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\input texinfo @c -*-texinfo-*-
@c %**start of header
@set copyrights-gfortran 2007-2020
@include gcc-common.texi
@synindex tp cp
@settitle GNU Fortran Compiler Internals
@c %**end of header
@c Use with @@smallbook.
@c %** start of document
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@c (To provide the reverse effect, set bindingoffset to -0.75in.)
@c @tex
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Copyright @copyright{} @value{copyrights-gfortran} Free Software Foundation, Inc.
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3 or
any later version published by the Free Software Foundation; with the
Invariant Sections being ``Funding Free Software'', the Front-Cover
Texts being (a) (see below), and with the Back-Cover Texts being (b)
(see below). A copy of the license is included in the section entitled
``GNU Free Documentation License''.
(a) The FSF's Front-Cover Text is:
A GNU Manual
(b) The FSF's Back-Cover Text is:
You have freedom to copy and modify this GNU Manual, like GNU
software. Copies published by the Free Software Foundation raise
funds for GNU development.
@end copying
@dircategory Software development
* gfortran: (gfortran). The GNU Fortran Compiler.
@end direntry
This file documents the internals of the GNU Fortran
compiler, (@command{gfortran}).
Published by the Free Software Foundation
51 Franklin Street, Fifth Floor
Boston, MA 02110-1301 USA
@end ifinfo
@setchapternewpage odd
@title GNU Fortran Internals
@author The @t{gfortran} team
@vskip 0pt plus 1filll
Published by the Free Software Foundation@*
51 Franklin Street, Fifth Floor@*
Boston, MA 02110-1301, USA@*
@c Last printed ??ber, 19??.@*
@c Printed copies are available for $? each.@*
@c ISBN ???
@sp 1
@end titlepage
@c ---------------------------------------------------------------------
@c TexInfo table of contents.
@c ---------------------------------------------------------------------
@node Top
@top Introduction
@cindex Introduction
This manual documents the internals of @command{gfortran},
the GNU Fortran compiler.
@emph{Warning:} This document, and the compiler it describes, are still
under development. While efforts are made to keep it up-to-date, it might
not accurately reflect the status of the most recent GNU Fortran compiler.
@end ifset
@comment When you add a new menu item, please keep the right hand
@comment aligned to the same column. Do not use tabs. This provides
@comment better formatting.
* Introduction:: About this manual.
* User Interface:: Code that Interacts with the User.
* Frontend Data Structures::
Data structures used by the frontend
* Object Orientation:: Internals of Fortran 2003 OOP features.
* Translating to GENERIC::
Generating the intermediate language for later stages.
* LibGFortran:: The LibGFortran Runtime Library.
* GNU Free Documentation License::
How you can copy and share this manual.
* Index:: Index of this documentation.
@end menu
@end ifnottex
@c ---------------------------------------------------------------------
@c Introduction
@c ---------------------------------------------------------------------
@node Introduction
@chapter Introduction
@c The following duplicates the text on the TexInfo table of contents.
This manual documents the internals of @command{gfortran}, the GNU Fortran
@emph{Warning:} This document, and the compiler it describes, are still
under development. While efforts are made to keep it up-to-date, it
might not accurately reflect the status of the most recent GNU Fortran
@end ifset
@end iftex
At present, this manual is very much a work in progress, containing
miscellaneous notes about the internals of the compiler. It is hoped
that at some point in the future it will become a reasonably complete
guide; in the interim, GNU Fortran developers are strongly encouraged to
contribute to it as a way of keeping notes while working on the
@c ---------------------------------------------------------------------
@c Code that Interacts with the User
@c ---------------------------------------------------------------------
@node User Interface
@chapter Code that Interacts with the User
* Command-Line Options:: Command-Line Options.
* Error Handling:: Error Handling.
@end menu
@c ---------------------------------------------------------------------
@c Command-Line Options
@c ---------------------------------------------------------------------
@node Command-Line Options
@section Command-Line Options
Command-line options for @command{gfortran} involve four interrelated
pieces within the Fortran compiler code.
The relevant command-line flag is defined in @file{lang.opt}, according
to the documentation in @ref{Options,, Options, gccint, GNU Compiler
Collection Internals}. This is then processed by the overall GCC
machinery to create the code that enables @command{gfortran} and
@command{gcc} to recognize the option in the command-line arguments and
call the relevant handler function.
This generated code calls the @code{gfc_handle_option} code in
@file{options.c} with an enumerator variable indicating which option is
to be processed, and the relevant integer or string values associated
with that option flag. Typically, @code{gfc_handle_option} uses these
arguments to set global flags which record the option states.
The global flags that record the option states are stored in the
@code{gfc_option_t} struct, which is defined in @file{gfortran.h}.
Before the options are processed, initial values for these flags are set
in @code{gfc_init_option} in @file{options.c}; these become the default
values for the options.
@c ---------------------------------------------------------------------
@c Error Handling
@c ---------------------------------------------------------------------
@node Error Handling
@section Error Handling
The GNU Fortran compiler's parser operates by testing each piece of
source code against a variety of matchers. In some cases, if these
matchers do not match the source code, they will store an error message
in a buffer. If the parser later finds a matcher that does correctly
match the source code, then the buffered error is discarded. However,
if the parser cannot find a match, then the buffered error message is
reported to the user. This enables the compiler to provide more
meaningful error messages even in the many cases where (erroneous)
Fortran syntax is ambiguous due to things like the absence of reserved
As an example of how this works, consider the following line:
IF = 3
@end smallexample
Hypothetically, this may get passed to the matcher for an @code{IF}
statement. Since this could plausibly be an erroneous @code{IF}
statement, the matcher will buffer an error message reporting the
absence of an expected @samp{(} following an @code{IF}. Since no
matchers reported an error-free match, however, the parser will also try
matching this against a variable assignment. When @code{IF} is a valid
variable, this will be parsed as an assignment statement, and the error
discarded. However, when @code{IF} is not a valid variable, this
buffered error message will be reported to the user.
The error handling code is implemented in @file{error.c}. Errors are
normally entered into the buffer with the @code{gfc_error} function.
Warnings go through a similar buffering process, and are entered into
the buffer with @code{gfc_warning}. There is also a special-purpose
function, @code{gfc_notify_std}, for things which have an error/warning
status that depends on the currently-selected language standard.
The @code{gfc_error_check} function checks the buffer for errors,
reports the error message to the user if one exists, clears the buffer,
and returns a flag to the user indicating whether or not an error
existed. To check the state of the buffer without changing its state or
reporting the errors, the @code{gfc_error_flag_test} function can be
used. The @code{gfc_clear_error} function will clear out any errors in
the buffer, without reporting them. The @code{gfc_warning_check} and
@code{gfc_clear_warning} functions provide equivalent functionality for
the warning buffer.
Only one error and one warning can be in the buffers at a time, and
buffering another will overwrite the existing one. In cases where one
may wish to work on a smaller piece of source code without disturbing an
existing error state, the @code{gfc_push_error}, @code{gfc_pop_error},
and @code{gfc_free_error} mechanism exists to implement a stack for the
error buffer.
For cases where an error or warning should be reported immediately
rather than buffered, the @code{gfc_error_now} and
@code{gfc_warning_now} functions can be used. Normally, the compiler
will continue attempting to parse the program after an error has
occurred, but if this is not appropriate, the @code{gfc_fatal_error}
function should be used instead. For errors that are always the result
of a bug somewhere in the compiler, the @code{gfc_internal_error}
function should be used.
The syntax for the strings used to produce the error/warning message in
the various error and warning functions is similar to the @code{printf}
syntax, with @samp{%}-escapes to insert variable values. The details,
and the allowable codes, are documented in the @code{error_print}
function in @file{error.c}.
@c ---------------------------------------------------------------------
@c Frontend Data Structures
@c ---------------------------------------------------------------------
@node Frontend Data Structures
@chapter Frontend Data Structures
@cindex data structures
This chapter should describe the details necessary to understand how
the various @code{gfc_*} data are used and interact. In general it is
advisable to read the code in @file{dump-parse-tree.c} as its routines
should exhaust all possible valid combinations of content for these
* gfc_code:: Representation of Executable Statements.
* gfc_expr:: Representation of Values and Expressions.
@end menu
@c gfc_code
@c --------
@node gfc_code
@section @code{gfc_code}
@cindex statement chaining
@tindex @code{gfc_code}
@tindex @code{struct gfc_code}
The executable statements in a program unit are represented by a
nested chain of @code{gfc_code} structures. The type of statement is
identified by the @code{op} member of the structure, the different
possible values are enumerated in @code{gfc_exec_op}. A special
member of this @code{enum} is @code{EXEC_NOP} which is used to
represent the various @code{END} statements if they carry a label.
Depending on the type of statement some of the other fields will be
filled in. Fields that are generally applicable are the @code{next}
and @code{here} fields. The former points to the next statement in
the current block or is @code{NULL} if the current statement is the
last in a block, @code{here} points to the statement label of the
current statement.
If the current statement is one of @code{IF}, @code{DO}, @code{SELECT}
it starts a block, i.e.@: a nested level in the program. In order to
represent this, the @code{block} member is set to point to a
@code{gfc_code} structure whose @code{next} member starts the chain of
statements inside the block; this structure's @code{op} member should be set to
the same value as the parent structure's @code{op} member. The @code{SELECT}
and @code{IF} statements may contain various blocks (the chain of @code{ELSE IF}
and @code{ELSE} blocks or the various @code{CASE}s, respectively). These chains
are linked-lists formed by the @code{block} members.
Consider the following example code:
IF (foo < 20) THEN
PRINT *, "Too small"
foo = 20
ELSEIF (foo > 50) THEN
PRINT *, "Too large"
foo = 50
PRINT *, "Good"
@end example
This statement-block will be represented in the internal gfortran tree as
follows, were the horizontal link-chains are those induced by the @code{next}
members and vertical links down are those of @code{block}. @samp{==|} and
@samp{--|} mean @code{NULL} pointers to mark the end of a chain:
... ==> IF ==> ...
+--> IF foo < 20 ==> PRINT *, "Too small" ==> foo = 20 ==|
+--> IF foo > 50 ==> PRINT *, "Too large" ==> foo = 50 ==|
+--> ELSE ==> PRINT *, "Good" ==|
@end example
@subsection IF Blocks
Conditionals are represented by @code{gfc_code} structures with their
@code{op} member set to @code{EXEC_IF}. This structure's @code{block}
member must point to another @code{gfc_code} node that is the header of the
if-block. This header's @code{op} member must be set to @code{EXEC_IF}, too,
its @code{expr} member holds the condition to check for, and its @code{next}
should point to the code-chain of the statements to execute if the condition is
If in addition an @code{ELSEIF} or @code{ELSE} block is present, the
@code{block} member of the if-block-header node points to yet another
@code{gfc_code} structure that is the header of the elseif- or else-block. Its
structure is identical to that of the if-block-header, except that in case of an
@code{ELSE} block without a new condition the @code{expr} member should be
@code{NULL}. This block can itself have its @code{block} member point to the
next @code{ELSEIF} or @code{ELSE} block if there's a chain of them.
@subsection Loops
@code{DO} loops are stored in the tree as @code{gfc_code} nodes with their
@code{op} set to @code{EXEC_DO} for a @code{DO} loop with iterator variable and
to @code{EXEC_DO_WHILE} for infinite @code{DO}s and @code{DO WHILE} blocks.
Their @code{block} member should point to a @code{gfc_code} structure heading
the code-chain of the loop body; its @code{op} member should be set to
@code{EXEC_DO} or @code{EXEC_DO_WHILE}, too, respectively.
For @code{DO WHILE} loops, the loop condition is stored on the top
@code{gfc_code} structure's @code{expr} member; @code{DO} forever loops are
simply @code{DO WHILE} loops with a constant @code{.TRUE.} loop condition in
the internal representation.
Similarly, @code{DO} loops with an iterator have instead of the condition their
@code{ext.iterator} member set to the correct values for the loop iterator
variable and its range.
@subsection @code{SELECT} Statements
A @code{SELECT} block is introduced by a @code{gfc_code} structure with an
@code{op} member of @code{EXEC_SELECT} and @code{expr} containing the expression
to evaluate and test. Its @code{block} member starts a list of @code{gfc_code}
structures linked together by their @code{block} members that stores the various
@code{CASE} parts.
Each @code{CASE} node has its @code{op} member set to @code{EXEC_SELECT}, too,
its @code{next} member points to the code-chain to be executed in the current
case-block, and @code{extx.case_list} contains the case-values this block
corresponds to. The @code{block} member links to the next case in the list.
@subsection @code{BLOCK} and @code{ASSOCIATE}
The code related to a @code{BLOCK} statement is stored inside an
@code{gfc_code} structure (say @var{c})
with @code{c.op} set to @code{EXEC_BLOCK}. The
@code{gfc_namespace} holding the locally defined variables of the
@code{BLOCK} is stored in @code{c.ext.block.ns}. The code inside the
construct is in @code{c.code}.
@code{ASSOCIATE} constructs are based on @code{BLOCK} and thus also have
the internal storage structure described above (including @code{EXEC_BLOCK}).
However, for them @code{c.ext.block.assoc} is set additionally and points
to a linked list of @code{gfc_association_list} structures. Those
structures basically store a link of associate-names to target expressions.
The associate-names themselves are still also added to the @code{BLOCK}'s
namespace as ordinary symbols, but they have their @code{gfc_symbol}'s
member @code{assoc} set also pointing to the association-list structure.
This way associate-names can be distinguished from ordinary variables
and their target expressions identified.
For association to expressions (as opposed to variables), at the very beginning
of the @code{BLOCK} construct assignments are automatically generated to
set the corresponding variables to their target expressions' values, and
later on the compiler simply disallows using such associate-names in contexts
that may change the value.
@c gfc_expr
@c --------
@node gfc_expr
@section @code{gfc_expr}
@tindex @code{gfc_expr}
@tindex @code{struct gfc_expr}
Expressions and ``values'', including constants, variable-, array- and
component-references as well as complex expressions consisting of operators and
function calls are internally represented as one or a whole tree of
@code{gfc_expr} objects. The member @code{expr_type} specifies the overall
type of an expression (for instance, @code{EXPR_CONSTANT} for constants or
@code{EXPR_VARIABLE} for variable references). The members @code{ts} and
@code{rank} as well as @code{shape}, which can be @code{NULL}, specify
the type, rank and, if applicable, shape of the whole expression or expression
tree of which the current structure is the root. @code{where} is the locus of
this expression in the source code.
Depending on the flavor of the expression being described by the object
(that is, the value of its @code{expr_type} member), the corresponding structure
in the @code{value} union will usually contain additional data describing the
expression's value in a type-specific manner. The @code{ref} member is used to
build chains of (array-, component- and substring-) references if the expression
in question contains such references, see below for details.
@subsection Constants
Scalar constants are represented by @code{gfc_expr} nodes with their
@code{expr_type} set to @code{EXPR_CONSTANT}. The constant's value shall
already be known at compile-time and is stored in the @code{logical},
@code{integer}, @code{real}, @code{complex} or @code{character} struct inside
@code{value}, depending on the constant's type specification.
@subsection Operators
Operator-expressions are expressions that are the result of the execution of
some operator on one or two operands. The expressions have an @code{expr_type}
of @code{EXPR_OP}. Their @code{value.op} structure contains additional data.
@code{op1} and optionally @code{op2} if the operator is binary point to the
two operands, and @code{operator} or @code{uop} describe the operator that
should be evaluated on these operands, where @code{uop} describes a user-defined
@subsection Function Calls
If the expression is the return value of a function-call, its @code{expr_type}
is set to @code{EXPR_FUNCTION}, and @code{symtree} must point to the symtree
identifying the function to be called. @code{value.function.actual} holds the
actual arguments given to the function as a linked list of
@code{gfc_actual_arglist} nodes.
The other members of @code{value.function} describe the function being called
in more detail, containing a link to the intrinsic symbol or user-defined
function symbol if the call is to an intrinsic or external function,
respectively. These values are determined during resolution-phase from the
structure's @code{symtree} member.
A special case of function calls are ``component calls'' to type-bound
procedures; those have the @code{expr_type} @code{EXPR_COMPCALL} with
@code{value.compcall} containing the argument list and the procedure called,
while @code{symtree} and @code{ref} describe the object on which the procedure
was called in the same way as a @code{EXPR_VARIABLE} expression would.
@xref{Type-bound Procedures}.
@subsection Array- and Structure-Constructors
Array- and structure-constructors (one could probably call them ``array-'' and
``derived-type constants'') are @code{gfc_expr} structures with their
@code{expr_type} member set to @code{EXPR_ARRAY} or @code{EXPR_STRUCTURE},
respectively. For structure constructors, @code{symtree} points to the
derived-type symbol for the type being constructed.
The values for initializing each array element or structure component are
stored as linked-list of @code{gfc_constructor} nodes in the
@code{value.constructor} member.
@subsection Null
@code{NULL} is a special value for pointers; it can be of different base types.
Such a @code{NULL} value is represented in the internal tree by a
@code{gfc_expr} node with @code{expr_type} @code{EXPR_NULL}. If the base type
of the @code{NULL} expression is known, it is stored in @code{ts} (that's for
instance the case for default-initializers of @code{ALLOCATABLE} components),
but this member can also be set to @code{BT_UNKNOWN} if the information is not
available (for instance, when the expression is a pointer-initializer
@subsection Variables and Reference Expressions
Variable references are @code{gfc_expr} structures with their @code{expr_type}
set to @code{EXPR_VARIABLE}; their @code{symtree} should point to the variable
that is referenced.
For this type of expression, it's also possible to chain array-, component-
or substring-references to the original expression to get something like
@samp{struct%component(2:5)}, where @code{component} is either an array or
a @code{CHARACTER} member of @code{struct} that is of some derived-type. Such a
chain of references is achieved by a linked list headed by @code{ref} of the
@code{gfc_expr} node. For the example above it would be (@samp{==|} is the
last @code{NULL} pointer):
EXPR_VARIABLE(struct) ==> REF_COMPONENT(component) ==> REF_ARRAY(2:5) ==|
@end smallexample
If @code{component} is a string rather than an array, the last element would be
a @code{REF_SUBSTRING} reference, of course. If the variable itself or some
component referenced is an array and the expression should reference the whole
array rather than being followed by an array-element or -section reference, a
@code{REF_ARRAY} reference must be built as the last element in the chain with
an array-reference type of @code{AR_FULL}. Consider this example code:
TYPE :: mytype
INTEGER :: array(42)
END TYPE mytype
TYPE(mytype) :: variable
INTEGER :: local_array(5)
CALL do_something (variable%array, local_array)
@end smallexample
The @code{gfc_expr} nodes representing the arguments to the @samp{do_something}
call will have a reference-chain like this:
EXPR_VARIABLE(variable) ==> REF_COMPONENT(array) ==> REF_ARRAY(FULL) ==|
EXPR_VARIABLE(local_array) ==> REF_ARRAY(FULL) ==|
@end smallexample
@subsection Constant Substring References
@code{EXPR_SUBSTRING} is a special type of expression that encodes a substring
reference of a constant string, as in the following code snippet:
x = "abcde"(1:2)
@end smallexample
In this case, @code{value.character} contains the full string's data as if it
was a string constant, but the @code{ref} member is also set and points to a
substring reference as described in the subsection above.
@c ---------------------------------------------------------------------
@c F2003 OOP
@c ---------------------------------------------------------------------
@node Object Orientation
@chapter Internals of Fortran 2003 OOP Features
* Type-bound Procedures:: Type-bound procedures.
* Type-bound Operators:: Type-bound operators.
@end menu
@c Type-bound procedures
@c ---------------------
@node Type-bound Procedures
@section Type-bound Procedures
Type-bound procedures are stored in the @code{tb_sym_root} of the namespace
@code{f2k_derived} associated with the derived-type symbol as @code{gfc_symtree}
nodes. The name and symbol of these symtrees corresponds to the binding-name
of the procedure, i.e. the name that is used to call it from the context of an
object of the derived-type.
In addition, this type of symtrees stores in @code{n.tb} a struct of type
@code{gfc_typebound_proc} containing the additional data needed: The
binding attributes (like @code{PASS} and @code{NOPASS}, @code{NON_OVERRIDABLE}
or the access-specifier), the binding's target(s) and, if the current binding
overrides or extends an inherited binding of the same name, @code{overridden}
points to this binding's @code{gfc_typebound_proc} structure.
@subsection Specific Bindings
@c --------------------------
For specific bindings (declared with @code{PROCEDURE}), if they have a
passed-object argument, the passed-object dummy argument is first saved by its
name, and later during resolution phase the corresponding argument is looked for
and its position remembered as @code{pass_arg_num} in @code{gfc_typebound_proc}.
The binding's target procedure is pointed-to by @code{u.specific}.
@code{DEFERRED} bindings are just like ordinary specific bindings, except
that their @code{deferred} flag is set of course and that @code{u.specific}
points to their ``interface'' defining symbol (might be an abstract interface)
instead of the target procedure.
At the moment, all type-bound procedure calls are statically dispatched and
transformed into ordinary procedure calls at resolution time; their actual
argument list is updated to include at the right position the passed-object
argument, if applicable, and then a simple procedure call to the binding's
target procedure is built. To handle dynamic dispatch in the future, this will
be extended to allow special code generation during the trans-phase to dispatch
based on the object's dynamic type.
@subsection Generic Bindings
@c -------------------------
Bindings declared as @code{GENERIC} store the specific bindings they target as
a linked list using nodes of type @code{gfc_tbp_generic} in @code{u.generic}.
For each specific target, the parser records its symtree and during resolution
this symtree is bound to the corresponding @code{gfc_typebound_proc} structure
of the specific target.
Calls to generic bindings are handled entirely in the resolution-phase, where
for the actual argument list present the matching specific binding is found
and the call's target procedure (@code{value.compcall.tbp}) is re-pointed to
the found specific binding and this call is subsequently handled by the logic
for specific binding calls.
@subsection Calls to Type-bound Procedures
@c ---------------------------------------
Calls to type-bound procedures are stored in the parse-tree as @code{gfc_expr}
nodes of type @code{EXPR_COMPCALL}. Their @code{value.compcall.actual} saves
the actual argument list of the call and @code{value.compcall.tbp} points to the
@code{gfc_typebound_proc} structure of the binding to be called. The object
in whose context the procedure was called is saved by combination of
@code{symtree} and @code{ref}, as if the expression was of type
For code like this:
CALL myobj%procedure (arg1, arg2)
@end smallexample
the @code{CALL} is represented in the parse-tree as a @code{gfc_code} node of
type @code{EXEC_COMPCALL}. The @code{expr} member of this node holds an
expression of type @code{EXPR_COMPCALL} of the same structure as mentioned above
except that its target procedure is of course a @code{SUBROUTINE} and not a
Expressions that are generated internally (as expansion of a type-bound
operator call) may also use additional flags and members.
@code{value.compcall.ignore_pass} signals that even though a @code{PASS}
attribute may be present the actual argument list should not be updated because
it already contains the passed-object.
@code{value.compcall.base_object} overrides, if it is set, the base-object
(that is normally stored in @code{symtree} and @code{ref} as mentioned above);
this is needed because type-bound operators can be called on a base-object that
need not be of type @code{EXPR_VARIABLE} and thus representable in this way.
Finally, if @code{value.compcall.assign} is set, the call was produced in
expansion of a type-bound assignment; this means that proper dependency-checking
needs to be done when relevant.
@c Type-bound operators
@c --------------------
@node Type-bound Operators
@section Type-bound Operators
Type-bound operators are in fact basically just @code{GENERIC} procedure
bindings and are represented much in the same way as those (see
@ref{Type-bound Procedures}).
They come in two flavours:
User-defined operators (like @code{.MYOPERATOR.})
are stored in the @code{f2k_derived} namespace's @code{tb_uop_root}
symtree exactly like ordinary type-bound procedures are stored in
@code{tb_sym_root}; their symtrees' names are the operator-names (e.g.
@samp{myoperator} in the example).
Intrinsic operators on the other hand are stored in the namespace's
array member @code{tb_op} indexed by the intrinsic operator's enum
value. Those need not be packed into @code{gfc_symtree} structures and are
only @code{gfc_typebound_proc} instances.
When an operator call or assignment is found that cannot be handled in
another way (i.e. neither matches an intrinsic nor interface operator
definition) but that contains a derived-type expression, all type-bound
operators defined on that derived-type are checked for a match with
the operator call. If there's indeed a relevant definition, the
operator call is replaced with an internally generated @code{GENERIC}
type-bound procedure call to the respective definition and that call is
further processed.
@c ---------------------------------------------------------------------
@c - Translating to GENERIC
@c ---------------------------------------------------------------------
@node Translating to GENERIC
@chapter Generating the intermediate language for later stages.
This chapter deals with the transformation of gfortran's frontend data
structures to the intermediate language used by the later stages of
the compiler, the so-called middle end.
Data structures relating to this are found in the source files
@file{trans*.h} and @file{trans-*.c}.
* Basic Data Structures:: Basic data structures.
* Converting Expressions:: Converting expressions to tree.
* Translating Statements:: Translating statements.
* Accessing Declarations:: Accessing declarations.
@end menu
@node Basic Data Structures
@section Basic data structures
Gfortran creates GENERIC as an intermediate language for the
middle-end. Details about GENERIC can be found in the GCC manual.
The basic data structure of GENERIC is a @code{tree}. Everything in
GENERIC is a @code{tree}, including types and statements. Fortunately
for the gfortran programmer, @code{tree} variables are
garbage-collected, so doing memory management for them is not
@code{tree} expressions are built using functions such as, for
example, @code{fold_build2_loc}. For two tree variables @code{a} and
@code{b}, both of which have the type @code{gfc_arry_index_type},
calculation @code{c = a * b} would be done by
c = fold_build2_loc (input_location, MULT_EXPR,
gfc_array_index_type, a, b);
@end smallexample
The types have to agree, otherwise internal compiler errors will occur
at a later stage. Expressions can be converted to a different type
using @code{fold_convert}.
Accessing individual members in the @code{tree} structures should not
be done. Rather, access should be done via macros.
One basic data structure is the @code{stmtblock_t} struct. This is
used for holding a list of statements, expressed as @code{tree}
expressions. If a block is created using @code{gfc_start_block}, it
has its own scope for variables; if it is created using
@code{gfc_init_block}, it does not have its own scope.
It is possible to
@itemize @bullet
@item Add an expression to the end of a block using
@item Add an expression to the beginning of a block using
@code{void gfc_prepend_expr_to_block}
@item Make a block into a single @code{tree} using
@code{gfc_finish_block}. For example, this is needed to put the
contents of a block into the @code{if} or @code{else} branch of
a @code{COND_EXPR}.
@end itemize
Variables are also @code{tree} expressions, they can be created using
@code{gfc_create_var}. Assigning to a variable can be done with
An example: Creating a default integer type variable in the current
scope with the prefix ``everything'' in the @code{stmt_block}
@code{block} and assigning the value 42 would be
tree var, *block;
/* Initialize block somewhere here. */
var = gfc_create_var (integer_type_node, "everything");
gfc_add_modify (block, var, build_int_cst (integer_type_node, 42));
@end smallexample
@node Converting Expressions
@section Converting Expressons to tree
Converting expressions to @code{tree} is done by functions called
The central data structure for a GENERIC expression is the
@code{gfc_se} structure. Its @code{expr} member is a @code{tree} that
holds the value of the expression. A @code{gfc_se} structure is
initialized using @code{gfc_init_se}; it needs to be embedded in an
outer @code{gfc_se}.
Evaluating Fortran expressions often require things to be done before
and after evaluation of the expression, for example code for the
allocation of a temporary variable and its subsequent deallocation.
Therefore, @code{gfc_se} contains the members @code{pre} and
@code{post}, which point to @code{stmt_block} blocks for code that
needs to be executed before and after evaluation of the expression.
When using a local @code{gfc_se} to convert some expression, it is
often necessary to add the generated @code{pre} and @code{post} blocks
to the @code{pre} or @code{post} blocks of the outer @code{gfc_se}.
Code like this (lifted from @file{trans-expr.c}) is fairly common:
gfc_se cont_se;
tree cont_var;
/* cont_var = is_contiguous (expr); . */
gfc_init_se (&cont_se, parmse);
gfc_conv_is_contiguous_expr (&cont_se, expr);
gfc_add_block_to_block (&se->pre, &(&cont_se)->pre);
gfc_add_modify (&se->pre, cont_var, cont_se.expr);
gfc_add_block_to_block (&se->pre, &(&cont_se)->post);
@end smallexample
Conversion functions which need a @code{gfc_se} structure will have a
corresponding argument.
@code{gfc_se} also contains pointers to a @code{gfc_ss} and a
@code{gfc_loopinfo} structure. These are needed by the scalarizer.
@node Translating Statements
@section Translating statements
Translating statements to @code{tree} is done by functions called
@code{gfc_trans_*}. These functions usually get passed a
@code{gfc_code} structure, evaluate any expressions and then
return a @code{tree} structure.
@node Accessing Declarations
@section Accessing declarations
@code{gfc_symbol}, @code{gfc_charlen} and other front-end structures
contain a @code{backend_decl} variable, which contains the @code{tree}
used for accessing that entity in the middle-end.
Accessing declarations is usually done by functions called
@c ---------------------------------------------------------------------
@c LibGFortran
@c ---------------------------------------------------------------------
@node LibGFortran
@chapter The LibGFortran Runtime Library
* Symbol Versioning:: Symbol Versioning.
@end menu
@c ---------------------------------------------------------------------
@c Symbol Versioning
@c ---------------------------------------------------------------------
@node Symbol Versioning
@section Symbol Versioning
@comment Based on,
@comment as of 2006-11-05, written by Janne Blomqvist.
In general, this capability exists only on a few platforms, thus there
is a need for configure magic so that it is used only on those targets
where it is supported.
The central concept in symbol versioning is the so-called map file,
which specifies the version node(s) exported symbols are labeled with.
Also, the map file is used to hide local symbols.
Some relevant references:
@itemize @bullet
GNU @command{ld} manual}
@uref{, ELF Symbol
Versioning - Ulrich Depper}
@uref{, How to Write Shared
Libraries - Ulrich Drepper (see Chapter 3)}
@end itemize
If one adds a new symbol to a library that should be exported, the new
symbol should be mentioned in the map file and a new version node
defined, e.g., if one adds a new symbols @code{foo} and @code{bar} to
libgfortran for the next GCC release, the following should be added to
the map file:
@} GFORTRAN_1.0;
@end smallexample
where @code{GFORTRAN_1.0} is the version node of the current release,
and @code{GFORTRAN_1.1} is the version node of the next release where
foo and bar are made available.
If one wants to change an existing interface, it is possible by using
some asm trickery (from the @command{ld} manual referenced above):
__asm__(".symver original_foo,foo@@");
__asm__(".symver old_foo,foo@@VERS_1.1");
__asm__(".symver old_foo1,foo@@VERS_1.2");
__asm__(".symver new_foo,foo@@VERS_2.0");
@end smallexample
In this example, @code{foo@@} represents the symbol @code{foo} bound to
the unspecified base version of the symbol. The source file that
contains this example would define 4 C functions: @code{original_foo},
@code{old_foo}, @code{old_foo1}, and @code{new_foo}.
In this case the map file must contain @code{foo} in @code{VERS_1.1}
and @code{VERS_1.2} as well as in @code{VERS_2.0}.
@c ---------------------------------------------------------------------
@c GNU Free Documentation License
@c ---------------------------------------------------------------------
@include fdl.texi
@c ---------------------------------------------------------------------
@c Index
@c ---------------------------------------------------------------------
@node Index
@unnumbered Index
@printindex cp