// RUN: %clang_cc1 -std=c++1y -verify %s -fcxx-exceptions -triple=x86_64-linux-gnu struct S { // dummy ctor to make this a literal type constexpr S(int); S(); int arr[10]; constexpr int &get(int n) { return arr[n]; } constexpr const int &get(int n) const { return arr[n]; } }; S s = S(); const S &sr = s; static_assert(&s.get(4) - &sr.get(2) == 2, ""); // Compound-statements can be used in constexpr functions. constexpr int e() {{{{}} return 5; }} static_assert(e() == 5, ""); // Types can be defined in constexpr functions. constexpr int f() { enum E { e1, e2, e3 }; struct S { constexpr S(E e) : e(e) {} constexpr int get() { return e; } E e; }; return S(e2).get(); } static_assert(f() == 1, ""); // Variables can be declared in constexpr functions. constexpr int g(int k) { const int n = 9; int k2 = k * k; int k3 = k2 * k; return 3 * k3 + 5 * k2 + n * k - 20; } static_assert(g(2) == 42, ""); constexpr int h(int n) { static const int m = n; // expected-error {{static variable not permitted in a constexpr function}} return m; } constexpr int i(int n) { thread_local const int m = n; // expected-error {{thread_local variable not permitted in a constexpr function}} return m; } // if-statements can be used in constexpr functions. constexpr int j(int k) { if (k == 5) return 1; if (k == 1) return 5; else { if (int n = 2 * k - 4) { return n + 1; return 2; } } } // expected-note 2{{control reached end of constexpr function}} static_assert(j(0) == -3, ""); static_assert(j(1) == 5, ""); static_assert(j(2), ""); // expected-error {{constant expression}} expected-note {{in call to 'j(2)'}} static_assert(j(3) == 3, ""); static_assert(j(4) == 5, ""); static_assert(j(5) == 1, ""); // There can be 0 return-statements. constexpr void k() { } // If the return type is not 'void', no return statements => never a constant // expression, so still diagnose that case. [[noreturn]] constexpr int fn() { // expected-error {{no return statement in constexpr function}} fn(); } // We evaluate the body of a constexpr constructor, to check for side-effects. struct U { constexpr U(int n) { if (j(n)) {} // expected-note {{in call to 'j(2)'}} } }; constexpr U u1{1}; constexpr U u2{2}; // expected-error {{constant expression}} expected-note {{in call to 'U(2)'}} // We allow expression-statements. constexpr int l(bool b) { if (b) throw "invalid value for b!"; // expected-note {{subexpression not valid}} return 5; } static_assert(l(false) == 5, ""); static_assert(l(true), ""); // expected-error {{constant expression}} expected-note {{in call to 'l(true)'}} // Potential constant expression checking is still applied where possible. constexpr int htonl(int x) { // expected-error {{never produces a constant expression}} typedef unsigned char uchar; uchar arr[4] = { uchar(x >> 24), uchar(x >> 16), uchar(x >> 8), uchar(x) }; return *reinterpret_cast(arr); // expected-note {{reinterpret_cast is not allowed in a constant expression}} } constexpr int maybe_htonl(bool isBigEndian, int x) { if (isBigEndian) return x; typedef unsigned char uchar; uchar arr[4] = { uchar(x >> 24), uchar(x >> 16), uchar(x >> 8), uchar(x) }; return *reinterpret_cast(arr); // expected-note {{reinterpret_cast is not allowed in a constant expression}} } constexpr int swapped = maybe_htonl(false, 123); // expected-error {{constant expression}} expected-note {{in call}} namespace NS { constexpr int n = 0; } constexpr int namespace_alias() { namespace N = NS; return N::n; } namespace assign { constexpr int a = 0; const int b = 0; int c = 0; // expected-note {{here}} constexpr void set(const int &a, int b) { const_cast(a) = b; // expected-note 3{{constant expression cannot modify an object that is visible outside that expression}} } constexpr int wrap(int a, int b) { set(a, b); return a; } static_assert((set(a, 1), a) == 1, ""); // expected-error {{constant expression}} expected-note {{in call to 'set(a, 1)'}} static_assert((set(b, 1), b) == 1, ""); // expected-error {{constant expression}} expected-note {{in call to 'set(b, 1)'}} static_assert((set(c, 1), c) == 1, ""); // expected-error {{constant expression}} expected-note {{in call to 'set(c, 1)'}} static_assert(wrap(a, 1) == 1, ""); static_assert(wrap(b, 1) == 1, ""); static_assert(wrap(c, 1) == 1, ""); // expected-error {{constant expression}} expected-note {{read of non-const variable 'c'}} } namespace string_assign { template constexpr void swap(T &a, T &b) { T tmp = a; a = b; b = tmp; } template constexpr void reverse(Iterator begin, Iterator end) { while (begin != end && begin != --end) swap(*begin++, *end); } template constexpr bool equal(Iterator1 a, Iterator1 ae, Iterator2 b, Iterator2 be) { while (a != ae && b != be) if (*a++ != *b++) return false; return a == ae && b == be; } constexpr bool test1(int n) { char stuff[100] = "foobarfoo"; const char stuff2[100] = "oofraboof"; reverse(stuff, stuff + n); // expected-note {{cannot refer to element 101 of array of 100 elements}} return equal(stuff, stuff + n, stuff2, stuff2 + n); } static_assert(!test1(1), ""); static_assert(test1(3), ""); static_assert(!test1(6), ""); static_assert(test1(9), ""); static_assert(!test1(100), ""); static_assert(!test1(101), ""); // expected-error {{constant expression}} expected-note {{in call to 'test1(101)'}} constexpr void f() { // expected-error{{constexpr function never produces a constant expression}} expected-note@+2{{assignment to dereferenced one-past-the-end pointer is not allowed in a constant expression}} char foo[10] = { "z" }; // expected-note {{here}} foo[10] = 'x'; // expected-warning {{past the end}} } } namespace array_resize { constexpr int do_stuff(int k1, int k2) { int arr[1234] = { 1, 2, 3, 4 }; arr[k1] = 5; // expected-note {{past-the-end}} expected-note {{cannot refer to element 1235}} expected-note {{cannot refer to element -1}} return arr[k2]; } static_assert(do_stuff(1, 2) == 3, ""); static_assert(do_stuff(0, 0) == 5, ""); static_assert(do_stuff(1233, 1233) == 5, ""); static_assert(do_stuff(1233, 0) == 1, ""); static_assert(do_stuff(1234, 0) == 1, ""); // expected-error {{constant expression}} expected-note {{in call}} static_assert(do_stuff(1235, 0) == 1, ""); // expected-error {{constant expression}} expected-note {{in call}} static_assert(do_stuff(-1, 0) == 1, ""); // expected-error {{constant expression}} expected-note {{in call}} } namespace potential_const_expr { constexpr void set(int &n) { n = 1; } constexpr int div_zero_1() { int z = 0; set(z); return 100 / z; } // no error constexpr int div_zero_2() { // expected-error {{never produces a constant expression}} int z = 0; return 100 / (set(z), 0); // expected-note {{division by zero}} } int n; // expected-note {{declared here}} constexpr int ref() { // expected-error {{never produces a constant expression}} int &r = n; return r; // expected-note {{read of non-const variable 'n'}} } } namespace subobject { union A { constexpr A() : y(5) {} int x, y; }; struct B { A a; }; struct C : B {}; union D { constexpr D() : c() {} constexpr D(int n) : n(n) {} C c; int n; }; constexpr void f(D &d) { d.c.a.y = 3; // expected-note@-1 {{cannot modify an object that is visible outside}} // expected-note@-2 {{assignment to member 'c' of union with active member 'n'}} } constexpr bool check(D &d) { return d.c.a.y == 3; } constexpr bool g() { D d; f(d); return d.c.a.y == 3; } static_assert(g(), ""); D d; constexpr bool h() { f(d); return check(d); } // expected-note {{in call}} static_assert(h(), ""); // expected-error {{constant expression}} expected-note {{in call}} constexpr bool i() { D d(0); f(d); return check(d); } // expected-note {{in call}} static_assert(i(), ""); // expected-error {{constant expression}} expected-note {{in call}} constexpr bool j() { D d; d.c.a.x = 3; return check(d); } // expected-note {{assignment to member 'x' of union with active member 'y'}} static_assert(j(), ""); // expected-error {{constant expression}} expected-note {{in call}} } namespace lifetime { constexpr int &&id(int &&n) { return static_cast(n); } constexpr int &&dead() { return id(0); } // expected-note {{temporary created here}} constexpr int bad() { int &&n = dead(); n = 1; return n; } // expected-note {{assignment to temporary whose lifetime has ended}} static_assert(bad(), ""); // expected-error {{constant expression}} expected-note {{in call}} } namespace const_modify { constexpr int modify(int &n) { return n = 1; } // expected-note 2 {{modification of object of const-qualified type 'const int'}} constexpr int test1() { int k = 0; return modify(k); } constexpr int test2() { const int k = 0; return modify(const_cast(k)); } // expected-note 2 {{in call}} static_assert(test1() == 1, ""); static_assert(test2() == 1, ""); // expected-error {{constant expression}} expected-note {{in call}} constexpr int i = test2(); // expected-error {{constant expression}} expected-note {{in call}} } namespace null { constexpr int test(int *p) { return *p = 123; // expected-note {{assignment to dereferenced null pointer}} } static_assert(test(0), ""); // expected-error {{constant expression}} expected-note {{in call}} } namespace incdec { template constexpr T &ref(T &&r) { return r; } template constexpr T postinc(T &&r) { return (r++, r); } template constexpr T postdec(T &&r) { return (r--, r); } static_assert(++ref(0) == 1, ""); static_assert(ref(0)++ == 0, ""); static_assert(postinc(0) == 1, ""); static_assert(--ref(0) == -1, ""); static_assert(ref(0)-- == 0, ""); static_assert(postdec(0) == -1, ""); constexpr int overflow_int_inc_1 = ref(0x7fffffff)++; // expected-error {{constant}} expected-note {{2147483648}} constexpr int overflow_int_inc_1_ok = ref(0x7ffffffe)++; constexpr int overflow_int_inc_2 = ++ref(0x7fffffff); // expected-error {{constant}} expected-note {{2147483648}} constexpr int overflow_int_inc_2_ok = ++ref(0x7ffffffe); // inc/dec on short can't overflow because we promote to int first static_assert(++ref(0x7fff) == (int)0xffff8000u, ""); static_assert(--ref(0x8000) == 0x7fff, ""); // inc on bool sets to true static_assert(++ref(false), ""); // expected-warning {{deprecated}} static_assert(++ref(true), ""); // expected-warning {{deprecated}} int arr[10]; static_assert(++ref(&arr[0]) == &arr[1], ""); static_assert(++ref(&arr[9]) == &arr[10], ""); static_assert(++ref(&arr[10]) == &arr[11], ""); // expected-error {{constant}} expected-note {{cannot refer to element 11}} static_assert(ref(&arr[0])++ == &arr[0], ""); static_assert(ref(&arr[10])++ == &arr[10], ""); // expected-error {{constant}} expected-note {{cannot refer to element 11}} static_assert(postinc(&arr[0]) == &arr[1], ""); static_assert(--ref(&arr[10]) == &arr[9], ""); static_assert(--ref(&arr[1]) == &arr[0], ""); static_assert(--ref(&arr[0]) != &arr[0], ""); // expected-error {{constant}} expected-note {{cannot refer to element -1}} static_assert(ref(&arr[1])-- == &arr[1], ""); static_assert(ref(&arr[0])-- == &arr[0], ""); // expected-error {{constant}} expected-note {{cannot refer to element -1}} static_assert(postdec(&arr[1]) == &arr[0], ""); int x; static_assert(++ref(&x) == &x + 1, ""); static_assert(++ref(0.0) == 1.0, ""); static_assert(ref(0.0)++ == 0.0, ""); static_assert(postinc(0.0) == 1.0, ""); static_assert(--ref(0.0) == -1.0, ""); static_assert(ref(0.0)-- == 0.0, ""); static_assert(postdec(0.0) == -1.0, ""); static_assert(++ref(1e100) == 1e100, ""); static_assert(--ref(1e100) == 1e100, ""); union U { int a, b; }; constexpr int f(U u) { return ++u.b; // expected-note {{increment of member 'b' of union with active member 'a'}} } constexpr int wrong_member = f({0}); // expected-error {{constant}} expected-note {{in call to 'f({.a = 0})'}} constexpr int vol = --ref(0); // expected-error {{constant}} expected-note {{decrement of volatile-qualified}} constexpr int incr(int k) { int x = k; if (x++ == 100) return x; return incr(x); } static_assert(incr(0) == 101, ""); } namespace compound_assign { constexpr bool test_int() { int a = 3; a += 6; if (a != 9) return false; a -= 2; if (a != 7) return false; a *= 3; if (a != 21) return false; if (&(a /= 10) != &a) return false; if (a != 2) return false; a <<= 3; if (a != 16) return false; a %= 6; if (a != 4) return false; a >>= 1; if (a != 2) return false; a ^= 10; if (a != 8) return false; a |= 5; if (a != 13) return false; a &= 14; if (a != 12) return false; a += -1.2; if (a != 10) return false; a -= 3.1; if (a != 6) return false; a *= 2.2; if (a != 13) return false; if (&(a /= 1.5) != &a) return false; if (a != 8) return false; return true; } static_assert(test_int(), ""); constexpr bool test_float() { float f = 123.; f *= 2; if (f != 246.) return false; if ((f -= 0.5) != 245.5) return false; if (f != 245.5) return false; f /= 0.5; if (f != 491.) return false; f += -40; if (f != 451.) return false; return true; } static_assert(test_float(), ""); constexpr bool test_bool() { bool b = false; b |= 2; if (b != true) return false; b <<= 1; if (b != true) return false; b *= 2; if (b != true) return false; b -= 1; if (b != false) return false; b -= 1; if (b != true) return false; b += -1; if (b != false) return false; b += 1; if (b != true) return false; b += 1; if (b != true) return false; b ^= b; if (b != false) return false; return true; } static_assert(test_bool(), ""); constexpr bool test_ptr() { int arr[123] = {}; int *p = arr; if ((p += 4) != &arr[4]) return false; if (p != &arr[4]) return false; p += -1; if (p != &arr[3]) return false; if ((p -= -10) != &arr[13]) return false; if (p != &arr[13]) return false; p -= 11; if (p != &arr[2]) return false; return true; } static_assert(test_ptr(), ""); template constexpr bool test_overflow() { T a = 1; while (a != a / 2) a *= 2; // expected-note {{value 2147483648 is outside the range}} expected-note {{ 9223372036854775808 }} return true; } static_assert(test_overflow(), ""); // expected-error {{constant}} expected-note {{call}} static_assert(test_overflow(), ""); // ok, unsigned overflow is defined static_assert(test_overflow(), ""); // ok, short is promoted to int before multiplication static_assert(test_overflow(), ""); // ok static_assert(test_overflow(), ""); // ok static_assert(test_overflow(), ""); // expected-error {{constant}} expected-note {{call}} static_assert(test_overflow(), ""); // ok static_assert(test_overflow(), ""); // ok constexpr short test_promotion(short k) { short s = k; s *= s; return s; } static_assert(test_promotion(100) == 10000, ""); static_assert(test_promotion(200) == -25536, ""); static_assert(test_promotion(256) == 0, ""); constexpr const char *test_bounds(const char *p, int o) { return p += o; // expected-note {{element 5 of}} expected-note {{element -1 of}} expected-note {{element 1000 of}} } static_assert(test_bounds("foo", 0)[0] == 'f', ""); static_assert(test_bounds("foo", 3)[0] == 0, ""); static_assert(test_bounds("foo", 4)[-3] == 'o', ""); static_assert(test_bounds(&"foo"[4], -4)[0] == 'f', ""); static_assert(test_bounds("foo", 5) != 0, ""); // expected-error {{constant}} expected-note {{call}} static_assert(test_bounds("foo", -1) != 0, ""); // expected-error {{constant}} expected-note {{call}} static_assert(test_bounds("foo", 1000) != 0, ""); // expected-error {{constant}} expected-note {{call}} } namespace loops { constexpr int fib_loop(int a) { int f_k = 0, f_k_plus_one = 1; for (int k = 1; k != a; ++k) { int f_k_plus_two = f_k + f_k_plus_one; f_k = f_k_plus_one; f_k_plus_one = f_k_plus_two; } return f_k_plus_one; } static_assert(fib_loop(46) == 1836311903, ""); constexpr bool breaks_work() { int a = 0; for (int n = 0; n != 100; ++n) { ++a; if (a == 5) continue; if ((a % 5) == 0) break; } int b = 0; while (b != 17) { ++b; if (b == 6) continue; if ((b % 6) == 0) break; } int c = 0; do { ++c; if (c == 7) continue; if ((c % 7) == 0) break; } while (c != 21); return a == 10 && b == 12 && c == 14; } static_assert(breaks_work(), ""); void not_constexpr(); constexpr bool no_cont_after_break() { for (;;) { break; not_constexpr(); } while (true) { break; not_constexpr(); } do { break; not_constexpr(); } while (true); return true; } static_assert(no_cont_after_break(), ""); constexpr bool cond() { for (int a = 1; bool b = a != 3; ++a) { if (!b) return false; } while (bool b = true) { b = false; break; } return true; } static_assert(cond(), ""); constexpr int range_for() { int arr[] = { 1, 2, 3, 4, 5 }; int sum = 0; for (int x : arr) sum += x; return sum; } static_assert(range_for() == 15, ""); template struct ints {}; template struct join_ints; template struct join_ints, ints> { using type = ints; }; template struct make_ints { using type = typename join_ints::type, typename make_ints<(N+1)/2>::type>::type; }; template<> struct make_ints<0> { using type = ints<>; }; template<> struct make_ints<1> { using type = ints<0>; }; struct ignore { template constexpr ignore(Ts &&...) {} }; template struct array { constexpr array() : arr{} {} template constexpr array(X ...x) : arr{} { init(typename make_ints::type{}, x...); } template constexpr void init(ints, X ...x) { ignore{arr[I] = x ...}; } T arr[N]; struct iterator { T *p; constexpr explicit iterator(T *p) : p(p) {} constexpr bool operator!=(iterator o) { return p != o.p; } constexpr iterator &operator++() { ++p; return *this; } constexpr T &operator*() { return *p; } }; constexpr iterator begin() { return iterator(arr); } constexpr iterator end() { return iterator(arr + N); } }; constexpr int range_for_2() { array arr { 1, 2, 3, 4, 5 }; int sum = 0; for (int k : arr) { sum += k; if (sum > 8) break; } return sum; } static_assert(range_for_2() == 10, ""); } namespace assignment_op { struct A { constexpr A() : n(5) {} int n; struct B { int k = 1; union U { constexpr U() : y(4) {} int x; int y; } u; } b; }; constexpr bool testA() { A a, b; a.n = 7; a.b.u.y = 5; b = a; return b.n == 7 && b.b.u.y == 5 && b.b.k == 1; } static_assert(testA(), ""); struct B { bool assigned = false; constexpr B &operator=(const B&) { assigned = true; return *this; } }; struct C : B { B b; int n = 5; }; constexpr bool testC() { C c, d; c.n = 7; d = c; c.n = 3; return d.n == 7 && d.assigned && d.b.assigned; } static_assert(testC(), ""); } namespace switch_stmt { constexpr bool no_such_case(int n) { switch (n) { case 1: return false; } return true; } static_assert(no_such_case(0), ""); constexpr int f(char k) { bool b = false; int z = 6; switch (k) { return -1; case 0: if (false) { case 1: z = 1; for (; b;) { return 5; while (0) case 2: return 2; case 7: z = 7; do case 6: { return z; if (false) case 3: return 3; case 4: z = 4; } while (1); case 5: b = true; case 9: z = 9; } return z; } else if (false) case 8: z = 8; else if (false) { case 10: z = -10; break; } else z = 0; return z; default: return -1; } return -z; } static_assert(f(0) == 0, ""); static_assert(f(1) == 1, ""); static_assert(f(2) == 2, ""); static_assert(f(3) == 3, ""); static_assert(f(4) == 4, ""); static_assert(f(5) == 5, ""); static_assert(f(6) == 6, ""); static_assert(f(7) == 7, ""); static_assert(f(8) == 8, ""); static_assert(f(9) == 9, ""); static_assert(f(10) == 10, ""); // Check that we can continue an outer loop from within a switch. constexpr bool contin() { for (int n = 0; n != 10; ++n) { switch (n) { case 0: ++n; continue; case 1: return false; case 2: return true; } } return false; } static_assert(contin(), ""); constexpr bool switch_into_for() { int n = 0; switch (n) { for (; n == 1; ++n) { return n == 1; case 0: ; } } return false; } static_assert(switch_into_for(), ""); constexpr void duff_copy(char *a, const char *b, int n) { switch ((n - 1) % 8 + 1) { for ( ; n; n = (n - 1) & ~7) { case 8: a[n-8] = b[n-8]; case 7: a[n-7] = b[n-7]; case 6: a[n-6] = b[n-6]; case 5: a[n-5] = b[n-5]; case 4: a[n-4] = b[n-4]; case 3: a[n-3] = b[n-3]; case 2: a[n-2] = b[n-2]; case 1: a[n-1] = b[n-1]; } case 0: ; } } constexpr bool test_copy(const char *str, int n) { char buffer[16] = {}; duff_copy(buffer, str, n); for (int i = 0; i != sizeof(buffer); ++i) if (buffer[i] != (i < n ? str[i] : 0)) return false; return true; } static_assert(test_copy("foo", 0), ""); static_assert(test_copy("foo", 1), ""); static_assert(test_copy("foo", 2), ""); static_assert(test_copy("hello world", 0), ""); static_assert(test_copy("hello world", 7), ""); static_assert(test_copy("hello world", 8), ""); static_assert(test_copy("hello world", 9), ""); static_assert(test_copy("hello world", 10), ""); static_assert(test_copy("hello world", 10), ""); } namespace deduced_return_type { constexpr auto f() { return 0; } template constexpr auto g(T t) { return t; } static_assert(f() == 0, ""); static_assert(g(true), ""); } namespace modify_temporary_during_construction { struct A { int &&temporary; int x; int y; }; constexpr int f(int &r) { r *= 9; return r - 12; } constexpr A a = { 6, f(a.temporary), a.temporary }; // expected-note {{temporary created here}} static_assert(a.x == 42, ""); static_assert(a.y == 54, ""); constexpr int k = a.temporary++; // expected-error {{constant expression}} expected-note {{outside the expression that created the temporary}} } namespace std { typedef decltype(sizeof(int)) size_t; template class initializer_list { const _E* __begin_; size_t __size_; constexpr initializer_list(const _E* __b, size_t __s) : __begin_(__b), __size_(__s) {} public: typedef _E value_type; typedef const _E& reference; typedef const _E& const_reference; typedef size_t size_type; typedef const _E* iterator; typedef const _E* const_iterator; constexpr initializer_list() : __begin_(nullptr), __size_(0) {} constexpr size_t size() const {return __size_;} constexpr const _E* begin() const {return __begin_;} constexpr const _E* end() const {return __begin_ + __size_;} }; } namespace InitializerList { constexpr int sum(std::initializer_list ints) { int total = 0; for (int n : ints) total += n; return total; } static_assert(sum({1, 2, 3, 4, 5}) == 15, ""); } namespace StmtExpr { constexpr int f(int k) { switch (k) { case 0: return 0; ({ case 1: // expected-note {{not supported}} return 1; }); } } static_assert(f(1) == 1, ""); // expected-error {{constant expression}} expected-note {{in call}} constexpr int g() { return ({ int n; n; }); // expected-note {{read of uninitialized object}} } static_assert(g() == 0, ""); // expected-error {{constant expression}} expected-note {{in call}} // FIXME: We should handle the void statement expression case. constexpr int h() { // expected-error {{never produces a constant}} ({ if (true) {} }); // expected-note {{not supported}} return 0; } } namespace VirtualFromBase { struct S1 { virtual int f() const; }; struct S2 { virtual int f(); }; template struct X : T { constexpr X() {} double d = 0.0; constexpr int f() { return sizeof(T); } }; // Non-virtual f(), OK. constexpr X> xxs1; constexpr X *p = const_cast>*>(&xxs1); static_assert(p->f() == sizeof(S1), ""); // Virtual f(), not OK. constexpr X> xxs2; constexpr X *q = const_cast>*>(&xxs2); static_assert(q->f() == sizeof(X), ""); // expected-error {{constant expression}} expected-note {{virtual function}} } namespace Lifetime { constexpr int &get(int &&r) { return r; } constexpr int f() { int &r = get(123); return r; // expected-note {{read of object outside its lifetime}} } static_assert(f() == 123, ""); // expected-error {{constant expression}} expected-note {{in call}} constexpr int g() { int *p = 0; { int n = 0; p = &n; n = 42; } *p = 123; // expected-note {{assignment to object outside its lifetime}} return *p; } static_assert(g() == 42, ""); // expected-error {{constant expression}} expected-note {{in call}} constexpr int h(int n) { int *p[4] = {}; int &&r = 1; p[0] = &r; while (int a = 1) { p[1] = &a; for (int b = 1; int c = 1; ) { p[2] = &b, p[3] = &c; break; } break; } *p[n] = 0; // expected-note 3{{assignment to object outside its lifetime}} return *p[n]; } static_assert(h(0) == 0, ""); // ok, lifetime-extended static_assert(h(1) == 0, ""); // expected-error {{constant expression}} expected-note {{in call}} static_assert(h(2) == 0, ""); // expected-error {{constant expression}} expected-note {{in call}} static_assert(h(3) == 0, ""); // expected-error {{constant expression}} expected-note {{in call}} constexpr void lifetime_versus_loops() { int *p = 0; for (int i = 0; i != 2; ++i) { int *q = p; int n = 0; p = &n; if (i) // This modifies the 'n' from the previous iteration of the loop outside // its lifetime. ++*q; // expected-note {{increment of object outside its lifetime}} } } static_assert((lifetime_versus_loops(), true), ""); // expected-error {{constant expression}} expected-note {{in call}} } namespace Bitfields { struct A { bool b : 1; int n : 4; unsigned u : 5; }; constexpr bool test() { A a {}; a.b += 2; --a.n; --a.u; a.n = -a.n * 3; return a.b == true && a.n == 3 && a.u == 31; } static_assert(test(), ""); } namespace PR17615 { struct A { int &&r; constexpr A(int &&r) : r(static_cast(r)) {} constexpr A() : A(0) { (void)+r; // expected-note {{outside its lifetime}} } }; constexpr int k = A().r; // expected-error {{constant expression}} expected-note {{in call to}} } namespace PR17331 { template constexpr T sum(const T (&arr)[N]) { T result = 0; for (T i : arr) result += i; return result; } constexpr int ARR[] = { 1, 2, 3, 4, 5 }; static_assert(sum(ARR) == 15, ""); } namespace EmptyClass { struct E1 {} e1; union E2 {} e2; // expected-note 4{{here}} struct E3 : E1 {} e3; template constexpr int f(E &a, int kind) { switch (kind) { case 0: { E e(a); return 0; } // expected-note {{read}} expected-note {{in call}} case 1: { E e(static_cast(a)); return 0; } // expected-note {{read}} expected-note {{in call}} case 2: { E e; e = a; return 0; } // expected-note {{read}} expected-note {{in call}} case 3: { E e; e = static_cast(a); return 0; } // expected-note {{read}} expected-note {{in call}} } } constexpr int test1 = f(e1, 0); constexpr int test2 = f(e2, 0); // expected-error {{constant expression}} expected-note {{in call}} constexpr int test3 = f(e3, 0); constexpr int test4 = f(e1, 1); constexpr int test5 = f(e2, 1); // expected-error {{constant expression}} expected-note {{in call}} constexpr int test6 = f(e3, 1); constexpr int test7 = f(e1, 2); constexpr int test8 = f(e2, 2); // expected-error {{constant expression}} expected-note {{in call}} constexpr int test9 = f(e3, 2); constexpr int testa = f(e1, 3); constexpr int testb = f(e2, 3); // expected-error {{constant expression}} expected-note {{in call}} constexpr int testc = f(e3, 3); } namespace SpeculativeEvalWrites { // Ensure that we don't try to speculatively evaluate writes. constexpr int f() { int i = 0; int a = 0; // __builtin_object_size speculatively evaluates its first argument. __builtin_object_size((i = 1, &a), 0); return i; } static_assert(!f(), ""); } namespace PR27989 { constexpr int f(int n) { int a = (n = 1, 0); return n; } static_assert(f(0) == 1, ""); } namespace const_char { template constexpr int sum(const char (&Arr)[N]) { int S = 0; for (unsigned I = 0; I != N; ++I) S += Arr[I]; // expected-note 2{{read of non-constexpr variable 'Cs' is not allowed}} return S; } // As an extension, we support evaluating some things that are `const` as though // they were `constexpr` when folding, but it should not be allowed in normal // constexpr evaluation. const char Cs[] = {'a', 'b'}; // expected-note 2{{declared here}} void foo() __attribute__((enable_if(sum(Cs) == 'a' + 'b', ""))); void run() { foo(); } static_assert(sum(Cs) == 'a' + 'b', ""); // expected-error{{not an integral constant expression}} expected-note{{in call to 'sum(Cs)'}} constexpr int S = sum(Cs); // expected-error{{must be initialized by a constant expression}} expected-note{{in call}} } constexpr void PR28739(int n) { // expected-error {{never produces a constant}} int *p = &n; p += (__int128)(unsigned long)-1; // expected-note {{cannot refer to element 18446744073709551615 of non-array object in a constant expression}} } constexpr void Void(int n) { void(n + 1); void(); } constexpr int void_test = (Void(0), 1); namespace PR19741 { constexpr void addone(int &m) { m++; } struct S { int m = 0; constexpr S() { addone(m); } }; constexpr bool evalS() { constexpr S s; return s.m == 1; } static_assert(evalS(), ""); struct Nested { struct First { int x = 42; }; union { First first; int second; }; int x; constexpr Nested(int x) : first(), x(x) { x = 4; } constexpr Nested() : Nested(42) { addone(first.x); x = 3; } }; constexpr bool evalNested() { constexpr Nested N; return N.first.x == 43; } static_assert(evalNested(), ""); } // namespace PR19741 namespace Mutable { struct A { mutable int n; }; // expected-note 2{{here}} constexpr int k = A{123}.n; // ok static_assert(k == 123, ""); struct Q { A &&a; int b = a.n; }; constexpr Q q = { A{456} }; // expected-note {{temporary}} static_assert(q.b == 456, ""); static_assert(q.a.n == 456, ""); // expected-error {{constant expression}} expected-note {{outside the expression that created the temporary}} constexpr A a = {123}; constexpr int m = a.n; // expected-error {{constant expression}} expected-note {{mutable}} constexpr Q r = { static_cast(const_cast(a)) }; // expected-error {{constant expression}} expected-note@-8 {{mutable}} struct B { mutable int n; // expected-note {{here}} int m; constexpr B() : n(1), m(n) {} // ok }; constexpr B b; constexpr int p = b.n; // expected-error {{constant expression}} expected-note {{mutable}} } namespace IndirectFields { // Reference indirect field. struct A { struct { union { int x = x = 3; // expected-note {{outside its lifetime}} }; }; constexpr A() {} }; static_assert(A().x == 3, ""); // expected-error{{not an integral constant expression}} expected-note{{in call to 'A()'}} // Reference another indirect field, with different 'this'. struct B { struct { union { int x = 3; }; int y = x; }; constexpr B() {} }; static_assert(B().y == 3, ""); // Nested evaluation of indirect field initializers. struct C { union { int x = 1; }; }; struct D { struct { C c; int y = c.x + 1; }; }; static_assert(D().y == 2, ""); // Explicit 'this'. struct E { int n = 0; struct { void *x = this; }; void *y = this; }; constexpr E e1 = E(); static_assert(e1.x != e1.y, ""); constexpr E e2 = E{0}; static_assert(e2.x != e2.y, ""); } // namespace IndirectFields constexpr bool indirect_builtin_constant_p(const char *__s) { return __builtin_constant_p(*__s); } constexpr bool n = indirect_builtin_constant_p("a"); __attribute__((enable_if(indirect_builtin_constant_p("a") == n, "OK"))) int test_in_enable_if() { return 0; } int n2 = test_in_enable_if(); template int test_in_template_param() { return 0; } int n3 = test_in_template_param(); void test_in_case(int n) { switch (n) { case indirect_builtin_constant_p("abc"): break; } } enum InEnum1 { ONE = indirect_builtin_constant_p("abc") }; enum InEnum2 : int { TWO = indirect_builtin_constant_p("abc") }; enum class InEnum3 { THREE = indirect_builtin_constant_p("abc") }; // [class.ctor]p4: // A constructor can be invoked for a const, volatile or const volatile // object. const and volatile semantics are not applied on an object under // construction. They come into effect when the constructor for the most // derived object ends. namespace ObjectsUnderConstruction { struct A { int n; constexpr A() : n(1) { n = 2; } }; struct B { const A a; constexpr B(bool mutate) { if (mutate) const_cast(a).n = 3; // expected-note {{modification of object of const-qualified type 'const int'}} } }; constexpr B b(false); static_assert(b.a.n == 2, ""); constexpr B bad(true); // expected-error {{must be initialized by a constant expression}} expected-note {{in call to 'B(true)'}} struct C { int n; constexpr C() : n(1) { n = 2; } }; constexpr int f(bool get) { volatile C c; // expected-note {{here}} return get ? const_cast(c.n) : 0; // expected-note {{read of volatile object 'c'}} } static_assert(f(false) == 0, ""); // ok, can modify volatile c.n during c's initialization: it's not volatile then static_assert(f(true) == 2, ""); // expected-error {{constant}} expected-note {{in call}} struct Aggregate { int x = 0; int y = ++x; }; constexpr Aggregate aggr1; static_assert(aggr1.x == 1 && aggr1.y == 1, ""); // FIXME: This is not specified by the standard, but sanity requires it. constexpr Aggregate aggr2 = {}; static_assert(aggr2.x == 1 && aggr2.y == 1, ""); // The lifetime of 'n' begins at the initialization, not before. constexpr int n = ++const_cast(n); // expected-error {{constant expression}} expected-note {{increment of object outside its lifetime}} } namespace PR39728 { struct Comment0 { Comment0 &operator=(const Comment0 &) = default; ~Comment0() = default; }; constexpr void f() { Comment0 a; a = a; } static_assert((f(), true), ""); struct Comment1 { constexpr Comment1 &operator=(const Comment1 &) = default; // OK ~Comment1() = default; }; } namespace TemporaryWithBadPointer { constexpr int *get_bad_pointer() { int n = 0; // expected-note 2{{here}} return &n; // expected-warning {{stack}} } constexpr int *bad_pointer = get_bad_pointer(); // expected-error {{constant expression}} expected-note {{pointer to 'n' is not a constant expression}} struct DoBadThings { int *&℘ int n; }; constexpr DoBadThings dbt = { // expected-error {{constant expression}} nullptr, // expected-note {{pointer to 'n' is not a constant expression}} (dbt.wp = get_bad_pointer(), 0) }; constexpr DoBadThings dbt2 = { // ok get_bad_pointer(), (dbt2.wp = nullptr, 0) }; }