385 lines
9.7 KiB
Text
385 lines
9.7 KiB
Text
/******************************************************************************
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Copyright (C) 2014 by Hugh Bailey <obs.jim@gmail.com>
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 2 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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******************************************************************************/
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//#define DEBUGGING
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uniform float4x4 ViewProj;
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uniform float u_plane_offset;
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uniform float v_plane_offset;
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uniform float width;
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uniform float height;
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uniform float width_i;
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uniform float height_i;
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uniform float width_d2;
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uniform float height_d2;
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uniform float width_d2_i;
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uniform float height_d2_i;
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uniform float input_width;
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uniform float input_height;
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uniform float input_width_i;
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uniform float input_height_i;
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uniform float input_width_i_d2;
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uniform float input_height_i_d2;
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uniform int int_width;
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uniform int int_input_width;
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uniform int int_u_plane_offset;
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uniform int int_v_plane_offset;
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uniform texture2d image;
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sampler_state def_sampler {
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Filter = Linear;
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AddressU = Clamp;
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AddressV = Clamp;
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};
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struct VertInOut {
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float4 pos : POSITION;
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float2 uv : TEXCOORD0;
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};
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VertInOut VSDefault(VertInOut vert_in)
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{
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VertInOut vert_out;
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vert_out.pos = mul(float4(vert_in.pos.xyz, 1.0), ViewProj);
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vert_out.uv = vert_in.uv;
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return vert_out;
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}
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/* used to prevent internal GPU precision issues width fmod in particular */
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#define PRECISION_OFFSET 0.2
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float4 PSNV12(VertInOut vert_in) : TARGET
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{
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float v_mul = floor(vert_in.uv.y * input_height);
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float byte_offset = floor((v_mul + vert_in.uv.x) * width) * 4.0;
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byte_offset += PRECISION_OFFSET;
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float2 sample_pos[4];
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if (byte_offset < u_plane_offset) {
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#ifdef DEBUGGING
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return float4(1.0, 1.0, 1.0, 1.0);
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#endif
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float lum_u = floor(fmod(byte_offset, width)) * width_i;
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float lum_v = floor(byte_offset * width_i) * height_i;
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/* move to texel centers to sample the 4 pixels properly */
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lum_u += width_i * 0.5;
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lum_v += height_i * 0.5;
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sample_pos[0] = float2(lum_u, lum_v);
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sample_pos[1] = float2(lum_u += width_i, lum_v);
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sample_pos[2] = float2(lum_u += width_i, lum_v);
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sample_pos[3] = float2(lum_u + width_i, lum_v);
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float4x4 out_val = float4x4(
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image.Sample(def_sampler, sample_pos[0]),
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image.Sample(def_sampler, sample_pos[1]),
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image.Sample(def_sampler, sample_pos[2]),
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image.Sample(def_sampler, sample_pos[3])
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);
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return transpose(out_val)[1];
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} else {
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#ifdef DEBUGGING
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return float4(0.5, 0.2, 0.5, 0.2);
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#endif
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float new_offset = byte_offset - u_plane_offset;
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float ch_u = floor(fmod(new_offset, width)) * width_i;
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float ch_v = floor(new_offset * width_i) * height_d2_i;
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float width_i2 = width_i*2.0;
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/* move to the borders of each set of 4 pixels to force it
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* to do bilinear averaging */
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ch_u += width_i;
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ch_v += height_i;
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sample_pos[0] = float2(ch_u, ch_v);
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sample_pos[1] = float2(ch_u + width_i2, ch_v);
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return float4(
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image.Sample(def_sampler, sample_pos[0]).rb,
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image.Sample(def_sampler, sample_pos[1]).rb
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);
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}
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}
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float4 PSPlanar420(VertInOut vert_in) : TARGET
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{
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float v_mul = floor(vert_in.uv.y * input_height);
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float byte_offset = floor((v_mul + vert_in.uv.x) * width) * 4.0;
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byte_offset += PRECISION_OFFSET;
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float2 sample_pos[4];
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if (byte_offset < u_plane_offset) {
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#ifdef DEBUGGING
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return float4(1.0, 1.0, 1.0, 1.0);
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#endif
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float lum_u = floor(fmod(byte_offset, width)) * width_i;
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float lum_v = floor(byte_offset * width_i) * height_i;
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/* move to texel centers to sample the 4 pixels properly */
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lum_u += width_i * 0.5;
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lum_v += height_i * 0.5;
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sample_pos[0] = float2(lum_u, lum_v);
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sample_pos[1] = float2(lum_u += width_i, lum_v);
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sample_pos[2] = float2(lum_u += width_i, lum_v);
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sample_pos[3] = float2(lum_u + width_i, lum_v);
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} else {
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#ifdef DEBUGGING
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return ((byte_offset < v_plane_offset) ?
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float4(0.5, 0.5, 0.5, 0.5) :
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float4(0.2, 0.2, 0.2, 0.2));
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#endif
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float new_offset = byte_offset -
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((byte_offset < v_plane_offset) ?
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u_plane_offset : v_plane_offset);
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float ch_u = floor(fmod(new_offset, width_d2)) * width_d2_i;
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float ch_v = floor(new_offset * width_d2_i) * height_d2_i;
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float width_i2 = width_i*2.0;
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/* move to the borders of each set of 4 pixels to force it
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* to do bilinear averaging */
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ch_u += width_i;
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ch_v += height_i;
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/* set up coordinates for next chroma line, in case
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* (width / 2) % 4 == 2, i.e. the current set of 4 pixels is split
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* between the current and the next chroma line; do note that the next
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* chroma line is two source lines below the current source line */
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float ch_u_n = 0. + width_i;
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float ch_v_n = ch_v + height_i * 3;
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sample_pos[0] = float2(ch_u, ch_v);
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sample_pos[1] = float2(ch_u += width_i2, ch_v);
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ch_u += width_i2;
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// check if ch_u overflowed the current source and chroma line
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if (ch_u > 1.0) {
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sample_pos[2] = float2(ch_u_n, ch_v_n);
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sample_pos[2] = float2(ch_u_n + width_i2, ch_v_n);
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} else {
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sample_pos[2] = float2(ch_u, ch_v);
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sample_pos[3] = float2(ch_u + width_i2, ch_v);
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}
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}
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float4x4 out_val = float4x4(
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image.Sample(def_sampler, sample_pos[0]),
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image.Sample(def_sampler, sample_pos[1]),
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image.Sample(def_sampler, sample_pos[2]),
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image.Sample(def_sampler, sample_pos[3])
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);
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out_val = transpose(out_val);
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if (byte_offset < u_plane_offset)
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return out_val[1];
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else if (byte_offset < v_plane_offset)
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return out_val[0];
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else
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return out_val[2];
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}
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float4 PSPlanar444(VertInOut vert_in) : TARGET
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{
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float v_mul = floor(vert_in.uv.y * input_height);
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float byte_offset = floor((v_mul + vert_in.uv.x) * width) * 4.0;
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byte_offset += PRECISION_OFFSET;
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float new_byte_offset = byte_offset;
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if (byte_offset >= v_plane_offset)
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new_byte_offset -= v_plane_offset;
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else if (byte_offset >= u_plane_offset)
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new_byte_offset -= u_plane_offset;
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float2 sample_pos[4];
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float u_val = floor(fmod(new_byte_offset, width)) * width_i;
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float v_val = floor(new_byte_offset * width_i) * height_i;
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/* move to texel centers to sample the 4 pixels properly */
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u_val += width_i * 0.5;
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v_val += height_i * 0.5;
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sample_pos[0] = float2(u_val, v_val);
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sample_pos[1] = float2(u_val += width_i, v_val);
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sample_pos[2] = float2(u_val += width_i, v_val);
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sample_pos[3] = float2(u_val + width_i, v_val);
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float4x4 out_val = float4x4(
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image.Sample(def_sampler, sample_pos[0]),
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image.Sample(def_sampler, sample_pos[1]),
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image.Sample(def_sampler, sample_pos[2]),
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image.Sample(def_sampler, sample_pos[3])
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);
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out_val = transpose(out_val);
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if (byte_offset < u_plane_offset)
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return out_val[1];
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else if (byte_offset < v_plane_offset)
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return out_val[0];
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else
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return out_val[2];
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}
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float GetIntOffsetColor(int offset)
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{
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return image.Load(int3(offset % int_input_width,
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offset / int_input_width,
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0)).r;
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}
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float4 PSPacked422_Reverse(VertInOut vert_in, int u_pos, int v_pos,
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int y0_pos, int y1_pos) : TARGET
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{
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float y = vert_in.uv.y;
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float odd = floor(fmod(width * vert_in.uv.x + PRECISION_OFFSET, 2.0));
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float x = floor(width_d2 * vert_in.uv.x + PRECISION_OFFSET) *
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width_d2_i;
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x += input_width_i_d2;
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float4 texel = image.Sample(def_sampler, float2(x, y));
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return float4(odd > 0.5 ? texel[y1_pos] : texel[y0_pos],
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texel[u_pos], texel[v_pos], 1.0);
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}
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float4 PSPlanar420_Reverse(VertInOut vert_in) : TARGET
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{
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int x = int(vert_in.uv.x * width + PRECISION_OFFSET);
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int y = int(vert_in.uv.y * height + PRECISION_OFFSET);
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int lum_offset = y * int_width + x;
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int chroma_offset = (y / 2) * (int_width / 2) + x / 2;
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int chroma1 = int_u_plane_offset + chroma_offset;
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int chroma2 = int_v_plane_offset + chroma_offset;
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return float4(
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GetIntOffsetColor(lum_offset),
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GetIntOffsetColor(chroma1),
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GetIntOffsetColor(chroma2),
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1.0
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);
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}
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float4 PSNV12_Reverse(VertInOut vert_in) : TARGET
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{
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int x = int(vert_in.uv.x * width + PRECISION_OFFSET);
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int y = int(vert_in.uv.y * height + PRECISION_OFFSET);
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int lum_offset = y * int_width + x;
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int chroma_offset = (y / 2) * (int_width / 2) + x / 2;
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int chroma = int_u_plane_offset + chroma_offset * 2;
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return float4(
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GetIntOffsetColor(lum_offset),
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GetIntOffsetColor(chroma),
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GetIntOffsetColor(chroma + 1),
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1.0
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);
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}
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technique Planar420
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSPlanar420(vert_in);
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}
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}
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technique Planar444
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSPlanar444(vert_in);
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}
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}
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technique NV12
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSNV12(vert_in);
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}
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}
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technique UYVY_Reverse
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSPacked422_Reverse(vert_in, 2, 0, 1, 3);
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}
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}
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technique YUY2_Reverse
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSPacked422_Reverse(vert_in, 1, 3, 2, 0);
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}
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}
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technique YVYU_Reverse
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSPacked422_Reverse(vert_in, 3, 1, 2, 0);
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}
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}
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technique I420_Reverse
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSPlanar420_Reverse(vert_in);
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}
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}
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technique NV12_Reverse
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{
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pass
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{
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vertex_shader = VSDefault(vert_in);
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pixel_shader = PSNV12_Reverse(vert_in);
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}
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}
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