fort77 [-c][-g][-L
directory]... [-O optlevel][-o
outfile][-s][-w]
operand...
The fort77 utility is the interface to the FORTRAN compilation system; it shall accept the full FORTRAN-77 language defined by the ANSI X3.9-1978 standard. The system conceptually consists of a compiler and link editor. The files referenced by operands are compiled and linked to produce an executable file. It is unspecified whether the linking occurs entirely within the operation of fort77; some implementations may produce objects that are not fully resolved until the file is executed.
If the -c option is present, for all pathname operands of the form file .f, the files:
$(basename pathname.f).o
shall be created or overwritten as the result of successful compilation. If the -c option is not specified, it is unspecified whether such .o files are created or deleted for the file .f operands.
If there are no options that prevent link editing (such as -c) and all operands compile and link without error, the resulting executable file shall be written into the file named by the -o option (if present) or to the file a.out. The executable file shall be created as specified in the System Interfaces volume of IEEE Std 1003.1-2001, except that the file permissions shall be set to:
S_IRWXO | S_IRWXG | S_IRWXU
and that the bits specified by the umask of the process shall be cleared.
The fort77 utility shall conform to the Base Definitions volume of IEEE Std 1003.1-2001, Section 12.2, Utility Syntax Guidelines, except that:
The following options shall be supported:
Multiple instances of -L options can be specified.
An operand is either in the form of a pathname or the form -l library. At least one operand of the pathname form shall be specified. The following operands shall be supported:
The processing of other files is implementation-defined.
liblibrary.a
A library is searched when its name is encountered, so the placement of a -l operand is significant. Several standard libraries can be specified in this manner, as described in the EXTENDED DESCRIPTION section. Implementations may recognize implementation-defined suffixes other than .a as denoting libraries.
The input file shall be one of the following: a text file containing FORTRAN source code; an object file in the format produced by fort77 -c; or a library of object files, in the format produced by archiving zero or more object files, using ar. Implementations may supply additional utilities that produce files in these formats. Additional input files are implementation-defined.
A <tab> encountered within the first six characters on a line of source code shall cause the compiler to interpret the following character as if it were the seventh character on the line (that is, in column 7).
The following environment variables shall affect the execution of fort77:
The standard error shall be used only for diagnostic messages. If more than one file operand ending in .f (or possibly other unspecified suffixes) is given, for each such file:
"%s:\n", <file>
may be written to allow identification of the diagnostic message with the appropriate input file.
This utility may produce warning messages about certain conditions that do not warrant returning an error (non-zero) exit value.
Object files, listing files, and executable files shall be produced in unspecified formats.
The fort77 utility shall recognize the following -l operand for the standard library:
In the absence of options that inhibit invocation of the link editor, such as -c, the fort77 utility shall cause the equivalent of a -l f operand to be passed to the link editor as the last -l operand, causing it to be searched after all other object files and libraries are loaded.
It is unspecified whether the library libf.a exists as a regular file. The implementation may accept as -l operands names of objects that do not exist as regular files.
The FORTRAN compiler and link editor shall support the significance of external symbols up to a length of at least 31 bytes; case folding is permitted. The action taken upon encountering symbols exceeding the implementation-defined maximum symbol length is unspecified.
The compiler and link editor shall support a minimum of 511 external symbols per source or object file, and a minimum of 4095 external symbols total. A diagnostic message is written to standard output if the implementation-defined limit is exceeded; other actions are unspecified.
The following exit values shall be returned:
When fort77 encounters a compilation error, it shall write a diagnostic to standard error and continue to compile other source code operands. It shall return a non-zero exit status, but it is implementation-defined whether an object module is created. If the link edit is unsuccessful, a diagnostic message shall be written to standard error, and fort77 shall exit with a non-zero status.
The following sections are informative.
The following usage example compiles xyz.f and creates the executable file foo:
fort77 -o foo xyz.f
The following example compiles xyz.f and creates the object file xyz.o:
fort77 -c xyz.f
The following example compiles xyz.f and creates the executable file a.out:
fort77 xyz.f
The following example compiles xyz.f, links it with b.o, and creates the executable a.out:
fort77 xyz.f b.o
The name of this utility was chosen as fort77 to parallel the renaming of the C compiler. The name f77 was not chosen to avoid problems with historical implementations. The ANSI X3.9-1978 standard was selected as a normative reference because the ISO/IEC version of FORTRAN-77 has been superseded by the ISO/IEC 1539:1990 standard (Fortran-90).
The file inclusion and symbol definition #define mechanisms used by the c99 utility were not included in this volume of IEEE Std 1003.1-2001-even though they are commonly implemented-since there is no requirement that the FORTRAN compiler use the C preprocessor.
The -onetrip option was not included in this volume of IEEE Std 1003.1-2001, even though many historical compilers support it, because it is derived from FORTRAN-66; it is an anachronism that should not be perpetuated.
Some implementations produce compilation listings. This aspect of FORTRAN has been left unspecified because there was controversy concerning the various methods proposed for implementing it: a -V option overlapped with historical vendor practice and a naming convention of creating files with .l suffixes collided with historical lex file naming practice.
There is no -I option in this version of this volume of IEEE Std 1003.1-2001 to specify a directory for file inclusion. An INCLUDE directive has been a part of the Fortran-90 discussions, but an interface supporting that standard is not in the current scope.
It is noted that many FORTRAN compilers produce an object module even when compilation errors occur; during a subsequent compilation, the compiler may patch the object module rather than recompiling all the code. Consequently, it is left to the implementor whether or not an object file is created.
A reference to MIL-STD-1753 was removed from an early proposal in response to a request from the POSIX FORTRAN-binding standard developers. It was not the intention of the standard developers to require certification of the FORTRAN compiler, and IEEE Std 1003.9-1992 does not specify the military standard or any special preprocessing requirements. Furthermore, use of that document would have been inappropriate for an international standard.
The specification of optimization has been subject to changes through early proposals. At one time, -O and -N were Booleans: optimize and do not optimize (with an unspecified default). Some historical practice led this to be changed to:
It is not always clear whether "good code generation" is the same thing as optimization. Simple optimizations of local actions do not usually affect the semantics of a program. The -O 0 option has been included to accommodate the very particular nature of scientific calculations in a highly optimized environment; compilers make errors. Some degree of optimization is expected, even if it is not documented here, and the ability to shut it off completely could be important when porting an application. An implementation may treat -O 0 as "do less than normal" if it wishes, but this is only meaningful if any of the operations it performs can affect the semantics of a program. It is highly dependent on the implementation whether doing less than normal is logical. It is not the intent of the -O 0 option to ask for inefficient code generation, but rather to assure that any semantically visible optimization is suppressed.
The specification of standard library access is consistent with the C compiler specification. Implementations are not required to have /usr/lib/libf.a, as many historical implementations do, but if not they are required to recognize f as a token.
External symbol size limits are in normative text; conforming applications need to know these limits. However, the minimum maximum symbol length should be taken as a constraint on a conforming application, not on an implementation, and consequently the action taken for a symbol exceeding the limit is unspecified. The minimum size for the external symbol table was added for similar reasons.
The CONSEQUENCES OF ERRORS section clearly specifies the behavior of the compiler when compilation or link-edit errors occur. The behavior of several historical implementations was examined, and the choice was made to be silent on the status of the executable, or a.out, file in the face of compiler or linker errors. If a linker writes the executable file, then links it on disk with lseek()s and write()s, the partially linked executable file can be left on disk and its execute bits turned off if the link edit fails. However, if the linker links the image in memory before writing the file to disk, it need not touch the executable file (if it already exists) because the link edit fails. Since both approaches are historical practice, a conforming application shall rely on the exit status of fort77, rather than on the existence or mode of the executable file.
The -g and -s options are not specified as mutually-exclusive. Historically these two options have been mutually-exclusive, but because both are so loosely specified, it seemed appropriate to leave their interaction unspecified.
The requirement that conforming applications specify compiler options separately is to reserve the multi-character option name space for vendor-specific compiler options, which are known to exist in many historical implementations. Implementations are not required to recognize, for example, -gc as if it were -g -c; nor are they forbidden from doing so. The SYNOPSIS shows all of the options separately to highlight this requirement on applications.
Echoing filenames to standard error is considered a diagnostic message because it would otherwise be difficult to associate an error message with the erring file. They are described with "may" to allow implementations to use other methods of identifying files and to parallel the description in c99.
A compilation system based on the ISO/IEC 1539:1990 standard (Fortran-90) may be considered for a future version; it may have a different utility name from fort77.
ar , asa , c99 , umask() , the System Interfaces volume of IEEE Std 1003.1-2001, exec