uvg266/src/search.c

/**
 * \file
 * 
 * \author Marko Viitanen ( fador@iki.fi ), 
 *         Tampere University of Technology,
 *         Department of Pervasive Computing.
 * \author Ari Koivula ( ari@koivu.la ), 
 *         Tampere University of Technology,
 *         Department of Pervasive Computing.
 */

#include "search.h"

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include "config.h"
#include "bitstream.h"
#include "picture.h"
#include "intra.h"
#include "inter.h"
#include "filter.h"
#include "debug.h"


// Temporarily for debugging.
#define USE_INTRA_IN_P 0
//#define RENDER_CU encoder->frame==2
#define RENDER_CU 0
#define USE_CHROMA_IN_MV_SEARCH 0

#define IN_FRAME(x, y, width, height, block_width, block_height) \
  ((x) >= 0 && (y) >= 0 \
  && (x) + (block_width) <= (width) \
  && (y) + (block_height) <= (height))

typedef struct {
  int x;
  int y;
} vector2d;

/** 
 * This is used in the hexagon_search to select 3 points to search.
 * 
 * The start of the hexagonal pattern has been repeated at the end so that
 * the indices between 1-6 can be used as the start of a 3-point list of new
 * points to search.
 * 
 *   6 o-o 1 / 7
 *    /   \
 * 5 o  0  o 2 / 8
 *    \   /
 *   4 o-o 3
 */
const vector2d large_hexbs[10] = {
  { 0, 0 },
  { 1, -2 }, { 2, 0 }, { 1, 2 }, { -1, 2 }, { -2, 0 }, { -1, -2 },
  { 1, -2 }, { 2, 0 }
};

/**
 * This is used as the last step of the hexagon search.
 */
const vector2d small_hexbs[5] = {
  { 0, 0 },
  { -1, -1 }, { -1, 0 }, { 1, 0 }, { 1, 1 }
};

void hexagon_search(picture *pic, picture *ref,
                    cu_info *cur_cu,  int orig_x, int orig_y, int x, int y, 
                    unsigned depth)
{
  int block_width = CU_WIDTH_FROM_DEPTH(depth);
  unsigned best_cost = -1;
  unsigned i;
  unsigned best_index = 0; // in large_hexbs[]

  // Search the initial 7 points of the hexagon.
  for (i = 0; i < 7; ++i) {
    const vector2d *pattern = large_hexbs + i;
    unsigned cost = calc_sad(pic, ref, orig_x, orig_y,
                             orig_x + x + pattern->x, orig_y + y + pattern->y,
                             block_width, block_width);
    if (cost > 0 && cost < best_cost) {
      best_cost = cost;
      best_index = i;
    }
  }

  // Try the 0,0 vector.
  if (!(x == 0 && y == 0)) {
    unsigned cost = calc_sad(pic, ref, orig_x, orig_y,
                             orig_x, orig_y,
                             block_width, block_width);
    if (cost > 0 && cost < best_cost) {
      best_cost = cost;
      best_index = 0;
      x = 0;
      y = 0;

      // Redo the search around the 0,0 point.
      for (i = 1; i < 7; ++i) {
        const vector2d *pattern = large_hexbs + i;
        unsigned cost = calc_sad(pic, ref, orig_x, orig_y,
                                 orig_x + pattern->x, orig_y + pattern->y,
                                 block_width, block_width);
        if (cost > 0 && cost < best_cost) {
          best_cost = cost;
          best_index = i;
        }
      }
    }
  }
  
  // Iteratively search the 3 new points around the best match, until the best
  // match is in the center.
  while (best_index != 0) {
    unsigned start; // Starting point of the 3 offsets to be searched.
    if (best_index == 1) {
      start = 6;
    } else if (best_index == 8) {
      start = 1;
    } else {
      start = best_index - 1;
    }

    // Move the center to the best match.
    x += large_hexbs[best_index].x;
    y += large_hexbs[best_index].y;
    best_index = 0;

    // Iterate through the next 3 points.
    for (i = 0; i < 3; ++i) {
      const vector2d *offset = large_hexbs + start + i;
      unsigned cost = calc_sad(pic, ref, orig_x, orig_y,
                               orig_x + x + offset->x, orig_y + y + offset->y,
                               block_width, block_width);
      if (cost > 0 && cost < best_cost) {
        best_cost = cost;
        best_index = start + i;
      }
      ++offset;
    }
  }

  // Do the final step of the search with a small pattern.
  x += large_hexbs[best_index].x;
  y += large_hexbs[best_index].y;
  best_index = 0;
  for (i = 1; i < 5; ++i) {
    const vector2d *offset = small_hexbs + i;
    unsigned cost = calc_sad(pic, ref, orig_x, orig_y,
                             orig_x + x + offset->x, orig_y + y + offset->y,
                             block_width, block_width);
    if (cost > 0 && cost < best_cost) {
      best_cost = cost;
      best_index = i;
    }
  }

  x += small_hexbs[best_index].x;
  y += small_hexbs[best_index].y;
  best_index = 0;
  cur_cu->inter.cost = best_cost + 1; // +1 so that cost is > 0.
  cur_cu->inter.mv[0] = x << 2;
  cur_cu->inter.mv[1] = y << 2;
}

/**
 * \brief
 */
void search_buildReferenceBorder(picture *pic, int32_t x_ctb, int32_t y_ctb,
                                 int16_t outwidth, int16_t *dst, 
                                 int32_t dststride, int8_t chroma)
{
  int32_t left_col; // left column iterator
  int16_t val;      // variable to store extrapolated value
  int32_t i;        // index iterator
  int16_t dc_val = 1 << (g_bitdepth - 1); // default predictor value
  int32_t top_row;  // top row iterator
  int32_t src_width = (pic->width >> (chroma ? 1 : 0));   // source picture width
  int32_t src_height = (pic->height >> (chroma ? 1 : 0)); // source picture height
  uint8_t *src_pic = (!chroma) ? pic->y_data : ((chroma == 1) ? pic->u_data : pic->v_data); // input picture pointer
  int16_t scu_width = LCU_WIDTH >> (MAX_DEPTH + (chroma ? 1 : 0)); // Smallest Coding Unit width
  uint8_t *src_shifted = &src_pic[x_ctb * scu_width + (y_ctb * scu_width) * src_width]; // input picture pointer shifted to start from the left-top corner of the current block
  int32_t width_in_scu = pic->width_in_lcu << MAX_DEPTH; // picture width in SCU

  // Fill left column
  if (x_ctb) {
    // Loop SCU's
    for (left_col = 1; left_col < outwidth / scu_width; left_col++) {
      // If over the picture height or block not yet searched, stop
      if ((y_ctb + left_col) * scu_width >= src_height
          || pic->cu_array[MAX_DEPTH][x_ctb - 1 + (y_ctb + left_col) * width_in_scu].type == CU_NOTSET) {
        break;
      }
    }

    // Copy the pixels to output
    for (i = 0; i < left_col * scu_width - 1; i++) {
      dst[(i + 1) * dststride] = src_shifted[i * src_width - 1];
    }

    // if the loop was not completed, extrapolate the last pixel pushed to output
    if (left_col != outwidth / scu_width) {
      val = src_shifted[(left_col * scu_width - 1) * src_width - 1];
      for (i = (left_col * scu_width); i < outwidth; i++) {
        dst[i * dststride] = val;
      }
    }
  } else { // If left column not available, copy from toprow or use the default predictor
    val = y_ctb ? src_shifted[-src_width] : dc_val;
    for (i = 0; i < outwidth; i++) {
      dst[i * dststride] = val;
    }
  }

  if (y_ctb) {
    // Loop top SCU's
    for (top_row = 1; top_row < outwidth / scu_width; top_row++) {
      if ((x_ctb + top_row) * scu_width >= src_width
          || pic->cu_array[MAX_DEPTH][x_ctb + top_row + (y_ctb - 1) * width_in_scu].type
              == CU_NOTSET) {
        break;
      }
    }

    for (i = 0; i < top_row * scu_width - 1; i++) {
      dst[i + 1] = src_shifted[i - src_width];
    }

    if (top_row != outwidth / scu_width) {
      val = src_shifted[(top_row * scu_width) - src_width - 1];
      for (i = (top_row * scu_width); i < outwidth; i++) {
        dst[i] = val;
      }
    }
  } else {
    val = x_ctb ? src_shifted[-1] : dc_val;
    for (i = 1; i < outwidth; i++) {
      dst[i] = val;
    }
  }
  // Topleft corner
  dst[0] = (x_ctb && y_ctb) ? src_shifted[-src_width - 1] : dst[dststride];

}

/**
 * \brief
 */
void search_tree(encoder_control *encoder, 
                 uint16_t x_ctb, uint16_t y_ctb, uint8_t depth)
{
  uint8_t border_x = ((encoder->in.width) < (x_ctb * (LCU_WIDTH >> MAX_DEPTH) + (LCU_WIDTH >> depth))) ? 1 : 0;
  uint8_t border_y = ((encoder->in.height) < (y_ctb * (LCU_WIDTH >> MAX_DEPTH) + (LCU_WIDTH >> depth))) ? 1 : 0;
  uint8_t border_split_x = ((encoder->in.width) < ((x_ctb + 1) * (LCU_WIDTH >> MAX_DEPTH) + (LCU_WIDTH >> (depth + 1)))) ? 0 : 1;
  uint8_t border_split_y = ((encoder->in.height) < ((y_ctb + 1) * (LCU_WIDTH >> MAX_DEPTH) + (LCU_WIDTH >> (depth + 1)))) ? 0 : 1;
  uint8_t border = border_x | border_y; // are we in any border CU
  cu_info *cur_cu = &encoder->in.cur_pic->cu_array[depth][x_ctb + y_ctb * (encoder->in.width_in_lcu << MAX_DEPTH)];

  cur_cu->intra.cost = 0xffffffff;
  cur_cu->inter.cost = 0xffffffff;

  // Force split on border
  if (depth != MAX_DEPTH) {
    if (border) {
      // Split blocks and remember to change x and y block positions
      uint8_t change = 1 << (MAX_DEPTH - 1 - depth);
      search_tree(encoder, x_ctb, y_ctb, depth + 1);
      if (!border_x || border_split_x) {
        search_tree(encoder, x_ctb + change, y_ctb, depth + 1);
      }
      if (!border_y || border_split_y) {
        search_tree(encoder, x_ctb, y_ctb + change, depth + 1);
      }
      if (!border || (border_split_x && border_split_y)) {
        search_tree(encoder, x_ctb + change, y_ctb + change, depth + 1);
      }
      // We don't need to do anything else here
      return;
    }
  }

  // INTER SEARCH
  if (depth >= MIN_INTER_SEARCH_DEPTH && depth <= MAX_INTER_SEARCH_DEPTH
      && encoder->in.cur_pic->slicetype != SLICE_I) {
    // Motion estimation on P-frame
    if (encoder->in.cur_pic->slicetype != SLICE_B) {

    }

    {
      picture *cur_pic = encoder->in.cur_pic;
      picture *ref_pic = encoder->ref->pics[0];
      unsigned width_in_scu = NO_SCU_IN_LCU(ref_pic->width_in_lcu);
      cu_info *ref_cu = &ref_pic->cu_array[MAX_DEPTH][y_ctb * width_in_scu + x_ctb];
      int x = x_ctb * CU_MIN_SIZE_PIXELS;
      int y = y_ctb * CU_MIN_SIZE_PIXELS;
      uint8_t *cur_data = &cur_pic->y_data[(y * cur_pic->width) + x];
      
      int start_x = 0;
      int start_y = 0;
      // Convert from sub-pixel accuracy.
      if (ref_cu->type == CU_INTER) {
        start_x = ref_cu->inter.mv[0] >> 2;
        start_y = ref_cu->inter.mv[1] >> 2;
      }

      hexagon_search(cur_pic, ref_pic, 
                     cur_cu, x, y, 
                     start_x, start_y, depth);
    }

    cur_cu->type = CU_INTER;
    cur_cu->inter.mv_dir = 1;
  }

  // INTRA SEARCH
  if (depth >= MIN_INTRA_SEARCH_DEPTH && depth <= MAX_INTRA_SEARCH_DEPTH
      && (encoder->in.cur_pic->slicetype == SLICE_I || USE_INTRA_IN_P)) {
    int x = 0, y = 0;
    uint8_t *base = &encoder->in.cur_pic->y_data[x_ctb * (LCU_WIDTH >> (MAX_DEPTH)) + (y_ctb * (LCU_WIDTH >> (MAX_DEPTH))) * encoder->in.width];
    uint32_t width = LCU_WIDTH >> depth;

    // INTRAPREDICTION
    int16_t pred[LCU_WIDTH * LCU_WIDTH + 1];
    int16_t rec[(LCU_WIDTH * 2 + 8) * (LCU_WIDTH * 2 + 8)];
    int16_t *recShift = &rec[(LCU_WIDTH >> (depth)) * 2 + 8 + 1];

    //int16_t *pred = (int16_t*)malloc(LCU_WIDTH*LCU_WIDTH*sizeof(int16_t));
    //int16_t *rec = (int16_t*)malloc((LCU_WIDTH*2+8)*(LCU_WIDTH*2+8)*sizeof(int16_t));

    // Build reconstructed block to use in prediction with extrapolated borders
    search_buildReferenceBorder(encoder->in.cur_pic, x_ctb, y_ctb,
        (LCU_WIDTH >> (depth)) * 2 + 8, rec, (LCU_WIDTH >> (depth)) * 2 + 8, 0);
    cur_cu->intra.mode = (uint8_t) intra_prediction(encoder->in.cur_pic->y_data,
        encoder->in.width, recShift, (LCU_WIDTH >> (depth)) * 2 + 8,
        x_ctb * (LCU_WIDTH >> (MAX_DEPTH)), y_ctb * (LCU_WIDTH >> (MAX_DEPTH)),
        width, pred, width, &cur_cu->intra.cost);
    //free(pred);
    //free(rec);
  }

  // Split and search to max_depth
  if (depth < MAX_INTRA_SEARCH_DEPTH && depth < MAX_INTER_SEARCH_DEPTH) {
    // Split blocks and remember to change x and y block positions
    uint8_t change = 1 << (MAX_DEPTH - 1 - depth);
    search_tree(encoder, x_ctb,          y_ctb,          depth + 1);
    search_tree(encoder, x_ctb + change, y_ctb,          depth + 1);
    search_tree(encoder, x_ctb,          y_ctb + change, depth + 1);
    search_tree(encoder, x_ctb + change, y_ctb + change, depth + 1);
  }
}

/**
 * \brief
 */
uint32_t search_best_mode(encoder_control *encoder, 
                          uint16_t x_ctb, uint16_t y_ctb, uint8_t depth)
{
  cu_info *cur_cu = &encoder->in.cur_pic->cu_array[depth][x_ctb
      + y_ctb * (encoder->in.width_in_lcu << MAX_DEPTH)];
  uint32_t best_intra_cost = cur_cu->intra.cost;
  uint32_t best_inter_cost = cur_cu->inter.cost;
  uint32_t best_cost = 0;
  uint32_t cost = 0;
  uint32_t lambdaCost = (4 * g_lambda_cost[encoder->QP]) << 4; //<<5; //TODO: Correct cost calculation

  // Split and search to max_depth
  if (depth != MAX_INTRA_SEARCH_DEPTH) {
    // Split blocks and remember to change x and y block positions
    uint8_t change = 1 << (MAX_DEPTH - 1 - depth);
    cost =  search_best_mode(encoder, x_ctb,          y_ctb,          depth + 1);
    cost += search_best_mode(encoder, x_ctb + change, y_ctb,          depth + 1);
    cost += search_best_mode(encoder, x_ctb,          y_ctb + change, depth + 1);
    cost += search_best_mode(encoder, x_ctb + change, y_ctb + change, depth + 1);

    // We split if the cost is better (0 cost -> not checked)
    if ( (encoder->in.cur_pic->slicetype == SLICE_I && depth < MIN_INTRA_SEARCH_DEPTH) ||
        (cost != 0 
        && (best_intra_cost != 0 && cost + lambdaCost < best_intra_cost)
        && (best_inter_cost != 0
            && cost + lambdaCost < best_inter_cost
            && encoder->in.cur_pic->slicetype != SLICE_I)))
    {
      // Set split to 1
      best_cost = cost + lambdaCost;
    } else if (best_inter_cost != 0 // Else, check if inter cost is smaller or the same as intra 
        && (best_inter_cost <= best_intra_cost || best_intra_cost == 0)
        && encoder->in.cur_pic->slicetype != SLICE_I)
    {
      // Set split to 0 and mode to inter.mode
      inter_set_block(encoder->in.cur_pic, x_ctb, y_ctb, depth, cur_cu);
      best_cost = best_inter_cost;
    } else { // Else, dont split and recursively set block mode
      // Set split to 0 and mode to intra.mode
      intra_set_block_mode(encoder->in.cur_pic, x_ctb, y_ctb, depth,
          cur_cu->intra.mode);
      best_cost = best_intra_cost;
    }
  } else if (best_inter_cost != 0
             && (best_inter_cost <= best_intra_cost || best_intra_cost == 0)
             && encoder->in.cur_pic->slicetype != SLICE_I)
  {
    // Set split to 0 and mode to inter.mode
    inter_set_block(encoder->in.cur_pic, x_ctb, y_ctb, depth, cur_cu);
    best_cost = best_inter_cost;
  } else {
    // Set split to 0 and mode to intra.mode
    intra_set_block_mode(encoder->in.cur_pic, x_ctb, y_ctb, depth,
        cur_cu->intra.mode);
    best_cost = best_intra_cost;
  }

  return best_cost;
}

/**
 * \brief
 */
void search_slice_data(encoder_control *encoder)
{
  int16_t x_lcu, y_lcu;
  FILE *fp = 0, *fp2 = 0;

  if (RENDER_CU) {
    fp = open_cu_file("cu_search.html");
    fp2 = open_cu_file("cu_best.html");
  }

  // Loop through every LCU in the slice
  for (y_lcu = 0; y_lcu < encoder->in.height_in_lcu; y_lcu++) {
    for (x_lcu = 0; x_lcu < encoder->in.width_in_lcu; x_lcu++) {
      uint8_t depth = 0;
      // Recursive function for looping through all the sub-blocks
      search_tree(encoder, x_lcu << MAX_DEPTH, y_lcu << MAX_DEPTH, depth);
      if (RENDER_CU) {
        render_cu_file(encoder, encoder->in.cur_pic, depth, x_lcu << MAX_DEPTH, y_lcu << MAX_DEPTH, fp);
      }

      // Decide actual coding modes
      search_best_mode(encoder, x_lcu << MAX_DEPTH, y_lcu << MAX_DEPTH, depth);
      if (RENDER_CU) {
        render_cu_file(encoder, encoder->in.cur_pic, depth, x_lcu << MAX_DEPTH, y_lcu << MAX_DEPTH, fp2);
      }
    }
  }

  if (RENDER_CU && fp) {
    close_cu_file(fp);
    fp = 0;
  }
  if (RENDER_CU && fp2) {
    close_cu_file(fp2);
    fp2 = 0;
  }
}