sdm/libs/utils/rect.cpp - platform/hardware/qcom/sm7250/display - Git at Google

 /*
 * Copyright (c) 2015-2019, 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 <math.h>
 #include <utils/rect.h>
 #include <utils/constants.h>
 #include <algorithm>

 #define __CLASS__ "RectUtils"

 namespace sdm {

 bool IsValid(const LayerRect &rect) {
   return ((rect.bottom > rect.top) && (rect.right > rect.left));
 }

 bool IsCongruent(const LayerRect &rect1, const LayerRect &rect2) {
   return ((rect1.left == rect2.left) &&
           (rect1.top == rect2.top) &&
           (rect1.right == rect2.right) &&
           (rect1.bottom == rect2.bottom));
 }

 void LogI(DebugTag debug_tag, const char *prefix, const LayerRect &roi) {
   DLOGI_IF(debug_tag, "%s: left = %.0f, top = %.0f, right = %.0f, bottom = %.0f",
            prefix, roi.left, roi.top, roi.right, roi.bottom);
 }

 void Log(DebugTag debug_tag, const char *prefix, const LayerRect &roi) {
   DLOGV_IF(debug_tag, "%s: left = %.0f, top = %.0f, right = %.0f, bottom = %.0f",
            prefix, roi.left, roi.top, roi.right, roi.bottom);
 }

 void Normalize(const uint32_t &align_x, const uint32_t &align_y, LayerRect *rect) {
     rect->left = ROUND_UP_ALIGN_UP(rect->left, align_x);
     rect->right = ROUND_UP_ALIGN_DOWN(rect->right, align_x);
     rect->top = ROUND_UP_ALIGN_UP(rect->top, align_y);
     rect->bottom = ROUND_UP_ALIGN_DOWN(rect->bottom, align_y);
 }

 LayerRect Intersection(const LayerRect &rect1, const LayerRect &rect2) {
   LayerRect res;

   if (!IsValid(rect1) || !IsValid(rect2)) {
     return LayerRect();
   }

   res.left = std::max(rect1.left, rect2.left);
   res.top = std::max(rect1.top, rect2.top);
   res.right = std::min(rect1.right, rect2.right);
   res.bottom = std::min(rect1.bottom, rect2.bottom);

   if (!IsValid(res)) {
     return LayerRect();
   }

   return res;
 }

 LayerRect Reposition(const LayerRect &rect, const int &x_offset, const int &y_offset) {
   LayerRect res;

   if (!IsValid(rect)) {
     return LayerRect();
   }

   res.left = rect.left + FLOAT(x_offset);
   res.top = rect.top + FLOAT(y_offset);
   res.right = rect.right + FLOAT(x_offset);
   res.bottom = rect.bottom + FLOAT(y_offset);

   return res;
 }

 // Is rect2 completely inside rect1?
 bool Contains(const LayerRect &rect1, const LayerRect &rect2) {
   if (!IsValid(rect1) || !IsValid(rect2)) {
     return false;
   }
   return (rect1.top <= rect2.top && rect1.bottom >= rect2.bottom &&
           rect1.left <= rect2.left && rect1.right >= rect2.right);
 }

 // subtracts 2 rects iff result of subtraction is 2 rects.
 void Subtract(const LayerRect &rect1, const LayerRect &rect2, LayerRect *res) {
   if (!res) {
     return;
   }
   if (!IsValid(rect1) || !IsValid(rect2)) {
     return;
   }

   if (rect1.left != rect2.left || rect1.right != rect2.right) {
     return;
   }
   res[0].left = rect1.left;
   res[0].right = rect1.right;
   if (rect1.top < rect2.top) {
     res[0].top = rect1.top;
     res[0].bottom = rect2.top;
   } else {
     res[0].top = rect2.top;
     res[0].bottom = rect1.top;
   }
   res[1].left = rect1.left;
   res[1].right = rect1.right;
   if (rect1.bottom < rect2.bottom) {
     res[1].top = rect1.bottom;
     res[1].bottom = rect2.bottom;
   } else {
     res[1].top = rect2.bottom;
     res[1].bottom = rect1.bottom;
   }
 }

 // Not a geometrical rect deduction. Deducts rect2 from rect1 only if it results a single rect
 LayerRect Subtract(const LayerRect &rect1, const LayerRect &rect2) {
   LayerRect res;

   res = rect1;

   if ((rect1.left == rect2.left) && (rect1.right == rect2.right)) {
     if ((rect1.top == rect2.top) && (rect2.bottom <= rect1.bottom)) {
       res.top = rect2.bottom;
     } else if ((rect1.bottom == rect2.bottom) && (rect2.top >= rect1.top)) {
       res.bottom = rect2.top;
     }
   } else if ((rect1.top == rect2.top) && (rect1.bottom == rect2.bottom)) {
     if ((rect1.left == rect2.left) && (rect2.right <= rect1.right)) {
       res.left = rect2.right;
     } else if ((rect1.right == rect2.right) && (rect2.left >= rect1.left)) {
       res.right = rect2.left;
     }
   }

   return res;
 }

 LayerRect Union(const LayerRect &rect1, const LayerRect &rect2) {
   LayerRect res;

   if (!IsValid(rect1) && !IsValid(rect2)) {
     return LayerRect();
   }

   if (!IsValid(rect1)) {
     return rect2;
   }

   if (!IsValid(rect2)) {
     return rect1;
   }

   res.left = std::min(rect1.left, rect2.left);
   res.top = std::min(rect1.top, rect2.top);
   res.right = std::max(rect1.right, rect2.right);
   res.bottom = std::max(rect1.bottom, rect2.bottom);

   return res;
 }

 void SplitLeftRight(const LayerRect &in_rect, uint32_t split_count, uint32_t align_x,
                     bool flip_horizontal, LayerRect *out_rects) {
   LayerRect rect_temp = in_rect;

   uint32_t split_width = UINT32(rect_temp.right - rect_temp.left) / split_count;
   float aligned_width = FLOAT(CeilToMultipleOf(split_width, align_x));

   for (uint32_t count = 0; count < split_count; count++) {
     float aligned_right = rect_temp.left + aligned_width;
     out_rects[count].left = rect_temp.left;
     out_rects[count].right = std::min(rect_temp.right, aligned_right);
     out_rects[count].top = rect_temp.top;
     out_rects[count].bottom = rect_temp.bottom;

     rect_temp.left = out_rects[count].right;

     Log(kTagRotator, "SplitLeftRight", out_rects[count]);
   }

   // If we have a horizontal flip, then we should be splitting the source from right to left
   // to ensure that the right split will have an aligned width that matches the alignment on the
   // destination.
   if (flip_horizontal && split_count > 1) {
     out_rects[0].right = out_rects[0].left + (out_rects[1].right - out_rects[1].left);
     out_rects[1].left = out_rects[0].right;
     Log(kTagRotator, "Adjusted Left", out_rects[0]);
     Log(kTagRotator, "Adjusted Right", out_rects[1]);
   }
 }

 void SplitTopBottom(const LayerRect &in_rect, uint32_t split_count, uint32_t align_y,
                     bool flip_horizontal, LayerRect *out_rects) {
   LayerRect rect_temp = in_rect;

   uint32_t split_height = UINT32(rect_temp.bottom - rect_temp.top) / split_count;
   float aligned_height = FLOAT(CeilToMultipleOf(split_height, align_y));

   for (uint32_t count = 0; count < split_count; count++) {
     float aligned_bottom = rect_temp.top + aligned_height;
     out_rects[count].top = rect_temp.top;
     out_rects[count].bottom = std::min(rect_temp.bottom, aligned_bottom);
     out_rects[count].left = rect_temp.left;
     out_rects[count].right = rect_temp.right;

     rect_temp.top = out_rects[count].bottom;

     Log(kTagRotator, "SplitTopBottom", out_rects[count]);
   }

   // If we have a horizontal flip, then we should be splitting the destination from bottom to top
   // to ensure that the bottom split's y-offset is aligned correctly after we swap the destinations
   // while accounting for the flip.
   if (flip_horizontal && split_count > 1) {
     out_rects[0].bottom = out_rects[0].top + (out_rects[1].bottom - out_rects[1].top);
     out_rects[1].top = out_rects[0].bottom;
     Log(kTagRotator, "Adjusted Top", out_rects[0]);
     Log(kTagRotator, "Adjusted Bottom", out_rects[1]);
   }
 }

 void MapRect(const LayerRect &src_domain, const LayerRect &dst_domain, const LayerRect &in_rect,
              LayerRect *out_rect) {
   if (!IsValid(src_domain) || !IsValid(dst_domain) || !IsValid(in_rect)) {
     return;
   }

   int x_offset = INT(src_domain.left);
   int y_offset = INT(src_domain.top);

   LayerRect modified_in_rect = Reposition(in_rect, -x_offset, -y_offset);
   double src_domain_width = DOUBLE(src_domain.right - src_domain.left);
   double src_domain_height = DOUBLE(src_domain.bottom - src_domain.top);
   double dst_domain_width = DOUBLE(dst_domain.right - dst_domain.left);
   double dst_domain_height = DOUBLE(dst_domain.bottom - dst_domain.top);

   double width_ratio = DOUBLE(dst_domain_width / src_domain_width);
   double height_ratio = DOUBLE(dst_domain_height / src_domain_height);

   // using floorf for all since ceilf on float will round to next int value.
   out_rect->left = floor(dst_domain.left + (width_ratio * modified_in_rect.left));
   out_rect->top = floor(dst_domain.top + (height_ratio * modified_in_rect.top));
   out_rect->right = floor(dst_domain.left + (width_ratio * modified_in_rect.right));
   out_rect->bottom = floor(dst_domain.top + (height_ratio * modified_in_rect.bottom));
 }

 void TransformHV(const LayerRect &src_domain, const LayerRect &in_rect,
                  const LayerTransform &transform, LayerRect *out_rect) {
   if (!IsValid(src_domain) || !IsValid(in_rect)) {
     return;
   }

   float in_width = in_rect.right - in_rect.left;
   float in_height = in_rect.bottom - in_rect.top;
   float x_offset = in_rect.left - src_domain.left;
   float y_offset = in_rect.top - src_domain.top;
   *out_rect = in_rect;

   if (transform.flip_horizontal) {
     out_rect->right = src_domain.right - x_offset;
     out_rect->left = out_rect->right - in_width;
   }

   if (transform.flip_vertical) {
     out_rect->bottom = src_domain.bottom - y_offset;
     out_rect->top = out_rect->bottom - in_height;
   }
 }

 RectOrientation GetOrientation(const LayerRect &in_rect) {
   if (!IsValid(in_rect)) {
     return kOrientationUnknown;
   }

   float input_width = in_rect.right - in_rect.left;
   float input_height = in_rect.bottom - in_rect.top;

   if (input_width < input_height) {
     return kOrientationPortrait;
   }

   return kOrientationLandscape;
 }

 DisplayError GetCropAndDestination(const LayerRect &crop, const LayerRect &dst,
                                    const bool rotated90, float *crop_width,
                                    float *crop_height, float *dst_width,
                                    float *dst_height) {
   if (!IsValid(crop)) {
     Log(kTagResources, "Invalid crop rect", crop);
     return kErrorNotSupported;
   }

   if (!IsValid(dst)) {
     Log(kTagResources, "Invalid dst rect", dst);
     return kErrorNotSupported;
   }

   *crop_width = crop.right - crop.left;
   *crop_height = crop.bottom - crop.top;
   if (rotated90) {
     std::swap(*crop_width, *crop_height);
   }

   *dst_width = dst.right - dst.left;
   *dst_height = dst.bottom - dst.top;

   return kErrorNone;
 }

 DisplayError GetScaleFactor(const LayerRect &crop, const LayerRect &dst,
                             bool rotated90, float *scale_x, float *scale_y) {
   float crop_width = 1.0f, crop_height = 1.0f, dst_width = 1.0f, dst_height = 1.0f;

   DisplayError error = GetCropAndDestination(crop, dst, rotated90, &crop_width, &crop_height,
                                              &dst_width, &dst_height);
   if (error != kErrorNone) {
     return error;
   }

   *scale_x = crop_width / dst_width;
   *scale_y = crop_height / dst_height;

   return kErrorNone;
 }

 }  // namespace sdm
	/*
	* Copyright (c) 2015-2019, 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 <math.h>
	#include <utils/rect.h>
	#include <utils/constants.h>
	#include <algorithm>

	#define __CLASS__ "RectUtils"

	namespace sdm {

	bool IsValid(const LayerRect &rect) {
	return ((rect.bottom > rect.top) && (rect.right > rect.left));
	}

	bool IsCongruent(const LayerRect &rect1, const LayerRect &rect2) {
	return ((rect1.left == rect2.left) &&
	(rect1.top == rect2.top) &&
	(rect1.right == rect2.right) &&
	(rect1.bottom == rect2.bottom));
	}

	void LogI(DebugTag debug_tag, const char *prefix, const LayerRect &roi) {
	DLOGI_IF(debug_tag, "%s: left = %.0f, top = %.0f, right = %.0f, bottom = %.0f",
	prefix, roi.left, roi.top, roi.right, roi.bottom);
	}

	void Log(DebugTag debug_tag, const char *prefix, const LayerRect &roi) {
	DLOGV_IF(debug_tag, "%s: left = %.0f, top = %.0f, right = %.0f, bottom = %.0f",
	prefix, roi.left, roi.top, roi.right, roi.bottom);
	}

	void Normalize(const uint32_t &align_x, const uint32_t &align_y, LayerRect *rect) {
	rect->left = ROUND_UP_ALIGN_UP(rect->left, align_x);
	rect->right = ROUND_UP_ALIGN_DOWN(rect->right, align_x);
	rect->top = ROUND_UP_ALIGN_UP(rect->top, align_y);
	rect->bottom = ROUND_UP_ALIGN_DOWN(rect->bottom, align_y);
	}

	LayerRect Intersection(const LayerRect &rect1, const LayerRect &rect2) {
	LayerRect res;

	if (!IsValid(rect1) \|\| !IsValid(rect2)) {
	return LayerRect();
	}

	res.left = std::max(rect1.left, rect2.left);
	res.top = std::max(rect1.top, rect2.top);
	res.right = std::min(rect1.right, rect2.right);
	res.bottom = std::min(rect1.bottom, rect2.bottom);

	if (!IsValid(res)) {
	return LayerRect();
	}

	return res;
	}

	LayerRect Reposition(const LayerRect &rect, const int &x_offset, const int &y_offset) {
	LayerRect res;

	if (!IsValid(rect)) {
	return LayerRect();
	}

	res.left = rect.left + FLOAT(x_offset);
	res.top = rect.top + FLOAT(y_offset);
	res.right = rect.right + FLOAT(x_offset);
	res.bottom = rect.bottom + FLOAT(y_offset);

	return res;
	}

	// Is rect2 completely inside rect1?
	bool Contains(const LayerRect &rect1, const LayerRect &rect2) {
	if (!IsValid(rect1) \|\| !IsValid(rect2)) {
	return false;
	}
	return (rect1.top <= rect2.top && rect1.bottom >= rect2.bottom &&
	rect1.left <= rect2.left && rect1.right >= rect2.right);
	}

	// subtracts 2 rects iff result of subtraction is 2 rects.
	void Subtract(const LayerRect &rect1, const LayerRect &rect2, LayerRect *res) {
	if (!res) {
	return;
	}
	if (!IsValid(rect1) \|\| !IsValid(rect2)) {
	return;
	}

	if (rect1.left != rect2.left \|\| rect1.right != rect2.right) {
	return;
	}
	res[0].left = rect1.left;
	res[0].right = rect1.right;
	if (rect1.top < rect2.top) {
	res[0].top = rect1.top;
	res[0].bottom = rect2.top;
	} else {
	res[0].top = rect2.top;
	res[0].bottom = rect1.top;
	}
	res[1].left = rect1.left;
	res[1].right = rect1.right;
	if (rect1.bottom < rect2.bottom) {
	res[1].top = rect1.bottom;
	res[1].bottom = rect2.bottom;
	} else {
	res[1].top = rect2.bottom;
	res[1].bottom = rect1.bottom;
	}
	}

	// Not a geometrical rect deduction. Deducts rect2 from rect1 only if it results a single rect
	LayerRect Subtract(const LayerRect &rect1, const LayerRect &rect2) {
	LayerRect res;

	res = rect1;

	if ((rect1.left == rect2.left) && (rect1.right == rect2.right)) {
	if ((rect1.top == rect2.top) && (rect2.bottom <= rect1.bottom)) {
	res.top = rect2.bottom;
	} else if ((rect1.bottom == rect2.bottom) && (rect2.top >= rect1.top)) {
	res.bottom = rect2.top;
	}
	} else if ((rect1.top == rect2.top) && (rect1.bottom == rect2.bottom)) {
	if ((rect1.left == rect2.left) && (rect2.right <= rect1.right)) {
	res.left = rect2.right;
	} else if ((rect1.right == rect2.right) && (rect2.left >= rect1.left)) {
	res.right = rect2.left;
	}
	}

	return res;
	}

	LayerRect Union(const LayerRect &rect1, const LayerRect &rect2) {
	LayerRect res;

	if (!IsValid(rect1) && !IsValid(rect2)) {
	return LayerRect();
	}

	if (!IsValid(rect1)) {
	return rect2;
	}

	if (!IsValid(rect2)) {
	return rect1;
	}

	res.left = std::min(rect1.left, rect2.left);
	res.top = std::min(rect1.top, rect2.top);
	res.right = std::max(rect1.right, rect2.right);
	res.bottom = std::max(rect1.bottom, rect2.bottom);

	return res;
	}

	void SplitLeftRight(const LayerRect &in_rect, uint32_t split_count, uint32_t align_x,
	bool flip_horizontal, LayerRect *out_rects) {
	LayerRect rect_temp = in_rect;

	uint32_t split_width = UINT32(rect_temp.right - rect_temp.left) / split_count;
	float aligned_width = FLOAT(CeilToMultipleOf(split_width, align_x));

	for (uint32_t count = 0; count < split_count; count++) {
	float aligned_right = rect_temp.left + aligned_width;
	out_rects[count].left = rect_temp.left;
	out_rects[count].right = std::min(rect_temp.right, aligned_right);
	out_rects[count].top = rect_temp.top;
	out_rects[count].bottom = rect_temp.bottom;

	rect_temp.left = out_rects[count].right;

	Log(kTagRotator, "SplitLeftRight", out_rects[count]);
	}

	// If we have a horizontal flip, then we should be splitting the source from right to left
	// to ensure that the right split will have an aligned width that matches the alignment on the
	// destination.
	if (flip_horizontal && split_count > 1) {
	out_rects[0].right = out_rects[0].left + (out_rects[1].right - out_rects[1].left);
	out_rects[1].left = out_rects[0].right;
	Log(kTagRotator, "Adjusted Left", out_rects[0]);
	Log(kTagRotator, "Adjusted Right", out_rects[1]);
	}
	}

	void SplitTopBottom(const LayerRect &in_rect, uint32_t split_count, uint32_t align_y,
	bool flip_horizontal, LayerRect *out_rects) {
	LayerRect rect_temp = in_rect;

	uint32_t split_height = UINT32(rect_temp.bottom - rect_temp.top) / split_count;
	float aligned_height = FLOAT(CeilToMultipleOf(split_height, align_y));

	for (uint32_t count = 0; count < split_count; count++) {
	float aligned_bottom = rect_temp.top + aligned_height;
	out_rects[count].top = rect_temp.top;
	out_rects[count].bottom = std::min(rect_temp.bottom, aligned_bottom);
	out_rects[count].left = rect_temp.left;
	out_rects[count].right = rect_temp.right;

	rect_temp.top = out_rects[count].bottom;

	Log(kTagRotator, "SplitTopBottom", out_rects[count]);
	}

	// If we have a horizontal flip, then we should be splitting the destination from bottom to top
	// to ensure that the bottom split's y-offset is aligned correctly after we swap the destinations
	// while accounting for the flip.
	if (flip_horizontal && split_count > 1) {
	out_rects[0].bottom = out_rects[0].top + (out_rects[1].bottom - out_rects[1].top);
	out_rects[1].top = out_rects[0].bottom;
	Log(kTagRotator, "Adjusted Top", out_rects[0]);
	Log(kTagRotator, "Adjusted Bottom", out_rects[1]);
	}
	}

	void MapRect(const LayerRect &src_domain, const LayerRect &dst_domain, const LayerRect &in_rect,
	LayerRect *out_rect) {
	if (!IsValid(src_domain) \|\| !IsValid(dst_domain) \|\| !IsValid(in_rect)) {
	return;
	}

	int x_offset = INT(src_domain.left);
	int y_offset = INT(src_domain.top);

	LayerRect modified_in_rect = Reposition(in_rect, -x_offset, -y_offset);
	double src_domain_width = DOUBLE(src_domain.right - src_domain.left);
	double src_domain_height = DOUBLE(src_domain.bottom - src_domain.top);
	double dst_domain_width = DOUBLE(dst_domain.right - dst_domain.left);
	double dst_domain_height = DOUBLE(dst_domain.bottom - dst_domain.top);

	double width_ratio = DOUBLE(dst_domain_width / src_domain_width);
	double height_ratio = DOUBLE(dst_domain_height / src_domain_height);

	// using floorf for all since ceilf on float will round to next int value.
	out_rect->left = floor(dst_domain.left + (width_ratio * modified_in_rect.left));
	out_rect->top = floor(dst_domain.top + (height_ratio * modified_in_rect.top));
	out_rect->right = floor(dst_domain.left + (width_ratio * modified_in_rect.right));
	out_rect->bottom = floor(dst_domain.top + (height_ratio * modified_in_rect.bottom));
	}

	void TransformHV(const LayerRect &src_domain, const LayerRect &in_rect,
	const LayerTransform &transform, LayerRect *out_rect) {
	if (!IsValid(src_domain) \|\| !IsValid(in_rect)) {
	return;
	}

	float in_width = in_rect.right - in_rect.left;
	float in_height = in_rect.bottom - in_rect.top;
	float x_offset = in_rect.left - src_domain.left;
	float y_offset = in_rect.top - src_domain.top;
	*out_rect = in_rect;

	if (transform.flip_horizontal) {
	out_rect->right = src_domain.right - x_offset;
	out_rect->left = out_rect->right - in_width;
	}

	if (transform.flip_vertical) {
	out_rect->bottom = src_domain.bottom - y_offset;
	out_rect->top = out_rect->bottom - in_height;
	}
	}

	RectOrientation GetOrientation(const LayerRect &in_rect) {
	if (!IsValid(in_rect)) {
	return kOrientationUnknown;
	}

	float input_width = in_rect.right - in_rect.left;
	float input_height = in_rect.bottom - in_rect.top;

	if (input_width < input_height) {
	return kOrientationPortrait;
	}

	return kOrientationLandscape;
	}

	DisplayError GetCropAndDestination(const LayerRect &crop, const LayerRect &dst,
	const bool rotated90, float *crop_width,
	float crop_height, float dst_width,
	float *dst_height) {
	if (!IsValid(crop)) {
	Log(kTagResources, "Invalid crop rect", crop);
	return kErrorNotSupported;
	}

	if (!IsValid(dst)) {
	Log(kTagResources, "Invalid dst rect", dst);
	return kErrorNotSupported;
	}

	*crop_width = crop.right - crop.left;
	*crop_height = crop.bottom - crop.top;
	if (rotated90) {
	std::swap(crop_width, crop_height);
	}

	*dst_width = dst.right - dst.left;
	*dst_height = dst.bottom - dst.top;

	return kErrorNone;
	}

	DisplayError GetScaleFactor(const LayerRect &crop, const LayerRect &dst,
	bool rotated90, float scale_x, float scale_y) {
	float crop_width = 1.0f, crop_height = 1.0f, dst_width = 1.0f, dst_height = 1.0f;

	DisplayError error = GetCropAndDestination(crop, dst, rotated90, &crop_width, &crop_height,
	&dst_width, &dst_height);
	if (error != kErrorNone) {
	return error;
	}

	*scale_x = crop_width / dst_width;
	*scale_y = crop_height / dst_height;

	return kErrorNone;
	}

	} // namespace sdm