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https://github.com/RPCS3/glslang.git
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415 lines
10 KiB
GLSL
415 lines
10 KiB
GLSL
float VertexShaderFunctionS(float inF0, float inF1, float inF2, uint inU0, uint inU1)
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{
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all(inF0);
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abs(inF0);
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acos(inF0);
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any(inF0);
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asin(inF0);
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asint(inF0);
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asuint(inF0);
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asfloat(inU0);
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// asdouble(inU0, inU1); // TODO: enable when HLSL parser used for intrinsics
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atan(inF0);
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atan2(inF0, inF1);
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ceil(inF0);
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clamp(inF0, inF1, inF2);
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cos(inF0);
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cosh(inF0);
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countbits(7);
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degrees(inF0);
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// EvaluateAttributeAtCentroid(inF0);
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// EvaluateAttributeAtSample(inF0, 0);
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// TODO: EvaluateAttributeSnapped(inF0, int2(1,2));
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exp(inF0);
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exp2(inF0);
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firstbithigh(7);
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firstbitlow(7);
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floor(inF0);
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// TODO: fma(inD0, inD1, inD2);
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fmod(inF0, inF1);
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frac(inF0);
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isinf(inF0);
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isnan(inF0);
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ldexp(inF0, inF1);
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lerp(inF0, inF1, inF2);
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log(inF0);
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log10(inF0);
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log2(inF0);
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max(inF0, inF1);
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min(inF0, inF1);
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// TODO: mul(inF0, inF1);
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pow(inF0, inF1);
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radians(inF0);
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reversebits(2);
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round(inF0);
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rsqrt(inF0);
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saturate(inF0);
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sign(inF0);
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sin(inF0);
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sincos(inF0, inF1, inF2);
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sinh(inF0);
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smoothstep(inF0, inF1, inF2);
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sqrt(inF0);
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step(inF0, inF1);
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tan(inF0);
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tanh(inF0);
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// TODO: sampler intrinsics, when we can declare the types.
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trunc(inF0);
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return 0.0;
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}
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float1 VertexShaderFunction1(float1 inF0, float1 inF1, float1 inF2)
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{
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// TODO: ... add when float1 prototypes are generated
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return 0.0;
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}
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float2 VertexShaderFunction2(float2 inF0, float2 inF1, float2 inF2, uint2 inU0, uint2 inU1)
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{
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all(inF0);
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abs(inF0);
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acos(inF0);
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any(inF0);
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asin(inF0);
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asint(inF0);
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asuint(inF0);
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asfloat(inU0);
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// asdouble(inU0, inU1); // TODO: enable when HLSL parser used for intrinsics
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atan(inF0);
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atan2(inF0, inF1);
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ceil(inF0);
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clamp(inF0, inF1, inF2);
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cos(inF0);
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cosh(inF0);
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countbits(int2(7,3));
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degrees(inF0);
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distance(inF0, inF1);
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dot(inF0, inF1);
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// EvaluateAttributeAtCentroid(inF0);
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// EvaluateAttributeAtSample(inF0, 0);
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// TODO: EvaluateAttributeSnapped(inF0, int2(1,2));
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exp(inF0);
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exp2(inF0);
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faceforward(inF0, inF1, inF2);
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firstbithigh(7);
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firstbitlow(7);
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floor(inF0);
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// TODO: fma(inD0, inD1, inD2);
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fmod(inF0, inF1);
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frac(inF0);
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isinf(inF0);
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isnan(inF0);
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ldexp(inF0, inF1);
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lerp(inF0, inF1, inF2);
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length(inF0);
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log(inF0);
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log10(inF0);
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log2(inF0);
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max(inF0, inF1);
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min(inF0, inF1);
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// TODO: mul(inF0, inF1);
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normalize(inF0);
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pow(inF0, inF1);
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radians(inF0);
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reflect(inF0, inF1);
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refract(inF0, inF1, 2.0);
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reversebits(int2(1,2));
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round(inF0);
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rsqrt(inF0);
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saturate(inF0);
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sign(inF0);
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sin(inF0);
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sincos(inF0, inF1, inF2);
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sinh(inF0);
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smoothstep(inF0, inF1, inF2);
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sqrt(inF0);
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step(inF0, inF1);
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tan(inF0);
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tanh(inF0);
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// TODO: sampler intrinsics, when we can declare the types.
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trunc(inF0);
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// TODO: ... add when float1 prototypes are generated
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return float2(1,2);
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}
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float3 VertexShaderFunction3(float3 inF0, float3 inF1, float3 inF2, uint3 inU0, uint3 inU1)
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{
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all(inF0);
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abs(inF0);
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acos(inF0);
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any(inF0);
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asin(inF0);
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asint(inF0);
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asuint(inF0);
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asfloat(inU0);
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// asdouble(inU0, inU1); // TODO: enable when HLSL parser used for intrinsics
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atan(inF0);
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atan2(inF0, inF1);
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ceil(inF0);
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clamp(inF0, inF1, inF2);
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cos(inF0);
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cosh(inF0);
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countbits(int3(7,3,5));
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cross(inF0, inF1);
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degrees(inF0);
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distance(inF0, inF1);
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dot(inF0, inF1);
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// EvaluateAttributeAtCentroid(inF0);
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// EvaluateAttributeAtSample(inF0, 0);
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// TODO: EvaluateAttributeSnapped(inF0, int2(1,2));
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exp(inF0);
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exp2(inF0);
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faceforward(inF0, inF1, inF2);
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firstbithigh(7);
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firstbitlow(7);
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floor(inF0);
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// TODO: fma(inD0, inD1, inD2);
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fmod(inF0, inF1);
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frac(inF0);
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isinf(inF0);
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isnan(inF0);
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ldexp(inF0, inF1);
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lerp(inF0, inF1, inF2);
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length(inF0);
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log(inF0);
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log10(inF0);
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log2(inF0);
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max(inF0, inF1);
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min(inF0, inF1);
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// TODO: mul(inF0, inF1);
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normalize(inF0);
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pow(inF0, inF1);
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radians(inF0);
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reflect(inF0, inF1);
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refract(inF0, inF1, 2.0);
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reversebits(int3(1,2,3));
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round(inF0);
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rsqrt(inF0);
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saturate(inF0);
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sign(inF0);
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sin(inF0);
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sincos(inF0, inF1, inF2);
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sinh(inF0);
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smoothstep(inF0, inF1, inF2);
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sqrt(inF0);
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step(inF0, inF1);
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tan(inF0);
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tanh(inF0);
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// TODO: sampler intrinsics, when we can declare the types.
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trunc(inF0);
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// TODO: ... add when float1 prototypes are generated
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return float3(1,2,3);
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}
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float4 VertexShaderFunction4(float4 inF0, float4 inF1, float4 inF2, uint4 inU0, uint4 inU1)
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{
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all(inF0);
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abs(inF0);
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acos(inF0);
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any(inF0);
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asin(inF0);
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asint(inF0);
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asuint(inF0);
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asfloat(inU0);
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// asdouble(inU0, inU1); // TODO: enable when HLSL parser used for intrinsics
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atan(inF0);
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atan2(inF0, inF1);
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ceil(inF0);
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clamp(inF0, inF1, inF2);
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cos(inF0);
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cosh(inF0);
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countbits(int4(7,3,5,2));
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degrees(inF0);
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distance(inF0, inF1);
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dot(inF0, inF1);
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dst(inF0, inF1);
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// EvaluateAttributeAtCentroid(inF0);
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// EvaluateAttributeAtSample(inF0, 0);
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// TODO: EvaluateAttributeSnapped(inF0, int2(1,2));
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exp(inF0);
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exp2(inF0);
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faceforward(inF0, inF1, inF2);
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firstbithigh(7);
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firstbitlow(7);
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floor(inF0);
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// TODO: fma(inD0, inD1, inD2);
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fmod(inF0, inF1);
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frac(inF0);
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isinf(inF0);
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isnan(inF0);
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ldexp(inF0, inF1);
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lerp(inF0, inF1, inF2);
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length(inF0);
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log(inF0);
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log10(inF0);
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log2(inF0);
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max(inF0, inF1);
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min(inF0, inF1);
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// TODO: mul(inF0, inF1);
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normalize(inF0);
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pow(inF0, inF1);
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radians(inF0);
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reflect(inF0, inF1);
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refract(inF0, inF1, 2.0);
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reversebits(int4(1,2,3,4));
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round(inF0);
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rsqrt(inF0);
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saturate(inF0);
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sign(inF0);
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sin(inF0);
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sincos(inF0, inF1, inF2);
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sinh(inF0);
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smoothstep(inF0, inF1, inF2);
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sqrt(inF0);
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step(inF0, inF1);
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tan(inF0);
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tanh(inF0);
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// TODO: sampler intrinsics, when we can declare the types.
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trunc(inF0);
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// TODO: ... add when float1 prototypes are generated
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return float4(1,2,3,4);
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}
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// TODO: for mats:
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// asfloat(inU0); \
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// asint(inF0); \
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// asuint(inF0); \
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// TODO: FXC doesn't accept this with (), but glslang doesn't accept it without.
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#define MATFNS() \
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all(inF0); \
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abs(inF0); \
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acos(inF0); \
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any(inF0); \
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asin(inF0); \
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atan(inF0); \
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atan2(inF0, inF1); \
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ceil(inF0); \
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clamp(inF0, inF1, inF2); \
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cos(inF0); \
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cosh(inF0); \
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degrees(inF0); \
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determinant(inF0); \
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exp(inF0); \
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exp2(inF0); \
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firstbithigh(7); \
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firstbitlow(7); \
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floor(inF0); \
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fmod(inF0, inF1); \
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frac(inF0); \
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ldexp(inF0, inF1); \
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lerp(inF0, inF1, inF2); \
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log(inF0); \
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log10(inF0); \
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log2(inF0); \
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max(inF0, inF1); \
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min(inF0, inF1); \
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pow(inF0, inF1); \
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radians(inF0); \
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round(inF0); \
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rsqrt(inF0); \
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saturate(inF0); \
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sign(inF0); \
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sin(inF0); \
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sincos(inF0, inF1, inF2); \
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sinh(inF0); \
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smoothstep(inF0, inF1, inF2); \
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sqrt(inF0); \
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step(inF0, inF1); \
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tan(inF0); \
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tanh(inF0); \
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transpose(inF0); \
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trunc(inF0);
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// TODO: turn on non-square matrix tests when protos are available.
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float2x2 VertexShaderFunction2x2(float2x2 inF0, float2x2 inF1, float2x2 inF2)
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{
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// TODO: FXC doesn't accept this with (), but glslang doesn't accept it without.
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MATFNS();
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// TODO: ... add when float1 prototypes are generated
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return float2x2(2,2,2,2);
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}
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float3x3 VertexShaderFunction3x3(float3x3 inF0, float3x3 inF1, float3x3 inF2)
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{
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// TODO: FXC doesn't accept this with (), but glslang doesn't accept it without.
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MATFNS();
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// TODO: ... add when float1 prototypes are generated
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return float3x3(3,3,3,3,3,3,3,3,3);
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}
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float4x4 VertexShaderFunction4x4(float4x4 inF0, float4x4 inF1, float4x4 inF2)
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{
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// TODO: FXC doesn't accept this with (), but glslang doesn't accept it without.
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MATFNS();
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// TODO: ... add when float1 prototypes are generated
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return float4x4(4,4,4,4,4,4,4,4,4,4,4,4,4,4,4,4);
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}
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#define TESTGENMUL(ST, VT, MT) \
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ST r0 = mul(inF0, inF1); \
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VT r1 = mul(inFV0, inF0); \
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VT r2 = mul(inF0, inFV0); \
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ST r3 = mul(inFV0, inFV1); \
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VT r4 = mul(inFM0, inFV0); \
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VT r5 = mul(inFV0, inFM0); \
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MT r6 = mul(inFM0, inF0); \
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MT r7 = mul(inF0, inFM0); \
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MT r8 = mul(inFM0, inFM1);
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void TestGenMul2(float inF0, float inF1,
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float2 inFV0, float2 inFV1,
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float2x2 inFM0, float2x2 inFM1)
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{
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TESTGENMUL(float, float2, float2x2);
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}
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void TestGenMul3(float inF0, float inF1,
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float3 inFV0, float3 inFV1,
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float3x3 inFM0, float3x3 inFM1)
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{
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TESTGENMUL(float, float3, float3x3);
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}
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void TestGenMul4(float inF0, float inF1,
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float4 inFV0, float4 inFV1,
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float4x4 inFM0, float4x4 inFM1)
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{
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TESTGENMUL(float, float4, float4x4);
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}
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// Test some non-square mats
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void TestGenMulNxM(float inF0, float inF1,
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float2 inFV2, float3 inFV3,
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float2x3 inFM2x3, float3x2 inFM3x2,
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float3x3 inFM3x3, float3x4 inFM3x4,
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float2x4 inFM2x4)
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{
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float r00 = mul(inF0, inF1); // S=S*S
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float2 r01 = mul(inFV2, inF0); // V=V*S
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float3 r02 = mul(inFV3, inF0); // V=V*S
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float2 r03 = mul(inF0, inFV2); // V=S*V
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float3 r04 = mul(inF0, inFV3); // V=S*V
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float r05 = mul(inFV2, inFV2); // S=V*V
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float r06 = mul(inFV3, inFV3); // S=V*V
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float3 r07 = mul(inFV2, inFM2x3); // V=V*M (return V dim is Mcols)
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float2 r08 = mul(inFV3, inFM3x2); // V=V*M (return V dim is Mcols)
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float2 r09 = mul(inFM2x3, inFV3); // V=M*V (return V dim is Mrows)
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float3 r10 = mul(inFM3x2, inFV2); // V=M*V (return V dim is Mrows)
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float2x3 r11 = mul(inFM2x3, inF0);
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float3x2 r12 = mul(inFM3x2, inF0);
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float2x2 r13 = mul(inFM2x3, inFM3x2);
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float2x3 r14 = mul(inFM2x3, inFM3x3);
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float2x4 r15 = mul(inFM2x3, inFM3x4);
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float3x4 r16 = mul(inFM3x2, inFM2x4);
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}
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