Preprocessor directives are lines included in the code of our programs that are not program statements but directives for the preprocessor. These lines are always preceded by a hash sign (#). The preprocessor is executed before the actual compilation of code begins, therefore the preprocessor digests all these directives before any code is generated by the statements.
These preprocessor directives extend only across a single line of code. As soon as a newline character is found, the preprocessor directive is considered to end. No semicolon (;) is expected at the end of a preprocessor directive. The only way a preprocessor directive can extend through more than one line is by preceding the newline character at the end of the line by a backslash ( \).
These preprocessor directives extend only across a single line of code. As soon as a newline character is found, the preprocessor directive is considered to end. No semicolon (;) is expected at the end of a preprocessor directive. The only way a preprocessor directive can extend through more than one line is by preceding the newline character at the end of the line by a backslash ( \).
macro definitions (#define, #undef)
To define preprocessor macros we can use #define. Its format is:#define identifier replacement
When the preprocessor encounters this directive, it replaces any occurrence of identifier in the rest of the code by replacement. This replacement can be an expression, a statement, a block or simply anything. The preprocessor does not understand C++, it simply replaces any occurrence of identifier by replacement.
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After the preprocessor has replaced TABLE_SIZE, the code becomes equivalent to:
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This use of #define as constant definer is already known by us from previous tutorials, but #define can work also with parameters to define function macros:
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This would replace any occurrence of getmax followed by two arguments by the replacement expression, but also replacing each argument by its identifier, exactly as you would expect if it was a function:
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Defined macros are not affected by block structure. A macro lasts until it is undefined with the #undef preprocessor directive:
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This would generate the same code as:
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Function macro definitions accept two special operators ( # and ##) in the replacement sequence:
If the operator # is used before a parameter is used in the replacement sequence, that parameter is replaced by a string literal (as if it were enclosed between double quotes)
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This would be translated into:
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The operator ## concatenates two arguments leaving no blank spaces between them:
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This would also be translated into:
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Because preprocessor replacements happen before any C++ syntax check, macro definitions can be a tricky feature, but be careful: code that relies heavily on complicated macros may seem obscure to other programmers, since the syntax they expect is on many occasions different from the regular expressions programmers expect in C++.
Conditional inclusions (#ifdef, #ifndef, #if, #endif, #else and #elif)
These directives allow to include or discard part of the code of a program if a certain condition is met.
#ifdef allows a section of a program to be compiled only if the macro that is specified as the parameter has been defined, no matter which its value is. For example:
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In this case, the line of code int table[TABLE_SIZE]; is only compiled if TABLE_SIZE was previously defined with #define, independently of its value. If it was not defined, that line will not be included in the program compilation.
#ifndef serves for the exact opposite: the code between #ifndef and #endif directives is only compiled if the specified identifier has not been previously defined. For example:
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In this case, if when arriving at this piece of code, the TABLE_SIZE macro has not been defined yet, it would be defined to a value of 100. If it already existed it would keep its previous value since the #define directive would not be executed.
The #if, #else and #elif (i.e., "else if") directives serve to specify some condition to be met in order for the portion of code they surround to be compiled. The condition that follows #if or #elif can only evaluate constant expressions, including macro expressions. For example:
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Notice how the whole structure of #if, #elif and #else chained directives ends with #endif.
The behavior of #ifdef and #ifndef can also be achieved by using the special operators defined and !defined respectively in any #if or #elif directive:
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Line control (#line)
When we compile a program and some error happens during the compiling process, the compiler shows an error message with references to the name of the file where the error happened and a line number, so it is easier to find the code generating the error.The #line directive allows us to control both things, the line numbers within the code files as well as the file name that we want that appears when an error takes place. Its format is:
#line number "filename"
Where number is the new line number that will be assigned to the next code line. The line numbers of successive lines will be increased one by one from this point on.
"filename" is an optional parameter that allows to redefine the file name that will be shown. For example:
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This code will generate an error that will be shown as error in file "assigning variable", line 20.
Error directive (#error)
This directive aborts the compilation process when it is found, generating a compilation the error that can be specified as its parameter:1 2 3 |
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This example aborts the compilation process if the macro name __cplusplus is not defined (this macro name is defined by default in all C++ compilers).
Source file inclusion (#include)
This directive has also been used assiduously in other sections of this tutorial. When the preprocessor finds an #include directive it replaces it by the entire content of the specified file. There are two ways to specify a file to be included:1 2 |
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The only difference between both expressions is the places (directories) where the compiler is going to look for the file. In the first case where the file name is specified between double-quotes, the file is searched first in the same directory that includes the file containing the directive. In case that it is not there, the compiler searches the file in the default directories where it is configured to look for the standard header files.
If the file name is enclosed between angle-brackets <> the file is searched directly where the compiler is configured to look for the standard header files. Therefore, standard header files are usually included in angle-brackets, while other specific header files are included using quotes.
Pragma directive (#pragma)
This directive is used to specify diverse options to the compiler. These options are specific for the platform and the compiler you use. Consult the manual or the reference of your compiler for more information on the possible parameters that you can define with #pragma.If the compiler does not support a specific argument for #pragma, it is ignored - no error is generated.
Predefined macro names
The following macro names are defined at any time:macro | value |
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__LINE__ | Integer value representing the current line in the source code file being compiled. |
__FILE__ | A string literal containing the presumed name of the source file being compiled. |
__DATE__ | A string literal in the form "Mmm dd yyyy" containing the date in which the compilation process began. |
__TIME__ | A string literal in the form "hh:mm:ss" containing the time at which the compilation process began. |
__cplusplus | An integer value. All C++ compilers have this constant defined to some value. If the compiler is fully compliant with the C++ standard its value is equal or greater than 199711L depending on the version of the standard they comply. |
For example:
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This is the line number 7 of file /home/jay/stdmacronames.cpp.
Its compilation began Nov 1 2005 at 10:12:29.
The compiler gives a __cplusplus value of 1