clang/test/CodeGen/RISCV/riscv-xcvalu.c - llvm-project.git - Git at Google

 // NOTE: Assertions have been autogenerated by utils/update_cc_test_checks.py
 // RUN: %clang_cc1 -triple riscv32 -target-feature +xcvalu -emit-llvm %s -o - \
 // RUN:     | FileCheck %s

 #include <stdint.h>

 // CHECK-LABEL: @test_abs(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = call i32 @llvm.abs.i32(i32 [[TMP0]], i1 true)
 // CHECK-NEXT:    ret i32 [[TMP1]]
 //
 int test_abs(int a) {
   return __builtin_abs(a);
 }

 // CHECK-LABEL: @test_alu_slet(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = icmp sle i32 [[TMP0]], [[TMP1]]
 // CHECK-NEXT:    [[SLE:%.*]] = zext i1 [[TMP2]] to i32
 // CHECK-NEXT:    ret i32 [[SLE]]
 //
 int test_alu_slet(int32_t a, int32_t b) {
   return __builtin_riscv_cv_alu_slet(a, b);
 }

 // CHECK-LABEL: @test_alu_sletu(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = icmp ule i32 [[TMP0]], [[TMP1]]
 // CHECK-NEXT:    [[SLEU:%.*]] = zext i1 [[TMP2]] to i32
 // CHECK-NEXT:    ret i32 [[SLEU]]
 //
 int test_alu_sletu(uint32_t a, uint32_t b) {
   return __builtin_riscv_cv_alu_sletu(a, b);
 }

 // CHECK-LABEL: @test_alu_exths(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i16, align 2
 // CHECK-NEXT:    store i16 [[A:%.*]], ptr [[A_ADDR]], align 2
 // CHECK-NEXT:    [[TMP0:%.*]] = load i16, ptr [[A_ADDR]], align 2
 // CHECK-NEXT:    [[CONV:%.*]] = sext i16 [[TMP0]] to i32
 // CHECK-NEXT:    [[TMP1:%.*]] = trunc i32 [[CONV]] to i16
 // CHECK-NEXT:    [[EXTHS:%.*]] = sext i16 [[TMP1]] to i32
 // CHECK-NEXT:    ret i32 [[EXTHS]]
 //
 int test_alu_exths(int16_t a) {
   return __builtin_riscv_cv_alu_exths(a);
 }

 // CHECK-LABEL: @test_alu_exthz(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i16, align 2
 // CHECK-NEXT:    store i16 [[A:%.*]], ptr [[A_ADDR]], align 2
 // CHECK-NEXT:    [[TMP0:%.*]] = load i16, ptr [[A_ADDR]], align 2
 // CHECK-NEXT:    [[CONV:%.*]] = zext i16 [[TMP0]] to i32
 // CHECK-NEXT:    [[TMP1:%.*]] = trunc i32 [[CONV]] to i16
 // CHECK-NEXT:    [[EXTHZ:%.*]] = zext i16 [[TMP1]] to i32
 // CHECK-NEXT:    ret i32 [[EXTHZ]]
 //
 int test_alu_exthz(uint16_t a) {
   return __builtin_riscv_cv_alu_exthz(a);
 }

 // CHECK-LABEL: @test_alu_extbs(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i8, align 1
 // CHECK-NEXT:    store i8 [[A:%.*]], ptr [[A_ADDR]], align 1
 // CHECK-NEXT:    [[TMP0:%.*]] = load i8, ptr [[A_ADDR]], align 1
 // CHECK-NEXT:    [[CONV:%.*]] = sext i8 [[TMP0]] to i32
 // CHECK-NEXT:    [[TMP1:%.*]] = trunc i32 [[CONV]] to i8
 // CHECK-NEXT:    [[EXTBS:%.*]] = sext i8 [[TMP1]] to i32
 // CHECK-NEXT:    ret i32 [[EXTBS]]
 //
 int test_alu_extbs(int8_t a) {
   return __builtin_riscv_cv_alu_extbs(a);
 }

 // CHECK-LABEL: @test_alu_extbz(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i8, align 1
 // CHECK-NEXT:    store i8 [[A:%.*]], ptr [[A_ADDR]], align 1
 // CHECK-NEXT:    [[TMP0:%.*]] = load i8, ptr [[A_ADDR]], align 1
 // CHECK-NEXT:    [[CONV:%.*]] = zext i8 [[TMP0]] to i32
 // CHECK-NEXT:    [[TMP1:%.*]] = trunc i32 [[CONV]] to i8
 // CHECK-NEXT:    [[EXTBZ:%.*]] = zext i8 [[TMP1]] to i32
 // CHECK-NEXT:    ret i32 [[EXTBZ]]
 //
 int test_alu_extbz(uint8_t a) {
   return __builtin_riscv_cv_alu_extbz(a);
 }

 // CHECK-LABEL: @test_alu_clip(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = call i32 @llvm.riscv.cv.alu.clip(i32 [[TMP0]], i32 15)
 // CHECK-NEXT:    ret i32 [[TMP1]]
 //
 int test_alu_clip(int32_t a) {
   return __builtin_riscv_cv_alu_clip(a, 15);
 }

 // CHECK-LABEL: @test_alu_clipu(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = call i32 @llvm.riscv.cv.alu.clipu(i32 [[TMP0]], i32 15)
 // CHECK-NEXT:    ret i32 [[TMP1]]
 //
 int test_alu_clipu(uint32_t a) {
   return __builtin_riscv_cv_alu_clipu(a, 15);
 }

 // CHECK-LABEL: @test_alu_addN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.addN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_addN(int32_t a, int32_t b) {
   return __builtin_riscv_cv_alu_addN(a, b, 0);
 }

 // CHECK-LABEL: @test_alu_adduN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.adduN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_adduN(uint32_t a, uint32_t b) {
   return __builtin_riscv_cv_alu_adduN(a, b, 0);
 }

 // CHECK-LABEL: @test_alu_addRN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.addRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_addRN(int32_t a, int32_t b) {
   return __builtin_riscv_cv_alu_addRN(a, b, 0);
 }

 // CHECK-LABEL: @test_alu_adduRN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.adduRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_adduRN(uint32_t a, uint32_t b) {
   return __builtin_riscv_cv_alu_adduRN(a, b, 0);
 }

 // CHECK-LABEL: @test_alu_subN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_subN(int32_t a, int32_t b) {
   return __builtin_riscv_cv_alu_subN(a, b, 0);
 }

 // CHECK-LABEL: @test_alu_subuN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subuN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_subuN(uint32_t a, uint32_t b) {
   return __builtin_riscv_cv_alu_subuN(a, b, 0);
 }

 // CHECK-LABEL: @test_alu_subRN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_subRN(int32_t a, int32_t b) {
   return __builtin_riscv_cv_alu_subRN(a, b, 0);
 }

 // CHECK-LABEL: @test_alu_subuRN(
 // CHECK-NEXT:  entry:
 // CHECK-NEXT:    [[A_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    [[B_ADDR:%.*]] = alloca i32, align 4
 // CHECK-NEXT:    store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
 // CHECK-NEXT:    [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
 // CHECK-NEXT:    [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subuRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
 // CHECK-NEXT:    ret i32 [[TMP2]]
 //
 int test_alu_subuRN(uint32_t a, uint32_t b) {
   return __builtin_riscv_cv_alu_subuRN(a, b, 0);
 }
	// NOTE: Assertions have been autogenerated by utils/update_cc_test_checks.py
	// RUN: %clang_cc1 -triple riscv32 -target-feature +xcvalu -emit-llvm %s -o - \
	// RUN: \| FileCheck %s

	#include <stdint.h>

	// CHECK-LABEL: @test_abs(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = call i32 @llvm.abs.i32(i32 [[TMP0]], i1 true)
	// CHECK-NEXT: ret i32 [[TMP1]]
	//
	int test_abs(int a) {
	return __builtin_abs(a);
	}

	// CHECK-LABEL: @test_alu_slet(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = icmp sle i32 [[TMP0]], [[TMP1]]
	// CHECK-NEXT: [[SLE:%.*]] = zext i1 [[TMP2]] to i32
	// CHECK-NEXT: ret i32 [[SLE]]
	//
	int test_alu_slet(int32_t a, int32_t b) {
	return __builtin_riscv_cv_alu_slet(a, b);
	}

	// CHECK-LABEL: @test_alu_sletu(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = icmp ule i32 [[TMP0]], [[TMP1]]
	// CHECK-NEXT: [[SLEU:%.*]] = zext i1 [[TMP2]] to i32
	// CHECK-NEXT: ret i32 [[SLEU]]
	//
	int test_alu_sletu(uint32_t a, uint32_t b) {
	return __builtin_riscv_cv_alu_sletu(a, b);
	}

	// CHECK-LABEL: @test_alu_exths(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i16, align 2
	// CHECK-NEXT: store i16 [[A:%.*]], ptr [[A_ADDR]], align 2
	// CHECK-NEXT: [[TMP0:%.*]] = load i16, ptr [[A_ADDR]], align 2
	// CHECK-NEXT: [[CONV:%.*]] = sext i16 [[TMP0]] to i32
	// CHECK-NEXT: [[TMP1:%.*]] = trunc i32 [[CONV]] to i16
	// CHECK-NEXT: [[EXTHS:%.*]] = sext i16 [[TMP1]] to i32
	// CHECK-NEXT: ret i32 [[EXTHS]]
	//
	int test_alu_exths(int16_t a) {
	return __builtin_riscv_cv_alu_exths(a);
	}

	// CHECK-LABEL: @test_alu_exthz(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i16, align 2
	// CHECK-NEXT: store i16 [[A:%.*]], ptr [[A_ADDR]], align 2
	// CHECK-NEXT: [[TMP0:%.*]] = load i16, ptr [[A_ADDR]], align 2
	// CHECK-NEXT: [[CONV:%.*]] = zext i16 [[TMP0]] to i32
	// CHECK-NEXT: [[TMP1:%.*]] = trunc i32 [[CONV]] to i16
	// CHECK-NEXT: [[EXTHZ:%.*]] = zext i16 [[TMP1]] to i32
	// CHECK-NEXT: ret i32 [[EXTHZ]]
	//
	int test_alu_exthz(uint16_t a) {
	return __builtin_riscv_cv_alu_exthz(a);
	}

	// CHECK-LABEL: @test_alu_extbs(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i8, align 1
	// CHECK-NEXT: store i8 [[A:%.*]], ptr [[A_ADDR]], align 1
	// CHECK-NEXT: [[TMP0:%.*]] = load i8, ptr [[A_ADDR]], align 1
	// CHECK-NEXT: [[CONV:%.*]] = sext i8 [[TMP0]] to i32
	// CHECK-NEXT: [[TMP1:%.*]] = trunc i32 [[CONV]] to i8
	// CHECK-NEXT: [[EXTBS:%.*]] = sext i8 [[TMP1]] to i32
	// CHECK-NEXT: ret i32 [[EXTBS]]
	//
	int test_alu_extbs(int8_t a) {
	return __builtin_riscv_cv_alu_extbs(a);
	}

	// CHECK-LABEL: @test_alu_extbz(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i8, align 1
	// CHECK-NEXT: store i8 [[A:%.*]], ptr [[A_ADDR]], align 1
	// CHECK-NEXT: [[TMP0:%.*]] = load i8, ptr [[A_ADDR]], align 1
	// CHECK-NEXT: [[CONV:%.*]] = zext i8 [[TMP0]] to i32
	// CHECK-NEXT: [[TMP1:%.*]] = trunc i32 [[CONV]] to i8
	// CHECK-NEXT: [[EXTBZ:%.*]] = zext i8 [[TMP1]] to i32
	// CHECK-NEXT: ret i32 [[EXTBZ]]
	//
	int test_alu_extbz(uint8_t a) {
	return __builtin_riscv_cv_alu_extbz(a);
	}

	// CHECK-LABEL: @test_alu_clip(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = call i32 @llvm.riscv.cv.alu.clip(i32 [[TMP0]], i32 15)
	// CHECK-NEXT: ret i32 [[TMP1]]
	//
	int test_alu_clip(int32_t a) {
	return __builtin_riscv_cv_alu_clip(a, 15);
	}

	// CHECK-LABEL: @test_alu_clipu(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = call i32 @llvm.riscv.cv.alu.clipu(i32 [[TMP0]], i32 15)
	// CHECK-NEXT: ret i32 [[TMP1]]
	//
	int test_alu_clipu(uint32_t a) {
	return __builtin_riscv_cv_alu_clipu(a, 15);
	}

	// CHECK-LABEL: @test_alu_addN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.addN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_addN(int32_t a, int32_t b) {
	return __builtin_riscv_cv_alu_addN(a, b, 0);
	}

	// CHECK-LABEL: @test_alu_adduN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.adduN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_adduN(uint32_t a, uint32_t b) {
	return __builtin_riscv_cv_alu_adduN(a, b, 0);
	}

	// CHECK-LABEL: @test_alu_addRN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.addRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_addRN(int32_t a, int32_t b) {
	return __builtin_riscv_cv_alu_addRN(a, b, 0);
	}

	// CHECK-LABEL: @test_alu_adduRN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.adduRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_adduRN(uint32_t a, uint32_t b) {
	return __builtin_riscv_cv_alu_adduRN(a, b, 0);
	}

	// CHECK-LABEL: @test_alu_subN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_subN(int32_t a, int32_t b) {
	return __builtin_riscv_cv_alu_subN(a, b, 0);
	}

	// CHECK-LABEL: @test_alu_subuN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subuN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_subuN(uint32_t a, uint32_t b) {
	return __builtin_riscv_cv_alu_subuN(a, b, 0);
	}

	// CHECK-LABEL: @test_alu_subRN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_subRN(int32_t a, int32_t b) {
	return __builtin_riscv_cv_alu_subRN(a, b, 0);
	}

	// CHECK-LABEL: @test_alu_subuRN(
	// CHECK-NEXT: entry:
	// CHECK-NEXT: [[A_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: [[B_ADDR:%.*]] = alloca i32, align 4
	// CHECK-NEXT: store i32 [[A:%.*]], ptr [[A_ADDR]], align 4
	// CHECK-NEXT: store i32 [[B:%.*]], ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP0:%.*]] = load i32, ptr [[A_ADDR]], align 4
	// CHECK-NEXT: [[TMP1:%.*]] = load i32, ptr [[B_ADDR]], align 4
	// CHECK-NEXT: [[TMP2:%.*]] = call i32 @llvm.riscv.cv.alu.subuRN(i32 [[TMP0]], i32 [[TMP1]], i32 0)
	// CHECK-NEXT: ret i32 [[TMP2]]
	//
	int test_alu_subuRN(uint32_t a, uint32_t b) {
	return __builtin_riscv_cv_alu_subuRN(a, b, 0);
	}