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1059 lines
41 KiB
Plaintext
This is Info file cpp.info, produced by Makeinfo version 1.67 from the
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input file cpp.texi.
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This file documents the GNU C Preprocessor.
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Copyright 1987, 1989, 1991, 1992, 1993, 1994, 1995 Free Software
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Foundation, Inc.
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Permission is granted to make and distribute verbatim copies of this
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manual provided the copyright notice and this permission notice are
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preserved on all copies.
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Permission is granted to copy and distribute modified versions of
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this manual under the conditions for verbatim copying, provided also
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that the entire resulting derived work is distributed under the terms
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of a permission notice identical to this one.
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Permission is granted to copy and distribute translations of this
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manual into another language, under the above conditions for modified
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versions.
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File: cpp.info, Node: Macro Pitfalls, Prev: Redefining, Up: Macros
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Pitfalls and Subtleties of Macros
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---------------------------------
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In this section we describe some special rules that apply to macros
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and macro expansion, and point out certain cases in which the rules have
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counterintuitive consequences that you must watch out for.
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* Menu:
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* Misnesting:: Macros can contain unmatched parentheses.
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* Macro Parentheses:: Why apparently superfluous parentheses
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may be necessary to avoid incorrect grouping.
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* Swallow Semicolon:: Macros that look like functions
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but expand into compound statements.
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* Side Effects:: Unsafe macros that cause trouble when
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arguments contain side effects.
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* Self-Reference:: Macros whose definitions use the macros' own names.
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* Argument Prescan:: Actual arguments are checked for macro calls
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before they are substituted.
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* Cascaded Macros:: Macros whose definitions use other macros.
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* Newlines in Args:: Sometimes line numbers get confused.
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File: cpp.info, Node: Misnesting, Next: Macro Parentheses, Prev: Macro Pitfalls, Up: Macro Pitfalls
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Improperly Nested Constructs
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............................
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Recall that when a macro is called with arguments, the arguments are
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substituted into the macro body and the result is checked, together with
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the rest of the input file, for more macro calls.
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It is possible to piece together a macro call coming partially from
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the macro body and partially from the actual arguments. For example,
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#define double(x) (2*(x))
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#define call_with_1(x) x(1)
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would expand `call_with_1 (double)' into `(2*(1))'.
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Macro definitions do not have to have balanced parentheses. By
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writing an unbalanced open parenthesis in a macro body, it is possible
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to create a macro call that begins inside the macro body but ends
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outside of it. For example,
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#define strange(file) fprintf (file, "%s %d",
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...
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strange(stderr) p, 35)
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This bizarre example expands to `fprintf (stderr, "%s %d", p, 35)'!
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File: cpp.info, Node: Macro Parentheses, Next: Swallow Semicolon, Prev: Misnesting, Up: Macro Pitfalls
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Unintended Grouping of Arithmetic
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.................................
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You may have noticed that in most of the macro definition examples
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shown above, each occurrence of a macro argument name had parentheses
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around it. In addition, another pair of parentheses usually surround
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the entire macro definition. Here is why it is best to write macros
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that way.
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Suppose you define a macro as follows,
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#define ceil_div(x, y) (x + y - 1) / y
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whose purpose is to divide, rounding up. (One use for this operation is
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to compute how many `int' objects are needed to hold a certain number
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of `char' objects.) Then suppose it is used as follows:
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a = ceil_div (b & c, sizeof (int));
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This expands into
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a = (b & c + sizeof (int) - 1) / sizeof (int);
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which does not do what is intended. The operator-precedence rules of C
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make it equivalent to this:
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a = (b & (c + sizeof (int) - 1)) / sizeof (int);
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But what we want is this:
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a = ((b & c) + sizeof (int) - 1)) / sizeof (int);
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Defining the macro as
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#define ceil_div(x, y) ((x) + (y) - 1) / (y)
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provides the desired result.
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Unintended grouping can result in another way. Consider `sizeof
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ceil_div(1, 2)'. That has the appearance of a C expression that would
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compute the size of the type of `ceil_div (1, 2)', but in fact it means
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something very different. Here is what it expands to:
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sizeof ((1) + (2) - 1) / (2)
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This would take the size of an integer and divide it by two. The
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precedence rules have put the division outside the `sizeof' when it was
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intended to be inside.
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Parentheses around the entire macro definition can prevent such
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problems. Here, then, is the recommended way to define `ceil_div':
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#define ceil_div(x, y) (((x) + (y) - 1) / (y))
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File: cpp.info, Node: Swallow Semicolon, Next: Side Effects, Prev: Macro Parentheses, Up: Macro Pitfalls
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Swallowing the Semicolon
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........................
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Often it is desirable to define a macro that expands into a compound
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statement. Consider, for example, the following macro, that advances a
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pointer (the argument `p' says where to find it) across whitespace
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characters:
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#define SKIP_SPACES (p, limit) \
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{ register char *lim = (limit); \
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while (p != lim) { \
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if (*p++ != ' ') { \
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p--; break; }}}
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Here Backslash-Newline is used to split the macro definition, which must
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be a single line, so that it resembles the way such C code would be
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laid out if not part of a macro definition.
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A call to this macro might be `SKIP_SPACES (p, lim)'. Strictly
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speaking, the call expands to a compound statement, which is a complete
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statement with no need for a semicolon to end it. But it looks like a
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function call. So it minimizes confusion if you can use it like a
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function call, writing a semicolon afterward, as in `SKIP_SPACES (p,
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lim);'
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But this can cause trouble before `else' statements, because the
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semicolon is actually a null statement. Suppose you write
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if (*p != 0)
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SKIP_SPACES (p, lim);
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else ...
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The presence of two statements--the compound statement and a null
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statement--in between the `if' condition and the `else' makes invalid C
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code.
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The definition of the macro `SKIP_SPACES' can be altered to solve
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this problem, using a `do ... while' statement. Here is how:
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#define SKIP_SPACES (p, limit) \
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do { register char *lim = (limit); \
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while (p != lim) { \
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if (*p++ != ' ') { \
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p--; break; }}} \
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while (0)
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Now `SKIP_SPACES (p, lim);' expands into
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do {...} while (0);
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which is one statement.
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File: cpp.info, Node: Side Effects, Next: Self-Reference, Prev: Swallow Semicolon, Up: Macro Pitfalls
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Duplication of Side Effects
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...........................
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Many C programs define a macro `min', for "minimum", like this:
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#define min(X, Y) ((X) < (Y) ? (X) : (Y))
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When you use this macro with an argument containing a side effect,
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as shown here,
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next = min (x + y, foo (z));
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it expands as follows:
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next = ((x + y) < (foo (z)) ? (x + y) : (foo (z)));
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where `x + y' has been substituted for `X' and `foo (z)' for `Y'.
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The function `foo' is used only once in the statement as it appears
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in the program, but the expression `foo (z)' has been substituted twice
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into the macro expansion. As a result, `foo' might be called two times
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when the statement is executed. If it has side effects or if it takes
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a long time to compute, the results might not be what you intended. We
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say that `min' is an "unsafe" macro.
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The best solution to this problem is to define `min' in a way that
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computes the value of `foo (z)' only once. The C language offers no
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standard way to do this, but it can be done with GNU C extensions as
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follows:
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#define min(X, Y) \
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({ typeof (X) __x = (X), __y = (Y); \
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(__x < __y) ? __x : __y; })
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If you do not wish to use GNU C extensions, the only solution is to
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be careful when *using* the macro `min'. For example, you can
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calculate the value of `foo (z)', save it in a variable, and use that
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variable in `min':
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#define min(X, Y) ((X) < (Y) ? (X) : (Y))
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...
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{
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int tem = foo (z);
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next = min (x + y, tem);
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}
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(where we assume that `foo' returns type `int').
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File: cpp.info, Node: Self-Reference, Next: Argument Prescan, Prev: Side Effects, Up: Macro Pitfalls
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Self-Referential Macros
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.......................
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A "self-referential" macro is one whose name appears in its
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definition. A special feature of ANSI Standard C is that the
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self-reference is not considered a macro call. It is passed into the
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preprocessor output unchanged.
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Let's consider an example:
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#define foo (4 + foo)
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where `foo' is also a variable in your program.
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Following the ordinary rules, each reference to `foo' will expand
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into `(4 + foo)'; then this will be rescanned and will expand into `(4
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+ (4 + foo))'; and so on until it causes a fatal error (memory full) in
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the preprocessor.
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However, the special rule about self-reference cuts this process
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short after one step, at `(4 + foo)'. Therefore, this macro definition
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has the possibly useful effect of causing the program to add 4 to the
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value of `foo' wherever `foo' is referred to.
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In most cases, it is a bad idea to take advantage of this feature. A
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person reading the program who sees that `foo' is a variable will not
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expect that it is a macro as well. The reader will come across the
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identifier `foo' in the program and think its value should be that of
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the variable `foo', whereas in fact the value is four greater.
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The special rule for self-reference applies also to "indirect"
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self-reference. This is the case where a macro X expands to use a
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macro `y', and the expansion of `y' refers to the macro `x'. The
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resulting reference to `x' comes indirectly from the expansion of `x',
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so it is a self-reference and is not further expanded. Thus, after
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#define x (4 + y)
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#define y (2 * x)
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`x' would expand into `(4 + (2 * x))'. Clear?
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But suppose `y' is used elsewhere, not from the definition of `x'.
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Then the use of `x' in the expansion of `y' is not a self-reference
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because `x' is not "in progress". So it does expand. However, the
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expansion of `x' contains a reference to `y', and that is an indirect
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self-reference now because `y' is "in progress". The result is that
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`y' expands to `(2 * (4 + y))'.
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It is not clear that this behavior would ever be useful, but it is
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specified by the ANSI C standard, so you may need to understand it.
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File: cpp.info, Node: Argument Prescan, Next: Cascaded Macros, Prev: Self-Reference, Up: Macro Pitfalls
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Separate Expansion of Macro Arguments
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.....................................
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We have explained that the expansion of a macro, including the
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substituted actual arguments, is scanned over again for macro calls to
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be expanded.
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What really happens is more subtle: first each actual argument text
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is scanned separately for macro calls. Then the results of this are
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substituted into the macro body to produce the macro expansion, and the
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macro expansion is scanned again for macros to expand.
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The result is that the actual arguments are scanned *twice* to expand
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macro calls in them.
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Most of the time, this has no effect. If the actual argument
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contained any macro calls, they are expanded during the first scan.
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The result therefore contains no macro calls, so the second scan does
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not change it. If the actual argument were substituted as given, with
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no prescan, the single remaining scan would find the same macro calls
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and produce the same results.
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You might expect the double scan to change the results when a
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self-referential macro is used in an actual argument of another macro
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(*note Self-Reference::.): the self-referential macro would be expanded
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once in the first scan, and a second time in the second scan. But this
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is not what happens. The self-references that do not expand in the
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first scan are marked so that they will not expand in the second scan
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either.
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The prescan is not done when an argument is stringified or
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concatenated. Thus,
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#define str(s) #s
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#define foo 4
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str (foo)
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expands to `"foo"'. Once more, prescan has been prevented from having
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any noticeable effect.
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More precisely, stringification and concatenation use the argument as
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written, in un-prescanned form. The same actual argument would be used
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in prescanned form if it is substituted elsewhere without
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stringification or concatenation.
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#define str(s) #s lose(s)
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#define foo 4
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str (foo)
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expands to `"foo" lose(4)'.
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You might now ask, "Why mention the prescan, if it makes no
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difference? And why not skip it and make the preprocessor faster?"
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The answer is that the prescan does make a difference in three special
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cases:
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* Nested calls to a macro.
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* Macros that call other macros that stringify or concatenate.
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||
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* Macros whose expansions contain unshielded commas.
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We say that "nested" calls to a macro occur when a macro's actual
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argument contains a call to that very macro. For example, if `f' is a
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macro that expects one argument, `f (f (1))' is a nested pair of calls
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to `f'. The desired expansion is made by expanding `f (1)' and
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substituting that into the definition of `f'. The prescan causes the
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expected result to happen. Without the prescan, `f (1)' itself would
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be substituted as an actual argument, and the inner use of `f' would
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appear during the main scan as an indirect self-reference and would not
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be expanded. Here, the prescan cancels an undesirable side effect (in
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the medical, not computational, sense of the term) of the special rule
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for self-referential macros.
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But prescan causes trouble in certain other cases of nested macro
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calls. Here is an example:
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|
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#define foo a,b
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#define bar(x) lose(x)
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#define lose(x) (1 + (x))
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bar(foo)
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We would like `bar(foo)' to turn into `(1 + (foo))', which would then
|
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turn into `(1 + (a,b))'. But instead, `bar(foo)' expands into
|
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`lose(a,b)', and you get an error because `lose' requires a single
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argument. In this case, the problem is easily solved by the same
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parentheses that ought to be used to prevent misnesting of arithmetic
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operations:
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||
|
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#define foo (a,b)
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#define bar(x) lose((x))
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||
|
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The problem is more serious when the operands of the macro are not
|
||
expressions; for example, when they are statements. Then parentheses
|
||
are unacceptable because they would make for invalid C code:
|
||
|
||
#define foo { int a, b; ... }
|
||
|
||
In GNU C you can shield the commas using the `({...})' construct which
|
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turns a compound statement into an expression:
|
||
|
||
#define foo ({ int a, b; ... })
|
||
|
||
Or you can rewrite the macro definition to avoid such commas:
|
||
|
||
#define foo { int a; int b; ... }
|
||
|
||
There is also one case where prescan is useful. It is possible to
|
||
use prescan to expand an argument and then stringify it--if you use two
|
||
levels of macros. Let's add a new macro `xstr' to the example shown
|
||
above:
|
||
|
||
#define xstr(s) str(s)
|
||
#define str(s) #s
|
||
#define foo 4
|
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xstr (foo)
|
||
|
||
This expands into `"4"', not `"foo"'. The reason for the difference
|
||
is that the argument of `xstr' is expanded at prescan (because `xstr'
|
||
does not specify stringification or concatenation of the argument).
|
||
The result of prescan then forms the actual argument for `str'. `str'
|
||
uses its argument without prescan because it performs stringification;
|
||
but it cannot prevent or undo the prescanning already done by `xstr'.
|
||
|
||
|
||
File: cpp.info, Node: Cascaded Macros, Next: Newlines in Args, Prev: Argument Prescan, Up: Macro Pitfalls
|
||
|
||
Cascaded Use of Macros
|
||
......................
|
||
|
||
A "cascade" of macros is when one macro's body contains a reference
|
||
to another macro. This is very common practice. For example,
|
||
|
||
#define BUFSIZE 1020
|
||
#define TABLESIZE BUFSIZE
|
||
|
||
This is not at all the same as defining `TABLESIZE' to be `1020'.
|
||
The `#define' for `TABLESIZE' uses exactly the body you specify--in
|
||
this case, `BUFSIZE'--and does not check to see whether it too is the
|
||
name of a macro.
|
||
|
||
It's only when you *use* `TABLESIZE' that the result of its expansion
|
||
is checked for more macro names.
|
||
|
||
This makes a difference if you change the definition of `BUFSIZE' at
|
||
some point in the source file. `TABLESIZE', defined as shown, will
|
||
always expand using the definition of `BUFSIZE' that is currently in
|
||
effect:
|
||
|
||
#define BUFSIZE 1020
|
||
#define TABLESIZE BUFSIZE
|
||
#undef BUFSIZE
|
||
#define BUFSIZE 37
|
||
|
||
Now `TABLESIZE' expands (in two stages) to `37'. (The `#undef' is to
|
||
prevent any warning about the nontrivial redefinition of `BUFSIZE'.)
|
||
|
||
|
||
File: cpp.info, Node: Newlines in Args, Prev: Cascaded Macros, Up: Macro Pitfalls
|
||
|
||
Newlines in Macro Arguments
|
||
---------------------------
|
||
|
||
Traditional macro processing carries forward all newlines in macro
|
||
arguments into the expansion of the macro. This means that, if some of
|
||
the arguments are substituted more than once, or not at all, or out of
|
||
order, newlines can be duplicated, lost, or moved around within the
|
||
expansion. If the expansion consists of multiple statements, then the
|
||
effect is to distort the line numbers of some of these statements. The
|
||
result can be incorrect line numbers, in error messages or displayed in
|
||
a debugger.
|
||
|
||
The GNU C preprocessor operating in ANSI C mode adjusts appropriately
|
||
for multiple use of an argument--the first use expands all the
|
||
newlines, and subsequent uses of the same argument produce no newlines.
|
||
But even in this mode, it can produce incorrect line numbering if
|
||
arguments are used out of order, or not used at all.
|
||
|
||
Here is an example illustrating this problem:
|
||
|
||
#define ignore_second_arg(a,b,c) a; c
|
||
|
||
ignore_second_arg (foo (),
|
||
ignored (),
|
||
syntax error);
|
||
|
||
The syntax error triggered by the tokens `syntax error' results in an
|
||
error message citing line four, even though the statement text comes
|
||
from line five.
|
||
|
||
|
||
File: cpp.info, Node: Conditionals, Next: Combining Sources, Prev: Macros, Up: Top
|
||
|
||
Conditionals
|
||
============
|
||
|
||
In a macro processor, a "conditional" is a directive that allows a
|
||
part of the program to be ignored during compilation, on some
|
||
conditions. In the C preprocessor, a conditional can test either an
|
||
arithmetic expression or whether a name is defined as a macro.
|
||
|
||
A conditional in the C preprocessor resembles in some ways an `if'
|
||
statement in C, but it is important to understand the difference between
|
||
them. The condition in an `if' statement is tested during the execution
|
||
of your program. Its purpose is to allow your program to behave
|
||
differently from run to run, depending on the data it is operating on.
|
||
The condition in a preprocessing conditional directive is tested when
|
||
your program is compiled. Its purpose is to allow different code to be
|
||
included in the program depending on the situation at the time of
|
||
compilation.
|
||
|
||
* Menu:
|
||
|
||
* Uses: Conditional Uses. What conditionals are for.
|
||
* Syntax: Conditional Syntax. How conditionals are written.
|
||
* Deletion: Deleted Code. Making code into a comment.
|
||
* Macros: Conditionals-Macros. Why conditionals are used with macros.
|
||
* Assertions:: How and why to use assertions.
|
||
* Errors: #error Directive. Detecting inconsistent compilation parameters.
|
||
|
||
|
||
File: cpp.info, Node: Conditional Uses, Next: Conditional Syntax, Up: Conditionals
|
||
|
||
Why Conditionals are Used
|
||
-------------------------
|
||
|
||
Generally there are three kinds of reason to use a conditional.
|
||
|
||
* A program may need to use different code depending on the machine
|
||
or operating system it is to run on. In some cases the code for
|
||
one operating system may be erroneous on another operating system;
|
||
for example, it might refer to library routines that do not exist
|
||
on the other system. When this happens, it is not enough to avoid
|
||
executing the invalid code: merely having it in the program makes
|
||
it impossible to link the program and run it. With a
|
||
preprocessing conditional, the offending code can be effectively
|
||
excised from the program when it is not valid.
|
||
|
||
* You may want to be able to compile the same source file into two
|
||
different programs. Sometimes the difference between the programs
|
||
is that one makes frequent time-consuming consistency checks on its
|
||
intermediate data, or prints the values of those data for
|
||
debugging, while the other does not.
|
||
|
||
* A conditional whose condition is always false is a good way to
|
||
exclude code from the program but keep it as a sort of comment for
|
||
future reference.
|
||
|
||
Most simple programs that are intended to run on only one machine
|
||
will not need to use preprocessing conditionals.
|
||
|
||
|
||
File: cpp.info, Node: Conditional Syntax, Next: Deleted Code, Prev: Conditional Uses, Up: Conditionals
|
||
|
||
Syntax of Conditionals
|
||
----------------------
|
||
|
||
A conditional in the C preprocessor begins with a "conditional
|
||
directive": `#if', `#ifdef' or `#ifndef'. *Note Conditionals-Macros::,
|
||
for information on `#ifdef' and `#ifndef'; only `#if' is explained here.
|
||
|
||
* Menu:
|
||
|
||
* If: #if Directive. Basic conditionals using `#if' and `#endif'.
|
||
* Else: #else Directive. Including some text if the condition fails.
|
||
* Elif: #elif Directive. Testing several alternative possibilities.
|
||
|
||
|
||
File: cpp.info, Node: #if Directive, Next: #else Directive, Up: Conditional Syntax
|
||
|
||
The `#if' Directive
|
||
...................
|
||
|
||
The `#if' directive in its simplest form consists of
|
||
|
||
#if EXPRESSION
|
||
CONTROLLED TEXT
|
||
#endif /* EXPRESSION */
|
||
|
||
The comment following the `#endif' is not required, but it is a good
|
||
practice because it helps people match the `#endif' to the
|
||
corresponding `#if'. Such comments should always be used, except in
|
||
short conditionals that are not nested. In fact, you can put anything
|
||
at all after the `#endif' and it will be ignored by the GNU C
|
||
preprocessor, but only comments are acceptable in ANSI Standard C.
|
||
|
||
EXPRESSION is a C expression of integer type, subject to stringent
|
||
restrictions. It may contain
|
||
|
||
* Integer constants, which are all regarded as `long' or `unsigned
|
||
long'.
|
||
|
||
* Character constants, which are interpreted according to the
|
||
character set and conventions of the machine and operating system
|
||
on which the preprocessor is running. The GNU C preprocessor uses
|
||
the C data type `char' for these character constants; therefore,
|
||
whether some character codes are negative is determined by the C
|
||
compiler used to compile the preprocessor. If it treats `char' as
|
||
signed, then character codes large enough to set the sign bit will
|
||
be considered negative; otherwise, no character code is considered
|
||
negative.
|
||
|
||
* Arithmetic operators for addition, subtraction, multiplication,
|
||
division, bitwise operations, shifts, comparisons, and logical
|
||
operations (`&&' and `||').
|
||
|
||
* Identifiers that are not macros, which are all treated as zero(!).
|
||
|
||
* Macro calls. All macro calls in the expression are expanded before
|
||
actual computation of the expression's value begins.
|
||
|
||
Note that `sizeof' operators and `enum'-type values are not allowed.
|
||
`enum'-type values, like all other identifiers that are not taken as
|
||
macro calls and expanded, are treated as zero.
|
||
|
||
The CONTROLLED TEXT inside of a conditional can include
|
||
preprocessing directives. Then the directives inside the conditional
|
||
are obeyed only if that branch of the conditional succeeds. The text
|
||
can also contain other conditional groups. However, the `#if' and
|
||
`#endif' directives must balance.
|
||
|
||
|
||
File: cpp.info, Node: #else Directive, Next: #elif Directive, Prev: #if Directive, Up: Conditional Syntax
|
||
|
||
The `#else' Directive
|
||
.....................
|
||
|
||
The `#else' directive can be added to a conditional to provide
|
||
alternative text to be used if the condition is false. This is what it
|
||
looks like:
|
||
|
||
#if EXPRESSION
|
||
TEXT-IF-TRUE
|
||
#else /* Not EXPRESSION */
|
||
TEXT-IF-FALSE
|
||
#endif /* Not EXPRESSION */
|
||
|
||
If EXPRESSION is nonzero, and thus the TEXT-IF-TRUE is active, then
|
||
`#else' acts like a failing conditional and the TEXT-IF-FALSE is
|
||
ignored. Contrariwise, if the `#if' conditional fails, the
|
||
TEXT-IF-FALSE is considered included.
|
||
|
||
|
||
File: cpp.info, Node: #elif Directive, Prev: #else Directive, Up: Conditional Syntax
|
||
|
||
The `#elif' Directive
|
||
.....................
|
||
|
||
One common case of nested conditionals is used to check for more
|
||
than two possible alternatives. For example, you might have
|
||
|
||
#if X == 1
|
||
...
|
||
#else /* X != 1 */
|
||
#if X == 2
|
||
...
|
||
#else /* X != 2 */
|
||
...
|
||
#endif /* X != 2 */
|
||
#endif /* X != 1 */
|
||
|
||
Another conditional directive, `#elif', allows this to be abbreviated
|
||
as follows:
|
||
|
||
#if X == 1
|
||
...
|
||
#elif X == 2
|
||
...
|
||
#else /* X != 2 and X != 1*/
|
||
...
|
||
#endif /* X != 2 and X != 1*/
|
||
|
||
`#elif' stands for "else if". Like `#else', it goes in the middle
|
||
of a `#if'-`#endif' pair and subdivides it; it does not require a
|
||
matching `#endif' of its own. Like `#if', the `#elif' directive
|
||
includes an expression to be tested.
|
||
|
||
The text following the `#elif' is processed only if the original
|
||
`#if'-condition failed and the `#elif' condition succeeds. More than
|
||
one `#elif' can go in the same `#if'-`#endif' group. Then the text
|
||
after each `#elif' is processed only if the `#elif' condition succeeds
|
||
after the original `#if' and any previous `#elif' directives within it
|
||
have failed. `#else' is equivalent to `#elif 1', and `#else' is
|
||
allowed after any number of `#elif' directives, but `#elif' may not
|
||
follow `#else'.
|
||
|
||
|
||
File: cpp.info, Node: Deleted Code, Next: Conditionals-Macros, Prev: Conditional Syntax, Up: Conditionals
|
||
|
||
Keeping Deleted Code for Future Reference
|
||
-----------------------------------------
|
||
|
||
If you replace or delete a part of the program but want to keep the
|
||
old code around as a comment for future reference, the easy way to do
|
||
this is to put `#if 0' before it and `#endif' after it. This is better
|
||
than using comment delimiters `/*' and `*/' since those won't work if
|
||
the code already contains comments (C comments do not nest).
|
||
|
||
This works even if the code being turned off contains conditionals,
|
||
but they must be entire conditionals (balanced `#if' and `#endif').
|
||
|
||
Conversely, do not use `#if 0' for comments which are not C code.
|
||
Use the comment delimiters `/*' and `*/' instead. The interior of `#if
|
||
0' must consist of complete tokens; in particular, singlequote
|
||
characters must balance. But comments often contain unbalanced
|
||
singlequote characters (known in English as apostrophes). These
|
||
confuse `#if 0'. They do not confuse `/*'.
|
||
|
||
|
||
File: cpp.info, Node: Conditionals-Macros, Next: Assertions, Prev: Deleted Code, Up: Conditionals
|
||
|
||
Conditionals and Macros
|
||
-----------------------
|
||
|
||
Conditionals are useful in connection with macros or assertions,
|
||
because those are the only ways that an expression's value can vary
|
||
from one compilation to another. A `#if' directive whose expression
|
||
uses no macros or assertions is equivalent to `#if 1' or `#if 0'; you
|
||
might as well determine which one, by computing the value of the
|
||
expression yourself, and then simplify the program.
|
||
|
||
For example, here is a conditional that tests the expression
|
||
`BUFSIZE == 1020', where `BUFSIZE' must be a macro.
|
||
|
||
#if BUFSIZE == 1020
|
||
printf ("Large buffers!\n");
|
||
#endif /* BUFSIZE is large */
|
||
|
||
(Programmers often wish they could test the size of a variable or
|
||
data type in `#if', but this does not work. The preprocessor does not
|
||
understand `sizeof', or typedef names, or even the type keywords such
|
||
as `int'.)
|
||
|
||
The special operator `defined' is used in `#if' expressions to test
|
||
whether a certain name is defined as a macro. Either `defined NAME' or
|
||
`defined (NAME)' is an expression whose value is 1 if NAME is defined
|
||
as macro at the current point in the program, and 0 otherwise. For the
|
||
`defined' operator it makes no difference what the definition of the
|
||
macro is; all that matters is whether there is a definition. Thus, for
|
||
example,
|
||
|
||
#if defined (vax) || defined (ns16000)
|
||
|
||
would succeed if either of the names `vax' and `ns16000' is defined as
|
||
a macro. You can test the same condition using assertions (*note
|
||
Assertions::.), like this:
|
||
|
||
#if #cpu (vax) || #cpu (ns16000)
|
||
|
||
If a macro is defined and later undefined with `#undef', subsequent
|
||
use of the `defined' operator returns 0, because the name is no longer
|
||
defined. If the macro is defined again with another `#define',
|
||
`defined' will recommence returning 1.
|
||
|
||
Conditionals that test whether just one name is defined are very
|
||
common, so there are two special short conditional directives for this
|
||
case.
|
||
|
||
`#ifdef NAME'
|
||
is equivalent to `#if defined (NAME)'.
|
||
|
||
`#ifndef NAME'
|
||
is equivalent to `#if ! defined (NAME)'.
|
||
|
||
Macro definitions can vary between compilations for several reasons.
|
||
|
||
* Some macros are predefined on each kind of machine. For example,
|
||
on a Vax, the name `vax' is a predefined macro. On other
|
||
machines, it would not be defined.
|
||
|
||
* Many more macros are defined by system header files. Different
|
||
systems and machines define different macros, or give them
|
||
different values. It is useful to test these macros with
|
||
conditionals to avoid using a system feature on a machine where it
|
||
is not implemented.
|
||
|
||
* Macros are a common way of allowing users to customize a program
|
||
for different machines or applications. For example, the macro
|
||
`BUFSIZE' might be defined in a configuration file for your
|
||
program that is included as a header file in each source file. You
|
||
would use `BUFSIZE' in a preprocessing conditional in order to
|
||
generate different code depending on the chosen configuration.
|
||
|
||
* Macros can be defined or undefined with `-D' and `-U' command
|
||
options when you compile the program. You can arrange to compile
|
||
the same source file into two different programs by choosing a
|
||
macro name to specify which program you want, writing conditionals
|
||
to test whether or how this macro is defined, and then controlling
|
||
the state of the macro with compiler command options. *Note
|
||
Invocation::.
|
||
|
||
Assertions are usually predefined, but can be defined with
|
||
preprocessor directives or command-line options.
|
||
|
||
|
||
File: cpp.info, Node: Assertions, Next: #error Directive, Prev: Conditionals-Macros, Up: Conditionals
|
||
|
||
Assertions
|
||
----------
|
||
|
||
"Assertions" are a more systematic alternative to macros in writing
|
||
conditionals to test what sort of computer or system the compiled
|
||
program will run on. Assertions are usually predefined, but you can
|
||
define them with preprocessing directives or command-line options.
|
||
|
||
The macros traditionally used to describe the type of target are not
|
||
classified in any way according to which question they answer; they may
|
||
indicate a hardware architecture, a particular hardware model, an
|
||
operating system, a particular version of an operating system, or
|
||
specific configuration options. These are jumbled together in a single
|
||
namespace. In contrast, each assertion consists of a named question and
|
||
an answer. The question is usually called the "predicate". An
|
||
assertion looks like this:
|
||
|
||
#PREDICATE (ANSWER)
|
||
|
||
You must use a properly formed identifier for PREDICATE. The value of
|
||
ANSWER can be any sequence of words; all characters are significant
|
||
except for leading and trailing whitespace, and differences in internal
|
||
whitespace sequences are ignored. Thus, `x + y' is different from
|
||
`x+y' but equivalent to `x + y'. `)' is not allowed in an answer.
|
||
|
||
Here is a conditional to test whether the answer ANSWER is asserted
|
||
for the predicate PREDICATE:
|
||
|
||
#if #PREDICATE (ANSWER)
|
||
|
||
There may be more than one answer asserted for a given predicate. If
|
||
you omit the answer, you can test whether *any* answer is asserted for
|
||
PREDICATE:
|
||
|
||
#if #PREDICATE
|
||
|
||
Most of the time, the assertions you test will be predefined
|
||
assertions. GNU C provides three predefined predicates: `system',
|
||
`cpu', and `machine'. `system' is for assertions about the type of
|
||
software, `cpu' describes the type of computer architecture, and
|
||
`machine' gives more information about the computer. For example, on a
|
||
GNU system, the following assertions would be true:
|
||
|
||
#system (gnu)
|
||
#system (mach)
|
||
#system (mach 3)
|
||
#system (mach 3.SUBVERSION)
|
||
#system (hurd)
|
||
#system (hurd VERSION)
|
||
|
||
and perhaps others. The alternatives with more or less version
|
||
information let you ask more or less detailed questions about the type
|
||
of system software.
|
||
|
||
On a Unix system, you would find `#system (unix)' and perhaps one of:
|
||
`#system (aix)', `#system (bsd)', `#system (hpux)', `#system (lynx)',
|
||
`#system (mach)', `#system (posix)', `#system (svr3)', `#system
|
||
(svr4)', or `#system (xpg4)' with possible version numbers following.
|
||
|
||
Other values for `system' are `#system (mvs)' and `#system (vms)'.
|
||
|
||
*Portability note:* Many Unix C compilers provide only one answer
|
||
for the `system' assertion: `#system (unix)', if they support
|
||
assertions at all. This is less than useful.
|
||
|
||
An assertion with a multi-word answer is completely different from
|
||
several assertions with individual single-word answers. For example,
|
||
the presence of `system (mach 3.0)' does not mean that `system (3.0)'
|
||
is true. It also does not directly imply `system (mach)', but in GNU
|
||
C, that last will normally be asserted as well.
|
||
|
||
The current list of possible assertion values for `cpu' is: `#cpu
|
||
(a29k)', `#cpu (alpha)', `#cpu (arm)', `#cpu (clipper)', `#cpu
|
||
(convex)', `#cpu (elxsi)', `#cpu (tron)', `#cpu (h8300)', `#cpu
|
||
(i370)', `#cpu (i386)', `#cpu (i860)', `#cpu (i960)', `#cpu (m68k)',
|
||
`#cpu (m88k)', `#cpu (mips)', `#cpu (ns32k)', `#cpu (hppa)', `#cpu
|
||
(pyr)', `#cpu (ibm032)', `#cpu (rs6000)', `#cpu (sh)', `#cpu (sparc)',
|
||
`#cpu (spur)', `#cpu (tahoe)', `#cpu (vax)', `#cpu (we32000)'.
|
||
|
||
You can create assertions within a C program using `#assert', like
|
||
this:
|
||
|
||
#assert PREDICATE (ANSWER)
|
||
|
||
(Note the absence of a `#' before PREDICATE.)
|
||
|
||
Each time you do this, you assert a new true answer for PREDICATE.
|
||
Asserting one answer does not invalidate previously asserted answers;
|
||
they all remain true. The only way to remove an assertion is with
|
||
`#unassert'. `#unassert' has the same syntax as `#assert'. You can
|
||
also remove all assertions about PREDICATE like this:
|
||
|
||
#unassert PREDICATE
|
||
|
||
You can also add or cancel assertions using command options when you
|
||
run `gcc' or `cpp'. *Note Invocation::.
|
||
|
||
|
||
File: cpp.info, Node: #error Directive, Prev: Assertions, Up: Conditionals
|
||
|
||
The `#error' and `#warning' Directives
|
||
--------------------------------------
|
||
|
||
The directive `#error' causes the preprocessor to report a fatal
|
||
error. The rest of the line that follows `#error' is used as the error
|
||
message. The line must consist of complete tokens.
|
||
|
||
You would use `#error' inside of a conditional that detects a
|
||
combination of parameters which you know the program does not properly
|
||
support. For example, if you know that the program will not run
|
||
properly on a Vax, you might write
|
||
|
||
#ifdef __vax__
|
||
#error "Won't work on Vaxen. See comments at get_last_object."
|
||
#endif
|
||
|
||
*Note Nonstandard Predefined::, for why this works.
|
||
|
||
If you have several configuration parameters that must be set up by
|
||
the installation in a consistent way, you can use conditionals to detect
|
||
an inconsistency and report it with `#error'. For example,
|
||
|
||
#if HASH_TABLE_SIZE % 2 == 0 || HASH_TABLE_SIZE % 3 == 0 \
|
||
|| HASH_TABLE_SIZE % 5 == 0
|
||
#error HASH_TABLE_SIZE should not be divisible by a small prime
|
||
#endif
|
||
|
||
The directive `#warning' is like the directive `#error', but causes
|
||
the preprocessor to issue a warning and continue preprocessing. The
|
||
rest of the line that follows `#warning' is used as the warning message.
|
||
|
||
You might use `#warning' in obsolete header files, with a message
|
||
directing the user to the header file which should be used instead.
|
||
|
||
|
||
File: cpp.info, Node: Combining Sources, Next: Other Directives, Prev: Conditionals, Up: Top
|
||
|
||
Combining Source Files
|
||
======================
|
||
|
||
One of the jobs of the C preprocessor is to inform the C compiler of
|
||
where each line of C code came from: which source file and which line
|
||
number.
|
||
|
||
C code can come from multiple source files if you use `#include';
|
||
both `#include' and the use of conditionals and macros can cause the
|
||
line number of a line in the preprocessor output to be different from
|
||
the line's number in the original source file. You will appreciate the
|
||
value of making both the C compiler (in error messages) and symbolic
|
||
debuggers such as GDB use the line numbers in your source file.
|
||
|
||
The C preprocessor builds on this feature by offering a directive by
|
||
which you can control the feature explicitly. This is useful when a
|
||
file for input to the C preprocessor is the output from another program
|
||
such as the `bison' parser generator, which operates on another file
|
||
that is the true source file. Parts of the output from `bison' are
|
||
generated from scratch, other parts come from a standard parser file.
|
||
The rest are copied nearly verbatim from the source file, but their
|
||
line numbers in the `bison' output are not the same as their original
|
||
line numbers. Naturally you would like compiler error messages and
|
||
symbolic debuggers to know the original source file and line number of
|
||
each line in the `bison' input.
|
||
|
||
`bison' arranges this by writing `#line' directives into the output
|
||
file. `#line' is a directive that specifies the original line number
|
||
and source file name for subsequent input in the current preprocessor
|
||
input file. `#line' has three variants:
|
||
|
||
`#line LINENUM'
|
||
Here LINENUM is a decimal integer constant. This specifies that
|
||
the line number of the following line of input, in its original
|
||
source file, was LINENUM.
|
||
|
||
`#line LINENUM FILENAME'
|
||
Here LINENUM is a decimal integer constant and FILENAME is a
|
||
string constant. This specifies that the following line of input
|
||
came originally from source file FILENAME and its line number there
|
||
was LINENUM. Keep in mind that FILENAME is not just a file name;
|
||
it is surrounded by doublequote characters so that it looks like a
|
||
string constant.
|
||
|
||
`#line ANYTHING ELSE'
|
||
ANYTHING ELSE is checked for macro calls, which are expanded. The
|
||
result should be a decimal integer constant followed optionally by
|
||
a string constant, as described above.
|
||
|
||
`#line' directives alter the results of the `__FILE__' and
|
||
`__LINE__' predefined macros from that point on. *Note Standard
|
||
Predefined::.
|
||
|
||
The output of the preprocessor (which is the input for the rest of
|
||
the compiler) contains directives that look much like `#line'
|
||
directives. They start with just `#' instead of `#line', but this is
|
||
followed by a line number and file name as in `#line'. *Note Output::.
|
||
|
||
|
||
File: cpp.info, Node: Other Directives, Next: Output, Prev: Combining Sources, Up: Top
|
||
|
||
Miscellaneous Preprocessing Directives
|
||
======================================
|
||
|
||
This section describes three additional preprocessing directives.
|
||
They are not very useful, but are mentioned for completeness.
|
||
|
||
The "null directive" consists of a `#' followed by a Newline, with
|
||
only whitespace (including comments) in between. A null directive is
|
||
understood as a preprocessing directive but has no effect on the
|
||
preprocessor output. The primary significance of the existence of the
|
||
null directive is that an input line consisting of just a `#' will
|
||
produce no output, rather than a line of output containing just a `#'.
|
||
Supposedly some old C programs contain such lines.
|
||
|
||
The ANSI standard specifies that the effect of the `#pragma'
|
||
directive is implementation-defined. In the GNU C preprocessor,
|
||
`#pragma' directives are not used, except for `#pragma once' (*note
|
||
Once-Only::.). However, they are left in the preprocessor output, so
|
||
they are available to the compilation pass.
|
||
|
||
The `#ident' directive is supported for compatibility with certain
|
||
other systems. It is followed by a line of text. On some systems, the
|
||
text is copied into a special place in the object file; on most systems,
|
||
the text is ignored and this directive has no effect. Typically
|
||
`#ident' is only used in header files supplied with those systems where
|
||
it is meaningful.
|
||
|
||
|
||
File: cpp.info, Node: Output, Next: Invocation, Prev: Other Directives, Up: Top
|
||
|
||
C Preprocessor Output
|
||
=====================
|
||
|
||
The output from the C preprocessor looks much like the input, except
|
||
that all preprocessing directive lines have been replaced with blank
|
||
lines and all comments with spaces. Whitespace within a line is not
|
||
altered; however, unless `-traditional' is used, spaces may be inserted
|
||
into the expansions of macro calls to prevent tokens from being
|
||
concatenated.
|
||
|
||
Source file name and line number information is conveyed by lines of
|
||
the form
|
||
|
||
# LINENUM FILENAME FLAGS
|
||
|
||
which are inserted as needed into the middle of the input (but never
|
||
within a string or character constant). Such a line means that the
|
||
following line originated in file FILENAME at line LINENUM.
|
||
|
||
After the file name comes zero or more flags, which are `1', `2',
|
||
`3', or `4'. If there are multiple flags, spaces separate them. Here
|
||
is what the flags mean:
|
||
|
||
`1'
|
||
This indicates the start of a new file.
|
||
|
||
`2'
|
||
This indicates returning to a file (after having included another
|
||
file).
|
||
|
||
`3'
|
||
This indicates that the following text comes from a system header
|
||
file, so certain warnings should be suppressed.
|
||
|
||
`4'
|
||
This indicates that the following text should be treated as C.
|
||
|