platform/msm_shared/utp.c - kernel/lk - Gitiles

 /* Copyright (c) 2013-2014, The Linux Foundation. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are
  * met:
  *     * Redistributions of source code must retain the above copyright
  *       notice, this list of conditions and the following disclaimer.
  *     * Redistributions in binary form must reproduce the above
  *       copyright notice, this list of conditions and the following
  *       disclaimer in the documentation and/or other materials provided
  *       with the distribution.
  *     * Neither the name of The Linux Foundation nor the names of its
  *       contributors may be used to endorse or promote products derived
  *       from this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
  * ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
  * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
  * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
  * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include <arch/ops.h>
 #include <sys/types.h>
 #include <kernel/thread.h>
 #include <debug.h>
 #include <err.h>
 #include <reg.h>
 #include <string.h>
 #include <malloc.h>
 #include <stdlib.h>
 #include <ufs_hw.h>
 #include <utp.h>
 #include <ufs.h>
 #include <platform/iomap.h>
 #include <platform/clock.h>
 #include <platform/timer.h>
 #include <arch/ops.h>
 #include <endian.h>
 #include <stdlib.h>
 #include <sys/types.h>

 void utp_process_req_completion(struct ufs_req_irq_type *irq)
 {
 	struct ufs_req_node *req;
 	struct list_node    *prev;
 	uint32_t            val;

 	/* Make sure we have more nodes than just the head in the list. */
 	if (list_next(irq->list, irq->list) == NULL)
 	{
 		dprintf(CRITICAL, "%s:%d UTRD/ UTMRD processed signalled and the wait queue is empty\n", __func__, __LINE__);
 		ASSERT(0);
 	}

 	/* Read the door bell register. */
 	val = readl(irq->door_bell_reg);

 	list_for_every_entry(irq->list, req, struct ufs_req_node, list_node)
 	{
 		if (!(req->door_bell_bit & val))
 		{
 			/* Transaction is complete: Either transaction completed in a normal way.
 			 * Delete and Signal all requests that have completed.
 			 */
 			prev = req->list_node.prev;
 			/* TODO: move delete to the caller function. */
 			list_delete(&(req->list_node));

 			if (event_signal(req->event, false))
 			{
 				dprintf(CRITICAL, "%s:%d Event signal failed.\n",__func__, __LINE__);
 				ASSERT(0);

 			}
 			req = containerof(prev, struct ufs_req_node, list_node);
 		}
 	}

 	return;
 }

 /* Always called within critical section: utrd_bitmap_mutex/ utmrd_bitmap_mutex. */
 static uint32_t utp_get_door_bell_bit(uint32_t reg, uint32_t *reg_bitmap, uint32_t *bit_num)
 {
 	uint32_t val = 0;
 	uint32_t doorbell_bit_val;
 	uint32_t found = 0;

 	*bit_num = 0;

 	val = readl(reg) | *reg_bitmap;
 	doorbell_bit_val = 1;

 	/* Find an empty slot. */
 	do
 	{
 		(*bit_num)++;

 		if (!(doorbell_bit_val & val))
 		{
 			found = 1;
 			*reg_bitmap |= doorbell_bit_val;
 			break;
 		}
 		doorbell_bit_val <<= 1;
 	}while (doorbell_bit_val <= (uint32_t) (1 << 31));

 	if (!found)
 	{
 		doorbell_bit_val = 0;
 		dprintf(CRITICAL, "%s:%d Unable to find a free slot for transaction.\n",__func__, __LINE__);
 	}

 	return doorbell_bit_val;
 }

 static void utp_ring_door_bell(uint32_t reg, uint32_t doorbell_bit)
 {
 	writel(doorbell_bit, reg);
 }

 static int utp_utrd_process_timeout_req(struct ufs_dev *dev,
 								 struct utp_utrd_req_build_type *utrd_req,
 								 struct ufs_req_node *req)
 {
 	switch (utrd_req->req_upiu->trans_type)
 	{
 		case UPIU_TYPE_NOP_OUT:
 							    writel(~req->door_bell_bit, UFS_UTRLCLR(dev->base));
 								return -UFS_RETRY;
 		default:
 								/* TODO : Add ufs hci sw reset.*/
 								ASSERT(0);
 								return -UFS_FAILURE;
 	}
 }

 static int utp_remove_from_bitmap(struct utp_bitmap_access_type *req)
 {

 	if (mutex_acquire(req->mutx))
 	{
 		return -UFS_FAILURE;
 	}

 	*(req->bitmap) &= ~req->door_bell_bit;

 	if (mutex_release(req->mutx))
 	{
 		return -UFS_FAILURE;
 	}

 	return UFS_SUCCESS;
 }

 static void utp_enqueue_utrd_fill_desc(struct utp_trans_req_desc *desc, struct utp_utrd_req_build_type *utrd_req)
 {
 	/* Fill transfer desc. */
 	memset(desc, 0, UPIU_HDR_LEN);
 	desc->cmd_type_dd_irq = UTP_REQ_BUILD_CMD_DD_IRQ_FIELD(utrd_req->cmd_type, utrd_req->dd, utrd_req->irq);
 	desc->overall_cmd_status = utrd_req->ocs;
 	/* Bits 0 - 6 are reserved in cmd_desc_base_addr[0] field. */
 	desc->cmd_desc_base_addr[0] = ((uint32_t) utrd_req->req_upiu) & 0xC0;
 	desc->cmd_desc_base_addr[1] = ((uint32_t) utrd_req->req_upiu >> 8) & 0xFF;
 	desc->cmd_desc_base_addr[2] = ((uint32_t) utrd_req->req_upiu >> 16) & 0xFF;
 	desc->cmd_desc_base_addr[3] = ((uint32_t) utrd_req->req_upiu >> 24) & 0xFF;
 	desc->resp_upiu_offset = ROUNDUP(utrd_req->req_upiu_len, UPIU_HDR_LEN) / 4;
 	desc->resp_upiu_len = utrd_req->resp_upiu_len;

 	if (utrd_req->dd != UTRD_NO_DATA_TRANSFER)
 	{
 		/* Data transfer command.
 		 * Fill in PRDT data.
 		 */
 		desc->prdt_offset = utrd_req->prdt_offset / 4;
 		desc->prdt_len    = utrd_req->prdt_len;
 	}

 	/* Flush UTRD to memory. */
 	cache_clean_invalidate_unaligned_start_addr((addr_t)desc, sizeof(struct utp_trans_req_desc));
 }

 static struct utp_trans_req_desc* utp_get_desc_slot_addr(struct ufs_dev *dev, struct utp_utrd_req_build_type *utrd_req, uint32_t *door_bell_val)
 {
 	struct utp_trans_req_desc *desc = NULL;
 	uint32_t                  door_bell_slot;

 	if (mutex_acquire(&(dev->utrd_data.bitmap_mutex)))
 	{
 		goto utp_get_desc_slot_addr_err;
 	}

 	*door_bell_val = utp_get_door_bell_bit(UFS_UTRLDBR(dev->base), &dev->utrd_data.bitmap, &door_bell_slot);
 	if (!(*door_bell_val))
 	{
 		goto utp_get_desc_slot_addr_err;
 	}

 	if (mutex_release(&(dev->utrd_data.bitmap_mutex)))
 	{
 		goto utp_get_desc_slot_addr_err;
 	}

 	desc = (struct utp_trans_req_desc *) ((addr_t)dev->utrd_data.list_base_addr + (door_bell_slot - 1) * sizeof(struct utp_trans_req_desc));

 utp_get_desc_slot_addr_err:
 	return desc;
 }

 int utp_poll_utrd_complete(struct ufs_dev *dev)
 {
 	int ret;
 	struct ufs_req_irq_type irq;
 	uint32_t val, base, retry = 0;
 	base = dev->base;
 	val = readl(UFS_IS(base));
 	irq.irq_handled = 0;
 	/* Wait till the desc has been processed. */
 	while(((val & UFS_IS_UTRCS) == 0) && ((val & UFS_IS_UTMRCS) == 0))
 	{
 		val = readl(UFS_IS(base));
 		retry++;
 		udelay(1);
 		if(retry == UTP_MAX_COMMAND_RETRY)
 		{
 			dprintf(CRITICAL, "%s:%d UTP command never completed.\n", __func__, __LINE__);
 			return ERR_TIMED_OUT;
 		}
 #ifdef DEBUG_UFS
 		dprintf(INFO, "Waiting for UTRCS/URMRCS Completion...\n");
 #endif
 	}
 	if (readl(UFS_IS(base)) & UFS_IS_UTRCS)
 	{
 		val = readl(UFS_IS(base)) & UFS_IS_UTRCS;
 		writel(UFS_IS_UTRCS, UFS_IS(base));
 		irq.irq_handled = UFS_IS_UTRCS;
 		irq.list = &(dev->utrd_data.list_head.list_node);
 		irq.door_bell_reg = UFS_UTRLDBR(base);
 		utp_process_req_completion(&irq);
 		ret = INT_NO_RESCHEDULE;
 	}
 	else if (readl(UFS_IS(base)) & (UFS_IS_UTMRCS))
 	{
 		val = readl(UFS_IS(base)) & UFS_IS_UTMRCS;
 		writel(UFS_IS_UTMRCS, UFS_IS(base));
 		irq.irq_handled = UFS_IS_UTMRCS;
 		irq.list = &(dev->utmrd_data.list_head.list_node);
 		utp_process_req_completion(&irq);
 		ret = INT_NO_RESCHEDULE;
 	}
 	return ret;
 }

 static int utp_enqueue_utrd(struct ufs_dev *dev, struct utp_utrd_req_build_type *utrd_req)
 {
 	int                           ret;
 	struct utp_trans_req_desc     *desc;
 	event_t                       utrd_evt;
 	struct ufs_req_node           req;
 	uint32_t                      door_bell_bit_val;
 	struct utp_bitmap_access_type bitmap_req;

 	ret = UFS_SUCCESS;

 	event_init(&utrd_evt, false, EVENT_FLAG_AUTOUNSIGNAL);

 	desc = utp_get_desc_slot_addr(dev, utrd_req, &door_bell_bit_val);
 	if (!desc)
 	{
 		ret = UFS_FAILURE;
 		goto utp_enqueue_utrd_err;
 	}

 	/* Check register UTRLRSR and make sure it is read 1 before continuing. */
 	if (!readl(UFS_UTRLRSR(dev->base)))
 	{
 		ret = -UFS_FAILURE;
 		goto utp_enqueue_utrd_err;
 	}

 	utp_enqueue_utrd_fill_desc(desc, utrd_req);

 	req.door_bell_bit = door_bell_bit_val;
 	req.event         = &utrd_evt;

 	/* Enqueue the req in the device utrd list. */
 	list_add_head(&(dev->utrd_data.list_head.list_node), &(req.list_node));

 	dsb();

 #ifdef DEBUG_UFS
 	// print IS before write
 	ufs_dump_is_register(dev);
 #endif

 	utp_ring_door_bell(UFS_UTRLDBR(dev->base), door_bell_bit_val);

 	dsb();

 #ifdef DEBUG_UFS
 	// print IS after write
 	ufs_dump_is_register(dev);
 #endif
 	ret = utp_poll_utrd_complete(dev);

 	if (ret == ERR_TIMED_OUT)
 	{
 		/* Transaction not completed even after timeout ms. */
 		dprintf(CRITICAL, "%s:%d Transaction timeout after polling %d times\n",__func__, __LINE__, UTP_MAX_COMMAND_RETRY);
 		ret = utp_utrd_process_timeout_req(dev, utrd_req, &req);
 		goto utp_enqueue_utrd_err;
 	}
 	else
 	{
 		/* Reset ret before returning. */
 		ret = UFS_SUCCESS;

 		/* Force read UTRD from memory. */
 		dsb();
 		cache_clean_invalidate_unaligned_start_addr((addr_t) desc, sizeof(struct ufs_req_node));

 		/* Check the response. */
 		if (desc->overall_cmd_status != UTRD_OCS_SUCCESS)
 		{
 			dprintf(CRITICAL, "%s:%d Command failed. command type = %x\n", __func__, __LINE__, utrd_req->cmd_type);
 			ret = -UFS_FAILURE;
 			goto utp_enqueue_utrd_err;
 		}
 	}

 	/* Signal slot as free. */
 	bitmap_req.bitmap        = &dev->utrd_data.bitmap;
 	bitmap_req.door_bell_bit = req.door_bell_bit;
 	bitmap_req.mutx          = &(dev->utrd_data.bitmap_mutex);

 	ret = utp_remove_from_bitmap(&bitmap_req);
 	if (ret)
 		goto utp_enqueue_utrd_err;

 utp_enqueue_utrd_err:
 	return ret;
 }

 static int utp_get_prdt_len(uint32_t data_len, uint32_t *num_prdt)
 {
 	/* Calculate the prdt entries required. */
 	*num_prdt = ROUNDUP(data_len, UTP_MAX_PRD_DATA_BYTE_CNT);
 	*num_prdt >>= UTP_MAX_PRD_DATA_BYTE_CNT_BYTE_SHIFT;

 	if (*num_prdt > UTP_MAX_PRD_TABLE_ENTRIES)
 	{
 		dprintf(CRITICAL, "%s:%d Data length exceeds for a single upiu transfer.\n", __func__,__LINE__);
 		return -UFS_FAILURE;
 	}

 	return UFS_SUCCESS;
 }

 static int utp_fill_req_upiu(struct ufs_dev *dev, struct upiu_req_build_type *upiu_data, struct upiu_gen_hdr *req_upiu)
 {
 	memset(req_upiu, 0, UPIU_HDR_LEN);

 	if (upiu_data->trans_type == UPIU_TYPE_QUERY_REQ)
 	{
 		/* Fill in query specific fields. */
 		if (utp_build_query_req_upiu((struct upiu_trans_mgmt_query_hdr *) req_upiu, upiu_data))
 		{
 			return -UFS_FAILURE;
 		}
 	}

 	/* If a data transfer cmd, check the alignment and length of the buffer. */
 	if (upiu_data->expected_data_len)
 	{
 		if (upiu_data->data_buffer_addr & 0x3)
 		{
 			dprintf(CRITICAL, "%s:%d Alignment and length check failed for data tranfer command.\n", __func__, __LINE__);
 			return -UFS_FAILURE;
 		}
 	}

 	req_upiu->basic_hdr.trans_type    = upiu_data->trans_type;
 	req_upiu->basic_hdr.flags         = upiu_data->flags;
 	req_upiu->basic_hdr.cmd_set_type  = upiu_data->cmd_set_type;
 	req_upiu->basic_hdr.data_seg_len  = upiu_data->data_seg_len;
 	req_upiu->basic_hdr.lun           = upiu_data->lun;
 	req_upiu->basic_hdr.total_ehs_len = upiu_data->ehs_len;
 	req_upiu->basic_hdr.task_tag      = atomic_add((int *) &(dev->utrd_data.task_id), 1);
 	if (upiu_data->cdb)
 		memcpy(&(req_upiu->trans_specific_fields[4]), (void *) upiu_data->cdb, 16);
 	/* If command upiu, fill in data length. */
 	if (req_upiu->basic_hdr.trans_type == UPIU_TYPE_COMMAND)
 		((struct upiu_cmd_hdr *)req_upiu)->data_expected_len = BE32(upiu_data->expected_data_len);

 	return UFS_SUCCESS;

 }

 static void utp_fill_utrd_properties(struct upiu_req_build_type *upiu_data,
 									 struct utp_utrd_req_build_type *utrd,
 									 struct utrd_cmd_desc *cmd_desc)
 {
 	utrd->cmd_type      = upiu_data->cmd_type;
 	utrd->dd            = upiu_data->dd;
 	utrd->irq           = UTRD_IRQ_CMD;
 	utrd->prdt_offset   = UPIU_HDR_LEN + cmd_desc->resp_upiu_len;
 	utrd->prdt_len      = cmd_desc->num_prdt;
 	utrd->req_upiu      = (struct upiu_basic_hdr *) cmd_desc->req_upiu;
 	utrd->req_upiu_len  = UPIU_HDR_LEN;
 	utrd->resp_upiu_len = cmd_desc->resp_upiu_len;
 	utrd->ocs           = 0xF;
 	utrd->timeout       = upiu_data->timeout_msecs;
 }

 static void utp_fill_prdt_entries(struct upiu_req_build_type *upiu_data, struct utp_prdt_entry *prdt_entry)
 {
 	uint64_t buf;
 	uint64_t bytes_remaining;
 	uint32_t prd_dbc;

 	buf                = upiu_data->data_buffer_addr;
 	bytes_remaining    = upiu_data->expected_data_len;

 	while (bytes_remaining)
 	{
 		prdt_entry->data_base_addr   = buf;
 		prdt_entry->data_upper_addr  = buf >> 32;
 		prd_dbc                      = MIN(UTP_MAX_PRD_DATA_BYTE_CNT, bytes_remaining) - 1;
 		prdt_entry->data_byte_cnt    = prd_dbc;
 		if (bytes_remaining <= UTP_MAX_PRD_DATA_BYTE_CNT)
 			break;
 		buf             += UTP_MAX_PRD_DATA_BYTE_CNT;
 		bytes_remaining -= UTP_MAX_PRD_DATA_BYTE_CNT;
 		prdt_entry++;
 	}

 }

 int utp_enqueue_upiu(struct ufs_dev *dev, struct upiu_req_build_type *upiu_data)
 {
 	struct upiu_gen_hdr            *req_upiu;
 	struct utp_utrd_req_build_type utrd;
 	uint32_t                       num_prdt;
 	struct utp_prdt_entry          *prdt_entry;
 	int                            ret = UFS_SUCCESS;
 	uint32_t                       resp_len;
 	uint32_t                       cmd_desc_len;
 	struct utrd_cmd_desc           cmd_desc;

 	/* Round up resp_upiu_len to a DWORD boundary.
 	 * Also, make sure it is of min required length.
 	 */
 	resp_len = ROUNDUP(upiu_data->resp_data_len, 4) + UPIU_HDR_LEN;

 	if (utp_get_prdt_len(upiu_data->expected_data_len, &num_prdt))
 		return -UFS_FAILURE;

 	/* Calculate the length. */
 	cmd_desc_len = UPIU_HDR_LEN + resp_len + num_prdt * sizeof(struct utp_prdt_entry);

 	/* Allocate memory for UTP Command Descriptor. */
 	req_upiu = (struct upiu_gen_hdr*) memalign((size_t ) lcm(CACHE_LINE, UTP_CMD_DESC_BASE_ALIGNMENT_SIZE), ROUNDUP(cmd_desc_len, CACHE_LINE));
 	if (!req_upiu)
 	{
 		dprintf(CRITICAL, "%s:%d Unable to allocate request upiu\n",__func__, __LINE__);
 		return -UFS_FAILURE;
 	}

 	/* Fill req upiu. */
 	ret = utp_fill_req_upiu(dev, upiu_data, req_upiu);
 	if (ret)
 	{
 		goto utp_enqueue_upiu_err;
 	}

 	/* Fill UTRD properties. */
 	cmd_desc.num_prdt      = num_prdt;
 	cmd_desc.req_upiu      = req_upiu;
 	cmd_desc.resp_upiu_len = resp_len;
 	utp_fill_utrd_properties(upiu_data, &utrd, &cmd_desc);

 	prdt_entry         = (struct utp_prdt_entry *) ((uint32_t) req_upiu + UPIU_HDR_LEN + resp_len);

 	/* Fill PRDT entries. */
 	if (num_prdt)
 	utp_fill_prdt_entries(upiu_data, prdt_entry);

 	/* Flush req_upiu */
 	dsb();
 	arch_clean_invalidate_cache_range((addr_t) req_upiu, cmd_desc_len);

 	/* Check the response. */
 	ret = utp_enqueue_utrd(dev, &utrd);
 	if (ret)
 	{
 		dprintf(CRITICAL, "%s:%d Command failed. command = %x\n", __func__, __LINE__, req_upiu->basic_hdr.trans_type);
 		goto utp_enqueue_upiu_err;
 	}

 	/* UPIU processed. Invalidate cache to update resp. */
 	arch_invalidate_cache_range((addr_t) req_upiu, cmd_desc_len);

 	/* Save the response. */
 	memcpy(upiu_data->resp_ptr, (void *) ((uint32_t)req_upiu + UPIU_HDR_LEN), upiu_data->resp_len);
 	memcpy((void *) upiu_data->resp_data_ptr, (void *) ((uint32_t)req_upiu + 2 * UPIU_HDR_LEN), upiu_data->resp_data_len);

 utp_enqueue_upiu_err:
 	free(req_upiu);
 	return ret;
 }
	/* Copyright (c) 2013-2014, The Linux Foundation. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are
	* met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above
	* copyright notice, this list of conditions and the following
	* disclaimer in the documentation and/or other materials provided
	* with the distribution.
	* * Neither the name of The Linux Foundation nor the names of its
	* contributors may be used to endorse or promote products derived
	* from this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
	* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
	* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
	* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
	* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
	* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
	* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include <arch/ops.h>
	#include <sys/types.h>
	#include <kernel/thread.h>
	#include <debug.h>
	#include <err.h>
	#include <reg.h>
	#include <string.h>
	#include <malloc.h>
	#include <stdlib.h>
	#include <ufs_hw.h>
	#include <utp.h>
	#include <ufs.h>
	#include <platform/iomap.h>
	#include <platform/clock.h>
	#include <platform/timer.h>
	#include <arch/ops.h>
	#include <endian.h>
	#include <stdlib.h>
	#include <sys/types.h>

	void utp_process_req_completion(struct ufs_req_irq_type *irq)
	{
	struct ufs_req_node *req;
	struct list_node *prev;
	uint32_t val;

	/* Make sure we have more nodes than just the head in the list. */
	if (list_next(irq->list, irq->list) == NULL)
	{
	dprintf(CRITICAL, "%s:%d UTRD/ UTMRD processed signalled and the wait queue is empty\n", __func__, __LINE__);
	ASSERT(0);
	}

	/* Read the door bell register. */
	val = readl(irq->door_bell_reg);

	list_for_every_entry(irq->list, req, struct ufs_req_node, list_node)
	{
	if (!(req->door_bell_bit & val))
	{
	/* Transaction is complete: Either transaction completed in a normal way.
	* Delete and Signal all requests that have completed.
	*/
	prev = req->list_node.prev;
	/* TODO: move delete to the caller function. */
	list_delete(&(req->list_node));

	if (event_signal(req->event, false))
	{
	dprintf(CRITICAL, "%s:%d Event signal failed.\n",__func__, __LINE__);
	ASSERT(0);

	}
	req = containerof(prev, struct ufs_req_node, list_node);
	}
	}

	return;
	}

	/* Always called within critical section: utrd_bitmap_mutex/ utmrd_bitmap_mutex. */
	static uint32_t utp_get_door_bell_bit(uint32_t reg, uint32_t reg_bitmap, uint32_t bit_num)
	{
	uint32_t val = 0;
	uint32_t doorbell_bit_val;
	uint32_t found = 0;

	*bit_num = 0;

	val = readl(reg) \| *reg_bitmap;
	doorbell_bit_val = 1;

	/* Find an empty slot. */
	do
	{
	(*bit_num)++;

	if (!(doorbell_bit_val & val))
	{
	found = 1;
	*reg_bitmap \|= doorbell_bit_val;
	break;
	}
	doorbell_bit_val <<= 1;
	}while (doorbell_bit_val <= (uint32_t) (1 << 31));

	if (!found)
	{
	doorbell_bit_val = 0;
	dprintf(CRITICAL, "%s:%d Unable to find a free slot for transaction.\n",__func__, __LINE__);
	}

	return doorbell_bit_val;
	}

	static void utp_ring_door_bell(uint32_t reg, uint32_t doorbell_bit)
	{
	writel(doorbell_bit, reg);
	}

	static int utp_utrd_process_timeout_req(struct ufs_dev *dev,
	struct utp_utrd_req_build_type *utrd_req,
	struct ufs_req_node *req)
	{
	switch (utrd_req->req_upiu->trans_type)
	{
	case UPIU_TYPE_NOP_OUT:
	writel(~req->door_bell_bit, UFS_UTRLCLR(dev->base));
	return -UFS_RETRY;
	default:
	/* TODO : Add ufs hci sw reset.*/
	ASSERT(0);
	return -UFS_FAILURE;
	}
	}

	static int utp_remove_from_bitmap(struct utp_bitmap_access_type *req)
	{

	if (mutex_acquire(req->mutx))
	{
	return -UFS_FAILURE;
	}

	*(req->bitmap) &= ~req->door_bell_bit;

	if (mutex_release(req->mutx))
	{
	return -UFS_FAILURE;
	}

	return UFS_SUCCESS;
	}

	static void utp_enqueue_utrd_fill_desc(struct utp_trans_req_desc desc, struct utp_utrd_req_build_type utrd_req)
	{
	/* Fill transfer desc. */
	memset(desc, 0, UPIU_HDR_LEN);
	desc->cmd_type_dd_irq = UTP_REQ_BUILD_CMD_DD_IRQ_FIELD(utrd_req->cmd_type, utrd_req->dd, utrd_req->irq);
	desc->overall_cmd_status = utrd_req->ocs;
	/* Bits 0 - 6 are reserved in cmd_desc_base_addr[0] field. */
	desc->cmd_desc_base_addr[0] = ((uint32_t) utrd_req->req_upiu) & 0xC0;
	desc->cmd_desc_base_addr[1] = ((uint32_t) utrd_req->req_upiu >> 8) & 0xFF;
	desc->cmd_desc_base_addr[2] = ((uint32_t) utrd_req->req_upiu >> 16) & 0xFF;
	desc->cmd_desc_base_addr[3] = ((uint32_t) utrd_req->req_upiu >> 24) & 0xFF;
	desc->resp_upiu_offset = ROUNDUP(utrd_req->req_upiu_len, UPIU_HDR_LEN) / 4;
	desc->resp_upiu_len = utrd_req->resp_upiu_len;

	if (utrd_req->dd != UTRD_NO_DATA_TRANSFER)
	{
	/* Data transfer command.
	* Fill in PRDT data.
	*/
	desc->prdt_offset = utrd_req->prdt_offset / 4;
	desc->prdt_len = utrd_req->prdt_len;
	}

	/* Flush UTRD to memory. */
	cache_clean_invalidate_unaligned_start_addr((addr_t)desc, sizeof(struct utp_trans_req_desc));
	}

	static struct utp_trans_req_desc* utp_get_desc_slot_addr(struct ufs_dev dev, struct utp_utrd_req_build_type utrd_req, uint32_t *door_bell_val)
	{
	struct utp_trans_req_desc *desc = NULL;
	uint32_t door_bell_slot;

	if (mutex_acquire(&(dev->utrd_data.bitmap_mutex)))
	{
	goto utp_get_desc_slot_addr_err;
	}

	*door_bell_val = utp_get_door_bell_bit(UFS_UTRLDBR(dev->base), &dev->utrd_data.bitmap, &door_bell_slot);
	if (!(*door_bell_val))
	{
	goto utp_get_desc_slot_addr_err;
	}

	if (mutex_release(&(dev->utrd_data.bitmap_mutex)))
	{
	goto utp_get_desc_slot_addr_err;
	}

	desc = (struct utp_trans_req_desc ) ((addr_t)dev->utrd_data.list_base_addr + (door_bell_slot - 1) sizeof(struct utp_trans_req_desc));

	utp_get_desc_slot_addr_err:
	return desc;
	}

	int utp_poll_utrd_complete(struct ufs_dev *dev)
	{
	int ret;
	struct ufs_req_irq_type irq;
	uint32_t val, base, retry = 0;
	base = dev->base;
	val = readl(UFS_IS(base));
	irq.irq_handled = 0;
	/* Wait till the desc has been processed. */
	while(((val & UFS_IS_UTRCS) == 0) && ((val & UFS_IS_UTMRCS) == 0))
	{
	val = readl(UFS_IS(base));
	retry++;
	udelay(1);
	if(retry == UTP_MAX_COMMAND_RETRY)
	{
	dprintf(CRITICAL, "%s:%d UTP command never completed.\n", __func__, __LINE__);
	return ERR_TIMED_OUT;
	}
	#ifdef DEBUG_UFS
	dprintf(INFO, "Waiting for UTRCS/URMRCS Completion...\n");
	#endif
	}
	if (readl(UFS_IS(base)) & UFS_IS_UTRCS)
	{
	val = readl(UFS_IS(base)) & UFS_IS_UTRCS;
	writel(UFS_IS_UTRCS, UFS_IS(base));
	irq.irq_handled = UFS_IS_UTRCS;
	irq.list = &(dev->utrd_data.list_head.list_node);
	irq.door_bell_reg = UFS_UTRLDBR(base);
	utp_process_req_completion(&irq);
	ret = INT_NO_RESCHEDULE;
	}
	else if (readl(UFS_IS(base)) & (UFS_IS_UTMRCS))
	{
	val = readl(UFS_IS(base)) & UFS_IS_UTMRCS;
	writel(UFS_IS_UTMRCS, UFS_IS(base));
	irq.irq_handled = UFS_IS_UTMRCS;
	irq.list = &(dev->utmrd_data.list_head.list_node);
	utp_process_req_completion(&irq);
	ret = INT_NO_RESCHEDULE;
	}
	return ret;
	}

	static int utp_enqueue_utrd(struct ufs_dev dev, struct utp_utrd_req_build_type utrd_req)
	{
	int ret;
	struct utp_trans_req_desc *desc;
	event_t utrd_evt;
	struct ufs_req_node req;
	uint32_t door_bell_bit_val;
	struct utp_bitmap_access_type bitmap_req;

	ret = UFS_SUCCESS;

	event_init(&utrd_evt, false, EVENT_FLAG_AUTOUNSIGNAL);

	desc = utp_get_desc_slot_addr(dev, utrd_req, &door_bell_bit_val);
	if (!desc)
	{
	ret = UFS_FAILURE;
	goto utp_enqueue_utrd_err;
	}

	/* Check register UTRLRSR and make sure it is read 1 before continuing. */
	if (!readl(UFS_UTRLRSR(dev->base)))
	{
	ret = -UFS_FAILURE;
	goto utp_enqueue_utrd_err;
	}

	utp_enqueue_utrd_fill_desc(desc, utrd_req);

	req.door_bell_bit = door_bell_bit_val;
	req.event = &utrd_evt;

	/* Enqueue the req in the device utrd list. */
	list_add_head(&(dev->utrd_data.list_head.list_node), &(req.list_node));

	dsb();

	#ifdef DEBUG_UFS
	// print IS before write
	ufs_dump_is_register(dev);
	#endif

	utp_ring_door_bell(UFS_UTRLDBR(dev->base), door_bell_bit_val);

	dsb();

	#ifdef DEBUG_UFS
	// print IS after write
	ufs_dump_is_register(dev);
	#endif
	ret = utp_poll_utrd_complete(dev);

	if (ret == ERR_TIMED_OUT)
	{
	/* Transaction not completed even after timeout ms. */
	dprintf(CRITICAL, "%s:%d Transaction timeout after polling %d times\n",__func__, __LINE__, UTP_MAX_COMMAND_RETRY);
	ret = utp_utrd_process_timeout_req(dev, utrd_req, &req);
	goto utp_enqueue_utrd_err;
	}
	else
	{
	/* Reset ret before returning. */
	ret = UFS_SUCCESS;

	/* Force read UTRD from memory. */
	dsb();
	cache_clean_invalidate_unaligned_start_addr((addr_t) desc, sizeof(struct ufs_req_node));

	/* Check the response. */
	if (desc->overall_cmd_status != UTRD_OCS_SUCCESS)
	{
	dprintf(CRITICAL, "%s:%d Command failed. command type = %x\n", __func__, __LINE__, utrd_req->cmd_type);
	ret = -UFS_FAILURE;
	goto utp_enqueue_utrd_err;
	}
	}

	/* Signal slot as free. */
	bitmap_req.bitmap = &dev->utrd_data.bitmap;
	bitmap_req.door_bell_bit = req.door_bell_bit;
	bitmap_req.mutx = &(dev->utrd_data.bitmap_mutex);

	ret = utp_remove_from_bitmap(&bitmap_req);
	if (ret)
	goto utp_enqueue_utrd_err;

	utp_enqueue_utrd_err:
	return ret;
	}

	static int utp_get_prdt_len(uint32_t data_len, uint32_t *num_prdt)
	{
	/* Calculate the prdt entries required. */
	*num_prdt = ROUNDUP(data_len, UTP_MAX_PRD_DATA_BYTE_CNT);
	*num_prdt >>= UTP_MAX_PRD_DATA_BYTE_CNT_BYTE_SHIFT;

	if (*num_prdt > UTP_MAX_PRD_TABLE_ENTRIES)
	{
	dprintf(CRITICAL, "%s:%d Data length exceeds for a single upiu transfer.\n", __func__,__LINE__);
	return -UFS_FAILURE;
	}

	return UFS_SUCCESS;
	}

	static int utp_fill_req_upiu(struct ufs_dev dev, struct upiu_req_build_type upiu_data, struct upiu_gen_hdr *req_upiu)
	{
	memset(req_upiu, 0, UPIU_HDR_LEN);

	if (upiu_data->trans_type == UPIU_TYPE_QUERY_REQ)
	{
	/* Fill in query specific fields. */
	if (utp_build_query_req_upiu((struct upiu_trans_mgmt_query_hdr *) req_upiu, upiu_data))
	{
	return -UFS_FAILURE;
	}
	}

	/* If a data transfer cmd, check the alignment and length of the buffer. */
	if (upiu_data->expected_data_len)
	{
	if (upiu_data->data_buffer_addr & 0x3)
	{
	dprintf(CRITICAL, "%s:%d Alignment and length check failed for data tranfer command.\n", __func__, __LINE__);
	return -UFS_FAILURE;
	}
	}

	req_upiu->basic_hdr.trans_type = upiu_data->trans_type;
	req_upiu->basic_hdr.flags = upiu_data->flags;
	req_upiu->basic_hdr.cmd_set_type = upiu_data->cmd_set_type;
	req_upiu->basic_hdr.data_seg_len = upiu_data->data_seg_len;
	req_upiu->basic_hdr.lun = upiu_data->lun;
	req_upiu->basic_hdr.total_ehs_len = upiu_data->ehs_len;
	req_upiu->basic_hdr.task_tag = atomic_add((int *) &(dev->utrd_data.task_id), 1);
	if (upiu_data->cdb)
	memcpy(&(req_upiu->trans_specific_fields[4]), (void *) upiu_data->cdb, 16);
	/* If command upiu, fill in data length. */
	if (req_upiu->basic_hdr.trans_type == UPIU_TYPE_COMMAND)
	((struct upiu_cmd_hdr *)req_upiu)->data_expected_len = BE32(upiu_data->expected_data_len);

	return UFS_SUCCESS;

	}

	static void utp_fill_utrd_properties(struct upiu_req_build_type *upiu_data,
	struct utp_utrd_req_build_type *utrd,
	struct utrd_cmd_desc *cmd_desc)
	{
	utrd->cmd_type = upiu_data->cmd_type;
	utrd->dd = upiu_data->dd;
	utrd->irq = UTRD_IRQ_CMD;
	utrd->prdt_offset = UPIU_HDR_LEN + cmd_desc->resp_upiu_len;
	utrd->prdt_len = cmd_desc->num_prdt;
	utrd->req_upiu = (struct upiu_basic_hdr *) cmd_desc->req_upiu;
	utrd->req_upiu_len = UPIU_HDR_LEN;
	utrd->resp_upiu_len = cmd_desc->resp_upiu_len;
	utrd->ocs = 0xF;
	utrd->timeout = upiu_data->timeout_msecs;
	}

	static void utp_fill_prdt_entries(struct upiu_req_build_type upiu_data, struct utp_prdt_entry prdt_entry)
	{
	uint64_t buf;
	uint64_t bytes_remaining;
	uint32_t prd_dbc;

	buf = upiu_data->data_buffer_addr;
	bytes_remaining = upiu_data->expected_data_len;

	while (bytes_remaining)
	{
	prdt_entry->data_base_addr = buf;
	prdt_entry->data_upper_addr = buf >> 32;
	prd_dbc = MIN(UTP_MAX_PRD_DATA_BYTE_CNT, bytes_remaining) - 1;
	prdt_entry->data_byte_cnt = prd_dbc;
	if (bytes_remaining <= UTP_MAX_PRD_DATA_BYTE_CNT)
	break;
	buf += UTP_MAX_PRD_DATA_BYTE_CNT;
	bytes_remaining -= UTP_MAX_PRD_DATA_BYTE_CNT;
	prdt_entry++;
	}

	}

	int utp_enqueue_upiu(struct ufs_dev dev, struct upiu_req_build_type upiu_data)
	{
	struct upiu_gen_hdr *req_upiu;
	struct utp_utrd_req_build_type utrd;
	uint32_t num_prdt;
	struct utp_prdt_entry *prdt_entry;
	int ret = UFS_SUCCESS;
	uint32_t resp_len;
	uint32_t cmd_desc_len;
	struct utrd_cmd_desc cmd_desc;

	/* Round up resp_upiu_len to a DWORD boundary.
	* Also, make sure it is of min required length.
	*/
	resp_len = ROUNDUP(upiu_data->resp_data_len, 4) + UPIU_HDR_LEN;

	if (utp_get_prdt_len(upiu_data->expected_data_len, &num_prdt))
	return -UFS_FAILURE;

	/* Calculate the length. */
	cmd_desc_len = UPIU_HDR_LEN + resp_len + num_prdt * sizeof(struct utp_prdt_entry);

	/* Allocate memory for UTP Command Descriptor. */
	req_upiu = (struct upiu_gen_hdr*) memalign((size_t ) lcm(CACHE_LINE, UTP_CMD_DESC_BASE_ALIGNMENT_SIZE), ROUNDUP(cmd_desc_len, CACHE_LINE));
	if (!req_upiu)
	{
	dprintf(CRITICAL, "%s:%d Unable to allocate request upiu\n",__func__, __LINE__);
	return -UFS_FAILURE;
	}

	/* Fill req upiu. */
	ret = utp_fill_req_upiu(dev, upiu_data, req_upiu);
	if (ret)
	{
	goto utp_enqueue_upiu_err;
	}

	/* Fill UTRD properties. */
	cmd_desc.num_prdt = num_prdt;
	cmd_desc.req_upiu = req_upiu;
	cmd_desc.resp_upiu_len = resp_len;
	utp_fill_utrd_properties(upiu_data, &utrd, &cmd_desc);

	prdt_entry = (struct utp_prdt_entry *) ((uint32_t) req_upiu + UPIU_HDR_LEN + resp_len);

	/* Fill PRDT entries. */
	if (num_prdt)
	utp_fill_prdt_entries(upiu_data, prdt_entry);

	/* Flush req_upiu */
	dsb();
	arch_clean_invalidate_cache_range((addr_t) req_upiu, cmd_desc_len);

	/* Check the response. */
	ret = utp_enqueue_utrd(dev, &utrd);
	if (ret)
	{
	dprintf(CRITICAL, "%s:%d Command failed. command = %x\n", __func__, __LINE__, req_upiu->basic_hdr.trans_type);
	goto utp_enqueue_upiu_err;
	}

	/* UPIU processed. Invalidate cache to update resp. */
	arch_invalidate_cache_range((addr_t) req_upiu, cmd_desc_len);

	/* Save the response. */
	memcpy(upiu_data->resp_ptr, (void *) ((uint32_t)req_upiu + UPIU_HDR_LEN), upiu_data->resp_len);
	memcpy((void ) upiu_data->resp_data_ptr, (void ) ((uint32_t)req_upiu + 2 * UPIU_HDR_LEN), upiu_data->resp_data_len);

	utp_enqueue_upiu_err:
	free(req_upiu);
	return ret;
	}