/*****************************************************************************
* slicetype.c: lookahead analysis
*****************************************************************************
- * Copyright (C) 2005-2011 x264 project
+ * Copyright (C) 2005-2015 x264 project
*
* Authors: Fiona Glaser <fiona@x264.com>
* Loren Merritt <lorenm@u.washington.edu>
x264_frame_t **frames, int p0, int p1, int b,
int b_intra_penalty );
+void x264_weights_analyse( x264_t *h, x264_frame_t *fenc, x264_frame_t *ref, int b_lookahead );
+
+#if HAVE_OPENCL
+int x264_opencl_lowres_init( x264_t *h, x264_frame_t *fenc, int lambda );
+int x264_opencl_motionsearch( x264_t *h, x264_frame_t **frames, int b, int ref, int b_islist1, int lambda, const x264_weight_t *w );
+int x264_opencl_finalize_cost( x264_t *h, int lambda, x264_frame_t **frames, int p0, int p1, int b, int dist_scale_factor );
+int x264_opencl_precalculate_frame_cost( x264_t *h, x264_frame_t **frames, int lambda, int p0, int p1, int b );
+void x264_opencl_flush( x264_t *h );
+void x264_opencl_slicetype_prep( x264_t *h, x264_frame_t **frames, int num_frames, int lambda );
+void x264_opencl_slicetype_end( x264_t *h );
+#endif
+
static void x264_lowres_context_init( x264_t *h, x264_mb_analysis_t *a )
{
a->i_qp = X264_LOOKAHEAD_QP;
w->i_offset = offset;
w->i_denom = 7;
w->i_scale = weight_nonh264;
- while( w->i_denom > 0 && (w->i_scale > 127 || !(w->i_scale & 1)) )
+ while( w->i_denom > 0 && (w->i_scale > 127) )
{
w->i_denom--;
w->i_scale >>= 1;
return ref->lowres[0];
}
-/* How data is organized for chroma weightp:
+/* How data is organized for 4:2:0/4:2:2 chroma weightp:
* [U: ref] [U: fenc]
* [V: ref] [V: fenc]
* fenc = ref + offset
- * v = u + stride * chroma height
- * We'll need more room if we do 4:2:2 or 4:4:4. */
+ * v = u + stride * chroma height */
static NOINLINE void x264_weight_cost_init_chroma( x264_t *h, x264_frame_t *fenc, x264_frame_t *ref, pixel *dstu, pixel *dstv )
{
int i_offset = i_stride / 2;
int i_lines = fenc->i_lines[1];
int i_width = fenc->i_width[1];
- int cw = h->mb.i_mb_width << 3;
- int ch = h->mb.i_mb_height << 3;
+ int v_shift = CHROMA_V_SHIFT;
+ int cw = 8*h->mb.i_mb_width;
+ int ch = 16*h->mb.i_mb_height >> v_shift;
+ int height = 16 >> v_shift;
if( fenc->lowres_mvs[0][ref0_distance][0][0] != 0x7FFF )
{
- for( int y = 0, mb_xy = 0, pel_offset_y = 0; y < i_lines; y += 8, pel_offset_y = y*i_stride )
+ x264_frame_expand_border_chroma( h, ref, 1 );
+ for( int y = 0, mb_xy = 0, pel_offset_y = 0; y < i_lines; y += height, pel_offset_y = y*i_stride )
for( int x = 0, pel_offset_x = 0; x < i_width; x += 8, mb_xy++, pel_offset_x += 8 )
{
pixel *pixu = dstu + pel_offset_y + pel_offset_x;
pixel *pixv = dstv + pel_offset_y + pel_offset_x;
- pixel *src1 = ref->plane[1] + pel_offset_y + pel_offset_x*2; /* NV12 */
+ pixel *src1 = ref->plane[1] + pel_offset_y + pel_offset_x*2; /* NV12/NV16 */
int mvx = fenc->lowres_mvs[0][ref0_distance][mb_xy][0];
int mvy = fenc->lowres_mvs[0][ref0_distance][mb_xy][1];
- h->mc.mc_chroma( pixu, pixv, i_stride, src1, i_stride, mvx, mvy, 8, 8 );
+ h->mc.mc_chroma( pixu, pixv, i_stride, src1, i_stride, mvx, 2*mvy>>v_shift, 8, height );
}
}
else
if( fenc->lowres_mvs[0][ref0_distance][0][0] != 0x7FFF )
{
+ x264_frame_expand_border_chroma( h, ref, p );
for( int y = 0, mb_xy = 0, pel_offset_y = 0; y < i_lines; y += 16, pel_offset_y = y*i_stride )
for( int x = 0, pel_offset_x = 0; x < i_width; x += 16, mb_xy++, pel_offset_x += 16 )
{
pixel *pix = dst + pel_offset_y + pel_offset_x;
- pixel *src = fenc->plane[p] + pel_offset_y + pel_offset_x;
+ pixel *src = ref->plane[p] + pel_offset_y + pel_offset_x;
int mvx = fenc->lowres_mvs[0][ref0_distance][mb_xy][0] / 2;
int mvy = fenc->lowres_mvs[0][ref0_distance][mb_xy][1] / 2;
/* We don't want to calculate hpels for fenc frames, so we round the motion
return dst;
}
x264_emms();
- return fenc->plane[p];
+ return ref->plane[p];
}
static int x264_weight_slice_header_cost( x264_t *h, x264_weight_t *w, int b_chroma )
{
unsigned int cost = 0;
int i_stride = fenc->i_stride[1];
- int i_offset = i_stride / 2;
int i_lines = fenc->i_lines[1];
int i_width = fenc->i_width[1];
- pixel *src = ref + i_offset;
- ALIGNED_ARRAY_16( pixel, buf, [8*8] );
+ pixel *src = ref + (i_stride >> 1);
+ ALIGNED_ARRAY_16( pixel, buf, [8*16] );
int pixoff = 0;
- ALIGNED_16( static pixel flat[8] ) = {0};
+ int height = 16 >> CHROMA_V_SHIFT;
if( w )
{
- for( int y = 0; y < i_lines; y += 8, pixoff = y*i_stride )
+ for( int y = 0; y < i_lines; y += height, pixoff = y*i_stride )
for( int x = 0; x < i_width; x += 8, pixoff += 8 )
{
- w->weightfn[8>>2]( buf, 8, &ref[pixoff], i_stride, w, 8 );
+ w->weightfn[8>>2]( buf, 8, &ref[pixoff], i_stride, w, height );
/* The naive and seemingly sensible algorithm is to use mbcmp as in luma.
* But testing shows that for chroma the DC coefficient is by far the most
* important part of the coding cost. Thus a more useful chroma weight is
* obtained by comparing each block's DC coefficient instead of the actual
- * pixels.
- *
- * FIXME: add a (faster) asm sum function to replace sad. */
- cost += abs( h->pixf.sad_aligned[PIXEL_8x8]( buf, 8, flat, 0 ) -
- h->pixf.sad_aligned[PIXEL_8x8]( &src[pixoff], i_stride, flat, 0 ) );
+ * pixels. */
+ cost += h->pixf.asd8( buf, 8, &src[pixoff], i_stride, height );
}
cost += x264_weight_slice_header_cost( h, w, 1 );
}
else
- for( int y = 0; y < i_lines; y += 8, pixoff = y*i_stride )
+ for( int y = 0; y < i_lines; y += height, pixoff = y*i_stride )
for( int x = 0; x < i_width; x += 8, pixoff += 8 )
- cost += abs( h->pixf.sad_aligned[PIXEL_8x8]( &ref[pixoff], i_stride, flat, 0 ) -
- h->pixf.sad_aligned[PIXEL_8x8]( &src[pixoff], i_stride, flat, 0 ) );
+ cost += h->pixf.asd8( &ref[pixoff], i_stride, &src[pixoff], i_stride, height );
x264_emms();
return cost;
}
SET_WEIGHT( weights[0], 0, 1, 0, 0 );
SET_WEIGHT( weights[1], 0, 1, 0, 0 );
SET_WEIGHT( weights[2], 0, 1, 0, 0 );
+ int chroma_initted = 0;
+ float guess_scale[3];
+ float fenc_mean[3];
+ float ref_mean[3];
+ for( int plane = 0; plane <= 2*!b_lookahead; plane++ )
+ {
+ float fenc_var = fenc->i_pixel_ssd[plane] + !ref->i_pixel_ssd[plane];
+ float ref_var = ref->i_pixel_ssd[plane] + !ref->i_pixel_ssd[plane];
+ guess_scale[plane] = sqrtf( fenc_var / ref_var );
+ fenc_mean[plane] = (float)fenc->i_pixel_sum[plane] / (fenc->i_lines[!!plane] * fenc->i_width[!!plane]) / (1 << (BIT_DEPTH - 8));
+ ref_mean[plane] = (float) ref->i_pixel_sum[plane] / (fenc->i_lines[!!plane] * fenc->i_width[!!plane]) / (1 << (BIT_DEPTH - 8));
+ }
+
+ int chroma_denom = 7;
+ if( !b_lookahead )
+ {
+ /* make sure both our scale factors fit */
+ while( chroma_denom > 0 )
+ {
+ float thresh = 127.f / (1<<chroma_denom);
+ if( guess_scale[1] < thresh && guess_scale[2] < thresh )
+ break;
+ chroma_denom--;
+ }
+ }
+
/* Don't check chroma in lookahead, or if there wasn't a luma weight. */
for( int plane = 0; plane <= 2 && !( plane && ( !weights[0].weightfn || b_lookahead ) ); plane++ )
{
- int cur_offset, start_offset, end_offset;
int minoff, minscale, mindenom;
unsigned int minscore, origscore;
int found;
- float fenc_var = fenc->i_pixel_ssd[plane] + !ref->i_pixel_ssd[plane];
- float ref_var = ref->i_pixel_ssd[plane] + !ref->i_pixel_ssd[plane];
- float guess_scale = sqrtf( fenc_var / ref_var );
- float fenc_mean = (float)fenc->i_pixel_sum[plane] / (fenc->i_lines[!!plane] * fenc->i_width[!!plane]) / (1 << (BIT_DEPTH - 8));
- float ref_mean = (float) ref->i_pixel_sum[plane] / (fenc->i_lines[!!plane] * fenc->i_width[!!plane]) / (1 << (BIT_DEPTH - 8));
//early termination
- if( fabsf( ref_mean - fenc_mean ) < 0.5f && fabsf( 1.f - guess_scale ) < epsilon )
+ if( fabsf( ref_mean[plane] - fenc_mean[plane] ) < 0.5f && fabsf( 1.f - guess_scale[plane] ) < epsilon )
{
SET_WEIGHT( weights[plane], 0, 1, 0, 0 );
continue;
if( plane )
{
- weights[plane].i_denom = 6;
- weights[plane].i_scale = x264_clip3( round( guess_scale * 64 ), 0, 255 );
+ weights[plane].i_denom = chroma_denom;
+ weights[plane].i_scale = x264_clip3( round( guess_scale[plane] * (1<<chroma_denom) ), 0, 255 );
if( weights[plane].i_scale > 127 )
{
weights[1].weightfn = weights[2].weightfn = NULL;
}
}
else
- x264_weight_get_h264( round( guess_scale * 128 ), 0, &weights[plane] );
+ x264_weight_get_h264( round( guess_scale[plane] * 128 ), 0, &weights[plane] );
found = 0;
mindenom = weights[plane].i_denom;
{
pixel *dstu = h->mb.p_weight_buf[0];
pixel *dstv = h->mb.p_weight_buf[0]+fenc->i_stride[1]*fenc->i_lines[1];
- /* Only initialize chroma data once. */
- if( plane == 1 )
+ if( !chroma_initted++ )
x264_weight_cost_init_chroma( h, fenc, ref, dstu, dstv );
mcbuf = plane == 1 ? dstu : dstv;
origscore = minscore = x264_weight_cost_chroma( h, fenc, mcbuf, NULL );
if( !minscore )
continue;
- // This gives a slight improvement due to rounding errors but only tests one offset in lookahead.
- // Currently only searches within +/- 1 of the best offset found so far.
- // TODO: Try other offsets/multipliers/combinations thereof?
- cur_offset = fenc_mean - ref_mean * minscale / (1 << mindenom) + 0.5f * b_lookahead;
- start_offset = x264_clip3( cur_offset - !b_lookahead, -128, 127 );
- end_offset = x264_clip3( cur_offset + !b_lookahead, -128, 127 );
- for( int i_off = start_offset; i_off <= end_offset; i_off++ )
+ /* Picked somewhat arbitrarily */
+ static const uint8_t weight_check_distance[][2] =
{
- SET_WEIGHT( weights[plane], 1, minscale, mindenom, i_off );
- unsigned int s;
- if( plane )
+ {0,0},{0,0},{0,1},{0,1},
+ {0,1},{0,1},{0,1},{1,1},
+ {1,1},{2,1},{2,1},{4,2}
+ };
+ int scale_dist = b_lookahead ? 0 : weight_check_distance[h->param.analyse.i_subpel_refine][0];
+ int offset_dist = b_lookahead ? 0 : weight_check_distance[h->param.analyse.i_subpel_refine][1];
+
+ int start_scale = x264_clip3( minscale - scale_dist, 0, 127 );
+ int end_scale = x264_clip3( minscale + scale_dist, 0, 127 );
+ for( int i_scale = start_scale; i_scale <= end_scale; i_scale++ )
+ {
+ int cur_scale = i_scale;
+ int cur_offset = fenc_mean[plane] - ref_mean[plane] * cur_scale / (1 << mindenom) + 0.5f * b_lookahead;
+ if( cur_offset < - 128 || cur_offset > 127 )
{
- if( CHROMA444 )
- s = x264_weight_cost_chroma444( h, fenc, mcbuf, &weights[plane], plane );
- else
- s = x264_weight_cost_chroma( h, fenc, mcbuf, &weights[plane] );
+ /* Rescale considering the constraints on cur_offset. We do it in this order
+ * because scale has a much wider range than offset (because of denom), so
+ * it should almost never need to be clamped. */
+ cur_offset = x264_clip3( cur_offset, -128, 127 );
+ cur_scale = (1 << mindenom) * (fenc_mean[plane] - cur_offset) / ref_mean[plane] + 0.5f;
+ cur_scale = x264_clip3( cur_scale, 0, 127 );
}
- else
- s = x264_weight_cost_luma( h, fenc, mcbuf, &weights[plane] );
- COPY3_IF_LT( minscore, s, minoff, i_off, found, 1 );
+ int start_offset = x264_clip3( cur_offset - offset_dist, -128, 127 );
+ int end_offset = x264_clip3( cur_offset + offset_dist, -128, 127 );
+ for( int i_off = start_offset; i_off <= end_offset; i_off++ )
+ {
+ SET_WEIGHT( weights[plane], 1, cur_scale, mindenom, i_off );
+ unsigned int s;
+ if( plane )
+ {
+ if( CHROMA444 )
+ s = x264_weight_cost_chroma444( h, fenc, mcbuf, &weights[plane], plane );
+ else
+ s = x264_weight_cost_chroma( h, fenc, mcbuf, &weights[plane] );
+ }
+ else
+ s = x264_weight_cost_luma( h, fenc, mcbuf, &weights[plane] );
+ COPY4_IF_LT( minscore, s, minscale, cur_scale, minoff, i_off, found, 1 );
- // Don't check any more offsets if the previous one had a lower cost than the current one
- if( minoff == start_offset && i_off != start_offset )
- break;
+ // Don't check any more offsets if the previous one had a lower cost than the current one
+ if( minoff == start_offset && i_off != start_offset )
+ break;
+ }
}
x264_emms();
+ /* Use a smaller denominator if possible */
+ if( !plane )
+ {
+ while( mindenom > 0 && !(minscale&1) )
+ {
+ mindenom--;
+ minscale >>= 1;
+ }
+ }
+
/* FIXME: More analysis can be done here on SAD vs. SATD termination. */
/* 0.2% termination derived experimentally to avoid weird weights in frames that are mostly intra. */
if( !found || (minscale == 1 << mindenom && minoff == 0) || (float)minscore / origscore > 0.998f )
fenc->f_weighted_cost_delta[i_delta_index] = (float)minscore / origscore;
}
- //FIXME, what is the correct way to deal with this?
- if( weights[1].weightfn && weights[2].weightfn && weights[1].i_denom != weights[2].i_denom )
+ /* Optimize and unify denominator */
+ if( weights[1].weightfn || weights[2].weightfn )
{
- int denom = X264_MIN( weights[1].i_denom, weights[2].i_denom );
- int i;
- for( i = 1; i <= 2; i++ )
+ int denom = weights[1].weightfn ? weights[1].i_denom : weights[2].i_denom;
+ int both_weighted = weights[1].weightfn && weights[2].weightfn;
+ /* If only one plane is weighted, the other has an implicit scale of 1<<denom.
+ * With denom==7, this comes out to 128, which is invalid, so don't allow that. */
+ while( (!both_weighted && denom==7) ||
+ (denom > 0 && !(weights[1].weightfn && (weights[1].i_scale&1))
+ && !(weights[2].weightfn && (weights[2].i_scale&1))) )
{
- weights[i].i_scale = x264_clip3( weights[i].i_scale >> ( weights[i].i_denom - denom ), 0, 255 );
- weights[i].i_denom = denom;
- h->mc.weight_cache( h, &weights[i] );
+ denom--;
+ for( int i = 1; i <= 2; i++ )
+ if( weights[i].weightfn )
+ {
+ weights[i].i_scale >>= 1;
+ weights[i].i_denom = denom;
+ }
}
}
+ for( int i = 1; i <= 2; i++ )
+ if( weights[i].weightfn )
+ h->mc.weight_cache( h, &weights[i] );
if( weights[0].weightfn && b_lookahead )
{
}
}
+/* Output buffers are separated by 128 bytes to avoid false sharing of cachelines
+ * in multithreaded lookahead. */
+#define PAD_SIZE 32
+/* cost_est, cost_est_aq, intra_mbs, num rows */
+#define NUM_INTS 4
+#define COST_EST 0
+#define COST_EST_AQ 1
+#define INTRA_MBS 2
+#define NUM_ROWS 3
+#define ROW_SATD (NUM_INTS + (h->mb.i_mb_y - h->i_threadslice_start))
+
static void x264_slicetype_mb_cost( x264_t *h, x264_mb_analysis_t *a,
x264_frame_t **frames, int p0, int p1, int b,
- int dist_scale_factor, int do_search[2], const x264_weight_t *w )
+ int dist_scale_factor, int do_search[2], const x264_weight_t *w,
+ int *output_inter, int *output_intra )
{
x264_frame_t *fref0 = frames[p0];
x264_frame_t *fref1 = frames[p1];
x264_me_t m[2];
int i_bcost = COST_MAX;
int list_used = 0;
+ /* A small, arbitrary bias to avoid VBV problems caused by zero-residual lookahead blocks. */
+ int lowres_penalty = 4;
h->mb.pic.p_fenc[0] = h->mb.pic.fenc_buf;
h->mc.copy[PIXEL_8x8]( h->mb.pic.p_fenc[0], FENC_STRIDE, &fenc->lowres[0][i_pel_offset], i_stride, 8 );
goto lowres_intra_mb;
// no need for h->mb.mv_min[]
- h->mb.mv_min_fpel[0] = -8*h->mb.i_mb_x - 4;
- h->mb.mv_max_fpel[0] = 8*( h->mb.i_mb_width - h->mb.i_mb_x - 1 ) + 4;
- h->mb.mv_min_spel[0] = 4*( h->mb.mv_min_fpel[0] - 8 );
- h->mb.mv_max_spel[0] = 4*( h->mb.mv_max_fpel[0] + 8 );
+ h->mb.mv_limit_fpel[0][0] = -8*h->mb.i_mb_x - 4;
+ h->mb.mv_limit_fpel[1][0] = 8*( h->mb.i_mb_width - h->mb.i_mb_x - 1 ) + 4;
+ h->mb.mv_min_spel[0] = 4*( h->mb.mv_limit_fpel[0][0] - 8 );
+ h->mb.mv_max_spel[0] = 4*( h->mb.mv_limit_fpel[1][0] + 8 );
if( h->mb.i_mb_x >= h->mb.i_mb_width - 2 )
{
- h->mb.mv_min_fpel[1] = -8*h->mb.i_mb_y - 4;
- h->mb.mv_max_fpel[1] = 8*( h->mb.i_mb_height - h->mb.i_mb_y - 1 ) + 4;
- h->mb.mv_min_spel[1] = 4*( h->mb.mv_min_fpel[1] - 8 );
- h->mb.mv_max_spel[1] = 4*( h->mb.mv_max_fpel[1] + 8 );
+ h->mb.mv_limit_fpel[0][1] = -8*h->mb.i_mb_y - 4;
+ h->mb.mv_limit_fpel[1][1] = 8*( h->mb.i_mb_height - h->mb.i_mb_y - 1 ) + 4;
+ h->mb.mv_min_spel[1] = 4*( h->mb.mv_limit_fpel[0][1] - 8 );
+ h->mb.mv_max_spel[1] = 4*( h->mb.mv_limit_fpel[1][1] + 8 );
}
#define LOAD_HPELS_LUMA(dst, src) \
} \
else \
{ \
- int stride1 = 16, stride2 = 16; \
+ intptr_t stride1 = 16, stride2 = 16; \
pixel *src1, *src2; \
src1 = h->mc.get_ref( pix1, &stride1, m[0].p_fref, m[0].i_stride[0], \
(mv0)[0], (mv0)[1], 8, 8, w ); \
if( b_bidir )
{
- int16_t *mvr = fref1->lowres_mvs[0][p1-p0-1][i_mb_xy];
ALIGNED_ARRAY_8( int16_t, dmv,[2],[2] );
m[1].i_pixel = PIXEL_8x8;
LOAD_HPELS_LUMA( m[1].p_fref, fref1->lowres );
m[1].p_fref_w = m[1].p_fref[0];
- dmv[0][0] = ( mvr[0] * dist_scale_factor + 128 ) >> 8;
- dmv[0][1] = ( mvr[1] * dist_scale_factor + 128 ) >> 8;
- dmv[1][0] = dmv[0][0] - mvr[0];
- dmv[1][1] = dmv[0][1] - mvr[1];
- CLIP_MV( dmv[0] );
- CLIP_MV( dmv[1] );
- if( h->param.analyse.i_subpel_refine <= 1 )
- M64( dmv ) &= ~0x0001000100010001ULL; /* mv & ~1 */
+ if( fref1->lowres_mvs[0][p1-p0-1][0][0] != 0x7FFF )
+ {
+ int16_t *mvr = fref1->lowres_mvs[0][p1-p0-1][i_mb_xy];
+ dmv[0][0] = ( mvr[0] * dist_scale_factor + 128 ) >> 8;
+ dmv[0][1] = ( mvr[1] * dist_scale_factor + 128 ) >> 8;
+ dmv[1][0] = dmv[0][0] - mvr[0];
+ dmv[1][1] = dmv[0][1] - mvr[1];
+ CLIP_MV( dmv[0] );
+ CLIP_MV( dmv[1] );
+ if( h->param.analyse.i_subpel_refine <= 1 )
+ M64( dmv ) &= ~0x0001000100010001ULL; /* mv & ~1 */
+ }
+ else
+ M64( dmv ) = 0;
TRY_BIDIR( dmv[0], dmv[1], 0 );
if( M64( dmv ) )
#define MVC(mv) { CP32( mvc[i_mvc], mv ); i_mvc++; }
if( i_mb_x < h->mb.i_mb_width - 1 )
MVC( fenc_mv[1] );
- if( i_mb_y < h->mb.i_mb_height - 1 )
+ if( i_mb_y < h->i_threadslice_end - 1 )
{
MVC( fenc_mv[i_mb_stride] );
if( i_mb_x > 0 )
lowres_intra_mb:
if( !fenc->b_intra_calculated )
{
- ALIGNED_ARRAY_16( pixel, edge,[33] );
- pixel *pix = &pix1[8+FDEC_STRIDE - 1];
- pixel *src = &fenc->lowres[0][i_pel_offset - 1];
+ ALIGNED_ARRAY_16( pixel, edge,[36] );
+ pixel *pix = &pix1[8+FDEC_STRIDE];
+ pixel *src = &fenc->lowres[0][i_pel_offset];
const int intra_penalty = 5 * a->i_lambda;
int satds[3];
+ int pixoff = 4 / sizeof(pixel);
- memcpy( pix-FDEC_STRIDE, src-i_stride, 17 * sizeof(pixel) );
- for( int i = 0; i < 8; i++ )
- pix[i*FDEC_STRIDE] = src[i*i_stride];
- pix++;
+ /* Avoid store forwarding stalls by writing larger chunks */
+ memcpy( pix-FDEC_STRIDE, src-i_stride, 16 * sizeof(pixel) );
+ for( int i = -1; i < 8; i++ )
+ M32( &pix[i*FDEC_STRIDE-pixoff] ) = M32( &src[i*i_stride-pixoff] );
h->pixf.intra_mbcmp_x3_8x8c( h->mb.pic.p_fenc[0], pix, satds );
int i_icost = X264_MIN3( satds[0], satds[1], satds[2] );
}
}
- i_icost += intra_penalty;
+ i_icost += intra_penalty + lowres_penalty;
fenc->i_intra_cost[i_mb_xy] = i_icost;
int i_icost_aq = i_icost;
if( h->param.rc.i_aq_mode )
i_icost_aq = (i_icost_aq * fenc->i_inv_qscale_factor[i_mb_xy] + 128) >> 8;
- fenc->i_row_satds[0][0][h->mb.i_mb_y] += i_icost_aq;
+ output_intra[ROW_SATD] += i_icost_aq;
if( b_frame_score_mb )
{
- fenc->i_cost_est[0][0] += i_icost;
- fenc->i_cost_est_aq[0][0] += i_icost_aq;
+ output_intra[COST_EST] += i_icost;
+ output_intra[COST_EST_AQ] += i_icost_aq;
}
}
+ i_bcost += lowres_penalty;
/* forbid intra-mbs in B-frames, because it's rare and not worth checking */
/* FIXME: Should we still forbid them now that we cache intra scores? */
list_used = 0;
}
if( b_frame_score_mb )
- fenc->i_intra_mbs[b-p0] += b_intra;
+ output_inter[INTRA_MBS] += b_intra;
}
/* In an I-frame, we've already added the results above in the intra section. */
int i_bcost_aq = i_bcost;
if( h->param.rc.i_aq_mode )
i_bcost_aq = (i_bcost_aq * fenc->i_inv_qscale_factor[i_mb_xy] + 128) >> 8;
- fenc->i_row_satds[b-p0][p1-b][h->mb.i_mb_y] += i_bcost_aq;
+ output_inter[ROW_SATD] += i_bcost_aq;
if( b_frame_score_mb )
{
/* Don't use AQ-weighted costs for slicetype decision, only for ratecontrol. */
- fenc->i_cost_est[b-p0][p1-b] += i_bcost;
- fenc->i_cost_est_aq[b-p0][p1-b] += i_bcost_aq;
+ output_inter[COST_EST] += i_bcost;
+ output_inter[COST_EST_AQ] += i_bcost_aq;
}
}
(h->mb.i_mb_width - 2) * (h->mb.i_mb_height - 2) :\
h->mb.i_mb_width * h->mb.i_mb_height)
+typedef struct
+{
+ x264_t *h;
+ x264_mb_analysis_t *a;
+ x264_frame_t **frames;
+ int p0;
+ int p1;
+ int b;
+ int dist_scale_factor;
+ int *do_search;
+ const x264_weight_t *w;
+ int *output_inter;
+ int *output_intra;
+} x264_slicetype_slice_t;
+
+static void x264_slicetype_slice_cost( x264_slicetype_slice_t *s )
+{
+ x264_t *h = s->h;
+
+ /* Lowres lookahead goes backwards because the MVs are used as predictors in the main encode.
+ * This considerably improves MV prediction overall. */
+
+ /* The edge mbs seem to reduce the predictive quality of the
+ * whole frame's score, but are needed for a spatial distribution. */
+ int do_edges = h->param.rc.b_mb_tree || h->param.rc.i_vbv_buffer_size || h->mb.i_mb_width <= 2 || h->mb.i_mb_height <= 2;
+
+ int start_y = X264_MIN( h->i_threadslice_end - 1, h->mb.i_mb_height - 2 + do_edges );
+ int end_y = X264_MAX( h->i_threadslice_start, 1 - do_edges );
+ int start_x = h->mb.i_mb_width - 2 + do_edges;
+ int end_x = 1 - do_edges;
+
+ for( h->mb.i_mb_y = start_y; h->mb.i_mb_y >= end_y; h->mb.i_mb_y-- )
+ for( h->mb.i_mb_x = start_x; h->mb.i_mb_x >= end_x; h->mb.i_mb_x-- )
+ x264_slicetype_mb_cost( h, s->a, s->frames, s->p0, s->p1, s->b, s->dist_scale_factor,
+ s->do_search, s->w, s->output_inter, s->output_intra );
+}
+
static int x264_slicetype_frame_cost( x264_t *h, x264_mb_analysis_t *a,
x264_frame_t **frames, int p0, int p1, int b,
int b_intra_penalty )
int i_score = 0;
int do_search[2];
const x264_weight_t *w = x264_weight_none;
+ x264_frame_t *fenc = frames[b];
+
/* Check whether we already evaluated this frame
* If we have tried this frame as P, then we have also tried
* the preceding frames as B. (is this still true?) */
/* Also check that we already calculated the row SATDs for the current frame. */
- if( frames[b]->i_cost_est[b-p0][p1-b] >= 0 && (!h->param.rc.i_vbv_buffer_size || frames[b]->i_row_satds[b-p0][p1-b][0] != -1) )
- i_score = frames[b]->i_cost_est[b-p0][p1-b];
+ if( fenc->i_cost_est[b-p0][p1-b] >= 0 && (!h->param.rc.i_vbv_buffer_size || fenc->i_row_satds[b-p0][p1-b][0] != -1) )
+ i_score = fenc->i_cost_est[b-p0][p1-b];
else
{
int dist_scale_factor = 128;
- int *row_satd = frames[b]->i_row_satds[b-p0][p1-b];
- int *row_satd_intra = frames[b]->i_row_satds[0][0];
/* For each list, check to see whether we have lowres motion-searched this reference frame before. */
- do_search[0] = b != p0 && frames[b]->lowres_mvs[0][b-p0-1][0][0] == 0x7FFF;
- do_search[1] = b != p1 && frames[b]->lowres_mvs[1][p1-b-1][0][0] == 0x7FFF;
+ do_search[0] = b != p0 && fenc->lowres_mvs[0][b-p0-1][0][0] == 0x7FFF;
+ do_search[1] = b != p1 && fenc->lowres_mvs[1][p1-b-1][0][0] == 0x7FFF;
if( do_search[0] )
{
if( h->param.analyse.i_weighted_pred && b == p1 )
{
x264_emms();
- x264_weights_analyse( h, frames[b], frames[p0], 1 );
- w = frames[b]->weight[0];
+ x264_weights_analyse( h, fenc, frames[p0], 1 );
+ w = fenc->weight[0];
}
- frames[b]->lowres_mvs[0][b-p0-1][0][0] = 0;
+ fenc->lowres_mvs[0][b-p0-1][0][0] = 0;
}
- if( do_search[1] ) frames[b]->lowres_mvs[1][p1-b-1][0][0] = 0;
+ if( do_search[1] ) fenc->lowres_mvs[1][p1-b-1][0][0] = 0;
- if( b == p1 )
- frames[b]->i_intra_mbs[b-p0] = 0;
- if( !frames[b]->b_intra_calculated )
- {
- frames[b]->i_cost_est[0][0] = 0;
- frames[b]->i_cost_est_aq[0][0] = 0;
- }
if( p1 != p0 )
dist_scale_factor = ( ((b-p0) << 8) + ((p1-p0) >> 1) ) / (p1-p0);
- frames[b]->i_cost_est[b-p0][p1-b] = 0;
- frames[b]->i_cost_est_aq[b-p0][p1-b] = 0;
-
- /* Lowres lookahead goes backwards because the MVs are used as predictors in the main encode.
- * This considerably improves MV prediction overall. */
+ int output_buf_size = h->mb.i_mb_height + (NUM_INTS + PAD_SIZE) * h->param.i_lookahead_threads;
+ int *output_inter[X264_LOOKAHEAD_THREAD_MAX+1];
+ int *output_intra[X264_LOOKAHEAD_THREAD_MAX+1];
+ output_inter[0] = h->scratch_buffer2;
+ output_intra[0] = output_inter[0] + output_buf_size;
- /* The edge mbs seem to reduce the predictive quality of the
- * whole frame's score, but are needed for a spatial distribution. */
- if( h->param.rc.b_mb_tree || h->param.rc.i_vbv_buffer_size ||
- h->mb.i_mb_width <= 2 || h->mb.i_mb_height <= 2 )
+#if HAVE_OPENCL
+ if( h->param.b_opencl )
{
- for( h->mb.i_mb_y = h->mb.i_mb_height - 1; h->mb.i_mb_y >= 0; h->mb.i_mb_y-- )
+ x264_opencl_lowres_init(h, fenc, a->i_lambda );
+ if( do_search[0] )
+ {
+ x264_opencl_lowres_init( h, frames[p0], a->i_lambda );
+ x264_opencl_motionsearch( h, frames, b, p0, 0, a->i_lambda, w );
+ }
+ if( do_search[1] )
{
- row_satd[h->mb.i_mb_y] = 0;
- if( !frames[b]->b_intra_calculated )
- row_satd_intra[h->mb.i_mb_y] = 0;
- for( h->mb.i_mb_x = h->mb.i_mb_width - 1; h->mb.i_mb_x >= 0; h->mb.i_mb_x-- )
- x264_slicetype_mb_cost( h, a, frames, p0, p1, b, dist_scale_factor, do_search, w );
+ x264_opencl_lowres_init( h, frames[p1], a->i_lambda );
+ x264_opencl_motionsearch( h, frames, b, p1, 1, a->i_lambda, NULL );
}
+ if( b != p0 )
+ x264_opencl_finalize_cost( h, a->i_lambda, frames, p0, p1, b, dist_scale_factor );
+ x264_opencl_flush( h );
+
+ i_score = fenc->i_cost_est[b-p0][p1-b];
}
else
+#endif
{
- for( h->mb.i_mb_y = h->mb.i_mb_height - 2; h->mb.i_mb_y >= 1; h->mb.i_mb_y-- )
- for( h->mb.i_mb_x = h->mb.i_mb_width - 2; h->mb.i_mb_x >= 1; h->mb.i_mb_x-- )
- x264_slicetype_mb_cost( h, a, frames, p0, p1, b, dist_scale_factor, do_search, w );
- }
+ if( h->param.i_lookahead_threads > 1 )
+ {
+ x264_slicetype_slice_t s[X264_LOOKAHEAD_THREAD_MAX];
- i_score = frames[b]->i_cost_est[b-p0][p1-b];
- if( b != p1 )
- i_score = (uint64_t)i_score * 100 / (120 + h->param.i_bframe_bias);
- else
- frames[b]->b_intra_calculated = 1;
+ for( int i = 0; i < h->param.i_lookahead_threads; i++ )
+ {
+ x264_t *t = h->lookahead_thread[i];
- frames[b]->i_cost_est[b-p0][p1-b] = i_score;
- x264_emms();
+ /* FIXME move this somewhere else */
+ t->mb.i_me_method = h->mb.i_me_method;
+ t->mb.i_subpel_refine = h->mb.i_subpel_refine;
+ t->mb.b_chroma_me = h->mb.b_chroma_me;
+
+ s[i] = (x264_slicetype_slice_t){ t, a, frames, p0, p1, b, dist_scale_factor, do_search, w,
+ output_inter[i], output_intra[i] };
+
+ t->i_threadslice_start = ((h->mb.i_mb_height * i + h->param.i_lookahead_threads/2) / h->param.i_lookahead_threads);
+ t->i_threadslice_end = ((h->mb.i_mb_height * (i+1) + h->param.i_lookahead_threads/2) / h->param.i_lookahead_threads);
+
+ int thread_height = t->i_threadslice_end - t->i_threadslice_start;
+ int thread_output_size = thread_height + NUM_INTS;
+ memset( output_inter[i], 0, thread_output_size * sizeof(int) );
+ memset( output_intra[i], 0, thread_output_size * sizeof(int) );
+ output_inter[i][NUM_ROWS] = output_intra[i][NUM_ROWS] = thread_height;
+
+ output_inter[i+1] = output_inter[i] + thread_output_size + PAD_SIZE;
+ output_intra[i+1] = output_intra[i] + thread_output_size + PAD_SIZE;
+
+ x264_threadpool_run( h->lookaheadpool, (void*)x264_slicetype_slice_cost, &s[i] );
+ }
+ for( int i = 0; i < h->param.i_lookahead_threads; i++ )
+ x264_threadpool_wait( h->lookaheadpool, &s[i] );
+ }
+ else
+ {
+ h->i_threadslice_start = 0;
+ h->i_threadslice_end = h->mb.i_mb_height;
+ memset( output_inter[0], 0, (output_buf_size - PAD_SIZE) * sizeof(int) );
+ memset( output_intra[0], 0, (output_buf_size - PAD_SIZE) * sizeof(int) );
+ output_inter[0][NUM_ROWS] = output_intra[0][NUM_ROWS] = h->mb.i_mb_height;
+ x264_slicetype_slice_t s = (x264_slicetype_slice_t){ h, a, frames, p0, p1, b, dist_scale_factor, do_search, w,
+ output_inter[0], output_intra[0] };
+ x264_slicetype_slice_cost( &s );
+ }
+
+ /* Sum up accumulators */
+ if( b == p1 )
+ fenc->i_intra_mbs[b-p0] = 0;
+ if( !fenc->b_intra_calculated )
+ {
+ fenc->i_cost_est[0][0] = 0;
+ fenc->i_cost_est_aq[0][0] = 0;
+ }
+ fenc->i_cost_est[b-p0][p1-b] = 0;
+ fenc->i_cost_est_aq[b-p0][p1-b] = 0;
+
+ int *row_satd_inter = fenc->i_row_satds[b-p0][p1-b];
+ int *row_satd_intra = fenc->i_row_satds[0][0];
+ for( int i = 0; i < h->param.i_lookahead_threads; i++ )
+ {
+ if( b == p1 )
+ fenc->i_intra_mbs[b-p0] += output_inter[i][INTRA_MBS];
+ if( !fenc->b_intra_calculated )
+ {
+ fenc->i_cost_est[0][0] += output_intra[i][COST_EST];
+ fenc->i_cost_est_aq[0][0] += output_intra[i][COST_EST_AQ];
+ }
+
+ fenc->i_cost_est[b-p0][p1-b] += output_inter[i][COST_EST];
+ fenc->i_cost_est_aq[b-p0][p1-b] += output_inter[i][COST_EST_AQ];
+
+ if( h->param.rc.i_vbv_buffer_size )
+ {
+ int row_count = output_inter[i][NUM_ROWS];
+ memcpy( row_satd_inter, output_inter[i] + NUM_INTS, row_count * sizeof(int) );
+ if( !fenc->b_intra_calculated )
+ memcpy( row_satd_intra, output_intra[i] + NUM_INTS, row_count * sizeof(int) );
+ row_satd_inter += row_count;
+ row_satd_intra += row_count;
+ }
+ }
+
+ i_score = fenc->i_cost_est[b-p0][p1-b];
+ if( b != p1 )
+ i_score = (uint64_t)i_score * 100 / (120 + h->param.i_bframe_bias);
+ else
+ fenc->b_intra_calculated = 1;
+
+ fenc->i_cost_est[b-p0][p1-b] = i_score;
+ x264_emms();
+ }
}
if( b_intra_penalty )
{
// arbitrary penalty for I-blocks after B-frames
int nmb = NUM_MBS;
- i_score += i_score * frames[b]->i_intra_mbs[b-p0] / (nmb * 8);
+ i_score += (uint64_t)i_score * fenc->i_intra_mbs[b-p0] / (nmb * 8);
}
return i_score;
}
return i_score;
}
+/* Trade off precision in mbtree for increased range */
+#define MBTREE_PRECISION 0.5f
+
static void x264_macroblock_tree_finish( x264_t *h, x264_frame_t *frame, float average_duration, int ref0_distance )
{
- int fps_factor = round( CLIP_DURATION(average_duration) / CLIP_DURATION(frame->f_duration) * 256 );
+ int fps_factor = round( CLIP_DURATION(average_duration) / CLIP_DURATION(frame->f_duration) * 256 / MBTREE_PRECISION );
float weightdelta = 0.0;
if( ref0_distance && frame->f_weighted_cost_delta[ref0_distance-1] > 0 )
weightdelta = (1.0 - frame->f_weighted_cost_delta[ref0_distance-1]);
int i_bipred_weight = h->param.analyse.b_weighted_bipred ? 64 - (dist_scale_factor>>2) : 32;
int16_t (*mvs[2])[2] = { frames[b]->lowres_mvs[0][b-p0-1], frames[b]->lowres_mvs[1][p1-b-1] };
int bipred_weights[2] = {i_bipred_weight, 64 - i_bipred_weight};
- int *buf = h->scratch_buffer;
+ int16_t *buf = h->scratch_buffer;
uint16_t *propagate_cost = frames[b]->i_propagate_cost;
+ uint16_t *lowres_costs = frames[b]->lowres_costs[b-p0][p1-b];
x264_emms();
- float fps_factor = CLIP_DURATION(frames[b]->f_duration) / CLIP_DURATION(average_duration);
+ float fps_factor = CLIP_DURATION(frames[b]->f_duration) / (CLIP_DURATION(average_duration) * 256.0f) * MBTREE_PRECISION;
/* For non-reffed frames the source costs are always zero, so just memset one row and re-use it. */
if( !referenced )
{
int mb_index = h->mb.i_mb_y*h->mb.i_mb_stride;
h->mc.mbtree_propagate_cost( buf, propagate_cost,
- frames[b]->i_intra_cost+mb_index, frames[b]->lowres_costs[b-p0][p1-b]+mb_index,
+ frames[b]->i_intra_cost+mb_index, lowres_costs+mb_index,
frames[b]->i_inv_qscale_factor+mb_index, &fps_factor, h->mb.i_mb_width );
if( referenced )
propagate_cost += h->mb.i_mb_width;
- for( h->mb.i_mb_x = 0; h->mb.i_mb_x < h->mb.i_mb_width; h->mb.i_mb_x++, mb_index++ )
+
+ h->mc.mbtree_propagate_list( h, ref_costs[0], &mvs[0][mb_index], buf, &lowres_costs[mb_index],
+ bipred_weights[0], h->mb.i_mb_y, h->mb.i_mb_width, 0 );
+ if( b != p1 )
{
- int propagate_amount = buf[h->mb.i_mb_x];
- /* Don't propagate for an intra block. */
- if( propagate_amount > 0 )
- {
- /* Access width-2 bitfield. */
- int lists_used = frames[b]->lowres_costs[b-p0][p1-b][mb_index] >> LOWRES_COST_SHIFT;
- /* Follow the MVs to the previous frame(s). */
- for( int list = 0; list < 2; list++ )
- if( (lists_used >> list)&1 )
- {
-#define CLIP_ADD(s,x) (s) = X264_MIN((s)+(x),(1<<16)-1)
- int listamount = propagate_amount;
- /* Apply bipred weighting. */
- if( lists_used == 3 )
- listamount = (listamount * bipred_weights[list] + 32) >> 6;
-
- /* Early termination for simple case of mv0. */
- if( !M32( mvs[list][mb_index] ) )
- {
- CLIP_ADD( ref_costs[list][mb_index], listamount );
- continue;
- }
-
- int x = mvs[list][mb_index][0];
- int y = mvs[list][mb_index][1];
- int mbx = (x>>5)+h->mb.i_mb_x;
- int mby = (y>>5)+h->mb.i_mb_y;
- int idx0 = mbx + mby * h->mb.i_mb_stride;
- int idx1 = idx0 + 1;
- int idx2 = idx0 + h->mb.i_mb_stride;
- int idx3 = idx0 + h->mb.i_mb_stride + 1;
- x &= 31;
- y &= 31;
- int idx0weight = (32-y)*(32-x);
- int idx1weight = (32-y)*x;
- int idx2weight = y*(32-x);
- int idx3weight = y*x;
-
- /* We could just clip the MVs, but pixels that lie outside the frame probably shouldn't
- * be counted. */
- if( mbx < h->mb.i_mb_width-1 && mby < h->mb.i_mb_height-1 && mbx >= 0 && mby >= 0 )
- {
- CLIP_ADD( ref_costs[list][idx0], (listamount*idx0weight+512)>>10 );
- CLIP_ADD( ref_costs[list][idx1], (listamount*idx1weight+512)>>10 );
- CLIP_ADD( ref_costs[list][idx2], (listamount*idx2weight+512)>>10 );
- CLIP_ADD( ref_costs[list][idx3], (listamount*idx3weight+512)>>10 );
- }
- else /* Check offsets individually */
- {
- if( mbx < h->mb.i_mb_width && mby < h->mb.i_mb_height && mbx >= 0 && mby >= 0 )
- CLIP_ADD( ref_costs[list][idx0], (listamount*idx0weight+512)>>10 );
- if( mbx+1 < h->mb.i_mb_width && mby < h->mb.i_mb_height && mbx+1 >= 0 && mby >= 0 )
- CLIP_ADD( ref_costs[list][idx1], (listamount*idx1weight+512)>>10 );
- if( mbx < h->mb.i_mb_width && mby+1 < h->mb.i_mb_height && mbx >= 0 && mby+1 >= 0 )
- CLIP_ADD( ref_costs[list][idx2], (listamount*idx2weight+512)>>10 );
- if( mbx+1 < h->mb.i_mb_width && mby+1 < h->mb.i_mb_height && mbx+1 >= 0 && mby+1 >= 0 )
- CLIP_ADD( ref_costs[list][idx3], (listamount*idx3weight+512)>>10 );
- }
- }
- }
+ h->mc.mbtree_propagate_list( h, ref_costs[1], &mvs[1][mb_index], buf, &lowres_costs[mb_index],
+ bipred_weights[1], h->mb.i_mb_y, h->mb.i_mb_width, 1 );
}
}
if( b_intra )
x264_slicetype_frame_cost( h, a, frames, 0, 0, 0, 0 );
- while( i > 0 && frames[i]->i_type == X264_TYPE_B )
+ while( i > 0 && IS_X264_TYPE_B( frames[i]->i_type ) )
i--;
last_nonb = i;
while( i-- > idx )
{
cur_nonb = i;
- while( frames[cur_nonb]->i_type == X264_TYPE_B && cur_nonb > 0 )
+ while( IS_X264_TYPE_B( frames[cur_nonb]->i_type ) && cur_nonb > 0 )
cur_nonb--;
if( cur_nonb < idx )
break;
if( !h->param.rc.i_lookahead )
{
+ x264_slicetype_frame_cost( h, a, frames, 0, last_nonb, last_nonb, 0 );
x264_macroblock_tree_propagate( h, frames, average_duration, 0, last_nonb, last_nonb, 1 );
XCHG( uint16_t*, frames[last_nonb]->i_propagate_cost, frames[0]->i_propagate_cost );
}
prev_frame->i_cpb_duration += cur_frame->i_dpb_output_delay;
}
- if( cur_frame->b_keyframe )
+ // don't reset cpb delay for IDR frames when using intra-refresh
+ if( cur_frame->b_keyframe && !h->param.b_intra_refresh )
*i_cpb_delay = 0;
*i_cpb_delay += cur_frame->i_duration;
int last_nonb = 0, cur_nonb = 1, idx = 0;
x264_frame_t *prev_frame = NULL;
int prev_frame_idx = 0;
- while( cur_nonb < num_frames && frames[cur_nonb]->i_type == X264_TYPE_B )
+ while( cur_nonb < num_frames && IS_X264_TYPE_B( frames[cur_nonb]->i_type ) )
cur_nonb++;
int next_nonb = keyframe ? last_nonb : cur_nonb;
}
last_nonb = cur_nonb;
cur_nonb++;
- while( cur_nonb <= num_frames && frames[cur_nonb]->i_type == X264_TYPE_B )
+ while( cur_nonb <= num_frames && IS_X264_TYPE_B( frames[cur_nonb]->i_type ) )
cur_nonb++;
}
frames[next_nonb]->i_planned_type[idx] = X264_TYPE_AUTO;
{
int loc = 1;
int cost = 0;
- int cur_p = 0;
+ int cur_nonb = 0;
path--; /* Since the 1st path element is really the second frame */
while( path[loc] )
{
- int next_p = loc;
- /* Find the location of the next P-frame. */
- while( path[next_p] != 'P' )
- next_p++;
-
- /* Add the cost of the P-frame found above */
- cost += x264_slicetype_frame_cost( h, a, frames, cur_p, next_p, next_p, 0 );
+ int next_nonb = loc;
+ /* Find the location of the next non-B-frame. */
+ while( path[next_nonb] == 'B' )
+ next_nonb++;
+
+ /* Add the cost of the non-B-frame found above */
+ if( path[next_nonb] == 'P' )
+ cost += x264_slicetype_frame_cost( h, a, frames, cur_nonb, next_nonb, next_nonb, 0 );
+ else /* I-frame */
+ cost += x264_slicetype_frame_cost( h, a, frames, next_nonb, next_nonb, next_nonb, 0 );
/* Early terminate if the cost we have found is larger than the best path cost so far */
if( cost > threshold )
break;
- if( h->param.i_bframe_pyramid && next_p - cur_p > 2 )
+ if( h->param.i_bframe_pyramid && next_nonb - cur_nonb > 2 )
{
- int middle = cur_p + (next_p - cur_p)/2;
- cost += x264_slicetype_frame_cost( h, a, frames, cur_p, next_p, middle, 0 );
+ int middle = cur_nonb + (next_nonb - cur_nonb)/2;
+ cost += x264_slicetype_frame_cost( h, a, frames, cur_nonb, next_nonb, middle, 0 );
for( int next_b = loc; next_b < middle && cost < threshold; next_b++ )
- cost += x264_slicetype_frame_cost( h, a, frames, cur_p, middle, next_b, 0 );
- for( int next_b = middle+1; next_b < next_p && cost < threshold; next_b++ )
- cost += x264_slicetype_frame_cost( h, a, frames, middle, next_p, next_b, 0 );
+ cost += x264_slicetype_frame_cost( h, a, frames, cur_nonb, middle, next_b, 0 );
+ for( int next_b = middle+1; next_b < next_nonb && cost < threshold; next_b++ )
+ cost += x264_slicetype_frame_cost( h, a, frames, middle, next_nonb, next_b, 0 );
}
else
- for( int next_b = loc; next_b < next_p && cost < threshold; next_b++ )
- cost += x264_slicetype_frame_cost( h, a, frames, cur_p, next_p, next_b, 0 );
+ for( int next_b = loc; next_b < next_nonb && cost < threshold; next_b++ )
+ cost += x264_slicetype_frame_cost( h, a, frames, cur_nonb, next_nonb, next_b, 0 );
- loc = next_p + 1;
- cur_p = next_p;
+ loc = next_nonb + 1;
+ cur_nonb = next_nonb;
}
return cost;
}
char paths[2][X264_LOOKAHEAD_MAX+1];
int num_paths = X264_MIN( h->param.i_bframe+1, length );
int best_cost = COST_MAX;
+ int best_possible = 0;
int idx = 0;
/* Iterate over all currently possible paths */
memset( paths[idx]+len, 'B', path );
strcpy( paths[idx]+len+path, "P" );
- /* Calculate the actual cost of the current path */
- int cost = x264_slicetype_path_cost( h, a, frames, paths[idx], best_cost );
- if( cost < best_cost )
+ int possible = 1;
+ for( int i = 1; i <= length; i++ )
+ {
+ int i_type = frames[i]->i_type;
+ if( i_type == X264_TYPE_AUTO )
+ continue;
+ if( IS_X264_TYPE_B( i_type ) )
+ possible = possible && (i < len || i == length || paths[idx][i-1] == 'B');
+ else
+ {
+ possible = possible && (i < len || paths[idx][i-1] != 'B');
+ paths[idx][i-1] = IS_X264_TYPE_I( i_type ) ? 'I' : 'P';
+ }
+ }
+
+ if( possible || !best_possible )
{
- best_cost = cost;
- idx ^= 1;
+ if( possible && !best_possible )
+ best_cost = COST_MAX;
+ /* Calculate the actual cost of the current path */
+ int cost = x264_slicetype_path_cost( h, a, frames, paths[idx], best_cost );
+ if( cost < best_cost )
+ {
+ best_cost = cost;
+ best_possible = possible;
+ idx ^= 1;
+ }
}
}
return scenecut_internal( h, a, frames, p0, p1, real_scenecut );
}
-void x264_slicetype_analyse( x264_t *h, int keyframe )
+#define IS_X264_TYPE_AUTO_OR_I(x) ((x)==X264_TYPE_AUTO || IS_X264_TYPE_I(x))
+#define IS_X264_TYPE_AUTO_OR_B(x) ((x)==X264_TYPE_AUTO || IS_X264_TYPE_B(x))
+
+void x264_slicetype_analyse( x264_t *h, int intra_minigop )
{
x264_mb_analysis_t a;
x264_frame_t *frames[X264_LOOKAHEAD_MAX+3] = { NULL, };
int num_frames, orig_num_frames, keyint_limit, framecnt;
int i_mb_count = NUM_MBS;
- int cost1p0, cost2p0, cost1b1, cost2p1;
int i_max_search = X264_MIN( h->lookahead->next.i_size, X264_LOOKAHEAD_MAX );
int vbv_lookahead = h->param.rc.i_vbv_buffer_size && h->param.rc.i_lookahead;
+ /* For determinism we should limit the search to the number of frames lookahead has for sure
+ * in h->lookahead->next.list buffer, except at the end of stream.
+ * For normal calls with (intra_minigop == 0) that is h->lookahead->i_slicetype_length + 1 frames.
+ * And for I-frame calls (intra_minigop != 0) we already removed intra_minigop frames from there. */
if( h->param.b_deterministic )
- i_max_search = X264_MIN( i_max_search, h->lookahead->i_slicetype_length + !keyframe );
+ i_max_search = X264_MIN( i_max_search, h->lookahead->i_slicetype_length + 1 - intra_minigop );
+ int keyframe = !!intra_minigop;
assert( h->frames.b_have_lowres );
if( !h->lookahead->last_nonb )
return;
frames[0] = h->lookahead->last_nonb;
- for( framecnt = 0; framecnt < i_max_search && h->lookahead->next.list[framecnt]->i_type == X264_TYPE_AUTO; framecnt++ )
+ for( framecnt = 0; framecnt < i_max_search; framecnt++ )
frames[framecnt+1] = h->lookahead->next.list[framecnt];
x264_lowres_context_init( h, &a );
return;
}
- int num_bframes = 0;
- int num_analysed_frames = num_frames;
- int reset_start;
- if( h->param.i_scenecut_threshold && scenecut( h, &a, frames, 0, 1, 1, orig_num_frames, i_max_search ) )
+ if( IS_X264_TYPE_AUTO_OR_I( frames[1]->i_type ) &&
+ h->param.i_scenecut_threshold && scenecut( h, &a, frames, 0, 1, 1, orig_num_frames, i_max_search ) )
{
- frames[1]->i_type = X264_TYPE_I;
+ if( frames[1]->i_type == X264_TYPE_AUTO )
+ frames[1]->i_type = X264_TYPE_I;
return;
}
+#if HAVE_OPENCL
+ x264_opencl_slicetype_prep( h, frames, num_frames, a.i_lambda );
+#endif
+
+ /* Replace forced keyframes with I/IDR-frames */
+ for( int j = 1; j <= num_frames; j++ )
+ {
+ if( frames[j]->i_type == X264_TYPE_KEYFRAME )
+ frames[j]->i_type = h->param.b_open_gop ? X264_TYPE_I : X264_TYPE_IDR;
+ }
+
+ /* Close GOP at IDR-frames */
+ for( int j = 2; j <= num_frames; j++ )
+ {
+ if( frames[j]->i_type == X264_TYPE_IDR && IS_X264_TYPE_AUTO_OR_B( frames[j-1]->i_type ) )
+ frames[j-1]->i_type = X264_TYPE_P;
+ }
+
+ int num_analysed_frames = num_frames;
+ int reset_start;
+
if( h->param.i_bframe )
{
if( h->param.i_bframe_adaptive == X264_B_ADAPT_TRELLIS )
for( int j = 2; j <= num_frames; j++ )
x264_slicetype_path( h, &a, frames, j, best_paths );
- num_bframes = strspn( best_paths[best_path_index], "B" );
/* Load the results of the analysis into the frame types. */
for( int j = 1; j < num_frames; j++ )
- frames[j]->i_type = best_paths[best_path_index][j-1] == 'B' ? X264_TYPE_B : X264_TYPE_P;
+ {
+ if( best_paths[best_path_index][j-1] != 'B' )
+ {
+ if( IS_X264_TYPE_AUTO_OR_B( frames[j]->i_type ) )
+ frames[j]->i_type = X264_TYPE_P;
+ }
+ else
+ {
+ if( frames[j]->i_type == X264_TYPE_AUTO )
+ frames[j]->i_type = X264_TYPE_B;
+ }
+ }
}
- frames[num_frames]->i_type = X264_TYPE_P;
}
else if( h->param.i_bframe_adaptive == X264_B_ADAPT_FAST )
{
- for( int i = 0; i <= num_frames-2; )
+ int last_nonb = 0;
+ int num_bframes = h->param.i_bframe;
+ for( int j = 1; j < num_frames; j++ )
{
- cost2p1 = x264_slicetype_frame_cost( h, &a, frames, i+0, i+2, i+2, 1 );
- if( frames[i+2]->i_intra_mbs[2] > i_mb_count / 2 )
+ if( j-1 > 0 && IS_X264_TYPE_B( frames[j-1]->i_type ) )
+ num_bframes--;
+ else
{
- frames[i+1]->i_type = X264_TYPE_P;
- frames[i+2]->i_type = X264_TYPE_P;
- i += 2;
+ last_nonb = j-1;
+ num_bframes = h->param.i_bframe;
+ }
+ if( !num_bframes )
+ {
+ if( IS_X264_TYPE_AUTO_OR_B( frames[j]->i_type ) )
+ frames[j]->i_type = X264_TYPE_P;
continue;
}
- cost1b1 = x264_slicetype_frame_cost( h, &a, frames, i+0, i+2, i+1, 0 );
- cost1p0 = x264_slicetype_frame_cost( h, &a, frames, i+0, i+1, i+1, 0 );
- cost2p0 = x264_slicetype_frame_cost( h, &a, frames, i+1, i+2, i+2, 0 );
+ if( frames[j]->i_type != X264_TYPE_AUTO )
+ continue;
- if( cost1p0 + cost2p0 < cost1b1 + cost2p1 )
+ if( IS_X264_TYPE_B( frames[j+1]->i_type ) )
{
- frames[i+1]->i_type = X264_TYPE_P;
- i += 1;
+ frames[j]->i_type = X264_TYPE_P;
+ continue;
+ }
+
+ if( j - last_nonb <= 1 )
+ {
+ int cost2p1 = x264_slicetype_frame_cost( h, &a, frames, last_nonb+0, j+1, j+1, 1 );
+ if( frames[j+1]->i_intra_mbs[2] > i_mb_count / 2 )
+ {
+ frames[j]->i_type = X264_TYPE_P;
+ continue;
+ }
+
+#if HAVE_OPENCL
+ if( h->param.b_opencl )
+ {
+ int b_work_done = 0;
+ b_work_done |= x264_opencl_precalculate_frame_cost(h, frames, a.i_lambda, last_nonb+0, j+1, j+0 );
+ b_work_done |= x264_opencl_precalculate_frame_cost(h, frames, a.i_lambda, last_nonb+0, j+0, j+0 );
+ b_work_done |= x264_opencl_precalculate_frame_cost(h, frames, a.i_lambda, last_nonb+1, j+1, j+1 );
+ if( b_work_done )
+ x264_opencl_flush( h );
+ }
+#endif
+
+ int cost1b1 = x264_slicetype_frame_cost( h, &a, frames, last_nonb+0, j+1, j+0, 0 );
+ int cost1p0 = x264_slicetype_frame_cost( h, &a, frames, last_nonb+0, j+0, j+0, 0 );
+ int cost2p0 = x264_slicetype_frame_cost( h, &a, frames, last_nonb+1, j+1, j+1, 0 );
+
+ if( cost1p0 + cost2p0 < cost1b1 + cost2p1 )
+ {
+ frames[j]->i_type = X264_TYPE_P;
+ continue;
+ }
+ frames[j]->i_type = X264_TYPE_B;
continue;
}
// arbitrary and untuned
#define INTER_THRESH 300
#define P_SENS_BIAS (50 - h->param.i_bframe_bias)
- frames[i+1]->i_type = X264_TYPE_B;
- int j;
- for( j = i+2; j <= X264_MIN( i+h->param.i_bframe, num_frames-1 ); j++ )
- {
- int pthresh = X264_MAX(INTER_THRESH - P_SENS_BIAS * (j-i-1), INTER_THRESH/10);
- int pcost = x264_slicetype_frame_cost( h, &a, frames, i+0, j+1, j+1, 1 );
- if( pcost > pthresh*i_mb_count || frames[j+1]->i_intra_mbs[j-i+1] > i_mb_count/3 )
- break;
+ int pthresh = X264_MAX(INTER_THRESH - P_SENS_BIAS * (j-last_nonb-1), INTER_THRESH/10);
+ int pcost = x264_slicetype_frame_cost( h, &a, frames, last_nonb, j+1, j+1, 1 );
+ if( pcost > pthresh*i_mb_count || frames[j+1]->i_intra_mbs[j-last_nonb+1] > i_mb_count/3 )
+ frames[j]->i_type = X264_TYPE_P;
+ else
frames[j]->i_type = X264_TYPE_B;
- }
- frames[j]->i_type = X264_TYPE_P;
- i = j;
}
- frames[num_frames]->i_type = X264_TYPE_P;
- num_bframes = 0;
- while( num_bframes < num_frames && frames[num_bframes+1]->i_type == X264_TYPE_B )
- num_bframes++;
}
else
{
- num_bframes = X264_MIN(num_frames-1, h->param.i_bframe);
+ int num_bframes = h->param.i_bframe;
for( int j = 1; j < num_frames; j++ )
- frames[j]->i_type = (j%(num_bframes+1)) ? X264_TYPE_B : X264_TYPE_P;
- frames[num_frames]->i_type = X264_TYPE_P;
+ {
+ if( !num_bframes )
+ {
+ if( IS_X264_TYPE_AUTO_OR_B( frames[j]->i_type ) )
+ frames[j]->i_type = X264_TYPE_P;
+ }
+ else if( frames[j]->i_type == X264_TYPE_AUTO )
+ {
+ if( IS_X264_TYPE_B( frames[j+1]->i_type ) )
+ frames[j]->i_type = X264_TYPE_P;
+ else
+ frames[j]->i_type = X264_TYPE_B;
+ }
+ if( IS_X264_TYPE_B( frames[j]->i_type ) )
+ num_bframes--;
+ else
+ num_bframes = h->param.i_bframe;
+ }
}
+ if( IS_X264_TYPE_AUTO_OR_B( frames[num_frames]->i_type ) )
+ frames[num_frames]->i_type = X264_TYPE_P;
+
+ int num_bframes = 0;
+ while( num_bframes < num_frames && IS_X264_TYPE_B( frames[num_bframes+1]->i_type ) )
+ num_bframes++;
/* Check scenecut on the first minigop. */
for( int j = 1; j < num_bframes+1; j++ )
- if( h->param.i_scenecut_threshold && scenecut( h, &a, frames, j, j+1, 0, orig_num_frames, i_max_search ) )
+ {
+ if( frames[j]->i_forced_type == X264_TYPE_AUTO && IS_X264_TYPE_AUTO_OR_I( frames[j+1]->i_forced_type ) &&
+ h->param.i_scenecut_threshold && scenecut( h, &a, frames, j, j+1, 0, orig_num_frames, i_max_search ) )
{
frames[j]->i_type = X264_TYPE_P;
num_analysed_frames = j;
break;
}
+ }
reset_start = keyframe ? 1 : X264_MIN( num_bframes+2, num_analysed_frames+1 );
}
else
{
for( int j = 1; j <= num_frames; j++ )
- frames[j]->i_type = X264_TYPE_P;
+ if( IS_X264_TYPE_AUTO_OR_B( frames[j]->i_type ) )
+ frames[j]->i_type = X264_TYPE_P;
reset_start = !keyframe + 1;
- num_bframes = 0;
}
/* Perform the actual macroblock tree analysis.
/* Enforce keyframe limit. */
if( !h->param.b_intra_refresh )
- for( int i = keyint_limit+1; i <= num_frames; i += h->param.i_keyint_max )
+ {
+ int last_keyframe = h->lookahead->i_last_keyframe;
+ int last_possible = 0;
+ for( int j = 1; j <= num_frames; j++ )
{
- frames[i]->i_type = X264_TYPE_I;
- reset_start = X264_MIN( reset_start, i+1 );
- if( h->param.b_open_gop && h->param.b_bluray_compat )
- while( IS_X264_TYPE_B( frames[i-1]->i_type ) )
- i--;
+ x264_frame_t *frm = frames[j];
+ int keyframe_dist = frm->i_frame - last_keyframe;
+
+ if( IS_X264_TYPE_AUTO_OR_I( frm->i_forced_type ) )
+ {
+ if( h->param.b_open_gop || !IS_X264_TYPE_B( frames[j-1]->i_forced_type ) )
+ last_possible = j;
+ }
+ if( keyframe_dist >= h->param.i_keyint_max )
+ {
+ if( last_possible != 0 && last_possible != j )
+ {
+ j = last_possible;
+ frm = frames[j];
+ keyframe_dist = frm->i_frame - last_keyframe;
+ }
+ last_possible = 0;
+ if( frm->i_type != X264_TYPE_IDR )
+ frm->i_type = h->param.b_open_gop ? X264_TYPE_I : X264_TYPE_IDR;
+ }
+ if( frm->i_type == X264_TYPE_I && keyframe_dist >= h->param.i_keyint_min )
+ {
+ if( h->param.b_open_gop )
+ {
+ last_keyframe = frm->i_frame;
+ if( h->param.b_bluray_compat )
+ {
+ // Use bluray order
+ int bframes = 0;
+ while( bframes < j-1 && IS_X264_TYPE_B( frames[j-1-bframes]->i_type ) )
+ bframes++;
+ last_keyframe -= bframes;
+ }
+ }
+ else if( frm->i_forced_type != X264_TYPE_I )
+ frm->i_type = X264_TYPE_IDR;
+ }
+ if( frm->i_type == X264_TYPE_IDR )
+ {
+ last_keyframe = frm->i_frame;
+ if( j > 1 && IS_X264_TYPE_B( frames[j-1]->i_type ) )
+ frames[j-1]->i_type = X264_TYPE_P;
+ }
}
+ }
if( vbv_lookahead )
x264_vbv_lookahead( h, &a, frames, num_frames, keyframe );
/* Restore frametypes for all frames that haven't actually been decided yet. */
for( int j = reset_start; j <= num_frames; j++ )
- frames[j]->i_type = X264_TYPE_AUTO;
+ frames[j]->i_type = frames[j]->i_forced_type;
+
+#if HAVE_OPENCL
+ x264_opencl_slicetype_end( h );
+#endif
}
void x264_slicetype_decide( x264_t *h )
for( bframes = 0, brefs = 0;; bframes++ )
{
frm = h->lookahead->next.list[bframes];
+
+ if( frm->i_forced_type != X264_TYPE_AUTO && frm->i_type != frm->i_forced_type &&
+ !(frm->i_forced_type == X264_TYPE_KEYFRAME && IS_X264_TYPE_I( frm->i_type )) )
+ {
+ x264_log( h, X264_LOG_WARNING, "forced frame type (%d) at %d was changed to frame type (%d)\n",
+ frm->i_forced_type, frm->i_frame, frm->i_type );
+ }
+
if( frm->i_type == X264_TYPE_BREF && h->param.i_bframe_pyramid < X264_B_PYRAMID_NORMAL &&
brefs == h->param.i_bframe_pyramid )
{
if( warn && h->param.b_open_gop )
warn &= frm->i_type != X264_TYPE_I;
if( warn )
+ {
x264_log( h, X264_LOG_WARNING, "specified frame type (%d) at %d is not compatible with keyframe interval\n", frm->i_type, frm->i_frame );
+ frm->i_type = h->param.b_open_gop && h->lookahead->i_last_keyframe >= 0 ? X264_TYPE_I : X264_TYPE_IDR;
+ }
}
if( frm->i_type == X264_TYPE_I && frm->i_frame - h->lookahead->i_last_keyframe >= h->param.i_keyint_min )
{
if( i )
{
x264_calculate_durations( h, h->lookahead->next.list[i], h->lookahead->next.list[i-1], &h->i_cpb_delay, &h->i_coded_fields );
- h->lookahead->next.list[0]->f_planned_cpb_duration[i-1] = (double)h->lookahead->next.list[i-1]->i_cpb_duration *
+ h->lookahead->next.list[0]->f_planned_cpb_duration[i-1] = (double)h->lookahead->next.list[i]->i_cpb_duration *
h->sps->vui.i_num_units_in_tick / h->sps->vui.i_time_scale;
}
else
x264_calculate_durations( h, h->lookahead->next.list[i], NULL, &h->i_cpb_delay, &h->i_coded_fields );
-
- h->lookahead->next.list[0]->f_planned_cpb_duration[i] = (double)h->lookahead->next.list[i]->i_cpb_duration *
- h->sps->vui.i_num_units_in_tick / h->sps->vui.i_time_scale;
}
}