test/benchmark/metaball-isosurface.wgsl.expected.hlsl - tint - Git at Google

 uint atomicAdd_1(RWByteAddressBuffer buffer, uint offset, uint value) {
   uint original_value = 0;
   buffer.InterlockedAdd(offset, value, original_value);
   return original_value;
 }

 ByteAddressBuffer tables : register(t0, space0);

 RWByteAddressBuffer volume : register(u1, space0);

 RWByteAddressBuffer positionsOut : register(u2, space0);

 RWByteAddressBuffer normalsOut : register(u3, space0);

 RWByteAddressBuffer indicesOut : register(u4, space0);

 RWByteAddressBuffer drawOut : register(u5, space0);

 float valueAt(uint3 index) {
   if (any((index >= volume.Load3(48u)))) {
     return 0.0f;
   }
   const uint valueIndex = ((index.x + (index.y * volume.Load(48u))) + ((index.z * volume.Load(48u)) * volume.Load(52u)));
   return asfloat(volume.Load((64u + (4u * valueIndex))));
 }

 float3 positionAt(uint3 index) {
   return (asfloat(volume.Load3(0u)) + (asfloat(volume.Load3(32u)) * float3(index.xyz)));
 }

 float3 normalAt(uint3 index) {
   return float3((valueAt((index - uint3(1u, 0u, 0u))) - valueAt((index + uint3(1u, 0u, 0u)))), (valueAt((index - uint3(0u, 1u, 0u))) - valueAt((index + uint3(0u, 1u, 0u)))), (valueAt((index - uint3(0u, 0u, 1u))) - valueAt((index + uint3(0u, 0u, 1u)))));
 }

 static float3 positions[12] = (float3[12])0;
 static float3 normals[12] = (float3[12])0;
 static uint indices[12] = (uint[12])0;
 static uint cubeVerts = 0u;

 void interpX(uint index, uint3 i, float va, float vb) {
   const float mu = ((asfloat(volume.Load(60u)) - va) / (vb - va));
   positions[cubeVerts] = (positionAt(i) + float3((asfloat(volume.Load(32u)) * mu), 0.0f, 0.0f));
   const float3 na = normalAt(i);
   const float3 nb = normalAt((i + uint3(1u, 0u, 0u)));
   normals[cubeVerts] = lerp(na, nb, float3(mu, mu, mu));
   indices[index] = cubeVerts;
   cubeVerts = (cubeVerts + 1u);
 }

 void interpY(uint index, uint3 i, float va, float vb) {
   const float mu = ((asfloat(volume.Load(60u)) - va) / (vb - va));
   positions[cubeVerts] = (positionAt(i) + float3(0.0f, (asfloat(volume.Load(36u)) * mu), 0.0f));
   const float3 na = normalAt(i);
   const float3 nb = normalAt((i + uint3(0u, 1u, 0u)));
   normals[cubeVerts] = lerp(na, nb, float3(mu, mu, mu));
   indices[index] = cubeVerts;
   cubeVerts = (cubeVerts + 1u);
 }

 void interpZ(uint index, uint3 i, float va, float vb) {
   const float mu = ((asfloat(volume.Load(60u)) - va) / (vb - va));
   positions[cubeVerts] = (positionAt(i) + float3(0.0f, 0.0f, (asfloat(volume.Load(40u)) * mu)));
   const float3 na = normalAt(i);
   const float3 nb = normalAt((i + uint3(0u, 0u, 1u)));
   normals[cubeVerts] = lerp(na, nb, float3(mu, mu, mu));
   indices[index] = cubeVerts;
   cubeVerts = (cubeVerts + 1u);
 }

 struct tint_symbol_1 {
   uint3 global_id : SV_DispatchThreadID;
 };

 void computeMain_inner(uint3 global_id) {
   const uint3 i0 = global_id;
   const uint3 i1 = (global_id + uint3(1u, 0u, 0u));
   const uint3 i2 = (global_id + uint3(1u, 1u, 0u));
   const uint3 i3 = (global_id + uint3(0u, 1u, 0u));
   const uint3 i4 = (global_id + uint3(0u, 0u, 1u));
   const uint3 i5 = (global_id + uint3(1u, 0u, 1u));
   const uint3 i6 = (global_id + uint3(1u, 1u, 1u));
   const uint3 i7 = (global_id + uint3(0u, 1u, 1u));
   const float v0 = valueAt(i0);
   const float v1 = valueAt(i1);
   const float v2 = valueAt(i2);
   const float v3 = valueAt(i3);
   const float v4 = valueAt(i4);
   const float v5 = valueAt(i5);
   const float v6 = valueAt(i6);
   const float v7 = valueAt(i7);
   uint cubeIndex = 0u;
   if ((v0 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 1u);
   }
   if ((v1 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 2u);
   }
   if ((v2 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 4u);
   }
   if ((v3 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 8u);
   }
   if ((v4 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 16u);
   }
   if ((v5 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 32u);
   }
   if ((v6 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 64u);
   }
   if ((v7 < asfloat(volume.Load(60u)))) {
     cubeIndex = (cubeIndex | 128u);
   }
   const uint edges = tables.Load((4u * cubeIndex));
   if (((edges & 1u) != 0u)) {
     interpX(0u, i0, v0, v1);
   }
   if (((edges & 2u) != 0u)) {
     interpY(1u, i1, v1, v2);
   }
   if (((edges & 4u) != 0u)) {
     interpX(2u, i3, v3, v2);
   }
   if (((edges & 8u) != 0u)) {
     interpY(3u, i0, v0, v3);
   }
   if (((edges & 16u) != 0u)) {
     interpX(4u, i4, v4, v5);
   }
   if (((edges & 32u) != 0u)) {
     interpY(5u, i5, v5, v6);
   }
   if (((edges & 64u) != 0u)) {
     interpX(6u, i7, v7, v6);
   }
   if (((edges & 128u) != 0u)) {
     interpY(7u, i4, v4, v7);
   }
   if (((edges & 256u) != 0u)) {
     interpZ(8u, i0, v0, v4);
   }
   if (((edges & 512u) != 0u)) {
     interpZ(9u, i1, v1, v5);
   }
   if (((edges & 1024u) != 0u)) {
     interpZ(10u, i2, v2, v6);
   }
   if (((edges & 2048u) != 0u)) {
     interpZ(11u, i3, v3, v7);
   }
   const uint triTableOffset = ((cubeIndex << 4u) + 1u);
   const uint indexCount = uint(asint(tables.Load((1024u + (4u * (triTableOffset - 1u))))));
   uint firstVertex = atomicAdd_1(drawOut, 4u, cubeVerts);
   const uint bufferOffset = ((global_id.x + (global_id.y * volume.Load(48u))) + ((global_id.z * volume.Load(48u)) * volume.Load(52u)));
   const uint firstIndex = (bufferOffset * 15u);
   {
     [loop] for(uint i = 0u; (i < cubeVerts); i = (i + 1u)) {
       positionsOut.Store((4u * ((firstVertex * 3u) + (i * 3u))), asuint(positions[i].x));
       positionsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 1u)), asuint(positions[i].y));
       positionsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 2u)), asuint(positions[i].z));
       normalsOut.Store((4u * ((firstVertex * 3u) + (i * 3u))), asuint(normals[i].x));
       normalsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 1u)), asuint(normals[i].y));
       normalsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 2u)), asuint(normals[i].z));
     }
   }
   {
     [loop] for(uint i = 0u; (i < indexCount); i = (i + 1u)) {
       const int index = asint(tables.Load((1024u + (4u * (triTableOffset + i)))));
       indicesOut.Store((4u * (firstIndex + i)), asuint((firstVertex + indices[index])));
     }
   }
   {
     [loop] for(uint i = indexCount; (i < 15u); i = (i + 1u)) {
       indicesOut.Store((4u * (firstIndex + i)), asuint(firstVertex));
     }
   }
 }

 [numthreads(4, 4, 4)]
 void computeMain(tint_symbol_1 tint_symbol) {
   computeMain_inner(tint_symbol.global_id);
   return;
 }
	uint atomicAdd_1(RWByteAddressBuffer buffer, uint offset, uint value) {
	uint original_value = 0;
	buffer.InterlockedAdd(offset, value, original_value);
	return original_value;
	}

	ByteAddressBuffer tables : register(t0, space0);

	RWByteAddressBuffer volume : register(u1, space0);

	RWByteAddressBuffer positionsOut : register(u2, space0);

	RWByteAddressBuffer normalsOut : register(u3, space0);

	RWByteAddressBuffer indicesOut : register(u4, space0);

	RWByteAddressBuffer drawOut : register(u5, space0);

	float valueAt(uint3 index) {
	if (any((index >= volume.Load3(48u)))) {
	return 0.0f;
	}
	const uint valueIndex = ((index.x + (index.y * volume.Load(48u))) + ((index.z * volume.Load(48u)) * volume.Load(52u)));
	return asfloat(volume.Load((64u + (4u * valueIndex))));
	}

	float3 positionAt(uint3 index) {
	return (asfloat(volume.Load3(0u)) + (asfloat(volume.Load3(32u)) * float3(index.xyz)));
	}

	float3 normalAt(uint3 index) {
	return float3((valueAt((index - uint3(1u, 0u, 0u))) - valueAt((index + uint3(1u, 0u, 0u)))), (valueAt((index - uint3(0u, 1u, 0u))) - valueAt((index + uint3(0u, 1u, 0u)))), (valueAt((index - uint3(0u, 0u, 1u))) - valueAt((index + uint3(0u, 0u, 1u)))));
	}

	static float3 positions[12] = (float3[12])0;
	static float3 normals[12] = (float3[12])0;
	static uint indices[12] = (uint[12])0;
	static uint cubeVerts = 0u;

	void interpX(uint index, uint3 i, float va, float vb) {
	const float mu = ((asfloat(volume.Load(60u)) - va) / (vb - va));
	positions[cubeVerts] = (positionAt(i) + float3((asfloat(volume.Load(32u)) * mu), 0.0f, 0.0f));
	const float3 na = normalAt(i);
	const float3 nb = normalAt((i + uint3(1u, 0u, 0u)));
	normals[cubeVerts] = lerp(na, nb, float3(mu, mu, mu));
	indices[index] = cubeVerts;
	cubeVerts = (cubeVerts + 1u);
	}

	void interpY(uint index, uint3 i, float va, float vb) {
	const float mu = ((asfloat(volume.Load(60u)) - va) / (vb - va));
	positions[cubeVerts] = (positionAt(i) + float3(0.0f, (asfloat(volume.Load(36u)) * mu), 0.0f));
	const float3 na = normalAt(i);
	const float3 nb = normalAt((i + uint3(0u, 1u, 0u)));
	normals[cubeVerts] = lerp(na, nb, float3(mu, mu, mu));
	indices[index] = cubeVerts;
	cubeVerts = (cubeVerts + 1u);
	}

	void interpZ(uint index, uint3 i, float va, float vb) {
	const float mu = ((asfloat(volume.Load(60u)) - va) / (vb - va));
	positions[cubeVerts] = (positionAt(i) + float3(0.0f, 0.0f, (asfloat(volume.Load(40u)) * mu)));
	const float3 na = normalAt(i);
	const float3 nb = normalAt((i + uint3(0u, 0u, 1u)));
	normals[cubeVerts] = lerp(na, nb, float3(mu, mu, mu));
	indices[index] = cubeVerts;
	cubeVerts = (cubeVerts + 1u);
	}

	struct tint_symbol_1 {
	uint3 global_id : SV_DispatchThreadID;
	};

	void computeMain_inner(uint3 global_id) {
	const uint3 i0 = global_id;
	const uint3 i1 = (global_id + uint3(1u, 0u, 0u));
	const uint3 i2 = (global_id + uint3(1u, 1u, 0u));
	const uint3 i3 = (global_id + uint3(0u, 1u, 0u));
	const uint3 i4 = (global_id + uint3(0u, 0u, 1u));
	const uint3 i5 = (global_id + uint3(1u, 0u, 1u));
	const uint3 i6 = (global_id + uint3(1u, 1u, 1u));
	const uint3 i7 = (global_id + uint3(0u, 1u, 1u));
	const float v0 = valueAt(i0);
	const float v1 = valueAt(i1);
	const float v2 = valueAt(i2);
	const float v3 = valueAt(i3);
	const float v4 = valueAt(i4);
	const float v5 = valueAt(i5);
	const float v6 = valueAt(i6);
	const float v7 = valueAt(i7);
	uint cubeIndex = 0u;
	if ((v0 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 1u);
	}
	if ((v1 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 2u);
	}
	if ((v2 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 4u);
	}
	if ((v3 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 8u);
	}
	if ((v4 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 16u);
	}
	if ((v5 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 32u);
	}
	if ((v6 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 64u);
	}
	if ((v7 < asfloat(volume.Load(60u)))) {
	cubeIndex = (cubeIndex \| 128u);
	}
	const uint edges = tables.Load((4u * cubeIndex));
	if (((edges & 1u) != 0u)) {
	interpX(0u, i0, v0, v1);
	}
	if (((edges & 2u) != 0u)) {
	interpY(1u, i1, v1, v2);
	}
	if (((edges & 4u) != 0u)) {
	interpX(2u, i3, v3, v2);
	}
	if (((edges & 8u) != 0u)) {
	interpY(3u, i0, v0, v3);
	}
	if (((edges & 16u) != 0u)) {
	interpX(4u, i4, v4, v5);
	}
	if (((edges & 32u) != 0u)) {
	interpY(5u, i5, v5, v6);
	}
	if (((edges & 64u) != 0u)) {
	interpX(6u, i7, v7, v6);
	}
	if (((edges & 128u) != 0u)) {
	interpY(7u, i4, v4, v7);
	}
	if (((edges & 256u) != 0u)) {
	interpZ(8u, i0, v0, v4);
	}
	if (((edges & 512u) != 0u)) {
	interpZ(9u, i1, v1, v5);
	}
	if (((edges & 1024u) != 0u)) {
	interpZ(10u, i2, v2, v6);
	}
	if (((edges & 2048u) != 0u)) {
	interpZ(11u, i3, v3, v7);
	}
	const uint triTableOffset = ((cubeIndex << 4u) + 1u);
	const uint indexCount = uint(asint(tables.Load((1024u + (4u * (triTableOffset - 1u))))));
	uint firstVertex = atomicAdd_1(drawOut, 4u, cubeVerts);
	const uint bufferOffset = ((global_id.x + (global_id.y * volume.Load(48u))) + ((global_id.z * volume.Load(48u)) * volume.Load(52u)));
	const uint firstIndex = (bufferOffset * 15u);
	{
	[loop] for(uint i = 0u; (i < cubeVerts); i = (i + 1u)) {
	positionsOut.Store((4u * ((firstVertex * 3u) + (i * 3u))), asuint(positions[i].x));
	positionsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 1u)), asuint(positions[i].y));
	positionsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 2u)), asuint(positions[i].z));
	normalsOut.Store((4u * ((firstVertex * 3u) + (i * 3u))), asuint(normals[i].x));
	normalsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 1u)), asuint(normals[i].y));
	normalsOut.Store((4u * (((firstVertex * 3u) + (i * 3u)) + 2u)), asuint(normals[i].z));
	}
	}
	{
	[loop] for(uint i = 0u; (i < indexCount); i = (i + 1u)) {
	const int index = asint(tables.Load((1024u + (4u * (triTableOffset + i)))));
	indicesOut.Store((4u * (firstIndex + i)), asuint((firstVertex + indices[index])));
	}
	}
	{
	[loop] for(uint i = indexCount; (i < 15u); i = (i + 1u)) {
	indicesOut.Store((4u * (firstIndex + i)), asuint(firstVertex));
	}
	}
	}

	[numthreads(4, 4, 4)]
	void computeMain(tint_symbol_1 tint_symbol) {
	computeMain_inner(tint_symbol.global_id);
	return;
	}