test/CodeGenCXX/stmtexpr.cpp - clang - Git at Google

 // RUN: %clang_cc1 -Wno-unused-value -triple i686-linux-gnu -emit-llvm -o - %s | FileCheck %s
 // rdar: //8540501
 extern "C" int printf(...);
 extern "C" void abort();

 struct A
 {
   int i;
   A (int j) : i(j) {printf("this = %p A(%d)\n", this, j);}
   A (const A &j) : i(j.i) {printf("this = %p const A&(%d)\n", this, i);}
   A& operator= (const A &j) { i = j.i; abort(); return *this; }
   ~A() { printf("this = %p ~A(%d)\n", this, i); }
 };

 struct B
 {
   int i;
   B (const A& a) { i = a.i; }
   B() {printf("this = %p B()\n", this);}
   B (const B &j) : i(j.i) {printf("this = %p const B&(%d)\n", this, i);}
   ~B() { printf("this = %p ~B(%d)\n", this, i); }
 };

 A foo(int j)
 {
   return ({ j ? A(1) : A(0); });
 }


 void foo2()
 {
   A b = ({ A a(1); A a1(2); A a2(3); a1; a2; a; });
   if (b.i != 1)
     abort();
   A c = ({ A a(1); A a1(2); A a2(3); a1; a2; a; A a3(4); a2; a3; });
   if (c.i != 4)
     abort();
 }

 void foo3()
 {
   const A &b = ({ A a(1); a; });
   if (b.i != 1)
     abort();
 }

 void foo4()
 {
 // CHECK: call {{.*}} @_ZN1AC1Ei
 // CHECK: call {{.*}} @_ZN1AC1ERKS_
 // CHECK: call {{.*}} @_ZN1AD1Ev
 // CHECK: call {{.*}} @_ZN1BC1ERK1A
 // CHECK: call {{.*}} @_ZN1AD1Ev
   const B &b = ({ A a(1); a; });
   if (b.i != 1)
     abort();
 }

 int main()
 {
   foo2();
   foo3();
   foo4();
   return foo(1).i-1;
 }

 // rdar: // 8600553
 int a[128];
 int* foo5() {
 // CHECK-NOT: memcpy
   // Check that array-to-pointer conversion occurs in a
   // statement-expression.
   return (({ a; }));
 }

 // <rdar://problem/14074868>
 // Make sure this doesn't crash.
 int foo5(bool b) {
   int y = 0;
   y = ({ A a(1); if (b) goto G; a.i; });
   G: return y;
 }

 // When we emit a full expression with cleanups that contains branches out of
 // the full expression, the result of the inner expression (the call to
 // call_with_cleanups in this case) may not dominate the fallthrough destination
 // of the shared cleanup block.
 //
 // In this case the CFG will be a sequence of two diamonds, but the only
 // dynamically possible execution paths are both left hand branches and both
 // right hand branches. The first diamond LHS will call bar, and the second
 // diamond LHS will assign the result to v, but the call to bar does not
 // dominate the assignment.
 int bar(A, int);
 extern "C" int cleanup_exit_scalar(bool b) {
   int v = bar(A(1), ({ if (b) return 42; 13; }));
   return v;
 }

 // CHECK-LABEL: define{{.*}} i32 @cleanup_exit_scalar({{.*}})
 // CHECK: call {{.*}} @_ZN1AC1Ei
 //    Spill after bar.
 // CHECK: %[[v:[^ ]*]] = call{{.*}} i32 @_Z3bar1Ai({{.*}})
 // CHECK-NEXT: store i32 %[[v]], i32* %[[tmp:[^, ]*]]
 //    Do cleanup.
 // CHECK: call {{.*}} @_ZN1AD1Ev
 // CHECK: switch
 //    Reload before v assignment.
 // CHECK: %[[v:[^ ]*]] = load i32, i32* %[[tmp]]
 // CHECK-NEXT: store i32 %[[v]], i32* %v

 // No need to spill when the expression result is a constant, constants don't
 // have dominance problems.
 extern "C" int cleanup_exit_scalar_constant(bool b) {
   int v = (A(1), (void)({ if (b) return 42; 0; }), 13);
   return v;
 }

 // CHECK-LABEL: define{{.*}} i32 @cleanup_exit_scalar_constant({{.*}})
 // CHECK: store i32 13, i32* %v

 // Check for the same bug for lvalue expression evaluation kind.
 // FIXME: What about non-reference lvalues, like bitfield lvalues and vector
 // lvalues?
 int &getref();
 extern "C" int cleanup_exit_lvalue(bool cond) {
   int &r = (A(1), ({ if (cond) return 0; (void)0; }), getref());
   return r;
 }
 // CHECK-LABEL: define{{.*}} i32 @cleanup_exit_lvalue({{.*}})
 // CHECK: call {{.*}} @_ZN1AC1Ei
 //    Spill after bar.
 // CHECK: %[[v:[^ ]*]] = call dereferenceable(4) i32* @_Z6getrefv({{.*}})
 // CHECK-NEXT: store i32* %[[v]], i32** %[[tmp:[^, ]*]]
 //    Do cleanup.
 // CHECK: call {{.*}} @_ZN1AD1Ev
 // CHECK: switch
 //    Reload before v assignment.
 // CHECK: %[[v:[^ ]*]] = load i32*, i32** %[[tmp]]
 // CHECK-NEXT: store i32* %[[v]], i32** %r

 // Bind the reference to a byval argument. It is not an instruction or Constant,
 // so it's a bit of a corner case.
 struct ByVal { int x[3]; };
 extern "C" int cleanup_exit_lvalue_byval(bool cond, ByVal arg) {
   ByVal &r = (A(1), ({ if (cond) return 0; (void)ByVal(); }), arg);
   return r.x[0];
 }
 // CHECK-LABEL: define{{.*}} i32 @cleanup_exit_lvalue_byval({{.*}}, %struct.ByVal* byval(%struct.ByVal) align 4 %arg)
 // CHECK: call {{.*}} @_ZN1AC1Ei
 // CHECK: call {{.*}} @_ZN1AD1Ev
 // CHECK: switch
 // CHECK: store %struct.ByVal* %arg, %struct.ByVal** %r

 // Bind the reference to a local variable. We don't need to spill it. Binding a
 // reference to it doesn't generate any instructions.
 extern "C" int cleanup_exit_lvalue_local(bool cond) {
   int local = 42;
   int &r = (A(1), ({ if (cond) return 0; (void)0; }), local);
   return r;
 }
 // CHECK-LABEL: define{{.*}} i32 @cleanup_exit_lvalue_local({{.*}})
 // CHECK: %local = alloca i32
 // CHECK: store i32 42, i32* %local
 // CHECK: call {{.*}} @_ZN1AC1Ei
 // CHECK-NOT: store i32* %local
 // CHECK: call {{.*}} @_ZN1AD1Ev
 // CHECK: switch
 // CHECK: store i32* %local, i32** %r, align 4

 // We handle ExprWithCleanups for complex evaluation type separately, and it had
 // the same bug.
 _Complex float bar_complex(A, int);
 extern "C" int cleanup_exit_complex(bool b) {
   _Complex float v = bar_complex(A(1), ({ if (b) return 42; 13; }));
   return (float)v;
 }

 // CHECK-LABEL: define{{.*}} i32 @cleanup_exit_complex({{.*}})
 // CHECK: call {{.*}} @_ZN1AC1Ei
 //    Spill after bar.
 // CHECK: call {{.*}} @_Z11bar_complex1Ai({{.*}})
 // CHECK: store float %{{.*}}, float* %[[tmp1:[^, ]*]]
 // CHECK: store float %{{.*}}, float* %[[tmp2:[^, ]*]]
 //    Do cleanup.
 // CHECK: call {{.*}} @_ZN1AD1Ev
 // CHECK: switch
 //    Reload before v assignment.
 // CHECK: %[[v1:[^ ]*]] = load float, float* %[[tmp1]]
 // CHECK: %[[v2:[^ ]*]] = load float, float* %[[tmp2]]
 // CHECK: store float %[[v1]], float* %v.realp
 // CHECK: store float %[[v2]], float* %v.imagp

 extern "C" void then(int);

 // CHECK-LABEL: @{{.*}}volatile_load
 void volatile_load() {
   volatile int n;

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({n;});

   // CHECK-LABEL: @then(i32 1)
   then(1);

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({goto lab; lab: n;});

   // CHECK-LABEL: @then(i32 2)
   then(2);

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({[[gsl::suppress("foo")]] n;});

   // CHECK-LABEL: @then(i32 3)
   then(3);

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({if (true) n;});

   // CHECK: }
 }

 // CHECK-LABEL: @{{.*}}volatile_load_template
 template<typename T>
 void volatile_load_template() {
   volatile T n;

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({n;});

   // CHECK-LABEL: @then(i32 1)
   then(1);

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({goto lab; lab: n;});

   // CHECK-LABEL: @then(i32 2)
   then(2);

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({[[gsl::suppress("foo")]] n;});

   // CHECK-LABEL: @then(i32 3)
   then(3);

   // CHECK-NOT: load volatile
   // CHECK: load volatile
   // CHECK-NOT: load volatile
   ({if (true) n;});

   // CHECK: }
 }
 template void volatile_load_template<int>();
	// RUN: %clang_cc1 -Wno-unused-value -triple i686-linux-gnu -emit-llvm -o - %s \| FileCheck %s
	// rdar: //8540501
	extern "C" int printf(...);
	extern "C" void abort();

	struct A
	{
	int i;
	A (int j) : i(j) {printf("this = %p A(%d)\n", this, j);}
	A (const A &j) : i(j.i) {printf("this = %p const A&(%d)\n", this, i);}
	A& operator= (const A &j) { i = j.i; abort(); return *this; }
	~A() { printf("this = %p ~A(%d)\n", this, i); }
	};

	struct B
	{
	int i;
	B (const A& a) { i = a.i; }
	B() {printf("this = %p B()\n", this);}
	B (const B &j) : i(j.i) {printf("this = %p const B&(%d)\n", this, i);}
	~B() { printf("this = %p ~B(%d)\n", this, i); }
	};

	A foo(int j)
	{
	return ({ j ? A(1) : A(0); });
	}


	void foo2()
	{
	A b = ({ A a(1); A a1(2); A a2(3); a1; a2; a; });
	if (b.i != 1)
	abort();
	A c = ({ A a(1); A a1(2); A a2(3); a1; a2; a; A a3(4); a2; a3; });
	if (c.i != 4)
	abort();
	}

	void foo3()
	{
	const A &b = ({ A a(1); a; });
	if (b.i != 1)
	abort();
	}

	void foo4()
	{
	// CHECK: call {{.*}} @_ZN1AC1Ei
	// CHECK: call {{.*}} @_ZN1AC1ERKS_
	// CHECK: call {{.*}} @_ZN1AD1Ev
	// CHECK: call {{.*}} @_ZN1BC1ERK1A
	// CHECK: call {{.*}} @_ZN1AD1Ev
	const B &b = ({ A a(1); a; });
	if (b.i != 1)
	abort();
	}

	int main()
	{
	foo2();
	foo3();
	foo4();
	return foo(1).i-1;
	}

	// rdar: // 8600553
	int a[128];
	int* foo5() {
	// CHECK-NOT: memcpy
	// Check that array-to-pointer conversion occurs in a
	// statement-expression.
	return (({ a; }));
	}

	// <rdar://problem/14074868>
	// Make sure this doesn't crash.
	int foo5(bool b) {
	int y = 0;
	y = ({ A a(1); if (b) goto G; a.i; });
	G: return y;
	}

	// When we emit a full expression with cleanups that contains branches out of
	// the full expression, the result of the inner expression (the call to
	// call_with_cleanups in this case) may not dominate the fallthrough destination
	// of the shared cleanup block.
	//
	// In this case the CFG will be a sequence of two diamonds, but the only
	// dynamically possible execution paths are both left hand branches and both
	// right hand branches. The first diamond LHS will call bar, and the second
	// diamond LHS will assign the result to v, but the call to bar does not
	// dominate the assignment.
	int bar(A, int);
	extern "C" int cleanup_exit_scalar(bool b) {
	int v = bar(A(1), ({ if (b) return 42; 13; }));
	return v;
	}

	// CHECK-LABEL: define{{.}} i32 @cleanup_exit_scalar({{.}})
	// CHECK: call {{.*}} @_ZN1AC1Ei
	// Spill after bar.
	// CHECK: %[[v:[^ ]]] = call{{.}} i32 @_Z3bar1Ai({{.*}})
	// CHECK-NEXT: store i32 %[[v]], i32* %[[tmp:[^, ]*]]
	// Do cleanup.
	// CHECK: call {{.*}} @_ZN1AD1Ev
	// CHECK: switch
	// Reload before v assignment.
	// CHECK: %[[v:[^ ]]] = load i32, i32 %[[tmp]]
	// CHECK-NEXT: store i32 %[[v]], i32* %v

	// No need to spill when the expression result is a constant, constants don't
	// have dominance problems.
	extern "C" int cleanup_exit_scalar_constant(bool b) {
	int v = (A(1), (void)({ if (b) return 42; 0; }), 13);
	return v;
	}

	// CHECK-LABEL: define{{.}} i32 @cleanup_exit_scalar_constant({{.}})
	// CHECK: store i32 13, i32* %v

	// Check for the same bug for lvalue expression evaluation kind.
	// FIXME: What about non-reference lvalues, like bitfield lvalues and vector
	// lvalues?
	int &getref();
	extern "C" int cleanup_exit_lvalue(bool cond) {
	int &r = (A(1), ({ if (cond) return 0; (void)0; }), getref());
	return r;
	}
	// CHECK-LABEL: define{{.}} i32 @cleanup_exit_lvalue({{.}})
	// CHECK: call {{.*}} @_ZN1AC1Ei
	// Spill after bar.
	// CHECK: %[[v:[^ ]]] = call dereferenceable(4) i32 @_Z6getrefv({{.*}})
	// CHECK-NEXT: store i32* %[[v]], i32** %[[tmp:[^, ]*]]
	// Do cleanup.
	// CHECK: call {{.*}} @_ZN1AD1Ev
	// CHECK: switch
	// Reload before v assignment.
	// CHECK: %[[v:[^ ]]] = load i32, i32** %[[tmp]]
	// CHECK-NEXT: store i32* %[[v]], i32** %r

	// Bind the reference to a byval argument. It is not an instruction or Constant,
	// so it's a bit of a corner case.
	struct ByVal { int x[3]; };
	extern "C" int cleanup_exit_lvalue_byval(bool cond, ByVal arg) {
	ByVal &r = (A(1), ({ if (cond) return 0; (void)ByVal(); }), arg);
	return r.x[0];
	}
	// CHECK-LABEL: define{{.}} i32 @cleanup_exit_lvalue_byval({{.}}, %struct.ByVal* byval(%struct.ByVal) align 4 %arg)
	// CHECK: call {{.*}} @_ZN1AC1Ei
	// CHECK: call {{.*}} @_ZN1AD1Ev
	// CHECK: switch
	// CHECK: store %struct.ByVal* %arg, %struct.ByVal** %r

	// Bind the reference to a local variable. We don't need to spill it. Binding a
	// reference to it doesn't generate any instructions.
	extern "C" int cleanup_exit_lvalue_local(bool cond) {
	int local = 42;
	int &r = (A(1), ({ if (cond) return 0; (void)0; }), local);
	return r;
	}
	// CHECK-LABEL: define{{.}} i32 @cleanup_exit_lvalue_local({{.}})
	// CHECK: %local = alloca i32
	// CHECK: store i32 42, i32* %local
	// CHECK: call {{.*}} @_ZN1AC1Ei
	// CHECK-NOT: store i32* %local
	// CHECK: call {{.*}} @_ZN1AD1Ev
	// CHECK: switch
	// CHECK: store i32* %local, i32** %r, align 4

	// We handle ExprWithCleanups for complex evaluation type separately, and it had
	// the same bug.
	_Complex float bar_complex(A, int);
	extern "C" int cleanup_exit_complex(bool b) {
	_Complex float v = bar_complex(A(1), ({ if (b) return 42; 13; }));
	return (float)v;
	}

	// CHECK-LABEL: define{{.}} i32 @cleanup_exit_complex({{.}})
	// CHECK: call {{.*}} @_ZN1AC1Ei
	// Spill after bar.
	// CHECK: call {{.}} @_Z11bar_complex1Ai({{.}})
	// CHECK: store float %{{.}}, float %[[tmp1:[^, ]*]]
	// CHECK: store float %{{.}}, float %[[tmp2:[^, ]*]]
	// Do cleanup.
	// CHECK: call {{.*}} @_ZN1AD1Ev
	// CHECK: switch
	// Reload before v assignment.
	// CHECK: %[[v1:[^ ]]] = load float, float %[[tmp1]]
	// CHECK: %[[v2:[^ ]]] = load float, float %[[tmp2]]
	// CHECK: store float %[[v1]], float* %v.realp
	// CHECK: store float %[[v2]], float* %v.imagp

	extern "C" void then(int);

	// CHECK-LABEL: @{{.*}}volatile_load
	void volatile_load() {
	volatile int n;

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({n;});

	// CHECK-LABEL: @then(i32 1)
	then(1);

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({goto lab; lab: n;});

	// CHECK-LABEL: @then(i32 2)
	then(2);

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({[[gsl::suppress("foo")]] n;});

	// CHECK-LABEL: @then(i32 3)
	then(3);

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({if (true) n;});

	// CHECK: }
	}

	// CHECK-LABEL: @{{.*}}volatile_load_template
	template<typename T>
	void volatile_load_template() {
	volatile T n;

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({n;});

	// CHECK-LABEL: @then(i32 1)
	then(1);

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({goto lab; lab: n;});

	// CHECK-LABEL: @then(i32 2)
	then(2);

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({[[gsl::suppress("foo")]] n;});

	// CHECK-LABEL: @then(i32 3)
	then(3);

	// CHECK-NOT: load volatile
	// CHECK: load volatile
	// CHECK-NOT: load volatile
	({if (true) n;});

	// CHECK: }
	}
	template void volatile_load_template<int>();