drivers/staging/msm/mdp_dma.c - kernel/skids - Git at Google

 /* Copyright (c) 2008-2009, Code Aurora Forum. All rights reserved.
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 and
  * only version 2 as published by the Free Software Foundation.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
  * 02110-1301, USA.
  */

 #include <linux/module.h>
 #include <linux/kernel.h>
 #include <linux/sched.h>
 #include <linux/time.h>
 #include <linux/init.h>
 #include <linux/interrupt.h>
 #include <linux/hrtimer.h>

 #include <mach/hardware.h>
 #include <linux/io.h>

 #include <asm/system.h>
 #include <asm/mach-types.h>
 #include <linux/semaphore.h>
 #include <linux/spinlock.h>

 #include <linux/fb.h>

 #include "mdp.h"
 #include "msm_fb.h"
 #include "mddihost.h"

 static uint32 mdp_last_dma2_update_width;
 static uint32 mdp_last_dma2_update_height;
 static uint32 mdp_curr_dma2_update_width;
 static uint32 mdp_curr_dma2_update_height;

 ktime_t mdp_dma2_last_update_time = { 0 };

 int mdp_lcd_rd_cnt_offset_slow = 20;
 int mdp_lcd_rd_cnt_offset_fast = 20;
 int mdp_vsync_usec_wait_line_too_short = 5;
 uint32 mdp_dma2_update_time_in_usec;
 uint32 mdp_total_vdopkts;

 extern u32 msm_fb_debug_enabled;
 extern struct workqueue_struct *mdp_dma_wq;

 int vsync_start_y_adjust = 4;

 static void mdp_dma2_update_lcd(struct msm_fb_data_type *mfd)
 {
 	MDPIBUF *iBuf = &mfd->ibuf;
 	int mddi_dest = FALSE;
 	uint32 outBpp = iBuf->bpp;
 	uint32 dma2_cfg_reg;
 	uint8 *src;
 	uint32 mddi_ld_param;
 	uint16 mddi_vdo_packet_reg;
 	struct msm_fb_panel_data *pdata =
 	    (struct msm_fb_panel_data *)mfd->pdev->dev.platform_data;
 	uint32 ystride = mfd->fbi->fix.line_length;

 	dma2_cfg_reg = DMA_PACK_TIGHT | DMA_PACK_ALIGN_LSB |
 	    DMA_OUT_SEL_AHB | DMA_IBUF_NONCONTIGUOUS;

 #ifdef CONFIG_FB_MSM_MDP30
 	/*
 	 * Software workaround:  On 7x25/7x27, the MDP will not
 	 * respond if dma_w is 1 pixel.  Set the update width to
 	 * 2 pixels and adjust the x offset if needed.
 	 */
 	if (iBuf->dma_w == 1) {
 		iBuf->dma_w = 2;
 		if (iBuf->dma_x == (iBuf->ibuf_width - 2))
 			iBuf->dma_x--;
 	}
 #endif

 	if (mfd->fb_imgType == MDP_BGR_565)
 		dma2_cfg_reg |= DMA_PACK_PATTERN_BGR;
 	else
 		dma2_cfg_reg |= DMA_PACK_PATTERN_RGB;

 	if (outBpp == 4)
 		dma2_cfg_reg |= DMA_IBUF_C3ALPHA_EN;

 	if (outBpp == 2)
 		dma2_cfg_reg |= DMA_IBUF_FORMAT_RGB565;

 	mddi_ld_param = 0;
 	mddi_vdo_packet_reg = mfd->panel_info.mddi.vdopkt;

 	if ((mfd->panel_info.type == MDDI_PANEL) ||
 	    (mfd->panel_info.type == EXT_MDDI_PANEL)) {
 		dma2_cfg_reg |= DMA_OUT_SEL_MDDI;
 		mddi_dest = TRUE;

 		if (mfd->panel_info.type == MDDI_PANEL) {
 			mdp_total_vdopkts++;
 			if (mfd->panel_info.pdest == DISPLAY_1) {
 				dma2_cfg_reg |= DMA_MDDI_DMAOUT_LCD_SEL_PRIMARY;
 				mddi_ld_param = 0;
 #ifdef MDDI_HOST_WINDOW_WORKAROUND
 				mddi_window_adjust(mfd, iBuf->dma_x,
 						   iBuf->dma_w - 1, iBuf->dma_y,
 						   iBuf->dma_h - 1);
 #endif
 			} else {
 				dma2_cfg_reg |=
 				    DMA_MDDI_DMAOUT_LCD_SEL_SECONDARY;
 				mddi_ld_param = 1;
 #ifdef MDDI_HOST_WINDOW_WORKAROUND
 				mddi_window_adjust(mfd, iBuf->dma_x,
 						   iBuf->dma_w - 1, iBuf->dma_y,
 						   iBuf->dma_h - 1);
 #endif
 			}
 		} else {
 			dma2_cfg_reg |= DMA_MDDI_DMAOUT_LCD_SEL_EXTERNAL;
 			mddi_ld_param = 2;
 		}
 	} else {
 		if (mfd->panel_info.pdest == DISPLAY_1) {
 			dma2_cfg_reg |= DMA_AHBM_LCD_SEL_PRIMARY;
 			outp32(MDP_EBI2_LCD0, mfd->data_port_phys);
 		} else {
 			dma2_cfg_reg |= DMA_AHBM_LCD_SEL_SECONDARY;
 			outp32(MDP_EBI2_LCD1, mfd->data_port_phys);
 		}
 	}

 	dma2_cfg_reg |= DMA_DITHER_EN;

 	src = (uint8 *) iBuf->buf;
 	/* starting input address */
 	src += iBuf->dma_x * outBpp + iBuf->dma_y * ystride;

 	mdp_curr_dma2_update_width = iBuf->dma_w;
 	mdp_curr_dma2_update_height = iBuf->dma_h;

 	/* MDP cmd block enable */
 	mdp_pipe_ctrl(MDP_CMD_BLOCK, MDP_BLOCK_POWER_ON, FALSE);

 #ifdef CONFIG_FB_MSM_MDP22
 	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0184,
 			(iBuf->dma_h << 16 | iBuf->dma_w));
 	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0188, src);
 	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x018C, ystride);
 #else
 	MDP_OUTP(MDP_BASE + 0x90004, (iBuf->dma_h << 16 | iBuf->dma_w));
 	MDP_OUTP(MDP_BASE + 0x90008, src);
 	MDP_OUTP(MDP_BASE + 0x9000c, ystride);
 #endif

 	if (mfd->panel_info.bpp == 18) {
 		dma2_cfg_reg |= DMA_DSTC0G_6BITS |	/* 666 18BPP */
 		    DMA_DSTC1B_6BITS | DMA_DSTC2R_6BITS;
 	} else {
 		dma2_cfg_reg |= DMA_DSTC0G_6BITS |	/* 565 16BPP */
 		    DMA_DSTC1B_5BITS | DMA_DSTC2R_5BITS;
 	}

 	if (mddi_dest) {
 #ifdef CONFIG_FB_MSM_MDP22
 		MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0194,
 			 (iBuf->dma_y << 16) | iBuf->dma_x);
 		MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x01a0, mddi_ld_param);
 		MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x01a4,
 			 (MDDI_VDO_PACKET_DESC << 16) | mddi_vdo_packet_reg);
 #else
 		MDP_OUTP(MDP_BASE + 0x90010, (iBuf->dma_y << 16) | iBuf->dma_x);
 		MDP_OUTP(MDP_BASE + 0x00090, mddi_ld_param);
 		MDP_OUTP(MDP_BASE + 0x00094,
 			 (MDDI_VDO_PACKET_DESC << 16) | mddi_vdo_packet_reg);
 #endif
 	} else {
 		/* setting EBI2 LCDC write window */
 		pdata->set_rect(iBuf->dma_x, iBuf->dma_y, iBuf->dma_w,
 				iBuf->dma_h);
 	}

 	/* dma2 config register */
 #ifdef MDP_HW_VSYNC
 	MDP_OUTP(MDP_BASE + 0x90000, dma2_cfg_reg);

 	if ((mfd->use_mdp_vsync) &&
 	    (mfd->ibuf.vsync_enable) && (mfd->panel_info.lcd.vsync_enable)) {
 		uint32 start_y;

 		if (vsync_start_y_adjust <= iBuf->dma_y)
 			start_y = iBuf->dma_y - vsync_start_y_adjust;
 		else
 			start_y =
 			    (mfd->total_lcd_lines - 1) - (vsync_start_y_adjust -
 							  iBuf->dma_y);

 		/*
 		 * MDP VSYNC clock must be On by now so, we don't have to
 		 * re-enable it
 		 */
 		MDP_OUTP(MDP_BASE + 0x210, start_y);
 		MDP_OUTP(MDP_BASE + 0x20c, 1);	/* enable prim vsync */
 	} else {
 		MDP_OUTP(MDP_BASE + 0x20c, 0);	/* disable prim vsync */
 	}
 #else
 #ifdef CONFIG_FB_MSM_MDP22
 	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0180, dma2_cfg_reg);
 #else
 	MDP_OUTP(MDP_BASE + 0x90000, dma2_cfg_reg);
 #endif
 #endif /* MDP_HW_VSYNC */

 	/* MDP cmd block disable */
 	mdp_pipe_ctrl(MDP_CMD_BLOCK, MDP_BLOCK_POWER_OFF, FALSE);
 }

 static ktime_t vt = { 0 };
 int mdp_usec_diff_threshold = 100;
 int mdp_expected_usec_wait;

 enum hrtimer_restart mdp_dma2_vsync_hrtimer_handler(struct hrtimer *ht)
 {
 	struct msm_fb_data_type *mfd = NULL;

 	mfd = container_of(ht, struct msm_fb_data_type, dma_hrtimer);

 	mdp_pipe_kickoff(MDP_DMA2_TERM, mfd);

 	if (msm_fb_debug_enabled) {
 		ktime_t t;
 		int usec_diff;
 		int actual_wait;

 		t = ktime_get_real();

 		actual_wait =
 		    (t.tv.sec - vt.tv.sec) * 1000000 + (t.tv.nsec -
 							vt.tv.nsec) / 1000;
 		usec_diff = actual_wait - mdp_expected_usec_wait;

 		if ((mdp_usec_diff_threshold < usec_diff) || (usec_diff < 0))
 			MSM_FB_DEBUG
 			    ("HRT Diff = %d usec Exp=%d usec  Act=%d usec\n",
 			     usec_diff, mdp_expected_usec_wait, actual_wait);
 	}

 	return HRTIMER_NORESTART;
 }

 static void mdp_dma_schedule(struct msm_fb_data_type *mfd, uint32 term)
 {
 	/*
 	 * dma2 configure VSYNC block
 	 * vsync supported on Primary LCD only for now
 	 */
 	int32 mdp_lcd_rd_cnt;
 	uint32 usec_wait_time;
 	uint32 start_y;

 	/*
 	 * ToDo: if we can move HRT timer callback to workqueue, we can
 	 * move DMA2 power on under mdp_pipe_kickoff().
 	 * This will save a power for hrt time wait.
 	 * However if the latency for context switch (hrt irq -> workqueue)
 	 * is too big, we will miss the vsync timing.
 	 */
 	if (term == MDP_DMA2_TERM)
 		mdp_pipe_ctrl(MDP_DMA2_BLOCK, MDP_BLOCK_POWER_ON, FALSE);

 	mdp_dma2_update_time_in_usec =
 	    MDP_KTIME2USEC(mdp_dma2_last_update_time);

 	if ((!mfd->ibuf.vsync_enable) || (!mfd->panel_info.lcd.vsync_enable)
 	    || (mfd->use_mdp_vsync)) {
 		mdp_pipe_kickoff(term, mfd);
 		return;
 	}
 	/* SW vsync logic starts here */

 	/* get current rd counter */
 	mdp_lcd_rd_cnt = mdp_get_lcd_line_counter(mfd);
 	if (mdp_dma2_update_time_in_usec != 0) {
 		uint32 num, den;

 		/*
 		 * roi width boundary calculation to know the size of pixel
 		 * width that MDP can send faster or slower than LCD read
 		 * pointer
 		 */

 		num = mdp_last_dma2_update_width * mdp_last_dma2_update_height;
 		den =
 		    (((mfd->panel_info.lcd.refx100 * mfd->total_lcd_lines) /
 		      1000) * (mdp_dma2_update_time_in_usec / 100)) / 1000;

 		if (den == 0)
 			mfd->vsync_width_boundary[mdp_last_dma2_update_width] =
 			    mfd->panel_info.xres + 1;
 		else
 			mfd->vsync_width_boundary[mdp_last_dma2_update_width] =
 			    (int)(num / den);
 	}

 	if (mfd->vsync_width_boundary[mdp_last_dma2_update_width] >
 	    mdp_curr_dma2_update_width) {
 		/* MDP wrp is faster than LCD rdp */
 		mdp_lcd_rd_cnt += mdp_lcd_rd_cnt_offset_fast;
 	} else {
 		/* MDP wrp is slower than LCD rdp */
 		mdp_lcd_rd_cnt -= mdp_lcd_rd_cnt_offset_slow;
 	}

 	if (mdp_lcd_rd_cnt < 0)
 		mdp_lcd_rd_cnt = mfd->total_lcd_lines + mdp_lcd_rd_cnt;
 	else if (mdp_lcd_rd_cnt > mfd->total_lcd_lines)
 		mdp_lcd_rd_cnt = mdp_lcd_rd_cnt - mfd->total_lcd_lines - 1;

 	/* get wrt pointer position */
 	start_y = mfd->ibuf.dma_y;

 	/* measure line difference between start_y and rd counter */
 	if (start_y > mdp_lcd_rd_cnt) {
 		/*
 		 * *100 for lcd_ref_hzx100 was already multiplied by 100
 		 * *1000000 is for usec conversion
 		 */

 		if ((start_y - mdp_lcd_rd_cnt) <=
 		    mdp_vsync_usec_wait_line_too_short)
 			usec_wait_time = 0;
 		else
 			usec_wait_time =
 			    ((start_y -
 			      mdp_lcd_rd_cnt) * 1000000) /
 			    ((mfd->total_lcd_lines *
 			      mfd->panel_info.lcd.refx100) / 100);
 	} else {
 		if ((start_y + (mfd->total_lcd_lines - mdp_lcd_rd_cnt)) <=
 		    mdp_vsync_usec_wait_line_too_short)
 			usec_wait_time = 0;
 		else
 			usec_wait_time =
 			    ((start_y +
 			      (mfd->total_lcd_lines -
 			       mdp_lcd_rd_cnt)) * 1000000) /
 			    ((mfd->total_lcd_lines *
 			      mfd->panel_info.lcd.refx100) / 100);
 	}

 	mdp_last_dma2_update_width = mdp_curr_dma2_update_width;
 	mdp_last_dma2_update_height = mdp_curr_dma2_update_height;

 	if (usec_wait_time == 0) {
 		mdp_pipe_kickoff(term, mfd);
 	} else {
 		ktime_t wait_time;

 		wait_time.tv.sec = 0;
 		wait_time.tv.nsec = usec_wait_time * 1000;

 		if (msm_fb_debug_enabled) {
 			vt = ktime_get_real();
 			mdp_expected_usec_wait = usec_wait_time;
 		}
 		hrtimer_start(&mfd->dma_hrtimer, wait_time, HRTIMER_MODE_REL);
 	}
 }

 #ifdef MDDI_HOST_WINDOW_WORKAROUND
 void mdp_dma2_update(struct msm_fb_data_type *mfd)
 {
 	MDPIBUF *iBuf;
 	uint32 upper_height;

 	if (mfd->panel.type == EXT_MDDI_PANEL) {
 		mdp_dma2_update_sub(mfd);
 		return;
 	}

 	iBuf = &mfd->ibuf;

 	upper_height =
 	    (uint32) mddi_assign_pkt_height((uint16) iBuf->dma_w,
 					    (uint16) iBuf->dma_h, 18);

 	if (upper_height >= iBuf->dma_h) {
 		mdp_dma2_update_sub(mfd);
 	} else {
 		MDPIBUF lower_height;

 		/* sending the upper region first */
 		lower_height = iBuf->dma_h - upper_height;
 		iBuf->dma_h = upper_height;
 		mdp_dma2_update_sub(mfd);

 		/* sending the lower region second */
 		iBuf->dma_h = lower_height;
 		iBuf->dma_y += lower_height;
 		iBuf->vsync_enable = FALSE;
 		mdp_dma2_update_sub(mfd);
 	}
 }

 void mdp_dma2_update_sub(struct msm_fb_data_type *mfd)
 #else
 void mdp_dma2_update(struct msm_fb_data_type *mfd)
 #endif
 {
 	down(&mfd->dma->mutex);
 	if ((mfd) && (!mfd->dma->busy) && (mfd->panel_power_on)) {
 		down(&mfd->sem);
 		mfd->ibuf_flushed = TRUE;
 		mdp_dma2_update_lcd(mfd);

 		mdp_enable_irq(MDP_DMA2_TERM);
 		mfd->dma->busy = TRUE;
 		INIT_COMPLETION(mfd->dma->comp);

 		/* schedule DMA to start */
 		mdp_dma_schedule(mfd, MDP_DMA2_TERM);
 		up(&mfd->sem);

 		/* wait until DMA finishes the current job */
 		wait_for_completion_killable(&mfd->dma->comp);
 		mdp_disable_irq(MDP_DMA2_TERM);

 	/* signal if pan function is waiting for the update completion */
 		if (mfd->pan_waiting) {
 			mfd->pan_waiting = FALSE;
 			complete(&mfd->pan_comp);
 		}
 	}
 	up(&mfd->dma->mutex);
 }

 void mdp_lcd_update_workqueue_handler(struct work_struct *work)
 {
 	struct msm_fb_data_type *mfd = NULL;

 	mfd = container_of(work, struct msm_fb_data_type, dma_update_worker);
 	if (mfd)
 		mfd->dma_fnc(mfd);
 }

 void mdp_set_dma_pan_info(struct fb_info *info, struct mdp_dirty_region *dirty,
 			  boolean sync)
 {
 	struct msm_fb_data_type *mfd = (struct msm_fb_data_type *)info->par;
 	MDPIBUF *iBuf;
 	int bpp = info->var.bits_per_pixel / 8;

 	down(&mfd->sem);
 	iBuf = &mfd->ibuf;
 	iBuf->buf = (uint8 *) info->fix.smem_start;
 	iBuf->buf += info->var.xoffset * bpp +
 			info->var.yoffset * info->fix.line_length;

 	iBuf->ibuf_width = info->var.xres_virtual;
 	iBuf->bpp = bpp;

 	iBuf->vsync_enable = sync;

 	if (dirty) {
 		/*
 		 * ToDo: dirty region check inside var.xoffset+xres
 		 * <-> var.yoffset+yres
 		 */
 		iBuf->dma_x = dirty->xoffset % info->var.xres;
 		iBuf->dma_y = dirty->yoffset % info->var.yres;
 		iBuf->dma_w = dirty->width;
 		iBuf->dma_h = dirty->height;
 	} else {
 		iBuf->dma_x = 0;
 		iBuf->dma_y = 0;
 		iBuf->dma_w = info->var.xres;
 		iBuf->dma_h = info->var.yres;
 	}
 	mfd->ibuf_flushed = FALSE;
 	up(&mfd->sem);
 }

 void mdp_set_offset_info(struct fb_info *info, uint32 addr, uint32 sync)
 {
 	struct msm_fb_data_type *mfd = (struct msm_fb_data_type *)info->par;
 	MDPIBUF *iBuf;

 	int bpp = info->var.bits_per_pixel / 8;

 	down(&mfd->sem);
 	iBuf = &mfd->ibuf;
 	iBuf->ibuf_width = info->var.xres_virtual;
 	iBuf->bpp = bpp;
 	iBuf->vsync_enable = sync;
 	iBuf->dma_x = 0;
 	iBuf->dma_y = 0;
 	iBuf->dma_w = info->var.xres;
 	iBuf->dma_h = info->var.yres;
 	iBuf->buf = (uint8 *) addr;

 	mfd->ibuf_flushed = FALSE;
 	up(&mfd->sem);
 }

 void mdp_dma_pan_update(struct fb_info *info)
 {
 	struct msm_fb_data_type *mfd = (struct msm_fb_data_type *)info->par;
 	MDPIBUF *iBuf;

 	iBuf = &mfd->ibuf;

 	if (mfd->sw_currently_refreshing) {
 		/* we need to wait for the pending update */
 		mfd->pan_waiting = TRUE;
 		if (!mfd->ibuf_flushed) {
 			wait_for_completion_killable(&mfd->pan_comp);
 		}
 		/* waiting for this update to complete */
 		mfd->pan_waiting = TRUE;
 		wait_for_completion_killable(&mfd->pan_comp);
 	} else
 		mfd->dma_fnc(mfd);
 }

 void mdp_refresh_screen(unsigned long data)
 {
 	struct msm_fb_data_type *mfd = (struct msm_fb_data_type *)data;

 	if ((mfd->sw_currently_refreshing) && (mfd->sw_refreshing_enable)) {
 		init_timer(&mfd->refresh_timer);
 		mfd->refresh_timer.function = mdp_refresh_screen;
 		mfd->refresh_timer.data = data;

 		if (mfd->dma->busy)
 			/* come back in 1 msec */
 			mfd->refresh_timer.expires = jiffies + (HZ / 1000);
 		else
 			mfd->refresh_timer.expires =
 			    jiffies + mfd->refresh_timer_duration;

 		add_timer(&mfd->refresh_timer);

 		if (!mfd->dma->busy) {
 			if (!queue_work(mdp_dma_wq, &mfd->dma_update_worker)) {
 				MSM_FB_DEBUG("mdp_dma: can't queue_work! -> \
 			MDP/MDDI/LCD clock speed needs to be increased\n");
 			}
 		}
 	} else {
 		if (!mfd->hw_refresh)
 			complete(&mfd->refresher_comp);
 	}
 }
	/* Copyright (c) 2008-2009, Code Aurora Forum. All rights reserved.
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 and
	* only version 2 as published by the Free Software Foundation.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
	* 02110-1301, USA.
	*/

	#include <linux/module.h>
	#include <linux/kernel.h>
	#include <linux/sched.h>
	#include <linux/time.h>
	#include <linux/init.h>
	#include <linux/interrupt.h>
	#include <linux/hrtimer.h>

	#include <mach/hardware.h>
	#include <linux/io.h>

	#include <asm/system.h>
	#include <asm/mach-types.h>
	#include <linux/semaphore.h>
	#include <linux/spinlock.h>

	#include <linux/fb.h>

	#include "mdp.h"
	#include "msm_fb.h"
	#include "mddihost.h"

	static uint32 mdp_last_dma2_update_width;
	static uint32 mdp_last_dma2_update_height;
	static uint32 mdp_curr_dma2_update_width;
	static uint32 mdp_curr_dma2_update_height;

	ktime_t mdp_dma2_last_update_time = { 0 };

	int mdp_lcd_rd_cnt_offset_slow = 20;
	int mdp_lcd_rd_cnt_offset_fast = 20;
	int mdp_vsync_usec_wait_line_too_short = 5;
	uint32 mdp_dma2_update_time_in_usec;
	uint32 mdp_total_vdopkts;

	extern u32 msm_fb_debug_enabled;
	extern struct workqueue_struct *mdp_dma_wq;

	int vsync_start_y_adjust = 4;

	static void mdp_dma2_update_lcd(struct msm_fb_data_type *mfd)
	{
	MDPIBUF *iBuf = &mfd->ibuf;
	int mddi_dest = FALSE;
	uint32 outBpp = iBuf->bpp;
	uint32 dma2_cfg_reg;
	uint8 *src;
	uint32 mddi_ld_param;
	uint16 mddi_vdo_packet_reg;
	struct msm_fb_panel_data *pdata =
	(struct msm_fb_panel_data *)mfd->pdev->dev.platform_data;
	uint32 ystride = mfd->fbi->fix.line_length;

	dma2_cfg_reg = DMA_PACK_TIGHT \| DMA_PACK_ALIGN_LSB \|
	DMA_OUT_SEL_AHB \| DMA_IBUF_NONCONTIGUOUS;

	#ifdef CONFIG_FB_MSM_MDP30
	/*
	* Software workaround: On 7x25/7x27, the MDP will not
	* respond if dma_w is 1 pixel. Set the update width to
	* 2 pixels and adjust the x offset if needed.
	*/
	if (iBuf->dma_w == 1) {
	iBuf->dma_w = 2;
	if (iBuf->dma_x == (iBuf->ibuf_width - 2))
	iBuf->dma_x--;
	}
	#endif

	if (mfd->fb_imgType == MDP_BGR_565)
	dma2_cfg_reg \|= DMA_PACK_PATTERN_BGR;
	else
	dma2_cfg_reg \|= DMA_PACK_PATTERN_RGB;

	if (outBpp == 4)
	dma2_cfg_reg \|= DMA_IBUF_C3ALPHA_EN;

	if (outBpp == 2)
	dma2_cfg_reg \|= DMA_IBUF_FORMAT_RGB565;

	mddi_ld_param = 0;
	mddi_vdo_packet_reg = mfd->panel_info.mddi.vdopkt;

	if ((mfd->panel_info.type == MDDI_PANEL) \|\|
	(mfd->panel_info.type == EXT_MDDI_PANEL)) {
	dma2_cfg_reg \|= DMA_OUT_SEL_MDDI;
	mddi_dest = TRUE;

	if (mfd->panel_info.type == MDDI_PANEL) {
	mdp_total_vdopkts++;
	if (mfd->panel_info.pdest == DISPLAY_1) {
	dma2_cfg_reg \|= DMA_MDDI_DMAOUT_LCD_SEL_PRIMARY;
	mddi_ld_param = 0;
	#ifdef MDDI_HOST_WINDOW_WORKAROUND
	mddi_window_adjust(mfd, iBuf->dma_x,
	iBuf->dma_w - 1, iBuf->dma_y,
	iBuf->dma_h - 1);
	#endif
	} else {
	dma2_cfg_reg \|=
	DMA_MDDI_DMAOUT_LCD_SEL_SECONDARY;
	mddi_ld_param = 1;
	#ifdef MDDI_HOST_WINDOW_WORKAROUND
	mddi_window_adjust(mfd, iBuf->dma_x,
	iBuf->dma_w - 1, iBuf->dma_y,
	iBuf->dma_h - 1);
	#endif
	}
	} else {
	dma2_cfg_reg \|= DMA_MDDI_DMAOUT_LCD_SEL_EXTERNAL;
	mddi_ld_param = 2;
	}
	} else {
	if (mfd->panel_info.pdest == DISPLAY_1) {
	dma2_cfg_reg \|= DMA_AHBM_LCD_SEL_PRIMARY;
	outp32(MDP_EBI2_LCD0, mfd->data_port_phys);
	} else {
	dma2_cfg_reg \|= DMA_AHBM_LCD_SEL_SECONDARY;
	outp32(MDP_EBI2_LCD1, mfd->data_port_phys);
	}
	}

	dma2_cfg_reg \|= DMA_DITHER_EN;

	src = (uint8 *) iBuf->buf;
	/* starting input address */
	src += iBuf->dma_x * outBpp + iBuf->dma_y * ystride;

	mdp_curr_dma2_update_width = iBuf->dma_w;
	mdp_curr_dma2_update_height = iBuf->dma_h;

	/* MDP cmd block enable */
	mdp_pipe_ctrl(MDP_CMD_BLOCK, MDP_BLOCK_POWER_ON, FALSE);

	#ifdef CONFIG_FB_MSM_MDP22
	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0184,
	(iBuf->dma_h << 16 \| iBuf->dma_w));
	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0188, src);
	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x018C, ystride);
	#else
	MDP_OUTP(MDP_BASE + 0x90004, (iBuf->dma_h << 16 \| iBuf->dma_w));
	MDP_OUTP(MDP_BASE + 0x90008, src);
	MDP_OUTP(MDP_BASE + 0x9000c, ystride);
	#endif

	if (mfd->panel_info.bpp == 18) {
	dma2_cfg_reg \|= DMA_DSTC0G_6BITS \| /* 666 18BPP */
	DMA_DSTC1B_6BITS \| DMA_DSTC2R_6BITS;
	} else {
	dma2_cfg_reg \|= DMA_DSTC0G_6BITS \| /* 565 16BPP */
	DMA_DSTC1B_5BITS \| DMA_DSTC2R_5BITS;
	}

	if (mddi_dest) {
	#ifdef CONFIG_FB_MSM_MDP22
	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0194,
	(iBuf->dma_y << 16) \| iBuf->dma_x);
	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x01a0, mddi_ld_param);
	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x01a4,
	(MDDI_VDO_PACKET_DESC << 16) \| mddi_vdo_packet_reg);
	#else
	MDP_OUTP(MDP_BASE + 0x90010, (iBuf->dma_y << 16) \| iBuf->dma_x);
	MDP_OUTP(MDP_BASE + 0x00090, mddi_ld_param);
	MDP_OUTP(MDP_BASE + 0x00094,
	(MDDI_VDO_PACKET_DESC << 16) \| mddi_vdo_packet_reg);
	#endif
	} else {
	/* setting EBI2 LCDC write window */
	pdata->set_rect(iBuf->dma_x, iBuf->dma_y, iBuf->dma_w,
	iBuf->dma_h);
	}

	/* dma2 config register */
	#ifdef MDP_HW_VSYNC
	MDP_OUTP(MDP_BASE + 0x90000, dma2_cfg_reg);

	if ((mfd->use_mdp_vsync) &&
	(mfd->ibuf.vsync_enable) && (mfd->panel_info.lcd.vsync_enable)) {
	uint32 start_y;

	if (vsync_start_y_adjust <= iBuf->dma_y)
	start_y = iBuf->dma_y - vsync_start_y_adjust;
	else
	start_y =
	(mfd->total_lcd_lines - 1) - (vsync_start_y_adjust -
	iBuf->dma_y);

	/*
	* MDP VSYNC clock must be On by now so, we don't have to
	* re-enable it
	*/
	MDP_OUTP(MDP_BASE + 0x210, start_y);
	MDP_OUTP(MDP_BASE + 0x20c, 1); /* enable prim vsync */
	} else {
	MDP_OUTP(MDP_BASE + 0x20c, 0); /* disable prim vsync */
	}
	#else
	#ifdef CONFIG_FB_MSM_MDP22
	MDP_OUTP(MDP_CMD_DEBUG_ACCESS_BASE + 0x0180, dma2_cfg_reg);
	#else
	MDP_OUTP(MDP_BASE + 0x90000, dma2_cfg_reg);
	#endif
	#endif /* MDP_HW_VSYNC */

	/* MDP cmd block disable */
	mdp_pipe_ctrl(MDP_CMD_BLOCK, MDP_BLOCK_POWER_OFF, FALSE);
	}

	static ktime_t vt = { 0 };
	int mdp_usec_diff_threshold = 100;
	int mdp_expected_usec_wait;

	enum hrtimer_restart mdp_dma2_vsync_hrtimer_handler(struct hrtimer *ht)
	{
	struct msm_fb_data_type *mfd = NULL;

	mfd = container_of(ht, struct msm_fb_data_type, dma_hrtimer);

	mdp_pipe_kickoff(MDP_DMA2_TERM, mfd);

	if (msm_fb_debug_enabled) {
	ktime_t t;
	int usec_diff;
	int actual_wait;

	t = ktime_get_real();

	actual_wait =
	(t.tv.sec - vt.tv.sec) * 1000000 + (t.tv.nsec -
	vt.tv.nsec) / 1000;
	usec_diff = actual_wait - mdp_expected_usec_wait;

	if ((mdp_usec_diff_threshold < usec_diff) \|\| (usec_diff < 0))
	MSM_FB_DEBUG
	("HRT Diff = %d usec Exp=%d usec Act=%d usec\n",
	usec_diff, mdp_expected_usec_wait, actual_wait);
	}

	return HRTIMER_NORESTART;
	}

	static void mdp_dma_schedule(struct msm_fb_data_type *mfd, uint32 term)
	{
	/*
	* dma2 configure VSYNC block
	* vsync supported on Primary LCD only for now
	*/
	int32 mdp_lcd_rd_cnt;
	uint32 usec_wait_time;
	uint32 start_y;

	/*
	* ToDo: if we can move HRT timer callback to workqueue, we can
	* move DMA2 power on under mdp_pipe_kickoff().
	* This will save a power for hrt time wait.
	* However if the latency for context switch (hrt irq -> workqueue)
	* is too big, we will miss the vsync timing.
	*/
	if (term == MDP_DMA2_TERM)
	mdp_pipe_ctrl(MDP_DMA2_BLOCK, MDP_BLOCK_POWER_ON, FALSE);

	mdp_dma2_update_time_in_usec =
	MDP_KTIME2USEC(mdp_dma2_last_update_time);

	if ((!mfd->ibuf.vsync_enable) \|\| (!mfd->panel_info.lcd.vsync_enable)
	\|\| (mfd->use_mdp_vsync)) {
	mdp_pipe_kickoff(term, mfd);
	return;
	}
	/* SW vsync logic starts here */

	/* get current rd counter */
	mdp_lcd_rd_cnt = mdp_get_lcd_line_counter(mfd);
	if (mdp_dma2_update_time_in_usec != 0) {
	uint32 num, den;

	/*
	* roi width boundary calculation to know the size of pixel
	* width that MDP can send faster or slower than LCD read
	* pointer
	*/

	num = mdp_last_dma2_update_width * mdp_last_dma2_update_height;
	den =
	(((mfd->panel_info.lcd.refx100 * mfd->total_lcd_lines) /
	1000) * (mdp_dma2_update_time_in_usec / 100)) / 1000;

	if (den == 0)
	mfd->vsync_width_boundary[mdp_last_dma2_update_width] =
	mfd->panel_info.xres + 1;
	else
	mfd->vsync_width_boundary[mdp_last_dma2_update_width] =
	(int)(num / den);
	}

	if (mfd->vsync_width_boundary[mdp_last_dma2_update_width] >
	mdp_curr_dma2_update_width) {
	/* MDP wrp is faster than LCD rdp */
	mdp_lcd_rd_cnt += mdp_lcd_rd_cnt_offset_fast;
	} else {
	/* MDP wrp is slower than LCD rdp */
	mdp_lcd_rd_cnt -= mdp_lcd_rd_cnt_offset_slow;
	}

	if (mdp_lcd_rd_cnt < 0)
	mdp_lcd_rd_cnt = mfd->total_lcd_lines + mdp_lcd_rd_cnt;
	else if (mdp_lcd_rd_cnt > mfd->total_lcd_lines)
	mdp_lcd_rd_cnt = mdp_lcd_rd_cnt - mfd->total_lcd_lines - 1;

	/* get wrt pointer position */
	start_y = mfd->ibuf.dma_y;

	/* measure line difference between start_y and rd counter */
	if (start_y > mdp_lcd_rd_cnt) {
	/*
	* *100 for lcd_ref_hzx100 was already multiplied by 100
	* *1000000 is for usec conversion
	*/

	if ((start_y - mdp_lcd_rd_cnt) <=
	mdp_vsync_usec_wait_line_too_short)
	usec_wait_time = 0;
	else
	usec_wait_time =
	((start_y -
	mdp_lcd_rd_cnt) * 1000000) /
	((mfd->total_lcd_lines *
	mfd->panel_info.lcd.refx100) / 100);
	} else {
	if ((start_y + (mfd->total_lcd_lines - mdp_lcd_rd_cnt)) <=
	mdp_vsync_usec_wait_line_too_short)
	usec_wait_time = 0;
	else
	usec_wait_time =
	((start_y +
	(mfd->total_lcd_lines -
	mdp_lcd_rd_cnt)) * 1000000) /
	((mfd->total_lcd_lines *
	mfd->panel_info.lcd.refx100) / 100);
	}

	mdp_last_dma2_update_width = mdp_curr_dma2_update_width;
	mdp_last_dma2_update_height = mdp_curr_dma2_update_height;

	if (usec_wait_time == 0) {
	mdp_pipe_kickoff(term, mfd);
	} else {
	ktime_t wait_time;

	wait_time.tv.sec = 0;
	wait_time.tv.nsec = usec_wait_time * 1000;

	if (msm_fb_debug_enabled) {
	vt = ktime_get_real();
	mdp_expected_usec_wait = usec_wait_time;
	}
	hrtimer_start(&mfd->dma_hrtimer, wait_time, HRTIMER_MODE_REL);
	}
	}

	#ifdef MDDI_HOST_WINDOW_WORKAROUND
	void mdp_dma2_update(struct msm_fb_data_type *mfd)
	{
	MDPIBUF *iBuf;
	uint32 upper_height;

	if (mfd->panel.type == EXT_MDDI_PANEL) {
	mdp_dma2_update_sub(mfd);
	return;
	}

	iBuf = &mfd->ibuf;

	upper_height =
	(uint32) mddi_assign_pkt_height((uint16) iBuf->dma_w,
	(uint16) iBuf->dma_h, 18);

	if (upper_height >= iBuf->dma_h) {
	mdp_dma2_update_sub(mfd);
	} else {
	MDPIBUF lower_height;

	/* sending the upper region first */
	lower_height = iBuf->dma_h - upper_height;
	iBuf->dma_h = upper_height;
	mdp_dma2_update_sub(mfd);

	/* sending the lower region second */
	iBuf->dma_h = lower_height;
	iBuf->dma_y += lower_height;
	iBuf->vsync_enable = FALSE;
	mdp_dma2_update_sub(mfd);
	}
	}

	void mdp_dma2_update_sub(struct msm_fb_data_type *mfd)
	#else
	void mdp_dma2_update(struct msm_fb_data_type *mfd)
	#endif
	{
	down(&mfd->dma->mutex);
	if ((mfd) && (!mfd->dma->busy) && (mfd->panel_power_on)) {
	down(&mfd->sem);
	mfd->ibuf_flushed = TRUE;
	mdp_dma2_update_lcd(mfd);

	mdp_enable_irq(MDP_DMA2_TERM);
	mfd->dma->busy = TRUE;
	INIT_COMPLETION(mfd->dma->comp);

	/* schedule DMA to start */
	mdp_dma_schedule(mfd, MDP_DMA2_TERM);
	up(&mfd->sem);

	/* wait until DMA finishes the current job */
	wait_for_completion_killable(&mfd->dma->comp);
	mdp_disable_irq(MDP_DMA2_TERM);

	/* signal if pan function is waiting for the update completion */
	if (mfd->pan_waiting) {
	mfd->pan_waiting = FALSE;
	complete(&mfd->pan_comp);
	}
	}
	up(&mfd->dma->mutex);
	}

	void mdp_lcd_update_workqueue_handler(struct work_struct *work)
	{
	struct msm_fb_data_type *mfd = NULL;

	mfd = container_of(work, struct msm_fb_data_type, dma_update_worker);
	if (mfd)
	mfd->dma_fnc(mfd);
	}

	void mdp_set_dma_pan_info(struct fb_info info, struct mdp_dirty_region dirty,
	boolean sync)
	{
	struct msm_fb_data_type mfd = (struct msm_fb_data_type )info->par;
	MDPIBUF *iBuf;
	int bpp = info->var.bits_per_pixel / 8;

	down(&mfd->sem);
	iBuf = &mfd->ibuf;
	iBuf->buf = (uint8 *) info->fix.smem_start;
	iBuf->buf += info->var.xoffset * bpp +
	info->var.yoffset * info->fix.line_length;

	iBuf->ibuf_width = info->var.xres_virtual;
	iBuf->bpp = bpp;

	iBuf->vsync_enable = sync;

	if (dirty) {
	/*
	* ToDo: dirty region check inside var.xoffset+xres
	* <-> var.yoffset+yres
	*/
	iBuf->dma_x = dirty->xoffset % info->var.xres;
	iBuf->dma_y = dirty->yoffset % info->var.yres;
	iBuf->dma_w = dirty->width;
	iBuf->dma_h = dirty->height;
	} else {
	iBuf->dma_x = 0;
	iBuf->dma_y = 0;
	iBuf->dma_w = info->var.xres;
	iBuf->dma_h = info->var.yres;
	}
	mfd->ibuf_flushed = FALSE;
	up(&mfd->sem);
	}

	void mdp_set_offset_info(struct fb_info *info, uint32 addr, uint32 sync)
	{
	struct msm_fb_data_type mfd = (struct msm_fb_data_type )info->par;
	MDPIBUF *iBuf;

	int bpp = info->var.bits_per_pixel / 8;

	down(&mfd->sem);
	iBuf = &mfd->ibuf;
	iBuf->ibuf_width = info->var.xres_virtual;
	iBuf->bpp = bpp;
	iBuf->vsync_enable = sync;
	iBuf->dma_x = 0;
	iBuf->dma_y = 0;
	iBuf->dma_w = info->var.xres;
	iBuf->dma_h = info->var.yres;
	iBuf->buf = (uint8 *) addr;

	mfd->ibuf_flushed = FALSE;
	up(&mfd->sem);
	}

	void mdp_dma_pan_update(struct fb_info *info)
	{
	struct msm_fb_data_type mfd = (struct msm_fb_data_type )info->par;
	MDPIBUF *iBuf;

	iBuf = &mfd->ibuf;

	if (mfd->sw_currently_refreshing) {
	/* we need to wait for the pending update */
	mfd->pan_waiting = TRUE;
	if (!mfd->ibuf_flushed) {
	wait_for_completion_killable(&mfd->pan_comp);
	}
	/* waiting for this update to complete */
	mfd->pan_waiting = TRUE;
	wait_for_completion_killable(&mfd->pan_comp);
	} else
	mfd->dma_fnc(mfd);
	}

	void mdp_refresh_screen(unsigned long data)
	{
	struct msm_fb_data_type mfd = (struct msm_fb_data_type )data;

	if ((mfd->sw_currently_refreshing) && (mfd->sw_refreshing_enable)) {
	init_timer(&mfd->refresh_timer);
	mfd->refresh_timer.function = mdp_refresh_screen;
	mfd->refresh_timer.data = data;

	if (mfd->dma->busy)
	/* come back in 1 msec */
	mfd->refresh_timer.expires = jiffies + (HZ / 1000);
	else
	mfd->refresh_timer.expires =
	jiffies + mfd->refresh_timer_duration;

	add_timer(&mfd->refresh_timer);

	if (!mfd->dma->busy) {
	if (!queue_work(mdp_dma_wq, &mfd->dma_update_worker)) {
	MSM_FB_DEBUG("mdp_dma: can't queue_work! -> \
	MDP/MDDI/LCD clock speed needs to be increased\n");
	}
	}
	} else {
	if (!mfd->hw_refresh)
	complete(&mfd->refresher_comp);
	}
	}