test/samples/compute_boids.wgsl.expected.msl - tint - Git at Google

 #include <metal_stdlib>

 using namespace metal;
 struct tint_symbol_1 {
   float2 a_particlePos [[attribute(0)]];
   float2 a_particleVel [[attribute(1)]];
   float2 a_pos [[attribute(2)]];
 };
 struct tint_symbol_2 {
   float4 value [[position]];
 };
 struct tint_symbol_3 {
   float4 value [[color(0)]];
 };
 struct Particle {
   /* 0x0000 */ float2 pos;
   /* 0x0008 */ float2 vel;
 };
 struct SimParams {
   /* 0x0000 */ float deltaT;
   /* 0x0004 */ float rule1Distance;
   /* 0x0008 */ float rule2Distance;
   /* 0x000c */ float rule3Distance;
   /* 0x0010 */ float rule1Scale;
   /* 0x0014 */ float rule2Scale;
   /* 0x0018 */ float rule3Scale;
 };
 struct tint_array_wrapper {
   /* 0x0000 */ Particle arr[5];
 };
 struct Particles {
   /* 0x0000 */ tint_array_wrapper particles;
 };

 float4 vert_main_inner(float2 a_particlePos, float2 a_particleVel, float2 a_pos) {
   float angle = -(atan2(a_particleVel.x, a_particleVel.y));
   float2 pos = float2(((a_pos.x * cos(angle)) - (a_pos.y * sin(angle))), ((a_pos.x * sin(angle)) + (a_pos.y * cos(angle))));
   return float4((pos + a_particlePos), 0.0f, 1.0f);
 }

 vertex tint_symbol_2 vert_main(tint_symbol_1 tint_symbol [[stage_in]]) {
   float4 const inner_result = vert_main_inner(tint_symbol.a_particlePos, tint_symbol.a_particleVel, tint_symbol.a_pos);
   tint_symbol_2 wrapper_result = {};
   wrapper_result.value = inner_result;
   return wrapper_result;
 }

 float4 frag_main_inner() {
   return float4(1.0f, 1.0f, 1.0f, 1.0f);
 }

 fragment tint_symbol_3 frag_main() {
   float4 const inner_result_1 = frag_main_inner();
   tint_symbol_3 wrapper_result_1 = {};
   wrapper_result_1.value = inner_result_1;
   return wrapper_result_1;
 }

 void comp_main_inner(constant SimParams& params, device Particles& particlesA, device Particles& particlesB, uint3 gl_GlobalInvocationID) {
   uint index = gl_GlobalInvocationID.x;
   if ((index >= 5u)) {
     return;
   }
   float2 vPos = particlesA.particles.arr[index].pos;
   float2 vVel = particlesA.particles.arr[index].vel;
   float2 cMass = float2(0.0f, 0.0f);
   float2 cVel = float2(0.0f, 0.0f);
   float2 colVel = float2(0.0f, 0.0f);
   int cMassCount = 0;
   int cVelCount = 0;
   float2 pos = 0.0f;
   float2 vel = 0.0f;
   for(uint i = 0u; (i < 5u); i = (i + 1u)) {
     if ((i == index)) {
       continue;
     }
     pos = particlesA.particles.arr[i].pos.xy;
     vel = particlesA.particles.arr[i].vel.xy;
     if ((distance(pos, vPos) < params.rule1Distance)) {
       cMass = (cMass + pos);
       cMassCount = as_type<int>((as_type<uint>(cMassCount) + as_type<uint>(1)));
     }
     if ((distance(pos, vPos) < params.rule2Distance)) {
       colVel = (colVel - (pos - vPos));
     }
     if ((distance(pos, vPos) < params.rule3Distance)) {
       cVel = (cVel + vel);
       cVelCount = as_type<int>((as_type<uint>(cVelCount) + as_type<uint>(1)));
     }
   }
   if ((cMassCount > 0)) {
     cMass = ((cMass / float2(float(cMassCount), float(cMassCount))) - vPos);
   }
   if ((cVelCount > 0)) {
     cVel = (cVel / float2(float(cVelCount), float(cVelCount)));
   }
   vVel = (((vVel + (cMass * params.rule1Scale)) + (colVel * params.rule2Scale)) + (cVel * params.rule3Scale));
   vVel = (normalize(vVel) * clamp(length(vVel), 0.0f, 0.100000001f));
   vPos = (vPos + (vVel * params.deltaT));
   if ((vPos.x < -1.0f)) {
     vPos.x = 1.0f;
   }
   if ((vPos.x > 1.0f)) {
     vPos.x = -1.0f;
   }
   if ((vPos.y < -1.0f)) {
     vPos.y = 1.0f;
   }
   if ((vPos.y > 1.0f)) {
     vPos.y = -1.0f;
   }
   particlesB.particles.arr[index].pos = vPos;
   particlesB.particles.arr[index].vel = vVel;
 }

 kernel void comp_main(uint3 gl_GlobalInvocationID [[thread_position_in_grid]], constant SimParams& params [[buffer(0)]], device Particles& particlesA [[buffer(1)]], device Particles& particlesB [[buffer(2)]]) {
   comp_main_inner(params, particlesA, particlesB, gl_GlobalInvocationID);
   return;
 }
	#include <metal_stdlib>

	using namespace metal;
	struct tint_symbol_1 {
	float2 a_particlePos [[attribute(0)]];
	float2 a_particleVel [[attribute(1)]];
	float2 a_pos [[attribute(2)]];
	};
	struct tint_symbol_2 {
	float4 value [[position]];
	};
	struct tint_symbol_3 {
	float4 value [[color(0)]];
	};
	struct Particle {
	/* 0x0000 */ float2 pos;
	/* 0x0008 */ float2 vel;
	};
	struct SimParams {
	/* 0x0000 */ float deltaT;
	/* 0x0004 */ float rule1Distance;
	/* 0x0008 */ float rule2Distance;
	/* 0x000c */ float rule3Distance;
	/* 0x0010 */ float rule1Scale;
	/* 0x0014 */ float rule2Scale;
	/* 0x0018 */ float rule3Scale;
	};
	struct tint_array_wrapper {
	/* 0x0000 */ Particle arr[5];
	};
	struct Particles {
	/* 0x0000 */ tint_array_wrapper particles;
	};

	float4 vert_main_inner(float2 a_particlePos, float2 a_particleVel, float2 a_pos) {
	float angle = -(atan2(a_particleVel.x, a_particleVel.y));
	float2 pos = float2(((a_pos.x * cos(angle)) - (a_pos.y * sin(angle))), ((a_pos.x * sin(angle)) + (a_pos.y * cos(angle))));
	return float4((pos + a_particlePos), 0.0f, 1.0f);
	}

	vertex tint_symbol_2 vert_main(tint_symbol_1 tint_symbol [[stage_in]]) {
	float4 const inner_result = vert_main_inner(tint_symbol.a_particlePos, tint_symbol.a_particleVel, tint_symbol.a_pos);
	tint_symbol_2 wrapper_result = {};
	wrapper_result.value = inner_result;
	return wrapper_result;
	}

	float4 frag_main_inner() {
	return float4(1.0f, 1.0f, 1.0f, 1.0f);
	}

	fragment tint_symbol_3 frag_main() {
	float4 const inner_result_1 = frag_main_inner();
	tint_symbol_3 wrapper_result_1 = {};
	wrapper_result_1.value = inner_result_1;
	return wrapper_result_1;
	}

	void comp_main_inner(constant SimParams& params, device Particles& particlesA, device Particles& particlesB, uint3 gl_GlobalInvocationID) {
	uint index = gl_GlobalInvocationID.x;
	if ((index >= 5u)) {
	return;
	}
	float2 vPos = particlesA.particles.arr[index].pos;
	float2 vVel = particlesA.particles.arr[index].vel;
	float2 cMass = float2(0.0f, 0.0f);
	float2 cVel = float2(0.0f, 0.0f);
	float2 colVel = float2(0.0f, 0.0f);
	int cMassCount = 0;
	int cVelCount = 0;
	float2 pos = 0.0f;
	float2 vel = 0.0f;
	for(uint i = 0u; (i < 5u); i = (i + 1u)) {
	if ((i == index)) {
	continue;
	}
	pos = particlesA.particles.arr[i].pos.xy;
	vel = particlesA.particles.arr[i].vel.xy;
	if ((distance(pos, vPos) < params.rule1Distance)) {
	cMass = (cMass + pos);
	cMassCount = as_type<int>((as_type<uint>(cMassCount) + as_type<uint>(1)));
	}
	if ((distance(pos, vPos) < params.rule2Distance)) {
	colVel = (colVel - (pos - vPos));
	}
	if ((distance(pos, vPos) < params.rule3Distance)) {
	cVel = (cVel + vel);
	cVelCount = as_type<int>((as_type<uint>(cVelCount) + as_type<uint>(1)));
	}
	}
	if ((cMassCount > 0)) {
	cMass = ((cMass / float2(float(cMassCount), float(cMassCount))) - vPos);
	}
	if ((cVelCount > 0)) {
	cVel = (cVel / float2(float(cVelCount), float(cVelCount)));
	}
	vVel = (((vVel + (cMass * params.rule1Scale)) + (colVel * params.rule2Scale)) + (cVel * params.rule3Scale));
	vVel = (normalize(vVel) * clamp(length(vVel), 0.0f, 0.100000001f));
	vPos = (vPos + (vVel * params.deltaT));
	if ((vPos.x < -1.0f)) {
	vPos.x = 1.0f;
	}
	if ((vPos.x > 1.0f)) {
	vPos.x = -1.0f;
	}
	if ((vPos.y < -1.0f)) {
	vPos.y = 1.0f;
	}
	if ((vPos.y > 1.0f)) {
	vPos.y = -1.0f;
	}
	particlesB.particles.arr[index].pos = vPos;
	particlesB.particles.arr[index].vel = vVel;
	}

	kernel void comp_main(uint3 gl_GlobalInvocationID [[thread_position_in_grid]], constant SimParams& params [[buffer(0)]], device Particles& particlesA [[buffer(1)]], device Particles& particlesB [[buffer(2)]]) {
	comp_main_inner(params, particlesA, particlesB, gl_GlobalInvocationID);
	return;
	}