clang/test/CodeGenHLSL/builtins/rsqrt-overloads.hlsl - llvm-project - Git at Google

 // RUN: %clang_cc1 -std=hlsl202x -finclude-default-header -x hlsl -triple \
 // RUN:   dxil-pc-shadermodel6.3-library %s -emit-llvm -disable-llvm-passes \
 // RUN:   -o - | FileCheck %s --check-prefixes=CHECK \
 // RUN:   -DFNATTRS="noundef nofpclass(nan inf)" -DTARGET=dx
 // RUN: %clang_cc1 -std=hlsl202x -finclude-default-header -x hlsl -triple \
 // RUN:   spirv-unknown-vulkan-compute %s -emit-llvm -disable-llvm-passes \
 // RUN:   -o - | FileCheck %s --check-prefixes=CHECK \
 // RUN:   -DFNATTRS="spir_func noundef nofpclass(nan inf)" -DTARGET=spv

 // CHECK: define [[FNATTRS]] float @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
 // CHECK: ret float %hlsl.rsqrt
 float test_rsqrt_double(double p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <2 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
 // CHECK: ret <2 x float> %hlsl.rsqrt
 float2 test_rsqrt_double2(double2 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <3 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
 // CHECK: ret <3 x float> %hlsl.rsqrt
 float3 test_rsqrt_double3(double3 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <4 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
 // CHECK: ret <4 x float> %hlsl.rsqrt
 float4 test_rsqrt_double4(double4 p0) { return rsqrt(p0); }

 // CHECK: define [[FNATTRS]] float @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
 // CHECK: ret float %hlsl.rsqrt
 float test_rsqrt_int(int p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <2 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
 // CHECK: ret <2 x float> %hlsl.rsqrt
 float2 test_rsqrt_int2(int2 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <3 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
 // CHECK: ret <3 x float> %hlsl.rsqrt
 float3 test_rsqrt_int3(int3 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <4 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
 // CHECK: ret <4 x float> %hlsl.rsqrt
 float4 test_rsqrt_int4(int4 p0) { return rsqrt(p0); }

 // CHECK: define [[FNATTRS]] float @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
 // CHECK: ret float %hlsl.rsqrt
 float test_rsqrt_uint(uint p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <2 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
 // CHECK: ret <2 x float> %hlsl.rsqrt
 float2 test_rsqrt_uint2(uint2 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <3 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
 // CHECK: ret <3 x float> %hlsl.rsqrt
 float3 test_rsqrt_uint3(uint3 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <4 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
 // CHECK: ret <4 x float> %hlsl.rsqrt
 float4 test_rsqrt_uint4(uint4 p0) { return rsqrt(p0); }

 // CHECK: define [[FNATTRS]] float @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
 // CHECK: ret float %hlsl.rsqrt
 float test_rsqrt_int64_t(int64_t p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <2 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
 // CHECK: ret <2 x float> %hlsl.rsqrt
 float2 test_rsqrt_int64_t2(int64_t2 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <3 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
 // CHECK: ret <3 x float> %hlsl.rsqrt
 float3 test_rsqrt_int64_t3(int64_t3 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <4 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
 // CHECK: ret <4 x float> %hlsl.rsqrt
 float4 test_rsqrt_int64_t4(int64_t4 p0) { return rsqrt(p0); }

 // CHECK: define [[FNATTRS]] float @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
 // CHECK: ret float %hlsl.rsqrt
 float test_rsqrt_uint64_t(uint64_t p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <2 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
 // CHECK: ret <2 x float> %hlsl.rsqrt
 float2 test_rsqrt_uint64_t2(uint64_t2 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <3 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
 // CHECK: ret <3 x float> %hlsl.rsqrt
 float3 test_rsqrt_uint64_t3(uint64_t3 p0) { return rsqrt(p0); }
 // CHECK: define [[FNATTRS]] <4 x float> @
 // CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
 // CHECK: ret <4 x float> %hlsl.rsqrt
 float4 test_rsqrt_uint64_t4(uint64_t4 p0) { return rsqrt(p0); }
	// RUN: %clang_cc1 -std=hlsl202x -finclude-default-header -x hlsl -triple \
	// RUN: dxil-pc-shadermodel6.3-library %s -emit-llvm -disable-llvm-passes \
	// RUN: -o - \| FileCheck %s --check-prefixes=CHECK \
	// RUN: -DFNATTRS="noundef nofpclass(nan inf)" -DTARGET=dx
	// RUN: %clang_cc1 -std=hlsl202x -finclude-default-header -x hlsl -triple \
	// RUN: spirv-unknown-vulkan-compute %s -emit-llvm -disable-llvm-passes \
	// RUN: -o - \| FileCheck %s --check-prefixes=CHECK \
	// RUN: -DFNATTRS="spir_func noundef nofpclass(nan inf)" -DTARGET=spv

	// CHECK: define [[FNATTRS]] float @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
	// CHECK: ret float %hlsl.rsqrt
	float test_rsqrt_double(double p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <2 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
	// CHECK: ret <2 x float> %hlsl.rsqrt
	float2 test_rsqrt_double2(double2 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <3 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
	// CHECK: ret <3 x float> %hlsl.rsqrt
	float3 test_rsqrt_double3(double3 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <4 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
	// CHECK: ret <4 x float> %hlsl.rsqrt
	float4 test_rsqrt_double4(double4 p0) { return rsqrt(p0); }

	// CHECK: define [[FNATTRS]] float @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
	// CHECK: ret float %hlsl.rsqrt
	float test_rsqrt_int(int p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <2 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
	// CHECK: ret <2 x float> %hlsl.rsqrt
	float2 test_rsqrt_int2(int2 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <3 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
	// CHECK: ret <3 x float> %hlsl.rsqrt
	float3 test_rsqrt_int3(int3 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <4 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
	// CHECK: ret <4 x float> %hlsl.rsqrt
	float4 test_rsqrt_int4(int4 p0) { return rsqrt(p0); }

	// CHECK: define [[FNATTRS]] float @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
	// CHECK: ret float %hlsl.rsqrt
	float test_rsqrt_uint(uint p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <2 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
	// CHECK: ret <2 x float> %hlsl.rsqrt
	float2 test_rsqrt_uint2(uint2 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <3 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
	// CHECK: ret <3 x float> %hlsl.rsqrt
	float3 test_rsqrt_uint3(uint3 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <4 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
	// CHECK: ret <4 x float> %hlsl.rsqrt
	float4 test_rsqrt_uint4(uint4 p0) { return rsqrt(p0); }

	// CHECK: define [[FNATTRS]] float @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
	// CHECK: ret float %hlsl.rsqrt
	float test_rsqrt_int64_t(int64_t p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <2 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
	// CHECK: ret <2 x float> %hlsl.rsqrt
	float2 test_rsqrt_int64_t2(int64_t2 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <3 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
	// CHECK: ret <3 x float> %hlsl.rsqrt
	float3 test_rsqrt_int64_t3(int64_t3 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <4 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
	// CHECK: ret <4 x float> %hlsl.rsqrt
	float4 test_rsqrt_int64_t4(int64_t4 p0) { return rsqrt(p0); }

	// CHECK: define [[FNATTRS]] float @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn float @llvm.[[TARGET]].rsqrt.f32(
	// CHECK: ret float %hlsl.rsqrt
	float test_rsqrt_uint64_t(uint64_t p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <2 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <2 x float> @llvm.[[TARGET]].rsqrt.v2f32
	// CHECK: ret <2 x float> %hlsl.rsqrt
	float2 test_rsqrt_uint64_t2(uint64_t2 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <3 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <3 x float> @llvm.[[TARGET]].rsqrt.v3f32
	// CHECK: ret <3 x float> %hlsl.rsqrt
	float3 test_rsqrt_uint64_t3(uint64_t3 p0) { return rsqrt(p0); }
	// CHECK: define [[FNATTRS]] <4 x float> @
	// CHECK: %hlsl.rsqrt = call reassoc nnan ninf nsz arcp afn <4 x float> @llvm.[[TARGET]].rsqrt.v4f32
	// CHECK: ret <4 x float> %hlsl.rsqrt
	float4 test_rsqrt_uint64_t4(uint64_t4 p0) { return rsqrt(p0); }