Here's how I think about this, maybe you'll find this helpful... maybe not. Note that I think writing
if constexpr (std::is_constant_evaluated()) will be a really common error, and it's an easy trap to fall into. But hopefully compilers will just diagnose that case.
We essentially have two different rules for code - the typical rules for normal runtime code, and the restrictions for constant expressions that are for
constexpr programming. Those are the expr.const restrictions: no UB, no
reinterpret_cast, etc. Those restrictions keep decreasing from language standard to language standard, which is great.
Basically, control flow (from a code path perspective) alternates between being in the "full runtime" mode and the
constexpr mode. Once we enter the
constexpr mode (whether by initializing a
constexpr object or evaluating a template parameter or ...), we stay there until we're done... and then we're back to full runtime mode.
is_constant_evaluated() does is simply: Am I in constexpr mode? It tells you if you're on a context that requires constant expressions.
In that view, let's look at
if constexpr (is_constant_evaluated()). Regardless of what state we used to be in,
if constexpr requires a constant expression as its initialized so this lifts us into constexpr mode if we weren't there already. Hence,
is_constant_evaluated() is just true - unconditionally.
if (is_constant_evaluated()), a simple
if doesn't change our state between runtime and constexpr. So the value here depends on the context it was called from. Initializing
test4 puts us onto constexpr mode because it's a constexpr object. For the duration of its initialization, we follow the constant expression rules... so
is_constant_evaluated()is true. But once we're done, we're back to runtime rules... so in the initialization of
is_constant_evaluated() is false. (And then
test6 is an unfortunate language special case - you can use constant integral variables as constant expressions, so we treat their initialization the same way for these purposes.)