/* * Copyright (c) 2010 The VP8 project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license and patent * grant that can be found in the LICENSE file in the root of the source * tree. All contributing project authors may be found in the AUTHORS * file in the root of the source tree. */ #include "vpx_ports/config.h" #include "loopfilter.h" #include "onyxc_int.h" typedef unsigned char uc; prototype_loopfilter(vp8_loop_filter_horizontal_edge_c); prototype_loopfilter(vp8_loop_filter_vertical_edge_c); prototype_loopfilter(vp8_mbloop_filter_horizontal_edge_c); prototype_loopfilter(vp8_mbloop_filter_vertical_edge_c); prototype_loopfilter(vp8_loop_filter_simple_horizontal_edge_c); prototype_loopfilter(vp8_loop_filter_simple_vertical_edge_c); // Horizontal MB filtering void vp8_loop_filter_mbh_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) simpler_lpf; vp8_mbloop_filter_horizontal_edge_c(y_ptr, y_stride, lfi->mbflim, lfi->lim, lfi->mbthr, 2); if (u_ptr) vp8_mbloop_filter_horizontal_edge_c(u_ptr, uv_stride, lfi->uvmbflim, lfi->uvlim, lfi->uvmbthr, 1); if (v_ptr) vp8_mbloop_filter_horizontal_edge_c(v_ptr, uv_stride, lfi->uvmbflim, lfi->uvlim, lfi->uvmbthr, 1); } void vp8_loop_filter_mbhs_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) u_ptr; (void) v_ptr; (void) uv_stride; (void) simpler_lpf; vp8_loop_filter_simple_horizontal_edge_c(y_ptr, y_stride, lfi->mbflim, lfi->lim, lfi->mbthr, 2); } // Vertical MB Filtering void vp8_loop_filter_mbv_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) simpler_lpf; vp8_mbloop_filter_vertical_edge_c(y_ptr, y_stride, lfi->mbflim, lfi->lim, lfi->mbthr, 2); if (u_ptr) vp8_mbloop_filter_vertical_edge_c(u_ptr, uv_stride, lfi->uvmbflim, lfi->uvlim, lfi->uvmbthr, 1); if (v_ptr) vp8_mbloop_filter_vertical_edge_c(v_ptr, uv_stride, lfi->uvmbflim, lfi->uvlim, lfi->uvmbthr, 1); } void vp8_loop_filter_mbvs_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) u_ptr; (void) v_ptr; (void) uv_stride; (void) simpler_lpf; vp8_loop_filter_simple_vertical_edge_c(y_ptr, y_stride, lfi->mbflim, lfi->lim, lfi->mbthr, 2); } // Horizontal B Filtering void vp8_loop_filter_bh_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) simpler_lpf; vp8_loop_filter_horizontal_edge_c(y_ptr + 4 * y_stride, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_horizontal_edge_c(y_ptr + 8 * y_stride, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_horizontal_edge_c(y_ptr + 12 * y_stride, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); if (u_ptr) vp8_loop_filter_horizontal_edge_c(u_ptr + 4 * uv_stride, uv_stride, lfi->uvflim, lfi->uvlim, lfi->uvthr, 1); if (v_ptr) vp8_loop_filter_horizontal_edge_c(v_ptr + 4 * uv_stride, uv_stride, lfi->uvflim, lfi->uvlim, lfi->uvthr, 1); } void vp8_loop_filter_bhs_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) u_ptr; (void) v_ptr; (void) uv_stride; (void) simpler_lpf; vp8_loop_filter_simple_horizontal_edge_c(y_ptr + 4 * y_stride, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_simple_horizontal_edge_c(y_ptr + 8 * y_stride, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_simple_horizontal_edge_c(y_ptr + 12 * y_stride, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); } // Vertical B Filtering void vp8_loop_filter_bv_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) simpler_lpf; vp8_loop_filter_vertical_edge_c(y_ptr + 4, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_vertical_edge_c(y_ptr + 8, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_vertical_edge_c(y_ptr + 12, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); if (u_ptr) vp8_loop_filter_vertical_edge_c(u_ptr + 4, uv_stride, lfi->uvflim, lfi->uvlim, lfi->uvthr, 1); if (v_ptr) vp8_loop_filter_vertical_edge_c(v_ptr + 4, uv_stride, lfi->uvflim, lfi->uvlim, lfi->uvthr, 1); } void vp8_loop_filter_bvs_c(unsigned char *y_ptr, unsigned char *u_ptr, unsigned char *v_ptr, int y_stride, int uv_stride, loop_filter_info *lfi, int simpler_lpf) { (void) u_ptr; (void) v_ptr; (void) uv_stride; (void) simpler_lpf; vp8_loop_filter_simple_vertical_edge_c(y_ptr + 4, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_simple_vertical_edge_c(y_ptr + 8, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); vp8_loop_filter_simple_vertical_edge_c(y_ptr + 12, y_stride, lfi->flim, lfi->lim, lfi->thr, 2); } void vp8_init_loop_filter(VP8_COMMON *cm) { loop_filter_info *lfi = cm->lf_info; LOOPFILTERTYPE lft = cm->filter_type; int sharpness_lvl = cm->sharpness_level; int frame_type = cm->frame_type; int i, j; int block_inside_limit = 0; int HEVThresh; const int yhedge_boost = 2; const int uvhedge_boost = 2; // For each possible value for the loop filter fill out a "loop_filter_info" entry. for (i = 0; i <= MAX_LOOP_FILTER; i++) { int filt_lvl = i; if (frame_type == KEY_FRAME) { if (filt_lvl >= 40) HEVThresh = 2; else if (filt_lvl >= 15) HEVThresh = 1; else HEVThresh = 0; } else { if (filt_lvl >= 40) HEVThresh = 3; else if (filt_lvl >= 20) HEVThresh = 2; else if (filt_lvl >= 15) HEVThresh = 1; else HEVThresh = 0; } // Set loop filter paramaeters that control sharpness. block_inside_limit = filt_lvl >> (sharpness_lvl > 0); block_inside_limit = block_inside_limit >> (sharpness_lvl > 4); if (sharpness_lvl > 0) { if (block_inside_limit > (9 - sharpness_lvl)) block_inside_limit = (9 - sharpness_lvl); } if (block_inside_limit < 1) block_inside_limit = 1; for (j = 0; j < 16; j++) { lfi[i].lim[j] = block_inside_limit; lfi[i].mbflim[j] = filt_lvl + yhedge_boost; lfi[i].mbthr[j] = HEVThresh; lfi[i].flim[j] = filt_lvl; lfi[i].thr[j] = HEVThresh; lfi[i].uvlim[j] = block_inside_limit; lfi[i].uvmbflim[j] = filt_lvl + uvhedge_boost; lfi[i].uvmbthr[j] = HEVThresh; lfi[i].uvflim[j] = filt_lvl; lfi[i].uvthr[j] = HEVThresh; } } // Set up the function pointers depending on the type of loop filtering selected if (lft == NORMAL_LOOPFILTER) { cm->lf_mbv = LF_INVOKE(&cm->rtcd.loopfilter, normal_mb_v); cm->lf_bv = LF_INVOKE(&cm->rtcd.loopfilter, normal_b_v); cm->lf_mbh = LF_INVOKE(&cm->rtcd.loopfilter, normal_mb_h); cm->lf_bh = LF_INVOKE(&cm->rtcd.loopfilter, normal_b_h); } else { cm->lf_mbv = LF_INVOKE(&cm->rtcd.loopfilter, simple_mb_v); cm->lf_bv = LF_INVOKE(&cm->rtcd.loopfilter, simple_b_v); cm->lf_mbh = LF_INVOKE(&cm->rtcd.loopfilter, simple_mb_h); cm->lf_bh = LF_INVOKE(&cm->rtcd.loopfilter, simple_b_h); } } // Put vp8_init_loop_filter() in vp8dx_create_decompressor(). Only call vp8_frame_init_loop_filter() while decoding // each frame. Check last_frame_type to skip the function most of times. void vp8_frame_init_loop_filter(loop_filter_info *lfi, int frame_type) { int HEVThresh; int i, j; // For each possible value for the loop filter fill out a "loop_filter_info" entry. for (i = 0; i <= MAX_LOOP_FILTER; i++) { int filt_lvl = i; if (frame_type == KEY_FRAME) { if (filt_lvl >= 40) HEVThresh = 2; else if (filt_lvl >= 15) HEVThresh = 1; else HEVThresh = 0; } else { if (filt_lvl >= 40) HEVThresh = 3; else if (filt_lvl >= 20) HEVThresh = 2; else if (filt_lvl >= 15) HEVThresh = 1; else HEVThresh = 0; } for (j = 0; j < 16; j++) { //lfi[i].lim[j] = block_inside_limit; //lfi[i].mbflim[j] = filt_lvl+yhedge_boost; lfi[i].mbthr[j] = HEVThresh; //lfi[i].flim[j] = filt_lvl; lfi[i].thr[j] = HEVThresh; //lfi[i].uvlim[j] = block_inside_limit; //lfi[i].uvmbflim[j] = filt_lvl+uvhedge_boost; lfi[i].uvmbthr[j] = HEVThresh; //lfi[i].uvflim[j] = filt_lvl; lfi[i].uvthr[j] = HEVThresh; } } } void vp8_adjust_mb_lf_value(MACROBLOCKD *mbd, int *filter_level) { MB_MODE_INFO *mbmi = &mbd->mode_info_context->mbmi; if (mbd->mode_ref_lf_delta_enabled) { // Aplly delta for reference frame *filter_level += mbd->ref_lf_deltas[mbmi->ref_frame]; // Apply delta for mode if (mbmi->ref_frame == INTRA_FRAME) { // Only the split mode BPRED has a further special case if (mbmi->mode == B_PRED) *filter_level += mbd->mode_lf_deltas[0]; } else { // Zero motion mode if (mbmi->mode == ZEROMV) *filter_level += mbd->mode_lf_deltas[1]; // Split MB motion mode else if (mbmi->mode == SPLITMV) *filter_level += mbd->mode_lf_deltas[3]; // All other inter motion modes (Nearest, Near, New) else *filter_level += mbd->mode_lf_deltas[2]; } // Range check if (*filter_level > MAX_LOOP_FILTER) *filter_level = MAX_LOOP_FILTER; else if (*filter_level < 0) *filter_level = 0; } } void vp8_loop_filter_frame ( VP8_COMMON *cm, MACROBLOCKD *mbd, int default_filt_lvl ) { YV12_BUFFER_CONFIG *post = cm->frame_to_show; loop_filter_info *lfi = cm->lf_info; int frame_type = cm->frame_type; int mb_row; int mb_col; int baseline_filter_level[MAX_MB_SEGMENTS]; int filter_level; int alt_flt_enabled = mbd->segmentation_enabled; int i; unsigned char *y_ptr, *u_ptr, *v_ptr; mbd->mode_info_context = cm->mi; // Point at base of Mb MODE_INFO list // Note the baseline filter values for each segment if (alt_flt_enabled) { for (i = 0; i < MAX_MB_SEGMENTS; i++) { // Abs value if (mbd->mb_segement_abs_delta == SEGMENT_ABSDATA) baseline_filter_level[i] = mbd->segment_feature_data[MB_LVL_ALT_LF][i]; // Delta Value else { baseline_filter_level[i] = default_filt_lvl + mbd->segment_feature_data[MB_LVL_ALT_LF][i]; baseline_filter_level[i] = (baseline_filter_level[i] >= 0) ? ((baseline_filter_level[i] <= MAX_LOOP_FILTER) ? baseline_filter_level[i] : MAX_LOOP_FILTER) : 0; // Clamp to valid range } } } else { for (i = 0; i < MAX_MB_SEGMENTS; i++) baseline_filter_level[i] = default_filt_lvl; } // Initialize the loop filter for this frame. if ((cm->last_filter_type != cm->filter_type) || (cm->last_sharpness_level != cm->sharpness_level)) vp8_init_loop_filter(cm); else if (frame_type != cm->last_frame_type) vp8_frame_init_loop_filter(lfi, frame_type); // Set up the buffer pointers y_ptr = post->y_buffer; u_ptr = post->u_buffer; v_ptr = post->v_buffer; // vp8_filter each macro block for (mb_row = 0; mb_row < cm->mb_rows; mb_row++) { for (mb_col = 0; mb_col < cm->mb_cols; mb_col++) { int Segment = (alt_flt_enabled) ? mbd->mode_info_context->mbmi.segment_id : 0; filter_level = baseline_filter_level[Segment]; // Distance of Mb to the various image edges. // These specified to 8th pel as they are always compared to values that are in 1/8th pel units // Apply any context driven MB level adjustment vp8_adjust_mb_lf_value(mbd, &filter_level); if (filter_level) { if (mb_col > 0) cm->lf_mbv(y_ptr, u_ptr, v_ptr, post->y_stride, post->uv_stride, &lfi[filter_level], cm->simpler_lpf); if (mbd->mode_info_context->mbmi.dc_diff > 0) cm->lf_bv(y_ptr, u_ptr, v_ptr, post->y_stride, post->uv_stride, &lfi[filter_level], cm->simpler_lpf); // don't apply across umv border if (mb_row > 0) cm->lf_mbh(y_ptr, u_ptr, v_ptr, post->y_stride, post->uv_stride, &lfi[filter_level], cm->simpler_lpf); if (mbd->mode_info_context->mbmi.dc_diff > 0) cm->lf_bh(y_ptr, u_ptr, v_ptr, post->y_stride, post->uv_stride, &lfi[filter_level], cm->simpler_lpf); } y_ptr += 16; u_ptr += 8; v_ptr += 8; mbd->mode_info_context++; // step to next MB } y_ptr += post->y_stride * 16 - post->y_width; u_ptr += post->uv_stride * 8 - post->uv_width; v_ptr += post->uv_stride * 8 - post->uv_width; mbd->mode_info_context++; // Skip border mb } } void vp8_loop_filter_frame_yonly ( VP8_COMMON *cm, MACROBLOCKD *mbd, int default_filt_lvl, int sharpness_lvl ) { YV12_BUFFER_CONFIG *post = cm->frame_to_show; int i; unsigned char *y_ptr; int mb_row; int mb_col; loop_filter_info *lfi = cm->lf_info; int baseline_filter_level[MAX_MB_SEGMENTS]; int filter_level; int alt_flt_enabled = mbd->segmentation_enabled; int frame_type = cm->frame_type; (void) sharpness_lvl; //MODE_INFO * this_mb_mode_info = cm->mi; // Point at base of Mb MODE_INFO list mbd->mode_info_context = cm->mi; // Point at base of Mb MODE_INFO list // Note the baseline filter values for each segment if (alt_flt_enabled) { for (i = 0; i < MAX_MB_SEGMENTS; i++) { // Abs value if (mbd->mb_segement_abs_delta == SEGMENT_ABSDATA) baseline_filter_level[i] = mbd->segment_feature_data[MB_LVL_ALT_LF][i]; // Delta Value else { baseline_filter_level[i] = default_filt_lvl + mbd->segment_feature_data[MB_LVL_ALT_LF][i]; baseline_filter_level[i] = (baseline_filter_level[i] >= 0) ? ((baseline_filter_level[i] <= MAX_LOOP_FILTER) ? baseline_filter_level[i] : MAX_LOOP_FILTER) : 0; // Clamp to valid range } } } else { for (i = 0; i < MAX_MB_SEGMENTS; i++) baseline_filter_level[i] = default_filt_lvl; } // Initialize the loop filter for this frame. if ((cm->last_filter_type != cm->filter_type) || (cm->last_sharpness_level != cm->sharpness_level)) vp8_init_loop_filter(cm); else if (frame_type != cm->last_frame_type) vp8_frame_init_loop_filter(lfi, frame_type); // Set up the buffer pointers y_ptr = post->y_buffer; // vp8_filter each macro block for (mb_row = 0; mb_row < cm->mb_rows; mb_row++) { for (mb_col = 0; mb_col < cm->mb_cols; mb_col++) { int Segment = (alt_flt_enabled) ? mbd->mode_info_context->mbmi.segment_id : 0; filter_level = baseline_filter_level[Segment]; // Apply any context driven MB level adjustment vp8_adjust_mb_lf_value(mbd, &filter_level); if (filter_level) { if (mb_col > 0) cm->lf_mbv(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); if (mbd->mode_info_context->mbmi.dc_diff > 0) cm->lf_bv(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); // don't apply across umv border if (mb_row > 0) cm->lf_mbh(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); if (mbd->mode_info_context->mbmi.dc_diff > 0) cm->lf_bh(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); } y_ptr += 16; mbd->mode_info_context ++; // step to next MB } y_ptr += post->y_stride * 16 - post->y_width; mbd->mode_info_context ++; // Skip border mb } } void vp8_loop_filter_partial_frame ( VP8_COMMON *cm, MACROBLOCKD *mbd, int default_filt_lvl, int sharpness_lvl, int Fraction ) { YV12_BUFFER_CONFIG *post = cm->frame_to_show; int i; unsigned char *y_ptr; int mb_row; int mb_col; //int mb_rows = post->y_height >> 4; int mb_cols = post->y_width >> 4; int linestocopy; loop_filter_info *lfi = cm->lf_info; int baseline_filter_level[MAX_MB_SEGMENTS]; int filter_level; int alt_flt_enabled = mbd->segmentation_enabled; int frame_type = cm->frame_type; (void) sharpness_lvl; //MODE_INFO * this_mb_mode_info = cm->mi + (post->y_height>>5) * (mb_cols + 1); // Point at base of Mb MODE_INFO list mbd->mode_info_context = cm->mi + (post->y_height >> 5) * (mb_cols + 1); // Point at base of Mb MODE_INFO list linestocopy = (post->y_height >> (4 + Fraction)); if (linestocopy < 1) linestocopy = 1; linestocopy <<= 4; // Note the baseline filter values for each segment if (alt_flt_enabled) { for (i = 0; i < MAX_MB_SEGMENTS; i++) { // Abs value if (mbd->mb_segement_abs_delta == SEGMENT_ABSDATA) baseline_filter_level[i] = mbd->segment_feature_data[MB_LVL_ALT_LF][i]; // Delta Value else { baseline_filter_level[i] = default_filt_lvl + mbd->segment_feature_data[MB_LVL_ALT_LF][i]; baseline_filter_level[i] = (baseline_filter_level[i] >= 0) ? ((baseline_filter_level[i] <= MAX_LOOP_FILTER) ? baseline_filter_level[i] : MAX_LOOP_FILTER) : 0; // Clamp to valid range } } } else { for (i = 0; i < MAX_MB_SEGMENTS; i++) baseline_filter_level[i] = default_filt_lvl; } // Initialize the loop filter for this frame. if ((cm->last_filter_type != cm->filter_type) || (cm->last_sharpness_level != cm->sharpness_level)) vp8_init_loop_filter(cm); else if (frame_type != cm->last_frame_type) vp8_frame_init_loop_filter(lfi, frame_type); // Set up the buffer pointers y_ptr = post->y_buffer + (post->y_height >> 5) * 16 * post->y_stride; // vp8_filter each macro block for (mb_row = 0; mb_row<(linestocopy >> 4); mb_row++) { for (mb_col = 0; mb_col < mb_cols; mb_col++) { int Segment = (alt_flt_enabled) ? mbd->mode_info_context->mbmi.segment_id : 0; filter_level = baseline_filter_level[Segment]; if (filter_level) { if (mb_col > 0) cm->lf_mbv(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); if (mbd->mode_info_context->mbmi.dc_diff > 0) cm->lf_bv(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); cm->lf_mbh(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); if (mbd->mode_info_context->mbmi.dc_diff > 0) cm->lf_bh(y_ptr, 0, 0, post->y_stride, 0, &lfi[filter_level], 0); } y_ptr += 16; mbd->mode_info_context += 1; // step to next MB } y_ptr += post->y_stride * 16 - post->y_width; mbd->mode_info_context += 1; // Skip border mb } }