test/tint/builtins/atomicStore/struct/struct_of_array.spvasm.expected.ir.msl - dawn - Git at Google

 #include <metal_stdlib>
 using namespace metal;

 template<typename T, size_t N>
 struct tint_array {
   const constant T& operator[](size_t i) const constant { return elements[i]; }
   device T& operator[](size_t i) device { return elements[i]; }
   const device T& operator[](size_t i) const device { return elements[i]; }
   thread T& operator[](size_t i) thread { return elements[i]; }
   const thread T& operator[](size_t i) const thread { return elements[i]; }
   threadgroup T& operator[](size_t i) threadgroup { return elements[i]; }
   const threadgroup T& operator[](size_t i) const threadgroup { return elements[i]; }
   T elements[N];
 };

 struct S_atomic {
   int x;
   tint_array<atomic_uint, 10> a;
   uint y;
 };

 struct tint_module_vars_struct {
   thread uint* local_invocation_index_1;
   threadgroup S_atomic* wg;
 };

 #define TINT_ISOLATE_UB(VOLATILE_NAME) \
   {volatile bool VOLATILE_NAME = false; if (VOLATILE_NAME) break;}

 struct tint_symbol_1 {
   S_atomic tint_symbol;
 };

 void compute_main_inner(uint local_invocation_index_2, tint_module_vars_struct tint_module_vars) {
   uint idx = 0u;
   (*tint_module_vars.wg).x = 0;
   (*tint_module_vars.wg).y = 0u;
   idx = local_invocation_index_2;
   {
     while(true) {
       TINT_ISOLATE_UB(tint_volatile_false)
       if (!((idx < 10u))) {
         break;
       }
       uint const x_35 = idx;
       atomic_store_explicit((&(*tint_module_vars.wg).a[x_35]), 0u, memory_order_relaxed);
       {
         idx = (idx + 1u);
       }
       continue;
     }
   }
   threadgroup_barrier(mem_flags::mem_threadgroup);
   atomic_store_explicit((&(*tint_module_vars.wg).a[4]), 1u, memory_order_relaxed);
 }

 void compute_main_1(tint_module_vars_struct tint_module_vars) {
   uint const x_53 = (*tint_module_vars.local_invocation_index_1);
   compute_main_inner(x_53, tint_module_vars);
 }

 void compute_main_inner_1(uint local_invocation_index_1_param, tint_module_vars_struct tint_module_vars) {
   if ((local_invocation_index_1_param == 0u)) {
     (*tint_module_vars.wg).x = 0;
     (*tint_module_vars.wg).y = 0u;
   }
   {
     uint v = 0u;
     v = local_invocation_index_1_param;
     while(true) {
       TINT_ISOLATE_UB(tint_volatile_false_1)
       uint const v_1 = v;
       if ((v_1 >= 10u)) {
         break;
       }
       atomic_store_explicit((&(*tint_module_vars.wg).a[v_1]), 0u, memory_order_relaxed);
       {
         v = (v_1 + 1u);
       }
       continue;
     }
   }
   threadgroup_barrier(mem_flags::mem_threadgroup);
   (*tint_module_vars.local_invocation_index_1) = local_invocation_index_1_param;
   compute_main_1(tint_module_vars);
 }

 kernel void compute_main(uint local_invocation_index_1_param [[thread_index_in_threadgroup]], threadgroup tint_symbol_1* v_2 [[threadgroup(0)]]) {
   thread uint local_invocation_index_1 = 0u;
   tint_module_vars_struct const tint_module_vars = tint_module_vars_struct{.local_invocation_index_1=(&local_invocation_index_1), .wg=(&(*v_2).tint_symbol)};
   compute_main_inner_1(local_invocation_index_1_param, tint_module_vars);
 }
	#include <metal_stdlib>
	using namespace metal;

	template<typename T, size_t N>
	struct tint_array {
	const constant T& operator[](size_t i) const constant { return elements[i]; }
	device T& operator[](size_t i) device { return elements[i]; }
	const device T& operator[](size_t i) const device { return elements[i]; }
	thread T& operator[](size_t i) thread { return elements[i]; }
	const thread T& operator[](size_t i) const thread { return elements[i]; }
	threadgroup T& operator[](size_t i) threadgroup { return elements[i]; }
	const threadgroup T& operator[](size_t i) const threadgroup { return elements[i]; }
	T elements[N];
	};

	struct S_atomic {
	int x;
	tint_array<atomic_uint, 10> a;
	uint y;
	};

	struct tint_module_vars_struct {
	thread uint* local_invocation_index_1;
	threadgroup S_atomic* wg;
	};

	#define TINT_ISOLATE_UB(VOLATILE_NAME) \
	{volatile bool VOLATILE_NAME = false; if (VOLATILE_NAME) break;}

	struct tint_symbol_1 {
	S_atomic tint_symbol;
	};

	void compute_main_inner(uint local_invocation_index_2, tint_module_vars_struct tint_module_vars) {
	uint idx = 0u;
	(*tint_module_vars.wg).x = 0;
	(*tint_module_vars.wg).y = 0u;
	idx = local_invocation_index_2;
	{
	while(true) {
	TINT_ISOLATE_UB(tint_volatile_false)
	if (!((idx < 10u))) {
	break;
	}
	uint const x_35 = idx;
	atomic_store_explicit((&(*tint_module_vars.wg).a[x_35]), 0u, memory_order_relaxed);
	{
	idx = (idx + 1u);
	}
	continue;
	}
	}
	threadgroup_barrier(mem_flags::mem_threadgroup);
	atomic_store_explicit((&(*tint_module_vars.wg).a[4]), 1u, memory_order_relaxed);
	}

	void compute_main_1(tint_module_vars_struct tint_module_vars) {
	uint const x_53 = (*tint_module_vars.local_invocation_index_1);
	compute_main_inner(x_53, tint_module_vars);
	}

	void compute_main_inner_1(uint local_invocation_index_1_param, tint_module_vars_struct tint_module_vars) {
	if ((local_invocation_index_1_param == 0u)) {
	(*tint_module_vars.wg).x = 0;
	(*tint_module_vars.wg).y = 0u;
	}
	{
	uint v = 0u;
	v = local_invocation_index_1_param;
	while(true) {
	TINT_ISOLATE_UB(tint_volatile_false_1)
	uint const v_1 = v;
	if ((v_1 >= 10u)) {
	break;
	}
	atomic_store_explicit((&(*tint_module_vars.wg).a[v_1]), 0u, memory_order_relaxed);
	{
	v = (v_1 + 1u);
	}
	continue;
	}
	}
	threadgroup_barrier(mem_flags::mem_threadgroup);
	(*tint_module_vars.local_invocation_index_1) = local_invocation_index_1_param;
	compute_main_1(tint_module_vars);
	}

	kernel void compute_main(uint local_invocation_index_1_param [[thread_index_in_threadgroup]], threadgroup tint_symbol_1* v_2 [[threadgroup(0)]]) {
	thread uint local_invocation_index_1 = 0u;
	tint_module_vars_struct const tint_module_vars = tint_module_vars_struct{.local_invocation_index_1=(&local_invocation_index_1), .wg=(&(*v_2).tint_symbol)};
	compute_main_inner_1(local_invocation_index_1_param, tint_module_vars);
	}