test/CodeGen/NVPTX/intrinsics.ll - llvm - Git at Google

 ; RUN: llc < %s -march=nvptx -mcpu=sm_20 | FileCheck %s
 ; RUN: llc < %s -march=nvptx64 -mcpu=sm_20 | FileCheck %s

 ; CHECK-LABEL test_fabsf(
 define float @test_fabsf(float %f) {
 ; CHECK: abs.f32
   %x = call float @llvm.fabs.f32(float %f)
   ret float %x
 }

 ; CHECK-LABEL: test_fabs(
 define double @test_fabs(double %d) {
 ; CHECK: abs.f64
   %x = call double @llvm.fabs.f64(double %d)
   ret double %x
 }

 ; CHECK-LABEL: test_nvvm_sqrt(
 define float @test_nvvm_sqrt(float %a) {
 ; CHECK: sqrt.rn.f32
   %val = call float @llvm.nvvm.sqrt.f(float %a)
   ret float %val
 }

 ; CHECK-LABEL: test_llvm_sqrt(
 define float @test_llvm_sqrt(float %a) {
 ; CHECK: sqrt.rn.f32
   %val = call float @llvm.sqrt.f32(float %a)
   ret float %val
 }

 ; CHECK-LABEL: test_bitreverse32(
 define i32 @test_bitreverse32(i32 %a) {
 ; CHECK: brev.b32
   %val = call i32 @llvm.bitreverse.i32(i32 %a)
   ret i32 %val
 }

 ; CHECK-LABEL: test_bitreverse64(
 define i64 @test_bitreverse64(i64 %a) {
 ; CHECK: brev.b64
   %val = call i64 @llvm.bitreverse.i64(i64 %a)
   ret i64 %val
 }

 ; CHECK-LABEL: test_popc32(
 define i32 @test_popc32(i32 %a) {
 ; CHECK: popc.b32
   %val = call i32 @llvm.ctpop.i32(i32 %a)
   ret i32 %val
 }

 ; CHECK-LABEL: test_popc64
 define i64 @test_popc64(i64 %a) {
 ; CHECK: popc.b64
 ; CHECK: cvt.u64.u32
   %val = call i64 @llvm.ctpop.i64(i64 %a)
   ret i64 %val
 }

 ; NVPTX popc.b64 returns an i32 even though @llvm.ctpop.i64 returns an i64, so
 ; if this function returns an i32, there's no need to do any type conversions
 ; in the ptx.
 ; CHECK-LABEL: test_popc64_trunc
 define i32 @test_popc64_trunc(i64 %a) {
 ; CHECK: popc.b64
 ; CHECK-NOT: cvt.
   %val = call i64 @llvm.ctpop.i64(i64 %a)
   %trunc = trunc i64 %val to i32
   ret i32 %trunc
 }

 ; llvm.ctpop.i16 is implemenented by converting to i32, running popc.b32, and
 ; then converting back to i16.
 ; CHECK-LABEL: test_popc16
 define void @test_popc16(i16 %a, i16* %b) {
 ; CHECK: cvt.u32.u16
 ; CHECK: popc.b32
 ; CHECK: cvt.u16.u32
   %val = call i16 @llvm.ctpop.i16(i16 %a)
   store i16 %val, i16* %b
   ret void
 }

 ; If we call llvm.ctpop.i16 and then zext the result to i32, we shouldn't need
 ; to do any conversions after calling popc.b32, because that returns an i32.
 ; CHECK-LABEL: test_popc16_to_32
 define i32 @test_popc16_to_32(i16 %a) {
 ; CHECK: cvt.u32.u16
 ; CHECK: popc.b32
 ; CHECK-NOT: cvt.
   %val = call i16 @llvm.ctpop.i16(i16 %a)
   %zext = zext i16 %val to i32
   ret i32 %zext
 }

 declare float @llvm.fabs.f32(float)
 declare double @llvm.fabs.f64(double)
 declare float @llvm.nvvm.sqrt.f(float)
 declare float @llvm.sqrt.f32(float)
 declare i32 @llvm.bitreverse.i32(i32)
 declare i64 @llvm.bitreverse.i64(i64)
 declare i16 @llvm.ctpop.i16(i16)
 declare i32 @llvm.ctpop.i32(i32)
 declare i64 @llvm.ctpop.i64(i64)
	; RUN: llc < %s -march=nvptx -mcpu=sm_20 \| FileCheck %s
	; RUN: llc < %s -march=nvptx64 -mcpu=sm_20 \| FileCheck %s

	; CHECK-LABEL test_fabsf(
	define float @test_fabsf(float %f) {
	; CHECK: abs.f32
	%x = call float @llvm.fabs.f32(float %f)
	ret float %x
	}

	; CHECK-LABEL: test_fabs(
	define double @test_fabs(double %d) {
	; CHECK: abs.f64
	%x = call double @llvm.fabs.f64(double %d)
	ret double %x
	}

	; CHECK-LABEL: test_nvvm_sqrt(
	define float @test_nvvm_sqrt(float %a) {
	; CHECK: sqrt.rn.f32
	%val = call float @llvm.nvvm.sqrt.f(float %a)
	ret float %val
	}

	; CHECK-LABEL: test_llvm_sqrt(
	define float @test_llvm_sqrt(float %a) {
	; CHECK: sqrt.rn.f32
	%val = call float @llvm.sqrt.f32(float %a)
	ret float %val
	}

	; CHECK-LABEL: test_bitreverse32(
	define i32 @test_bitreverse32(i32 %a) {
	; CHECK: brev.b32
	%val = call i32 @llvm.bitreverse.i32(i32 %a)
	ret i32 %val
	}

	; CHECK-LABEL: test_bitreverse64(
	define i64 @test_bitreverse64(i64 %a) {
	; CHECK: brev.b64
	%val = call i64 @llvm.bitreverse.i64(i64 %a)
	ret i64 %val
	}

	; CHECK-LABEL: test_popc32(
	define i32 @test_popc32(i32 %a) {
	; CHECK: popc.b32
	%val = call i32 @llvm.ctpop.i32(i32 %a)
	ret i32 %val
	}

	; CHECK-LABEL: test_popc64
	define i64 @test_popc64(i64 %a) {
	; CHECK: popc.b64
	; CHECK: cvt.u64.u32
	%val = call i64 @llvm.ctpop.i64(i64 %a)
	ret i64 %val
	}

	; NVPTX popc.b64 returns an i32 even though @llvm.ctpop.i64 returns an i64, so
	; if this function returns an i32, there's no need to do any type conversions
	; in the ptx.
	; CHECK-LABEL: test_popc64_trunc
	define i32 @test_popc64_trunc(i64 %a) {
	; CHECK: popc.b64
	; CHECK-NOT: cvt.
	%val = call i64 @llvm.ctpop.i64(i64 %a)
	%trunc = trunc i64 %val to i32
	ret i32 %trunc
	}

	; llvm.ctpop.i16 is implemenented by converting to i32, running popc.b32, and
	; then converting back to i16.
	; CHECK-LABEL: test_popc16
	define void @test_popc16(i16 %a, i16* %b) {
	; CHECK: cvt.u32.u16
	; CHECK: popc.b32
	; CHECK: cvt.u16.u32
	%val = call i16 @llvm.ctpop.i16(i16 %a)
	store i16 %val, i16* %b
	ret void
	}

	; If we call llvm.ctpop.i16 and then zext the result to i32, we shouldn't need
	; to do any conversions after calling popc.b32, because that returns an i32.
	; CHECK-LABEL: test_popc16_to_32
	define i32 @test_popc16_to_32(i16 %a) {
	; CHECK: cvt.u32.u16
	; CHECK: popc.b32
	; CHECK-NOT: cvt.
	%val = call i16 @llvm.ctpop.i16(i16 %a)
	%zext = zext i16 %val to i32
	ret i32 %zext
	}

	declare float @llvm.fabs.f32(float)
	declare double @llvm.fabs.f64(double)
	declare float @llvm.nvvm.sqrt.f(float)
	declare float @llvm.sqrt.f32(float)
	declare i32 @llvm.bitreverse.i32(i32)
	declare i64 @llvm.bitreverse.i64(i64)
	declare i16 @llvm.ctpop.i16(i16)
	declare i32 @llvm.ctpop.i32(i32)
	declare i64 @llvm.ctpop.i64(i64)