drivers/firmware/tegra/ivc.c - third_party/kernel - Git at Google

 // SPDX-License-Identifier: GPL-2.0-only
 /*
  * Copyright (c) 2014-2016, NVIDIA CORPORATION.  All rights reserved.
  */

 #include <soc/tegra/ivc.h>

 #define TEGRA_IVC_ALIGN 64

 /*
  * IVC channel reset protocol.
  *
  * Each end uses its tx_channel.state to indicate its synchronization state.
  */
 enum tegra_ivc_state {
 	/*
 	 * This value is zero for backwards compatibility with services that
 	 * assume channels to be initially zeroed. Such channels are in an
 	 * initially valid state, but cannot be asynchronously reset, and must
 	 * maintain a valid state at all times.
 	 *
 	 * The transmitting end can enter the established state from the sync or
 	 * ack state when it observes the receiving endpoint in the ack or
 	 * established state, indicating that has cleared the counters in our
 	 * rx_channel.
 	 */
 	TEGRA_IVC_STATE_ESTABLISHED = 0,

 	/*
 	 * If an endpoint is observed in the sync state, the remote endpoint is
 	 * allowed to clear the counters it owns asynchronously with respect to
 	 * the current endpoint. Therefore, the current endpoint is no longer
 	 * allowed to communicate.
 	 */
 	TEGRA_IVC_STATE_SYNC,

 	/*
 	 * When the transmitting end observes the receiving end in the sync
 	 * state, it can clear the w_count and r_count and transition to the ack
 	 * state. If the remote endpoint observes us in the ack state, it can
 	 * return to the established state once it has cleared its counters.
 	 */
 	TEGRA_IVC_STATE_ACK
 };

 /*
  * This structure is divided into two-cache aligned parts, the first is only
  * written through the tx.channel pointer, while the second is only written
  * through the rx.channel pointer. This delineates ownership of the cache
  * lines, which is critical to performance and necessary in non-cache coherent
  * implementations.
  */
 struct tegra_ivc_header {
 	union {
 		struct {
 			/* fields owned by the transmitting end */
 			u32 count;
 			u32 state;
 		};

 		u8 pad[TEGRA_IVC_ALIGN];
 	} tx;

 	union {
 		/* fields owned by the receiving end */
 		u32 count;
 		u8 pad[TEGRA_IVC_ALIGN];
 	} rx;
 };

 static inline void tegra_ivc_invalidate(struct tegra_ivc *ivc, dma_addr_t phys)
 {
 	if (!ivc->peer)
 		return;

 	dma_sync_single_for_cpu(ivc->peer, phys, TEGRA_IVC_ALIGN,
 				DMA_FROM_DEVICE);
 }

 static inline void tegra_ivc_flush(struct tegra_ivc *ivc, dma_addr_t phys)
 {
 	if (!ivc->peer)
 		return;

 	dma_sync_single_for_device(ivc->peer, phys, TEGRA_IVC_ALIGN,
 				   DMA_TO_DEVICE);
 }

 static inline bool tegra_ivc_empty(struct tegra_ivc *ivc,
 				   struct tegra_ivc_header *header)
 {
 	/*
 	 * This function performs multiple checks on the same values with
 	 * security implications, so create snapshots with READ_ONCE() to
 	 * ensure that these checks use the same values.
 	 */
 	u32 tx = READ_ONCE(header->tx.count);
 	u32 rx = READ_ONCE(header->rx.count);

 	/*
 	 * Perform an over-full check to prevent denial of service attacks
 	 * where a server could be easily fooled into believing that there's
 	 * an extremely large number of frames ready, since receivers are not
 	 * expected to check for full or over-full conditions.
 	 *
 	 * Although the channel isn't empty, this is an invalid case caused by
 	 * a potentially malicious peer, so returning empty is safer, because
 	 * it gives the impression that the channel has gone silent.
 	 */
 	if (tx - rx > ivc->num_frames)
 		return true;

 	return tx == rx;
 }

 static inline bool tegra_ivc_full(struct tegra_ivc *ivc,
 				  struct tegra_ivc_header *header)
 {
 	u32 tx = READ_ONCE(header->tx.count);
 	u32 rx = READ_ONCE(header->rx.count);

 	/*
 	 * Invalid cases where the counters indicate that the queue is over
 	 * capacity also appear full.
 	 */
 	return tx - rx >= ivc->num_frames;
 }

 static inline u32 tegra_ivc_available(struct tegra_ivc *ivc,
 				      struct tegra_ivc_header *header)
 {
 	u32 tx = READ_ONCE(header->tx.count);
 	u32 rx = READ_ONCE(header->rx.count);

 	/*
 	 * This function isn't expected to be used in scenarios where an
 	 * over-full situation can lead to denial of service attacks. See the
 	 * comment in tegra_ivc_empty() for an explanation about special
 	 * over-full considerations.
 	 */
 	return tx - rx;
 }

 static inline void tegra_ivc_advance_tx(struct tegra_ivc *ivc)
 {
 	WRITE_ONCE(ivc->tx.channel->tx.count,
 		   READ_ONCE(ivc->tx.channel->tx.count) + 1);

 	if (ivc->tx.position == ivc->num_frames - 1)
 		ivc->tx.position = 0;
 	else
 		ivc->tx.position++;
 }

 static inline void tegra_ivc_advance_rx(struct tegra_ivc *ivc)
 {
 	WRITE_ONCE(ivc->rx.channel->rx.count,
 		   READ_ONCE(ivc->rx.channel->rx.count) + 1);

 	if (ivc->rx.position == ivc->num_frames - 1)
 		ivc->rx.position = 0;
 	else
 		ivc->rx.position++;
 }

 static inline int tegra_ivc_check_read(struct tegra_ivc *ivc)
 {
 	unsigned int offset = offsetof(struct tegra_ivc_header, tx.count);

 	/*
 	 * tx.channel->state is set locally, so it is not synchronized with
 	 * state from the remote peer. The remote peer cannot reset its
 	 * transmit counters until we've acknowledged its synchronization
 	 * request, so no additional synchronization is required because an
 	 * asynchronous transition of rx.channel->state to
 	 * TEGRA_IVC_STATE_ACK is not allowed.
 	 */
 	if (ivc->tx.channel->tx.state != TEGRA_IVC_STATE_ESTABLISHED)
 		return -ECONNRESET;

 	/*
 	 * Avoid unnecessary invalidations when performing repeated accesses
 	 * to an IVC channel by checking the old queue pointers first.
 	 *
 	 * Synchronization is only necessary when these pointers indicate
 	 * empty or full.
 	 */
 	if (!tegra_ivc_empty(ivc, ivc->rx.channel))
 		return 0;

 	tegra_ivc_invalidate(ivc, ivc->rx.phys + offset);

 	if (tegra_ivc_empty(ivc, ivc->rx.channel))
 		return -ENOSPC;

 	return 0;
 }

 static inline int tegra_ivc_check_write(struct tegra_ivc *ivc)
 {
 	unsigned int offset = offsetof(struct tegra_ivc_header, rx.count);

 	if (ivc->tx.channel->tx.state != TEGRA_IVC_STATE_ESTABLISHED)
 		return -ECONNRESET;

 	if (!tegra_ivc_full(ivc, ivc->tx.channel))
 		return 0;

 	tegra_ivc_invalidate(ivc, ivc->tx.phys + offset);

 	if (tegra_ivc_full(ivc, ivc->tx.channel))
 		return -ENOSPC;

 	return 0;
 }

 static void *tegra_ivc_frame_virt(struct tegra_ivc *ivc,
 				  struct tegra_ivc_header *header,
 				  unsigned int frame)
 {
 	if (WARN_ON(frame >= ivc->num_frames))
 		return ERR_PTR(-EINVAL);

 	return (void *)(header + 1) + ivc->frame_size * frame;
 }

 static inline dma_addr_t tegra_ivc_frame_phys(struct tegra_ivc *ivc,
 					      dma_addr_t phys,
 					      unsigned int frame)
 {
 	unsigned long offset;

 	offset = sizeof(struct tegra_ivc_header) + ivc->frame_size * frame;

 	return phys + offset;
 }

 static inline void tegra_ivc_invalidate_frame(struct tegra_ivc *ivc,
 					      dma_addr_t phys,
 					      unsigned int frame,
 					      unsigned int offset,
 					      size_t size)
 {
 	if (!ivc->peer || WARN_ON(frame >= ivc->num_frames))
 		return;

 	phys = tegra_ivc_frame_phys(ivc, phys, frame) + offset;

 	dma_sync_single_for_cpu(ivc->peer, phys, size, DMA_FROM_DEVICE);
 }

 static inline void tegra_ivc_flush_frame(struct tegra_ivc *ivc,
 					 dma_addr_t phys,
 					 unsigned int frame,
 					 unsigned int offset,
 					 size_t size)
 {
 	if (!ivc->peer || WARN_ON(frame >= ivc->num_frames))
 		return;

 	phys = tegra_ivc_frame_phys(ivc, phys, frame) + offset;

 	dma_sync_single_for_device(ivc->peer, phys, size, DMA_TO_DEVICE);
 }

 /* directly peek at the next frame rx'ed */
 void *tegra_ivc_read_get_next_frame(struct tegra_ivc *ivc)
 {
 	int err;

 	if (WARN_ON(ivc == NULL))
 		return ERR_PTR(-EINVAL);

 	err = tegra_ivc_check_read(ivc);
 	if (err < 0)
 		return ERR_PTR(err);

 	/*
 	 * Order observation of ivc->rx.position potentially indicating new
 	 * data before data read.
 	 */
 	smp_rmb();

 	tegra_ivc_invalidate_frame(ivc, ivc->rx.phys, ivc->rx.position, 0,
 				   ivc->frame_size);

 	return tegra_ivc_frame_virt(ivc, ivc->rx.channel, ivc->rx.position);
 }
 EXPORT_SYMBOL(tegra_ivc_read_get_next_frame);

 int tegra_ivc_read_advance(struct tegra_ivc *ivc)
 {
 	unsigned int rx = offsetof(struct tegra_ivc_header, rx.count);
 	unsigned int tx = offsetof(struct tegra_ivc_header, tx.count);
 	int err;

 	/*
 	 * No read barriers or synchronization here: the caller is expected to
 	 * have already observed the channel non-empty. This check is just to
 	 * catch programming errors.
 	 */
 	err = tegra_ivc_check_read(ivc);
 	if (err < 0)
 		return err;

 	tegra_ivc_advance_rx(ivc);

 	tegra_ivc_flush(ivc, ivc->rx.phys + rx);

 	/*
 	 * Ensure our write to ivc->rx.position occurs before our read from
 	 * ivc->tx.position.
 	 */
 	smp_mb();

 	/*
 	 * Notify only upon transition from full to non-full. The available
 	 * count can only asynchronously increase, so the worst possible
 	 * side-effect will be a spurious notification.
 	 */
 	tegra_ivc_invalidate(ivc, ivc->rx.phys + tx);

 	if (tegra_ivc_available(ivc, ivc->rx.channel) == ivc->num_frames - 1)
 		ivc->notify(ivc, ivc->notify_data);

 	return 0;
 }
 EXPORT_SYMBOL(tegra_ivc_read_advance);

 /* directly poke at the next frame to be tx'ed */
 void *tegra_ivc_write_get_next_frame(struct tegra_ivc *ivc)
 {
 	int err;

 	err = tegra_ivc_check_write(ivc);
 	if (err < 0)
 		return ERR_PTR(err);

 	return tegra_ivc_frame_virt(ivc, ivc->tx.channel, ivc->tx.position);
 }
 EXPORT_SYMBOL(tegra_ivc_write_get_next_frame);

 /* advance the tx buffer */
 int tegra_ivc_write_advance(struct tegra_ivc *ivc)
 {
 	unsigned int tx = offsetof(struct tegra_ivc_header, tx.count);
 	unsigned int rx = offsetof(struct tegra_ivc_header, rx.count);
 	int err;

 	err = tegra_ivc_check_write(ivc);
 	if (err < 0)
 		return err;

 	tegra_ivc_flush_frame(ivc, ivc->tx.phys, ivc->tx.position, 0,
 			      ivc->frame_size);

 	/*
 	 * Order any possible stores to the frame before update of
 	 * ivc->tx.position.
 	 */
 	smp_wmb();

 	tegra_ivc_advance_tx(ivc);
 	tegra_ivc_flush(ivc, ivc->tx.phys + tx);

 	/*
 	 * Ensure our write to ivc->tx.position occurs before our read from
 	 * ivc->rx.position.
 	 */
 	smp_mb();

 	/*
 	 * Notify only upon transition from empty to non-empty. The available
 	 * count can only asynchronously decrease, so the worst possible
 	 * side-effect will be a spurious notification.
 	 */
 	tegra_ivc_invalidate(ivc, ivc->tx.phys + rx);

 	if (tegra_ivc_available(ivc, ivc->tx.channel) == 1)
 		ivc->notify(ivc, ivc->notify_data);

 	return 0;
 }
 EXPORT_SYMBOL(tegra_ivc_write_advance);

 void tegra_ivc_reset(struct tegra_ivc *ivc)
 {
 	unsigned int offset = offsetof(struct tegra_ivc_header, tx.count);

 	ivc->tx.channel->tx.state = TEGRA_IVC_STATE_SYNC;
 	tegra_ivc_flush(ivc, ivc->tx.phys + offset);
 	ivc->notify(ivc, ivc->notify_data);
 }
 EXPORT_SYMBOL(tegra_ivc_reset);

 /*
  * =======================================================
  *  IVC State Transition Table - see tegra_ivc_notified()
  * =======================================================
  *
  *	local	remote	action
  *	-----	------	-----------------------------------
  *	SYNC	EST	<none>
  *	SYNC	ACK	reset counters; move to EST; notify
  *	SYNC	SYNC	reset counters; move to ACK; notify
  *	ACK	EST	move to EST; notify
  *	ACK	ACK	move to EST; notify
  *	ACK	SYNC	reset counters; move to ACK; notify
  *	EST	EST	<none>
  *	EST	ACK	<none>
  *	EST	SYNC	reset counters; move to ACK; notify
  *
  * ===============================================================
  */

 int tegra_ivc_notified(struct tegra_ivc *ivc)
 {
 	unsigned int offset = offsetof(struct tegra_ivc_header, tx.count);
 	enum tegra_ivc_state state;

 	/* Copy the receiver's state out of shared memory. */
 	tegra_ivc_invalidate(ivc, ivc->rx.phys + offset);
 	state = READ_ONCE(ivc->rx.channel->tx.state);

 	if (state == TEGRA_IVC_STATE_SYNC) {
 		offset = offsetof(struct tegra_ivc_header, tx.count);

 		/*
 		 * Order observation of TEGRA_IVC_STATE_SYNC before stores
 		 * clearing tx.channel.
 		 */
 		smp_rmb();

 		/*
 		 * Reset tx.channel counters. The remote end is in the SYNC
 		 * state and won't make progress until we change our state,
 		 * so the counters are not in use at this time.
 		 */
 		ivc->tx.channel->tx.count = 0;
 		ivc->rx.channel->rx.count = 0;

 		ivc->tx.position = 0;
 		ivc->rx.position = 0;

 		/*
 		 * Ensure that counters appear cleared before new state can be
 		 * observed.
 		 */
 		smp_wmb();

 		/*
 		 * Move to ACK state. We have just cleared our counters, so it
 		 * is now safe for the remote end to start using these values.
 		 */
 		ivc->tx.channel->tx.state = TEGRA_IVC_STATE_ACK;
 		tegra_ivc_flush(ivc, ivc->tx.phys + offset);

 		/*
 		 * Notify remote end to observe state transition.
 		 */
 		ivc->notify(ivc, ivc->notify_data);

 	} else if (ivc->tx.channel->tx.state == TEGRA_IVC_STATE_SYNC &&
 		   state == TEGRA_IVC_STATE_ACK) {
 		offset = offsetof(struct tegra_ivc_header, tx.count);

 		/*
 		 * Order observation of ivc_state_sync before stores clearing
 		 * tx_channel.
 		 */
 		smp_rmb();

 		/*
 		 * Reset tx.channel counters. The remote end is in the ACK
 		 * state and won't make progress until we change our state,
 		 * so the counters are not in use at this time.
 		 */
 		ivc->tx.channel->tx.count = 0;
 		ivc->rx.channel->rx.count = 0;

 		ivc->tx.position = 0;
 		ivc->rx.position = 0;

 		/*
 		 * Ensure that counters appear cleared before new state can be
 		 * observed.
 		 */
 		smp_wmb();

 		/*
 		 * Move to ESTABLISHED state. We know that the remote end has
 		 * already cleared its counters, so it is safe to start
 		 * writing/reading on this channel.
 		 */
 		ivc->tx.channel->tx.state = TEGRA_IVC_STATE_ESTABLISHED;
 		tegra_ivc_flush(ivc, ivc->tx.phys + offset);

 		/*
 		 * Notify remote end to observe state transition.
 		 */
 		ivc->notify(ivc, ivc->notify_data);

 	} else if (ivc->tx.channel->tx.state == TEGRA_IVC_STATE_ACK) {
 		offset = offsetof(struct tegra_ivc_header, tx.count);

 		/*
 		 * At this point, we have observed the peer to be in either
 		 * the ACK or ESTABLISHED state. Next, order observation of
 		 * peer state before storing to tx.channel.
 		 */
 		smp_rmb();

 		/*
 		 * Move to ESTABLISHED state. We know that we have previously
 		 * cleared our counters, and we know that the remote end has
 		 * cleared its counters, so it is safe to start writing/reading
 		 * on this channel.
 		 */
 		ivc->tx.channel->tx.state = TEGRA_IVC_STATE_ESTABLISHED;
 		tegra_ivc_flush(ivc, ivc->tx.phys + offset);

 		/*
 		 * Notify remote end to observe state transition.
 		 */
 		ivc->notify(ivc, ivc->notify_data);

 	} else {
 		/*
 		 * There is no need to handle any further action. Either the
 		 * channel is already fully established, or we are waiting for
 		 * the remote end to catch up with our current state. Refer
 		 * to the diagram in "IVC State Transition Table" above.
 		 */
 	}

 	if (ivc->tx.channel->tx.state != TEGRA_IVC_STATE_ESTABLISHED)
 		return -EAGAIN;

 	return 0;
 }
 EXPORT_SYMBOL(tegra_ivc_notified);

 size_t tegra_ivc_align(size_t size)
 {
 	return ALIGN(size, TEGRA_IVC_ALIGN);
 }
 EXPORT_SYMBOL(tegra_ivc_align);

 unsigned tegra_ivc_total_queue_size(unsigned queue_size)
 {
 	if (!IS_ALIGNED(queue_size, TEGRA_IVC_ALIGN)) {
 		pr_err("%s: queue_size (%u) must be %u-byte aligned\n",
 		       __func__, queue_size, TEGRA_IVC_ALIGN);
 		return 0;
 	}

 	return queue_size + sizeof(struct tegra_ivc_header);
 }
 EXPORT_SYMBOL(tegra_ivc_total_queue_size);

 static int tegra_ivc_check_params(unsigned long rx, unsigned long tx,
 				  unsigned int num_frames, size_t frame_size)
 {
 	BUILD_BUG_ON(!IS_ALIGNED(offsetof(struct tegra_ivc_header, tx.count),
 				 TEGRA_IVC_ALIGN));
 	BUILD_BUG_ON(!IS_ALIGNED(offsetof(struct tegra_ivc_header, rx.count),
 				 TEGRA_IVC_ALIGN));
 	BUILD_BUG_ON(!IS_ALIGNED(sizeof(struct tegra_ivc_header),
 				 TEGRA_IVC_ALIGN));

 	if ((uint64_t)num_frames * (uint64_t)frame_size >= 0x100000000UL) {
 		pr_err("num_frames * frame_size overflows\n");
 		return -EINVAL;
 	}

 	if (!IS_ALIGNED(frame_size, TEGRA_IVC_ALIGN)) {
 		pr_err("frame size not adequately aligned: %zu\n", frame_size);
 		return -EINVAL;
 	}

 	/*
 	 * The headers must at least be aligned enough for counters
 	 * to be accessed atomically.
 	 */
 	if (!IS_ALIGNED(rx, TEGRA_IVC_ALIGN)) {
 		pr_err("IVC channel start not aligned: %#lx\n", rx);
 		return -EINVAL;
 	}

 	if (!IS_ALIGNED(tx, TEGRA_IVC_ALIGN)) {
 		pr_err("IVC channel start not aligned: %#lx\n", tx);
 		return -EINVAL;
 	}

 	if (rx < tx) {
 		if (rx + frame_size * num_frames > tx) {
 			pr_err("queue regions overlap: %#lx + %zx > %#lx\n",
 			       rx, frame_size * num_frames, tx);
 			return -EINVAL;
 		}
 	} else {
 		if (tx + frame_size * num_frames > rx) {
 			pr_err("queue regions overlap: %#lx + %zx > %#lx\n",
 			       tx, frame_size * num_frames, rx);
 			return -EINVAL;
 		}
 	}

 	return 0;
 }

 int tegra_ivc_init(struct tegra_ivc *ivc, struct device *peer, void *rx,
 		   dma_addr_t rx_phys, void *tx, dma_addr_t tx_phys,
 		   unsigned int num_frames, size_t frame_size,
 		   void (*notify)(struct tegra_ivc *ivc, void *data),
 		   void *data)
 {
 	size_t queue_size;
 	int err;

 	if (WARN_ON(!ivc || !notify))
 		return -EINVAL;

 	/*
 	 * All sizes that can be returned by communication functions should
 	 * fit in an int.
 	 */
 	if (frame_size > INT_MAX)
 		return -E2BIG;

 	err = tegra_ivc_check_params((unsigned long)rx, (unsigned long)tx,
 				     num_frames, frame_size);
 	if (err < 0)
 		return err;

 	queue_size = tegra_ivc_total_queue_size(num_frames * frame_size);

 	if (peer) {
 		ivc->rx.phys = dma_map_single(peer, rx, queue_size,
 					      DMA_BIDIRECTIONAL);
 		if (dma_mapping_error(peer, ivc->rx.phys))
 			return -ENOMEM;

 		ivc->tx.phys = dma_map_single(peer, tx, queue_size,
 					      DMA_BIDIRECTIONAL);
 		if (dma_mapping_error(peer, ivc->tx.phys)) {
 			dma_unmap_single(peer, ivc->rx.phys, queue_size,
 					 DMA_BIDIRECTIONAL);
 			return -ENOMEM;
 		}
 	} else {
 		ivc->rx.phys = rx_phys;
 		ivc->tx.phys = tx_phys;
 	}

 	ivc->rx.channel = rx;
 	ivc->tx.channel = tx;
 	ivc->peer = peer;
 	ivc->notify = notify;
 	ivc->notify_data = data;
 	ivc->frame_size = frame_size;
 	ivc->num_frames = num_frames;

 	/*
 	 * These values aren't necessarily correct until the channel has been
 	 * reset.
 	 */
 	ivc->tx.position = 0;
 	ivc->rx.position = 0;

 	return 0;
 }
 EXPORT_SYMBOL(tegra_ivc_init);

 void tegra_ivc_cleanup(struct tegra_ivc *ivc)
 {
 	if (ivc->peer) {
 		size_t size = tegra_ivc_total_queue_size(ivc->num_frames *
 							 ivc->frame_size);

 		dma_unmap_single(ivc->peer, ivc->rx.phys, size,
 				 DMA_BIDIRECTIONAL);
 		dma_unmap_single(ivc->peer, ivc->tx.phys, size,
 				 DMA_BIDIRECTIONAL);
 	}
 }
 EXPORT_SYMBOL(tegra_ivc_cleanup);
	// SPDX-License-Identifier: GPL-2.0-only
	/*
	* Copyright (c) 2014-2016, NVIDIA CORPORATION. All rights reserved.
	*/

	#include <soc/tegra/ivc.h>

	#define TEGRA_IVC_ALIGN 64

	/*
	* IVC channel reset protocol.
	*
	* Each end uses its tx_channel.state to indicate its synchronization state.
	*/
	enum tegra_ivc_state {
	/*
	* This value is zero for backwards compatibility with services that
	* assume channels to be initially zeroed. Such channels are in an
	* initially valid state, but cannot be asynchronously reset, and must
	* maintain a valid state at all times.
	*
	* The transmitting end can enter the established state from the sync or
	* ack state when it observes the receiving endpoint in the ack or
	* established state, indicating that has cleared the counters in our
	* rx_channel.
	*/
	TEGRA_IVC_STATE_ESTABLISHED = 0,

	/*
	* If an endpoint is observed in the sync state, the remote endpoint is
	* allowed to clear the counters it owns asynchronously with respect to
	* the current endpoint. Therefore, the current endpoint is no longer
	* allowed to communicate.
	*/
	TEGRA_IVC_STATE_SYNC,

	/*
	* When the transmitting end observes the receiving end in the sync
	* state, it can clear the w_count and r_count and transition to the ack
	* state. If the remote endpoint observes us in the ack state, it can
	* return to the established state once it has cleared its counters.
	*/
	TEGRA_IVC_STATE_ACK
	};

	/*
	* This structure is divided into two-cache aligned parts, the first is only
	* written through the tx.channel pointer, while the second is only written
	* through the rx.channel pointer. This delineates ownership of the cache
	* lines, which is critical to performance and necessary in non-cache coherent
	* implementations.
	*/
	struct tegra_ivc_header {
	union {
	struct {
	/* fields owned by the transmitting end */
	u32 count;
	u32 state;
	};

	u8 pad[TEGRA_IVC_ALIGN];
	} tx;

	union {
	/* fields owned by the receiving end */
	u32 count;
	u8 pad[TEGRA_IVC_ALIGN];
	} rx;
	};

	static inline void tegra_ivc_invalidate(struct tegra_ivc *ivc, dma_addr_t phys)
	{
	if (!ivc->peer)
	return;

	dma_sync_single_for_cpu(ivc->peer, phys, TEGRA_IVC_ALIGN,
	DMA_FROM_DEVICE);
	}

	static inline void tegra_ivc_flush(struct tegra_ivc *ivc, dma_addr_t phys)
	{
	if (!ivc->peer)
	return;

	dma_sync_single_for_device(ivc->peer, phys, TEGRA_IVC_ALIGN,
	DMA_TO_DEVICE);
	}

	static inline bool tegra_ivc_empty(struct tegra_ivc *ivc,
	struct tegra_ivc_header *header)
	{
	/*
	* This function performs multiple checks on the same values with
	* security implications, so create snapshots with READ_ONCE() to
	* ensure that these checks use the same values.
	*/
	u32 tx = READ_ONCE(header->tx.count);
	u32 rx = READ_ONCE(header->rx.count);

	/*
	* Perform an over-full check to prevent denial of service attacks
	* where a server could be easily fooled into believing that there's
	* an extremely large number of frames ready, since receivers are not
	* expected to check for full or over-full conditions.
	*
	* Although the channel isn't empty, this is an invalid case caused by
	* a potentially malicious peer, so returning empty is safer, because
	* it gives the impression that the channel has gone silent.
	*/
	if (tx - rx > ivc->num_frames)
	return true;

	return tx == rx;
	}

	static inline bool tegra_ivc_full(struct tegra_ivc *ivc,
	struct tegra_ivc_header *header)
	{
	u32 tx = READ_ONCE(header->tx.count);
	u32 rx = READ_ONCE(header->rx.count);

	/*
	* Invalid cases where the counters indicate that the queue is over
	* capacity also appear full.
	*/
	return tx - rx >= ivc->num_frames;
	}

	static inline u32 tegra_ivc_available(struct tegra_ivc *ivc,
	struct tegra_ivc_header *header)
	{
	u32 tx = READ_ONCE(header->tx.count);
	u32 rx = READ_ONCE(header->rx.count);

	/*
	* This function isn't expected to be used in scenarios where an
	* over-full situation can lead to denial of service attacks. See the
	* comment in tegra_ivc_empty() for an explanation about special
	* over-full considerations.
	*/
	return tx - rx;
	}

	static inline void tegra_ivc_advance_tx(struct tegra_ivc *ivc)
	{
	WRITE_ONCE(ivc->tx.channel->tx.count,
	READ_ONCE(ivc->tx.channel->tx.count) + 1);

	if (ivc->tx.position == ivc->num_frames - 1)
	ivc->tx.position = 0;
	else
	ivc->tx.position++;
	}

	static inline void tegra_ivc_advance_rx(struct tegra_ivc *ivc)
	{
	WRITE_ONCE(ivc->rx.channel->rx.count,
	READ_ONCE(ivc->rx.channel->rx.count) + 1);

	if (ivc->rx.position == ivc->num_frames - 1)
	ivc->rx.position = 0;
	else
	ivc->rx.position++;
	}

	static inline int tegra_ivc_check_read(struct tegra_ivc *ivc)
	{
	unsigned int offset = offsetof(struct tegra_ivc_header, tx.count);

	/*
	* tx.channel->state is set locally, so it is not synchronized with
	* state from the remote peer. The remote peer cannot reset its
	* transmit counters until we've acknowledged its synchronization
	* request, so no additional synchronization is required because an
	* asynchronous transition of rx.channel->state to
	* TEGRA_IVC_STATE_ACK is not allowed.
	*/
	if (ivc->tx.channel->tx.state != TEGRA_IVC_STATE_ESTABLISHED)
	return -ECONNRESET;

	/*
	* Avoid unnecessary invalidations when performing repeated accesses
	* to an IVC channel by checking the old queue pointers first.
	*
	* Synchronization is only necessary when these pointers indicate
	* empty or full.
	*/
	if (!tegra_ivc_empty(ivc, ivc->rx.channel))
	return 0;

	tegra_ivc_invalidate(ivc, ivc->rx.phys + offset);

	if (tegra_ivc_empty(ivc, ivc->rx.channel))
	return -ENOSPC;

	return 0;
	}

	static inline int tegra_ivc_check_write(struct tegra_ivc *ivc)
	{
	unsigned int offset = offsetof(struct tegra_ivc_header, rx.count);

	if (ivc->tx.channel->tx.state != TEGRA_IVC_STATE_ESTABLISHED)
	return -ECONNRESET;

	if (!tegra_ivc_full(ivc, ivc->tx.channel))
	return 0;

	tegra_ivc_invalidate(ivc, ivc->tx.phys + offset);

	if (tegra_ivc_full(ivc, ivc->tx.channel))
	return -ENOSPC;

	return 0;
	}

	static void tegra_ivc_frame_virt(struct tegra_ivc ivc,
	struct tegra_ivc_header *header,
	unsigned int frame)
	{
	if (WARN_ON(frame >= ivc->num_frames))
	return ERR_PTR(-EINVAL);

	return (void )(header + 1) + ivc->frame_size frame;
	}

	static inline dma_addr_t tegra_ivc_frame_phys(struct tegra_ivc *ivc,
	dma_addr_t phys,
	unsigned int frame)
	{
	unsigned long offset;

	offset = sizeof(struct tegra_ivc_header) + ivc->frame_size * frame;

	return phys + offset;
	}

	static inline void tegra_ivc_invalidate_frame(struct tegra_ivc *ivc,
	dma_addr_t phys,
	unsigned int frame,
	unsigned int offset,
	size_t size)
	{
	if (!ivc->peer \|\| WARN_ON(frame >= ivc->num_frames))
	return;

	phys = tegra_ivc_frame_phys(ivc, phys, frame) + offset;

	dma_sync_single_for_cpu(ivc->peer, phys, size, DMA_FROM_DEVICE);
	}

	static inline void tegra_ivc_flush_frame(struct tegra_ivc *ivc,
	dma_addr_t phys,
	unsigned int frame,
	unsigned int offset,
	size_t size)
	{
	if (!ivc->peer \|\| WARN_ON(frame >= ivc->num_frames))
	return;

	phys = tegra_ivc_frame_phys(ivc, phys, frame) + offset;

	dma_sync_single_for_device(ivc->peer, phys, size, DMA_TO_DEVICE);
	}

	/* directly peek at the next frame rx'ed */
	void tegra_ivc_read_get_next_frame(struct tegra_ivc ivc)
	{
	int err;

	if (WARN_ON(ivc == NULL))
	return ERR_PTR(-EINVAL);

	err = tegra_ivc_check_read(ivc);
	if (err < 0)
	return ERR_PTR(err);

	/*
	* Order observation of ivc->rx.position potentially indicating new
	* data before data read.
	*/
	smp_rmb();

	tegra_ivc_invalidate_frame(ivc, ivc->rx.phys, ivc->rx.position, 0,
	ivc->frame_size);

	return tegra_ivc_frame_virt(ivc, ivc->rx.channel, ivc->rx.position);
	}
	EXPORT_SYMBOL(tegra_ivc_read_get_next_frame);

	int tegra_ivc_read_advance(struct tegra_ivc *ivc)
	{
	unsigned int rx = offsetof(struct tegra_ivc_header, rx.count);
	unsigned int tx = offsetof(struct tegra_ivc_header, tx.count);
	int err;

	/*
	* No read barriers or synchronization here: the caller is expected to
	* have already observed the channel non-empty. This check is just to
	* catch programming errors.
	*/
	err = tegra_ivc_check_read(ivc);
	if (err < 0)
	return err;

	tegra_ivc_advance_rx(ivc);

	tegra_ivc_flush(ivc, ivc->rx.phys + rx);

	/*
	* Ensure our write to ivc->rx.position occurs before our read from
	* ivc->tx.position.
	*/
	smp_mb();

	/*
	* Notify only upon transition from full to non-full. The available
	* count can only asynchronously increase, so the worst possible
	* side-effect will be a spurious notification.
	*/
	tegra_ivc_invalidate(ivc, ivc->rx.phys + tx);

	if (tegra_ivc_available(ivc, ivc->rx.channel) == ivc->num_frames - 1)
	ivc->notify(ivc, ivc->notify_data);

	return 0;
	}
	EXPORT_SYMBOL(tegra_ivc_read_advance);

	/* directly poke at the next frame to be tx'ed */
	void tegra_ivc_write_get_next_frame(struct tegra_ivc ivc)
	{
	int err;

	err = tegra_ivc_check_write(ivc);
	if (err < 0)
	return ERR_PTR(err);

	return tegra_ivc_frame_virt(ivc, ivc->tx.channel, ivc->tx.position);
	}
	EXPORT_SYMBOL(tegra_ivc_write_get_next_frame);

	/* advance the tx buffer */
	int tegra_ivc_write_advance(struct tegra_ivc *ivc)
	{
	unsigned int tx = offsetof(struct tegra_ivc_header, tx.count);
	unsigned int rx = offsetof(struct tegra_ivc_header, rx.count);
	int err;

	err = tegra_ivc_check_write(ivc);
	if (err < 0)
	return err;

	tegra_ivc_flush_frame(ivc, ivc->tx.phys, ivc->tx.position, 0,
	ivc->frame_size);

	/*
	* Order any possible stores to the frame before update of
	* ivc->tx.position.
	*/
	smp_wmb();

	tegra_ivc_advance_tx(ivc);
	tegra_ivc_flush(ivc, ivc->tx.phys + tx);

	/*
	* Ensure our write to ivc->tx.position occurs before our read from
	* ivc->rx.position.
	*/
	smp_mb();

	/*
	* Notify only upon transition from empty to non-empty. The available
	* count can only asynchronously decrease, so the worst possible
	* side-effect will be a spurious notification.
	*/
	tegra_ivc_invalidate(ivc, ivc->tx.phys + rx);

	if (tegra_ivc_available(ivc, ivc->tx.channel) == 1)
	ivc->notify(ivc, ivc->notify_data);

	return 0;
	}
	EXPORT_SYMBOL(tegra_ivc_write_advance);

	void tegra_ivc_reset(struct tegra_ivc *ivc)
	{
	unsigned int offset = offsetof(struct tegra_ivc_header, tx.count);

	ivc->tx.channel->tx.state = TEGRA_IVC_STATE_SYNC;
	tegra_ivc_flush(ivc, ivc->tx.phys + offset);
	ivc->notify(ivc, ivc->notify_data);
	}
	EXPORT_SYMBOL(tegra_ivc_reset);

	/*
	* =======================================================
	* IVC State Transition Table - see tegra_ivc_notified()
	* =======================================================
	*
	* local remote action
	* ----- ------ -----------------------------------
	* SYNC EST <none>
	* SYNC ACK reset counters; move to EST; notify
	* SYNC SYNC reset counters; move to ACK; notify
	* ACK EST move to EST; notify
	* ACK ACK move to EST; notify
	* ACK SYNC reset counters; move to ACK; notify
	* EST EST <none>
	* EST ACK <none>
	* EST SYNC reset counters; move to ACK; notify
	*
	* ===============================================================
	*/

	int tegra_ivc_notified(struct tegra_ivc *ivc)
	{
	unsigned int offset = offsetof(struct tegra_ivc_header, tx.count);
	enum tegra_ivc_state state;

	/* Copy the receiver's state out of shared memory. */
	tegra_ivc_invalidate(ivc, ivc->rx.phys + offset);
	state = READ_ONCE(ivc->rx.channel->tx.state);

	if (state == TEGRA_IVC_STATE_SYNC) {
	offset = offsetof(struct tegra_ivc_header, tx.count);

	/*
	* Order observation of TEGRA_IVC_STATE_SYNC before stores
	* clearing tx.channel.
	*/
	smp_rmb();

	/*
	* Reset tx.channel counters. The remote end is in the SYNC
	* state and won't make progress until we change our state,
	* so the counters are not in use at this time.
	*/
	ivc->tx.channel->tx.count = 0;
	ivc->rx.channel->rx.count = 0;

	ivc->tx.position = 0;
	ivc->rx.position = 0;

	/*
	* Ensure that counters appear cleared before new state can be
	* observed.
	*/
	smp_wmb();

	/*
	* Move to ACK state. We have just cleared our counters, so it
	* is now safe for the remote end to start using these values.
	*/
	ivc->tx.channel->tx.state = TEGRA_IVC_STATE_ACK;
	tegra_ivc_flush(ivc, ivc->tx.phys + offset);

	/*
	* Notify remote end to observe state transition.
	*/
	ivc->notify(ivc, ivc->notify_data);

	} else if (ivc->tx.channel->tx.state == TEGRA_IVC_STATE_SYNC &&
	state == TEGRA_IVC_STATE_ACK) {
	offset = offsetof(struct tegra_ivc_header, tx.count);

	/*
	* Order observation of ivc_state_sync before stores clearing
	* tx_channel.
	*/
	smp_rmb();

	/*
	* Reset tx.channel counters. The remote end is in the ACK
	* state and won't make progress until we change our state,
	* so the counters are not in use at this time.
	*/
	ivc->tx.channel->tx.count = 0;
	ivc->rx.channel->rx.count = 0;

	ivc->tx.position = 0;
	ivc->rx.position = 0;

	/*
	* Ensure that counters appear cleared before new state can be
	* observed.
	*/
	smp_wmb();

	/*
	* Move to ESTABLISHED state. We know that the remote end has
	* already cleared its counters, so it is safe to start
	* writing/reading on this channel.
	*/
	ivc->tx.channel->tx.state = TEGRA_IVC_STATE_ESTABLISHED;
	tegra_ivc_flush(ivc, ivc->tx.phys + offset);

	/*
	* Notify remote end to observe state transition.
	*/
	ivc->notify(ivc, ivc->notify_data);

	} else if (ivc->tx.channel->tx.state == TEGRA_IVC_STATE_ACK) {
	offset = offsetof(struct tegra_ivc_header, tx.count);

	/*
	* At this point, we have observed the peer to be in either
	* the ACK or ESTABLISHED state. Next, order observation of
	* peer state before storing to tx.channel.
	*/
	smp_rmb();

	/*
	* Move to ESTABLISHED state. We know that we have previously
	* cleared our counters, and we know that the remote end has
	* cleared its counters, so it is safe to start writing/reading
	* on this channel.
	*/
	ivc->tx.channel->tx.state = TEGRA_IVC_STATE_ESTABLISHED;
	tegra_ivc_flush(ivc, ivc->tx.phys + offset);

	/*
	* Notify remote end to observe state transition.
	*/
	ivc->notify(ivc, ivc->notify_data);

	} else {
	/*
	* There is no need to handle any further action. Either the
	* channel is already fully established, or we are waiting for
	* the remote end to catch up with our current state. Refer
	* to the diagram in "IVC State Transition Table" above.
	*/
	}

	if (ivc->tx.channel->tx.state != TEGRA_IVC_STATE_ESTABLISHED)
	return -EAGAIN;

	return 0;
	}
	EXPORT_SYMBOL(tegra_ivc_notified);

	size_t tegra_ivc_align(size_t size)
	{
	return ALIGN(size, TEGRA_IVC_ALIGN);
	}
	EXPORT_SYMBOL(tegra_ivc_align);

	unsigned tegra_ivc_total_queue_size(unsigned queue_size)
	{
	if (!IS_ALIGNED(queue_size, TEGRA_IVC_ALIGN)) {
	pr_err("%s: queue_size (%u) must be %u-byte aligned\n",
	__func__, queue_size, TEGRA_IVC_ALIGN);
	return 0;
	}

	return queue_size + sizeof(struct tegra_ivc_header);
	}
	EXPORT_SYMBOL(tegra_ivc_total_queue_size);

	static int tegra_ivc_check_params(unsigned long rx, unsigned long tx,
	unsigned int num_frames, size_t frame_size)
	{
	BUILD_BUG_ON(!IS_ALIGNED(offsetof(struct tegra_ivc_header, tx.count),
	TEGRA_IVC_ALIGN));
	BUILD_BUG_ON(!IS_ALIGNED(offsetof(struct tegra_ivc_header, rx.count),
	TEGRA_IVC_ALIGN));
	BUILD_BUG_ON(!IS_ALIGNED(sizeof(struct tegra_ivc_header),
	TEGRA_IVC_ALIGN));

	if ((uint64_t)num_frames * (uint64_t)frame_size >= 0x100000000UL) {
	pr_err("num_frames * frame_size overflows\n");
	return -EINVAL;
	}

	if (!IS_ALIGNED(frame_size, TEGRA_IVC_ALIGN)) {
	pr_err("frame size not adequately aligned: %zu\n", frame_size);
	return -EINVAL;
	}

	/*
	* The headers must at least be aligned enough for counters
	* to be accessed atomically.
	*/
	if (!IS_ALIGNED(rx, TEGRA_IVC_ALIGN)) {
	pr_err("IVC channel start not aligned: %#lx\n", rx);
	return -EINVAL;
	}

	if (!IS_ALIGNED(tx, TEGRA_IVC_ALIGN)) {
	pr_err("IVC channel start not aligned: %#lx\n", tx);
	return -EINVAL;
	}

	if (rx < tx) {
	if (rx + frame_size * num_frames > tx) {
	pr_err("queue regions overlap: %#lx + %zx > %#lx\n",
	rx, frame_size * num_frames, tx);
	return -EINVAL;
	}
	} else {
	if (tx + frame_size * num_frames > rx) {
	pr_err("queue regions overlap: %#lx + %zx > %#lx\n",
	tx, frame_size * num_frames, rx);
	return -EINVAL;
	}
	}

	return 0;
	}

	int tegra_ivc_init(struct tegra_ivc ivc, struct device peer, void *rx,
	dma_addr_t rx_phys, void *tx, dma_addr_t tx_phys,
	unsigned int num_frames, size_t frame_size,
	void (notify)(struct tegra_ivc ivc, void *data),
	void *data)
	{
	size_t queue_size;
	int err;

	if (WARN_ON(!ivc \|\| !notify))
	return -EINVAL;

	/*
	* All sizes that can be returned by communication functions should
	* fit in an int.
	*/
	if (frame_size > INT_MAX)
	return -E2BIG;

	err = tegra_ivc_check_params((unsigned long)rx, (unsigned long)tx,
	num_frames, frame_size);
	if (err < 0)
	return err;

	queue_size = tegra_ivc_total_queue_size(num_frames * frame_size);

	if (peer) {
	ivc->rx.phys = dma_map_single(peer, rx, queue_size,
	DMA_BIDIRECTIONAL);
	if (dma_mapping_error(peer, ivc->rx.phys))
	return -ENOMEM;

	ivc->tx.phys = dma_map_single(peer, tx, queue_size,
	DMA_BIDIRECTIONAL);
	if (dma_mapping_error(peer, ivc->tx.phys)) {
	dma_unmap_single(peer, ivc->rx.phys, queue_size,
	DMA_BIDIRECTIONAL);
	return -ENOMEM;
	}
	} else {
	ivc->rx.phys = rx_phys;
	ivc->tx.phys = tx_phys;
	}

	ivc->rx.channel = rx;
	ivc->tx.channel = tx;
	ivc->peer = peer;
	ivc->notify = notify;
	ivc->notify_data = data;
	ivc->frame_size = frame_size;
	ivc->num_frames = num_frames;

	/*
	* These values aren't necessarily correct until the channel has been
	* reset.
	*/
	ivc->tx.position = 0;
	ivc->rx.position = 0;

	return 0;
	}
	EXPORT_SYMBOL(tegra_ivc_init);

	void tegra_ivc_cleanup(struct tegra_ivc *ivc)
	{
	if (ivc->peer) {
	size_t size = tegra_ivc_total_queue_size(ivc->num_frames *
	ivc->frame_size);

	dma_unmap_single(ivc->peer, ivc->rx.phys, size,
	DMA_BIDIRECTIONAL);
	dma_unmap_single(ivc->peer, ivc->tx.phys, size,
	DMA_BIDIRECTIONAL);
	}
	}
	EXPORT_SYMBOL(tegra_ivc_cleanup);