forked from OSchip/llvm-project
169 lines
5.1 KiB
C++
169 lines
5.1 KiB
C++
// RUN: %clang_cc1 -std=c++17 -verify %s
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// RUN: %clang_cc1 -std=c++20 -verify %s
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using intptr_t = __INTPTR_TYPE__;
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// Test interaction of constexpr and __builtin_constant_p.
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template<typename T> constexpr bool bcp(T t) {
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return __builtin_constant_p(t);
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}
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template<typename T> constexpr bool bcp_fold(T t) {
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return __builtin_constant_p(((void)(intptr_t)&t, t));
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}
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constexpr intptr_t ensure_fold_is_generally_not_enabled = // expected-error {{constant expression}}
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(intptr_t)&ensure_fold_is_generally_not_enabled; // expected-note {{cast}}
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constexpr intptr_t ptr_to_int(const void *p) {
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return __builtin_constant_p(1) ? (intptr_t)p : (intptr_t)p;
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}
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constexpr int *int_to_ptr(intptr_t n) {
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return __builtin_constant_p(1) ? (int*)n : (int*)n;
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}
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int x;
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// Integer and floating point constants encountered during constant expression
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// evaluation are considered constant. So is nullptr_t.
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static_assert(bcp(1));
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static_assert(bcp_fold(1));
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static_assert(bcp(1.0));
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static_assert(bcp_fold(1.0));
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static_assert(bcp(nullptr));
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static_assert(bcp_fold(nullptr));
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// Pointers to the start of strings are considered constant.
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static_assert(bcp("foo"));
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static_assert(bcp_fold("foo"));
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// Null pointers are considered constant.
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static_assert(bcp<int*>(nullptr));
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static_assert(bcp_fold<int*>(nullptr));
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static_assert(bcp<const char*>(nullptr));
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static_assert(bcp_fold<const char*>(nullptr));
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// Other pointers are not.
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static_assert(!bcp(&x));
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static_assert(!bcp_fold(&x));
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// Pointers cast to integers follow the rules for pointers.
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static_assert(bcp(ptr_to_int("foo")));
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static_assert(bcp_fold(ptr_to_int("foo")));
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static_assert(!bcp(ptr_to_int(&x)));
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static_assert(!bcp_fold(ptr_to_int(&x)));
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// Integers cast to pointers follow the integer rules.
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static_assert(bcp(int_to_ptr(0)));
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static_assert(bcp_fold(int_to_ptr(0)));
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static_assert(bcp(int_to_ptr(123))); // GCC rejects these due to not recognizing
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static_assert(bcp_fold(int_to_ptr(123))); // the bcp conditional in 'int_to_ptr' ...
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static_assert(__builtin_constant_p((int*)123)); // ... but GCC accepts this
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// State mutations in the operand are not permitted.
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//
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// The rule GCC uses for this is not entirely understood, but seems to depend
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// in some way on what local state is mentioned in the operand of
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// __builtin_constant_p and where.
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//
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// We approximate GCC's rule by evaluating the operand in a speculative
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// evaluation context; only state created within the evaluation can be
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// modified.
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constexpr int mutate1() {
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int n = 1;
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int m = __builtin_constant_p(++n);
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return n * 10 + m;
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}
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static_assert(mutate1() == 10);
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// FIXME: GCC treats this as being non-constant because of the "n = 2", even
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// though evaluation in the context of the enclosing constant expression
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// succeeds without mutating any state.
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constexpr int mutate2() {
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int n = 1;
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int m = __builtin_constant_p(n ? n + 1 : n = 2);
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return n * 10 + m;
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}
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static_assert(mutate2() == 11);
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constexpr int internal_mutation(int unused) {
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int x = 1;
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++x;
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return x;
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}
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constexpr int mutate3() {
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int n = 1;
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int m = __builtin_constant_p(internal_mutation(0));
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return n * 10 + m;
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}
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static_assert(mutate3() == 11);
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constexpr int mutate4() {
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int n = 1;
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int m = __builtin_constant_p(n ? internal_mutation(0) : 0);
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return n * 10 + m;
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}
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static_assert(mutate4() == 11);
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// FIXME: GCC treats this as being non-constant because of something to do with
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// the 'n' in the argument to internal_mutation.
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constexpr int mutate5() {
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int n = 1;
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int m = __builtin_constant_p(n ? internal_mutation(n) : 0);
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return n * 10 + m;
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}
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static_assert(mutate5() == 11);
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constexpr int mutate_param(bool mutate, int ¶m) {
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mutate = mutate; // Mutation of internal state is OK
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if (mutate)
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++param;
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return param;
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}
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constexpr int mutate6(bool mutate) {
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int n = 1;
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int m = __builtin_constant_p(mutate_param(mutate, n));
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return n * 10 + m;
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}
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// No mutation of state outside __builtin_constant_p: evaluates to true.
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static_assert(mutate6(false) == 11);
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// Mutation of state outside __builtin_constant_p: evaluates to false.
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static_assert(mutate6(true) == 10);
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// GCC strangely returns true for the address of a type_info object, despite it
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// not being a pointer to the start of a string literal.
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namespace std { struct type_info; }
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static_assert(__builtin_constant_p(&typeid(int)));
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void mutate_as_side_effect() {
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int a;
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static_assert(!__builtin_constant_p(((void)++a, 1)));
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}
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namespace dtor_side_effect {
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struct A {
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constexpr A() {}
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~A();
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};
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static_assert(!__builtin_constant_p((A{}, 123)));
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}
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#if __cplusplus >= 202002L
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namespace constexpr_dtor {
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struct A {
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int *p;
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constexpr ~A() { *p = 0; }
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};
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struct Q { int n; constexpr int *get() { return &n; } };
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static_assert(!__builtin_constant_p(((void)A{}, 123)));
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// FIXME: We should probably accept this. GCC does.
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// However, GCC appears to do so by running the destructors at the end of the
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// enclosing full-expression, which seems broken; running them at the end of
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// the evaluation of the __builtin_constant_p argument would be more
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// defensible.
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static_assert(!__builtin_constant_p(((void)A{Q().get()}, 123)));
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}
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#endif
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