%s: CPU incr (%d)\n", __func__, syncpt_incrs);

	host1x_job_dump(dev, job);

	/* safe to use CPU to incr syncpts */
	host1x_hw_cdma_timeout_cpu_incr(host1x, cdma, job->first_get,
	syncpt_incrs, job->syncpt_end,
	job->num_slots);

	dev_dbg(dev, "%s: finished sync_queue modification\n",
	__func__);
	}

	/* roll back DMAGET and start up channel again */
	host1x_hw_cdma_resume(host1x, cdma, restart_addr);
	}

	/*
	* Create a cdma
	*/
	int host1x_cdma_init(struct host1x_cdma *cdma)
	{
	int err;

	mutex_init(&cdma->lock);
	init_completion(&cdma->complete);

	INIT_LIST_HEAD(&cdma->sync_queue);

	cdma->event = CDMA_EVENT_NONE;
	cdma->running = false;
	cdma->torndown = false;

	err = host1x_pushbuffer_init(&cdma->push_buffer);
	if (err)
	return err;

	return 0;
	}

	/*
	* Destroy a cdma
	*/
	int host1x_cdma_deinit(struct host1x_cdma *cdma)
	{
	struct push_buffer *pb = &cdma->push_buffer;
	struct host1x *host1x = cdma_to_host1x(cdma);

	if (cdma->running) {
	pr_warn("%s: CDMA still running\n", __func__);
	return -EBUSY;
	}

	host1x_pushbuffer_destroy(pb);
	host1x_hw_cdma_timeout_destroy(host1x, cdma);

	return 0;
	}

	/*
	* Begin a cdma submit
	*/
	int host1x_cdma_begin(struct host1x_cdma cdma, struct host1x_job job)
	{
	struct host1x *host1x = cdma_to_host1x(cdma);

	mutex_lock(&cdma->lock);

	if (job->timeout) {
	/* init state on first submit with timeout value */
	if (!cdma->timeout.initialized) {
	int err;

	err = host1x_hw_cdma_timeout_init(host1x, cdma,
	job->syncpt_id);
	if (err) {
	mutex_unlock(&cdma->lock);
	return err;
	}
	}
	}

	if (!cdma->running)
	host1x_hw_cdma_start(host1x, cdma);

	cdma->slots_free = 0;
	cdma->slots_used = 0;
	cdma->first_get = cdma->push_buffer.pos;

	trace_host1x_cdma_begin(dev_name(job->channel->dev));
	return 0;
	}

	/*
	* Push two words into a push buffer slot
	* Blocks as necessary if the push buffer is full.
	*/
	void host1x_cdma_push(struct host1x_cdma *cdma, u32 op1, u32 op2)
	{
	struct host1x *host1x = cdma_to_host1x(cdma);
	struct push_buffer *pb = &cdma->push_buffer;
	u32 slots_free = cdma->slots_free;

	if (host1x_debug_trace_cmdbuf)
	trace_host1x_cdma_push(dev_name(cdma_to_channel(cdma)->dev),
	op1, op2);

	if (slots_free == 0) {
	host1x_hw_cdma_flush(host1x, cdma);
	slots_free = host1x_cdma_wait_locked(cdma,
	CDMA_EVENT_PUSH_BUFFER_SPACE);
	}

	cdma->slots_free = slots_free - 1;
	cdma->slots_used++;
	host1x_pushbuffer_push(pb, op1, op2);
	}

	/*
	* Push four words into two consecutive push buffer slots. Note that extra
	* care needs to be taken not to split the two slots across the end of the
	* push buffer. Otherwise the RESTART opcode at the end of the push buffer
	* that ensures processing will restart at the beginning will break up the
	* four words.
	*
	* Blocks as necessary if the push buffer is full.
	*/
	void host1x_cdma_push_wide(struct host1x_cdma *cdma, u32 op1, u32 op2,
	u32 op3, u32 op4)
	{
	struct host1x_channel *channel = cdma_to_channel(cdma);
	struct host1x *host1x = cdma_to_host1x(cdma);
	struct push_buffer *pb = &cdma->push_buffer;
	unsigned int needed = 2, extra = 0, i;
	unsigned int space = cdma->slots_free;

	if (host1x_debug_trace_cmdbuf)
	trace_host1x_cdma_push_wide(dev_name(channel->dev), op1, op2,
	op3, op4);

	/* compute number of extra slots needed for padding */
	if (pb->pos + 16 > pb->size) {
	extra = (pb->size - pb->pos) / 8;
	needed += extra;
	}

	host1x_cdma_wait_pushbuffer_space(host1x, cdma, needed);
	space = host1x_pushbuffer_space(pb);

	cdma->slots_free = space - needed;
	cdma->slots_used += needed;

	/*
	* Note that we rely on the fact that this is only used to submit wide
	* gather opcodes, which consist of 3 words, and they are padded with
	* a NOP to avoid having to deal with fractional slots (a slot always
	* represents 2 words). The fourth opcode passed to this function will
	* therefore always be a NOP.
	*
	* This works around a slight ambiguity when it comes to opcodes. For
	* all current host1x incarnations the NOP opcode uses the exact same
	* encoding (0x20000000), so we could hard-code the value here, but a
	* new incarnation may change it and break that assumption.
	*/
	for (i = 0; i < extra; i++)
	host1x_pushbuffer_push(pb, op4, op4);

	host1x_pushbuffer_push(pb, op1, op2);
	host1x_pushbuffer_push(pb, op3, op4);
	}

	/*
	* End a cdma submit
	* Kick off DMA, add job to the sync queue, and a number of slots to be freed
	* from the pushbuffer. The handles for a submit must all be pinned at the same
	* time, but they can be unpinned in smaller chunks.
	*/
	void host1x_cdma_end(struct host1x_cdma *cdma,
	struct host1x_job *job)
	{
	struct host1x *host1x = cdma_to_host1x(cdma);
	bool idle = list_empty(&cdma->sync_queue);

	host1x_hw_cdma_flush(host1x, cdma);

	job->first_get = cdma->first_get;
	job->num_slots = cdma->slots_used;
	host1x_job_get(job);
	list_add_tail(&job->list, &cdma->sync_queue);

	/* start timer on idle -> active transitions */
	if (job->timeout && idle)
	cdma_start_timer_locked(cdma, job);

	trace_host1x_cdma_end(dev_name(job->channel->dev));
	mutex_unlock(&cdma->lock);
	}

	/*
	* Update cdma state according to current sync point values
	*/
	void host1x_cdma_update(struct host1x_cdma *cdma)
	{
	mutex_lock(&cdma->lock);
	update_cdma_locked(cdma);
	mutex_unlock(&cdma->lock);
	}