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C++03 5.1 Primary expressions

A literal is a primary expression. Its type depends on its form (2.13). A string literal is an lvalue; all other literals are rvalues.

What is the rationale behind this?
As I understand, string literals are objects, while all other literals are not.And an l-value always refers to an object.

But the question then is why are string literals objects while all other literals are not?
This rationale seems to me more like an egg or chicken problem.

I understand the answer to this may be related to hardware architecture rather than C/C++ as programming languages, nevertheless I would like to hear the same.

Note: I am tagging this question as c & c++ both because C99 standard also has similar quotations, specifically §

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Lvalues are not objects. Lvalues are values which can appear on the left-hand side of an assignment, such as variables, members of structures, and array element lookups. (L = Left.) – duskwuff Apr 4 '12 at 3:26
@duskwuff: The Committee begs to differ. Per, "An lvalue is an expression with an object type or an incomplete type other than void; if an lvalue does not designate an object when it is evaluated, the behavior is undefined." Per the footnote (53) referenced in that citation, an lvalue should be thought of as an "object locator value". – R.. Apr 4 '12 at 3:31
@JohnCalsbeek C++11 'fixed' that, e.g. alias<T[N]> {} is possible now. U {}.arr is also an rvalue of array type if arr is declared as such in the class definition for U. – Luc Danton Apr 4 '12 at 3:50
BTW, a better approximation of lvalue is "syntactically valid operand of the & operator". I suspect that definition is actually equivalent to the standard's definition, unless I'm missing something... – R.. Apr 4 '12 at 4:10
Update: It is only approximate. Register-storage-class objects are not valid as operands of &, but are lvalues. Also, I'm rather unclear on why it's (presumably) invalid to apply & to the return value of a function, which is specified to have object type... – R.. Apr 4 '12 at 4:56

A string literal is a literal with array type, and in C there is no way for an array type to exist in an expression except as an lvalue. String literals could have been specified to have pointer type (rather than array type that usually decays to a pointer) pointing to the string "contents", but this would make them rather less useful; in particular, the sizeof operator could not be applied to them.

Note that C99 introduced compound literals, which are also lvalues, so having a literal be an lvalue is no longer a special exception; it's closer to being the norm.

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puts("hello") is an expression with type int. – R.. Apr 4 '12 at 3:40
"hello" is not an rvalue. It's an lvalue array which decays to an expression of type pointer-to-char. – R.. Apr 4 '12 at 3:43
The literal can't have array type without being an lvalue, because of the way array decay to pointers works. If it did not have object type, there would be no address of its initial element for it to decay to. As my (slightly revised) answer states, the language could have been designed such that string literals are originally of pointer type, without any decay, and then they would not need to be lvalues. But that would be a lot less useful in practice. – R.. Apr 4 '12 at 3:48
It is possible to have rvalue array types - for example if you have struct x { int a[2]; }; struct x foo(void); then foo().a is an rvalue array. Also, given struct x bar, quux; then (1 ? bar : quux).a is an rvalue array. – caf Apr 4 '12 at 4:21
@R.: That definition does not seem complete, because for example the expression +1 has object type (int) but is not ordinarily considered an lvalue. Note that Example 1 in C99 § specifically calls out f().x as being "a valid postfix expression but is not an lvalue". – caf Apr 4 '12 at 6:24

I'd guess that the original motive was mainly a pragmatic one: a string literal must reside in memory and have an address. The type of a string literal is an array type (char[] in C, char const[] in C++), and array types convert to pointers in most contexts. The language could have found other ways to define this (e.g. a string literal could have pointer type to begin with, with special rules concerning what it pointed to), but just making the literal an lvalue is probably the easiest way of defining what is concretely needed.

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Why the down vote for what is almost certainly the correct answer? – James Kanze Apr 4 '12 at 7:47
Not my downvote. So if I understand your answer correctly, the committee just accepted what was probably suggested without delving in to whether it was the best possible approach, but just that it seemed more flexible to chose at the time? – Alok Save Apr 4 '12 at 8:25
For whatever it's worth, the C99 standard just took the text from the C89 standard, and in the C89 standardization process, as I recall (from reading minutes, I was never at any actual meetings) there was some minor argument about this but it never went anywhere. The big fiery arguments were about making string literals const. – torek Apr 4 '12 at 8:30
@Als Even before the committee, the specification of C has been strongly motivated by pragmatic considerations, rather than language theory or more abstract considerations. Esthetically, it would be more elegant if the all of the literal types were rvalues. Pragmatically, string literals have an array type, array types work differently than other types, and making them lvalues sorts things out with the least number of other special rules. – James Kanze Apr 4 '12 at 8:51
@torek IIRC, the distinction was already present in K&R C (1st edition), although my copy isn't handy to check with. Pragmatically, it's easier to say that they're lvalues than it is to write several paragraphs of special rules so that they can be rvalues, but still work as they do. Pragmatically, too, it's easier to say that they are non-const (but cannot be modified), than it is to define special conversion rules (a la C++) to avoid breaking code. K&R and the C committee have always been very pragmatic about things. – James Kanze Apr 4 '12 at 8:57

An lvalue in C++ does not always refer to an object. It can refer to a function too. Moreover objects do not have to be referred to by lvalues. They may be referred to by rvalues, including for arrays (in C++ and C). However in old C89, the array to pointer conversion did not apply for rvalues arrays.

Now, an rvalue denotes no, limited or soon to be expired lifetime. A string literal however lives for the entire program.

So string literals being lvalues is exactly right.

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How about the lifetime of integral literals? And how would one refer them anyways if their address can't be taken? – Alok Save Apr 4 '12 at 8:26
integer literals do not refer to an object so there is no lifetime to be considered. – Johannes Schaub - litb Apr 4 '12 at 8:44

String literals are arrays - objects of inherently unpredictable size (i.e of user-defined and possibly large size). In general case there's simply no other way to represent such literals except as objects in memory, i.e. as lvalues. In C99 this also applies to compound literals, which are also lvalues.

Any attempts to artificially hide the fact that string literals are lvalues at the language level would produce a considerable number of completely unnecessary difficulties, since the ability to point to a string literal with a pointer as well as the ability to access it as an array relies critically on its lvalue-ness being visible at the language level.

Meanwhile, literals of scalar types have fixed compile-time size. At the same time such literals are very likely to be embedded directly into the machine commands on the given hardware architecture. For example, when you write something like i = i * 5 + 2, the literal values 5 and 2 become explicit (or even implicit) parts of the generated machine code. They don't exist and don't need to exist as standalone locations in data storage. There's imply no point in storing values 5 and 2 in data memory.

It is also worth nothing that on many (if not most, or all) hardware architectures floating-point literals are actually implemented as "hidden" lvalues (even though the language does not expose them as such). On platforms like x86 machine commands from floating-point group do not support embedded immediate operands. This means that virtually every floating-point literal has to be stored in (and read from) data memory by the compiler. E.g. when you write something like i = i * 5.5 + 2.1 it is translated into something like

const double unnamed_double_5_5 = 5.5;
const double unnamed_double_2_1 = 2.1;
i = i * unnamed_double_5_5 + unnamed_double_2_1;

In other words, floating-point literals often end up becoming "unofficial" lvalues internally. However, it makes perfect sense that language specification did not make any attempts to expose this implementation detail. At language level arithmetic literals make more sense as rvalues.

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