test/tint/buffer/uniform/std140/struct/mat3x2_f16/to_storage.wgsl.expected.fxc.hlsl - dawn - Git at Google

 SKIP: FAILED

 struct S {
   int before;
   matrix<float16_t, 3, 2> m;
   int after;
 };

 cbuffer cbuffer_u : register(b0, space0) {
   uint4 u[32];
 };
 RWByteAddressBuffer s : register(u1, space0);

 void s_store_3(uint offset, matrix<float16_t, 3, 2> value) {
   s.Store<vector<float16_t, 2> >((offset + 0u), value[0u]);
   s.Store<vector<float16_t, 2> >((offset + 4u), value[1u]);
   s.Store<vector<float16_t, 2> >((offset + 8u), value[2u]);
 }

 void s_store_1(uint offset, S value) {
   s.Store((offset + 0u), asuint(value.before));
   s_store_3((offset + 4u), value.m);
   s.Store((offset + 64u), asuint(value.after));
 }

 void s_store(uint offset, S value[4]) {
   S array_1[4] = value;
   {
     for(uint i = 0u; (i < 4u); i = (i + 1u)) {
       s_store_1((offset + (i * 128u)), array_1[i]);
     }
   }
 }

 matrix<float16_t, 3, 2> u_load_3(uint offset) {
   const uint scalar_offset = ((offset + 0u)) / 4;
   uint ubo_load = u[scalar_offset / 4][scalar_offset % 4];
   const uint scalar_offset_1 = ((offset + 4u)) / 4;
   uint ubo_load_1 = u[scalar_offset_1 / 4][scalar_offset_1 % 4];
   const uint scalar_offset_2 = ((offset + 8u)) / 4;
   uint ubo_load_2 = u[scalar_offset_2 / 4][scalar_offset_2 % 4];
   return matrix<float16_t, 3, 2>(vector<float16_t, 2>(float16_t(f16tof32(ubo_load & 0xFFFF)), float16_t(f16tof32(ubo_load >> 16))), vector<float16_t, 2>(float16_t(f16tof32(ubo_load_1 & 0xFFFF)), float16_t(f16tof32(ubo_load_1 >> 16))), vector<float16_t, 2>(float16_t(f16tof32(ubo_load_2 & 0xFFFF)), float16_t(f16tof32(ubo_load_2 >> 16))));
 }

 S u_load_1(uint offset) {
   const uint scalar_offset_3 = ((offset + 0u)) / 4;
   const uint scalar_offset_4 = ((offset + 64u)) / 4;
   const S tint_symbol = {asint(u[scalar_offset_3 / 4][scalar_offset_3 % 4]), u_load_3((offset + 4u)), asint(u[scalar_offset_4 / 4][scalar_offset_4 % 4])};
   return tint_symbol;
 }

 typedef S u_load_ret[4];
 u_load_ret u_load(uint offset) {
   S arr[4] = (S[4])0;
   {
     for(uint i_1 = 0u; (i_1 < 4u); i_1 = (i_1 + 1u)) {
       arr[i_1] = u_load_1((offset + (i_1 * 128u)));
     }
   }
   return arr;
 }

 [numthreads(1, 1, 1)]
 void f() {
   s_store(0u, u_load(0u));
   s_store_1(128u, u_load_1(256u));
   s_store_3(388u, u_load_3(260u));
   uint ubo_load_3 = u[0].z;
   s.Store<vector<float16_t, 2> >(132u, vector<float16_t, 2>(float16_t(f16tof32(ubo_load_3 & 0xFFFF)), float16_t(f16tof32(ubo_load_3 >> 16))).yx);
   return;
 }
	SKIP: FAILED

	struct S {
	int before;
	matrix<float16_t, 3, 2> m;
	int after;
	};

	cbuffer cbuffer_u : register(b0, space0) {
	uint4 u[32];
	};
	RWByteAddressBuffer s : register(u1, space0);

	void s_store_3(uint offset, matrix<float16_t, 3, 2> value) {
	s.Store<vector<float16_t, 2> >((offset + 0u), value[0u]);
	s.Store<vector<float16_t, 2> >((offset + 4u), value[1u]);
	s.Store<vector<float16_t, 2> >((offset + 8u), value[2u]);
	}

	void s_store_1(uint offset, S value) {
	s.Store((offset + 0u), asuint(value.before));
	s_store_3((offset + 4u), value.m);
	s.Store((offset + 64u), asuint(value.after));
	}

	void s_store(uint offset, S value[4]) {
	S array_1[4] = value;
	{
	for(uint i = 0u; (i < 4u); i = (i + 1u)) {
	s_store_1((offset + (i * 128u)), array_1[i]);
	}
	}
	}

	matrix<float16_t, 3, 2> u_load_3(uint offset) {
	const uint scalar_offset = ((offset + 0u)) / 4;
	uint ubo_load = u[scalar_offset / 4][scalar_offset % 4];
	const uint scalar_offset_1 = ((offset + 4u)) / 4;
	uint ubo_load_1 = u[scalar_offset_1 / 4][scalar_offset_1 % 4];
	const uint scalar_offset_2 = ((offset + 8u)) / 4;
	uint ubo_load_2 = u[scalar_offset_2 / 4][scalar_offset_2 % 4];
	return matrix<float16_t, 3, 2>(vector<float16_t, 2>(float16_t(f16tof32(ubo_load & 0xFFFF)), float16_t(f16tof32(ubo_load >> 16))), vector<float16_t, 2>(float16_t(f16tof32(ubo_load_1 & 0xFFFF)), float16_t(f16tof32(ubo_load_1 >> 16))), vector<float16_t, 2>(float16_t(f16tof32(ubo_load_2 & 0xFFFF)), float16_t(f16tof32(ubo_load_2 >> 16))));
	}

	S u_load_1(uint offset) {
	const uint scalar_offset_3 = ((offset + 0u)) / 4;
	const uint scalar_offset_4 = ((offset + 64u)) / 4;
	const S tint_symbol = {asint(u[scalar_offset_3 / 4][scalar_offset_3 % 4]), u_load_3((offset + 4u)), asint(u[scalar_offset_4 / 4][scalar_offset_4 % 4])};
	return tint_symbol;
	}

	typedef S u_load_ret[4];
	u_load_ret u_load(uint offset) {
	S arr[4] = (S[4])0;
	{
	for(uint i_1 = 0u; (i_1 < 4u); i_1 = (i_1 + 1u)) {
	arr[i_1] = u_load_1((offset + (i_1 * 128u)));
	}
	}
	return arr;
	}

	[numthreads(1, 1, 1)]
	void f() {
	s_store(0u, u_load(0u));
	s_store_1(128u, u_load_1(256u));
	s_store_3(388u, u_load_3(260u));
	uint ubo_load_3 = u[0].z;
	s.Store<vector<float16_t, 2> >(132u, vector<float16_t, 2>(float16_t(f16tof32(ubo_load_3 & 0xFFFF)), float16_t(f16tof32(ubo_load_3 >> 16))).yx);
	return;
	}