src/third_party/llvm-project/clang/test/CodeGen/nullptr-arithmetic.c - cobalt - Git at Google

 // RUN: %clang_cc1 -S %s -emit-llvm -o - | FileCheck %s
 // RUN: %clang_cc1 -S %s -emit-llvm -triple i686-unknown-unknown -o - | FileCheck %s
 // RUN: %clang_cc1 -S %s -emit-llvm -triple x86_64-unknown-unknown -o - | FileCheck %s

 #include <stdint.h>

 // This test is meant to verify code that handles the 'p = nullptr + n' idiom
 // used by some versions of glibc and gcc.  This is undefined behavior but
 // it is intended there to act like a conversion from a pointer-sized integer
 // to a pointer, and we would like to tolerate that.

 #define NULLPTRI8 ((int8_t*)0)

 // This should get the inttoptr instruction.
 int8_t *test1(intptr_t n) {
   return NULLPTRI8 + n;
 }
 // CHECK-LABEL: test1
 // CHECK: inttoptr
 // CHECK-NOT: getelementptr

 // This doesn't meet the idiom because the element type is larger than a byte.
 int16_t *test2(intptr_t n) {
   return (int16_t*)0 + n;
 }
 // CHECK-LABEL: test2
 // CHECK: getelementptr
 // CHECK-NOT: inttoptr

 // This doesn't meet the idiom because the offset is subtracted.
 int8_t* test3(intptr_t n) {
   return NULLPTRI8 - n;
 }
 // CHECK-LABEL: test3
 // CHECK: getelementptr
 // CHECK-NOT: inttoptr

 // This checks the case where the offset isn't pointer-sized.
 // The front end will implicitly cast the offset to an integer, so we need to
 // make sure that doesn't cause problems on targets where integers and pointers
 // are not the same size.
 int8_t *test4(int8_t b) {
   return NULLPTRI8 + b;
 }
 // CHECK-LABEL: test4
 // CHECK: inttoptr
 // CHECK-NOT: getelementptr
	// RUN: %clang_cc1 -S %s -emit-llvm -o - \| FileCheck %s
	// RUN: %clang_cc1 -S %s -emit-llvm -triple i686-unknown-unknown -o - \| FileCheck %s
	// RUN: %clang_cc1 -S %s -emit-llvm -triple x86_64-unknown-unknown -o - \| FileCheck %s

	#include <stdint.h>

	// This test is meant to verify code that handles the 'p = nullptr + n' idiom
	// used by some versions of glibc and gcc. This is undefined behavior but
	// it is intended there to act like a conversion from a pointer-sized integer
	// to a pointer, and we would like to tolerate that.

	#define NULLPTRI8 ((int8_t*)0)

	// This should get the inttoptr instruction.
	int8_t *test1(intptr_t n) {
	return NULLPTRI8 + n;
	}
	// CHECK-LABEL: test1
	// CHECK: inttoptr
	// CHECK-NOT: getelementptr

	// This doesn't meet the idiom because the element type is larger than a byte.
	int16_t *test2(intptr_t n) {
	return (int16_t*)0 + n;
	}
	// CHECK-LABEL: test2
	// CHECK: getelementptr
	// CHECK-NOT: inttoptr

	// This doesn't meet the idiom because the offset is subtracted.
	int8_t* test3(intptr_t n) {
	return NULLPTRI8 - n;
	}
	// CHECK-LABEL: test3
	// CHECK: getelementptr
	// CHECK-NOT: inttoptr

	// This checks the case where the offset isn't pointer-sized.
	// The front end will implicitly cast the offset to an integer, so we need to
	// make sure that doesn't cause problems on targets where integers and pointers
	// are not the same size.
	int8_t *test4(int8_t b) {
	return NULLPTRI8 + b;
	}
	// CHECK-LABEL: test4
	// CHECK: inttoptr
	// CHECK-NOT: getelementptr