av1/common/scale.c - aom - Git at Google

 /*
  * Copyright (c) 2016, Alliance for Open Media. All rights reserved
  *
  * This source code is subject to the terms of the BSD 2 Clause License and
  * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
  * was not distributed with this source code in the LICENSE file, you can
  * obtain it at www.aomedia.org/license/software. If the Alliance for Open
  * Media Patent License 1.0 was not distributed with this source code in the
  * PATENTS file, you can obtain it at www.aomedia.org/license/patent.
  */

 #include "./aom_dsp_rtcd.h"
 #include "av1/common/filter.h"
 #include "av1/common/scale.h"
 #include "aom_dsp/aom_filter.h"

 // Note: Expect val to be in q4 precision
 static INLINE int scaled_x(int val, const struct scale_factors *sf) {
   const int off = (sf->x_scale_fp - (1 << REF_SCALE_SHIFT))
                   << (SUBPEL_BITS - 1);
   const int64_t tval = (int64_t)val * sf->x_scale_fp + off;
   return (int)ROUND_POWER_OF_TWO_SIGNED_64(tval,
                                            REF_SCALE_SHIFT - SCALE_EXTRA_BITS);
 }

 // Note: Expect val to be in q4 precision
 static INLINE int scaled_y(int val, const struct scale_factors *sf) {
   const int off = (sf->y_scale_fp - (1 << REF_SCALE_SHIFT))
                   << (SUBPEL_BITS - 1);
   const int64_t tval = (int64_t)val * sf->y_scale_fp + off;
   return (int)ROUND_POWER_OF_TWO_SIGNED_64(tval,
                                            REF_SCALE_SHIFT - SCALE_EXTRA_BITS);
 }

 // Note: Expect val to be in q4 precision
 static int unscaled_value(int val, const struct scale_factors *sf) {
   (void)sf;
   return val << SCALE_EXTRA_BITS;
 }

 static int get_fixed_point_scale_factor(int other_size, int this_size) {
   // Calculate scaling factor once for each reference frame
   // and use fixed point scaling factors in decoding and encoding routines.
   // Hardware implementations can calculate scale factor in device driver
   // and use multiplication and shifting on hardware instead of division.
   return ((other_size << REF_SCALE_SHIFT) + this_size / 2) / this_size;
 }

 static int get_coarse_point_scale_factor(int other_size, int this_size) {
   // Calculate scaling factor once for each reference frame
   // and use fixed point scaling factors in decoding and encoding routines.
   // Hardware implementations can calculate scale factor in device driver
   // and use multiplication and shifting on hardware instead of division.
   return ((other_size << SCALE_SUBPEL_BITS) + this_size / 2) / this_size;
 }

 // Note: x and y are integer precision, mvq4 is q4 precision.
 MV32 av1_scale_mv(const MV *mvq4, int x, int y,
                   const struct scale_factors *sf) {
   const int x_off_q4 = scaled_x(x << SUBPEL_BITS, sf);
   const int y_off_q4 = scaled_y(y << SUBPEL_BITS, sf);
   const MV32 res = { scaled_y((y << SUBPEL_BITS) + mvq4->row, sf) - y_off_q4,
                      scaled_x((x << SUBPEL_BITS) + mvq4->col, sf) - x_off_q4 };
   return res;
 }

 #if CONFIG_HIGHBITDEPTH
 void av1_setup_scale_factors_for_frame(struct scale_factors *sf, int other_w,
                                        int other_h, int this_w, int this_h,
                                        int use_highbd) {
 #else
 void av1_setup_scale_factors_for_frame(struct scale_factors *sf, int other_w,
                                        int other_h, int this_w, int this_h) {
 #endif
   if (!valid_ref_frame_size(other_w, other_h, this_w, this_h)) {
     sf->x_scale_fp = REF_INVALID_SCALE;
     sf->y_scale_fp = REF_INVALID_SCALE;
     return;
   }

   sf->x_scale_fp = get_fixed_point_scale_factor(other_w, this_w);
   sf->y_scale_fp = get_fixed_point_scale_factor(other_h, this_h);

   sf->x_step_q4 = get_coarse_point_scale_factor(other_w, this_w);
   sf->y_step_q4 = get_coarse_point_scale_factor(other_h, this_h);

   if (av1_is_scaled(sf)) {
     sf->scale_value_x = scaled_x;
     sf->scale_value_y = scaled_y;
   } else {
     sf->scale_value_x = unscaled_value;
     sf->scale_value_y = unscaled_value;
   }

   // TODO(agrange): Investigate the best choice of functions to use here
   // for EIGHTTAP_SMOOTH. Since it is not interpolating, need to choose what
   // to do at full-pel offsets. The current selection, where the filter is
   // applied in one direction only, and not at all for 0,0, seems to give the
   // best quality, but it may be worth trying an additional mode that does
   // do the filtering on full-pel.
   if (sf->x_step_q4 == SCALE_SUBPEL_SHIFTS) {
     if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
       // No scaling in either direction.
       sf->predict[0][0][0] = aom_convolve_copy;
       sf->predict[0][0][1] = aom_convolve_avg;
       sf->predict[0][1][0] = aom_convolve8_vert;
       sf->predict[0][1][1] = aom_convolve8_avg_vert;
       sf->predict[1][0][0] = aom_convolve8_horiz;
       sf->predict[1][0][1] = aom_convolve8_avg_horiz;
     } else {
       // No scaling in x direction. Must always scale in the y direction.
       sf->predict[0][0][0] = aom_convolve8_vert;
       sf->predict[0][0][1] = aom_convolve8_avg_vert;
       sf->predict[0][1][0] = aom_convolve8_vert;
       sf->predict[0][1][1] = aom_convolve8_avg_vert;
       sf->predict[1][0][0] = aom_convolve8;
       sf->predict[1][0][1] = aom_convolve8_avg;
     }
   } else {
     if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
       // No scaling in the y direction. Must always scale in the x direction.
       sf->predict[0][0][0] = aom_convolve8_horiz;
       sf->predict[0][0][1] = aom_convolve8_avg_horiz;
       sf->predict[0][1][0] = aom_convolve8;
       sf->predict[0][1][1] = aom_convolve8_avg;
       sf->predict[1][0][0] = aom_convolve8_horiz;
       sf->predict[1][0][1] = aom_convolve8_avg_horiz;
     } else {
       // Must always scale in both directions.
       sf->predict[0][0][0] = aom_convolve8;
       sf->predict[0][0][1] = aom_convolve8_avg;
       sf->predict[0][1][0] = aom_convolve8;
       sf->predict[0][1][1] = aom_convolve8_avg;
       sf->predict[1][0][0] = aom_convolve8;
       sf->predict[1][0][1] = aom_convolve8_avg;
     }
   }
   // 2D subpel motion always gets filtered in both directions
   sf->predict[1][1][0] = aom_convolve8;
   sf->predict[1][1][1] = aom_convolve8_avg;

 #if CONFIG_HIGHBITDEPTH
   if (use_highbd) {
     if (sf->x_step_q4 == SCALE_SUBPEL_SHIFTS) {
       if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
         // No scaling in either direction.
         sf->highbd_predict[0][0][0] = aom_highbd_convolve_copy;
         sf->highbd_predict[0][0][1] = aom_highbd_convolve_avg;
         sf->highbd_predict[0][1][0] = aom_highbd_convolve8_vert;
         sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg_vert;
         sf->highbd_predict[1][0][0] = aom_highbd_convolve8_horiz;
         sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg_horiz;
       } else {
         // No scaling in x direction. Must always scale in the y direction.
         sf->highbd_predict[0][0][0] = aom_highbd_convolve8_vert;
         sf->highbd_predict[0][0][1] = aom_highbd_convolve8_avg_vert;
         sf->highbd_predict[0][1][0] = aom_highbd_convolve8_vert;
         sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg_vert;
         sf->highbd_predict[1][0][0] = aom_highbd_convolve8;
         sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg;
       }
     } else {
       if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
         // No scaling in the y direction. Must always scale in the x direction.
         sf->highbd_predict[0][0][0] = aom_highbd_convolve8_horiz;
         sf->highbd_predict[0][0][1] = aom_highbd_convolve8_avg_horiz;
         sf->highbd_predict[0][1][0] = aom_highbd_convolve8;
         sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg;
         sf->highbd_predict[1][0][0] = aom_highbd_convolve8_horiz;
         sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg_horiz;
       } else {
         // Must always scale in both directions.
         sf->highbd_predict[0][0][0] = aom_highbd_convolve8;
         sf->highbd_predict[0][0][1] = aom_highbd_convolve8_avg;
         sf->highbd_predict[0][1][0] = aom_highbd_convolve8;
         sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg;
         sf->highbd_predict[1][0][0] = aom_highbd_convolve8;
         sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg;
       }
     }
     // 2D subpel motion always gets filtered in both directions.
     sf->highbd_predict[1][1][0] = aom_highbd_convolve8;
     sf->highbd_predict[1][1][1] = aom_highbd_convolve8_avg;
   }
 #endif  // CONFIG_HIGHBITDEPTH
 }
	/*
	* Copyright (c) 2016, Alliance for Open Media. All rights reserved
	*
	* This source code is subject to the terms of the BSD 2 Clause License and
	* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
	* was not distributed with this source code in the LICENSE file, you can
	* obtain it at www.aomedia.org/license/software. If the Alliance for Open
	* Media Patent License 1.0 was not distributed with this source code in the
	* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
	*/

	#include "./aom_dsp_rtcd.h"
	#include "av1/common/filter.h"
	#include "av1/common/scale.h"
	#include "aom_dsp/aom_filter.h"

	// Note: Expect val to be in q4 precision
	static INLINE int scaled_x(int val, const struct scale_factors *sf) {
	const int off = (sf->x_scale_fp - (1 << REF_SCALE_SHIFT))
	<< (SUBPEL_BITS - 1);
	const int64_t tval = (int64_t)val * sf->x_scale_fp + off;
	return (int)ROUND_POWER_OF_TWO_SIGNED_64(tval,
	REF_SCALE_SHIFT - SCALE_EXTRA_BITS);
	}

	// Note: Expect val to be in q4 precision
	static INLINE int scaled_y(int val, const struct scale_factors *sf) {
	const int off = (sf->y_scale_fp - (1 << REF_SCALE_SHIFT))
	<< (SUBPEL_BITS - 1);
	const int64_t tval = (int64_t)val * sf->y_scale_fp + off;
	return (int)ROUND_POWER_OF_TWO_SIGNED_64(tval,
	REF_SCALE_SHIFT - SCALE_EXTRA_BITS);
	}

	// Note: Expect val to be in q4 precision
	static int unscaled_value(int val, const struct scale_factors *sf) {
	(void)sf;
	return val << SCALE_EXTRA_BITS;
	}

	static int get_fixed_point_scale_factor(int other_size, int this_size) {
	// Calculate scaling factor once for each reference frame
	// and use fixed point scaling factors in decoding and encoding routines.
	// Hardware implementations can calculate scale factor in device driver
	// and use multiplication and shifting on hardware instead of division.
	return ((other_size << REF_SCALE_SHIFT) + this_size / 2) / this_size;
	}

	static int get_coarse_point_scale_factor(int other_size, int this_size) {
	// Calculate scaling factor once for each reference frame
	// and use fixed point scaling factors in decoding and encoding routines.
	// Hardware implementations can calculate scale factor in device driver
	// and use multiplication and shifting on hardware instead of division.
	return ((other_size << SCALE_SUBPEL_BITS) + this_size / 2) / this_size;
	}

	// Note: x and y are integer precision, mvq4 is q4 precision.
	MV32 av1_scale_mv(const MV *mvq4, int x, int y,
	const struct scale_factors *sf) {
	const int x_off_q4 = scaled_x(x << SUBPEL_BITS, sf);
	const int y_off_q4 = scaled_y(y << SUBPEL_BITS, sf);
	const MV32 res = { scaled_y((y << SUBPEL_BITS) + mvq4->row, sf) - y_off_q4,
	scaled_x((x << SUBPEL_BITS) + mvq4->col, sf) - x_off_q4 };
	return res;
	}

	#if CONFIG_HIGHBITDEPTH
	void av1_setup_scale_factors_for_frame(struct scale_factors *sf, int other_w,
	int other_h, int this_w, int this_h,
	int use_highbd) {
	#else
	void av1_setup_scale_factors_for_frame(struct scale_factors *sf, int other_w,
	int other_h, int this_w, int this_h) {
	#endif
	if (!valid_ref_frame_size(other_w, other_h, this_w, this_h)) {
	sf->x_scale_fp = REF_INVALID_SCALE;
	sf->y_scale_fp = REF_INVALID_SCALE;
	return;
	}

	sf->x_scale_fp = get_fixed_point_scale_factor(other_w, this_w);
	sf->y_scale_fp = get_fixed_point_scale_factor(other_h, this_h);

	sf->x_step_q4 = get_coarse_point_scale_factor(other_w, this_w);
	sf->y_step_q4 = get_coarse_point_scale_factor(other_h, this_h);

	if (av1_is_scaled(sf)) {
	sf->scale_value_x = scaled_x;
	sf->scale_value_y = scaled_y;
	} else {
	sf->scale_value_x = unscaled_value;
	sf->scale_value_y = unscaled_value;
	}

	// TODO(agrange): Investigate the best choice of functions to use here
	// for EIGHTTAP_SMOOTH. Since it is not interpolating, need to choose what
	// to do at full-pel offsets. The current selection, where the filter is
	// applied in one direction only, and not at all for 0,0, seems to give the
	// best quality, but it may be worth trying an additional mode that does
	// do the filtering on full-pel.
	if (sf->x_step_q4 == SCALE_SUBPEL_SHIFTS) {
	if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
	// No scaling in either direction.
	sf->predict[0][0][0] = aom_convolve_copy;
	sf->predict[0][0][1] = aom_convolve_avg;
	sf->predict[0][1][0] = aom_convolve8_vert;
	sf->predict[0][1][1] = aom_convolve8_avg_vert;
	sf->predict[1][0][0] = aom_convolve8_horiz;
	sf->predict[1][0][1] = aom_convolve8_avg_horiz;
	} else {
	// No scaling in x direction. Must always scale in the y direction.
	sf->predict[0][0][0] = aom_convolve8_vert;
	sf->predict[0][0][1] = aom_convolve8_avg_vert;
	sf->predict[0][1][0] = aom_convolve8_vert;
	sf->predict[0][1][1] = aom_convolve8_avg_vert;
	sf->predict[1][0][0] = aom_convolve8;
	sf->predict[1][0][1] = aom_convolve8_avg;
	}
	} else {
	if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
	// No scaling in the y direction. Must always scale in the x direction.
	sf->predict[0][0][0] = aom_convolve8_horiz;
	sf->predict[0][0][1] = aom_convolve8_avg_horiz;
	sf->predict[0][1][0] = aom_convolve8;
	sf->predict[0][1][1] = aom_convolve8_avg;
	sf->predict[1][0][0] = aom_convolve8_horiz;
	sf->predict[1][0][1] = aom_convolve8_avg_horiz;
	} else {
	// Must always scale in both directions.
	sf->predict[0][0][0] = aom_convolve8;
	sf->predict[0][0][1] = aom_convolve8_avg;
	sf->predict[0][1][0] = aom_convolve8;
	sf->predict[0][1][1] = aom_convolve8_avg;
	sf->predict[1][0][0] = aom_convolve8;
	sf->predict[1][0][1] = aom_convolve8_avg;
	}
	}
	// 2D subpel motion always gets filtered in both directions
	sf->predict[1][1][0] = aom_convolve8;
	sf->predict[1][1][1] = aom_convolve8_avg;

	#if CONFIG_HIGHBITDEPTH
	if (use_highbd) {
	if (sf->x_step_q4 == SCALE_SUBPEL_SHIFTS) {
	if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
	// No scaling in either direction.
	sf->highbd_predict[0][0][0] = aom_highbd_convolve_copy;
	sf->highbd_predict[0][0][1] = aom_highbd_convolve_avg;
	sf->highbd_predict[0][1][0] = aom_highbd_convolve8_vert;
	sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg_vert;
	sf->highbd_predict[1][0][0] = aom_highbd_convolve8_horiz;
	sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg_horiz;
	} else {
	// No scaling in x direction. Must always scale in the y direction.
	sf->highbd_predict[0][0][0] = aom_highbd_convolve8_vert;
	sf->highbd_predict[0][0][1] = aom_highbd_convolve8_avg_vert;
	sf->highbd_predict[0][1][0] = aom_highbd_convolve8_vert;
	sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg_vert;
	sf->highbd_predict[1][0][0] = aom_highbd_convolve8;
	sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg;
	}
	} else {
	if (sf->y_step_q4 == SCALE_SUBPEL_SHIFTS) {
	// No scaling in the y direction. Must always scale in the x direction.
	sf->highbd_predict[0][0][0] = aom_highbd_convolve8_horiz;
	sf->highbd_predict[0][0][1] = aom_highbd_convolve8_avg_horiz;
	sf->highbd_predict[0][1][0] = aom_highbd_convolve8;
	sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg;
	sf->highbd_predict[1][0][0] = aom_highbd_convolve8_horiz;
	sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg_horiz;
	} else {
	// Must always scale in both directions.
	sf->highbd_predict[0][0][0] = aom_highbd_convolve8;
	sf->highbd_predict[0][0][1] = aom_highbd_convolve8_avg;
	sf->highbd_predict[0][1][0] = aom_highbd_convolve8;
	sf->highbd_predict[0][1][1] = aom_highbd_convolve8_avg;
	sf->highbd_predict[1][0][0] = aom_highbd_convolve8;
	sf->highbd_predict[1][0][1] = aom_highbd_convolve8_avg;
	}
	}
	// 2D subpel motion always gets filtered in both directions.
	sf->highbd_predict[1][1][0] = aom_highbd_convolve8;
	sf->highbd_predict[1][1][1] = aom_highbd_convolve8_avg;
	}
	#endif // CONFIG_HIGHBITDEPTH
	}