Next: Inheritance and GTY, Up: Type Information [Contents][Index]
GTY(())
Sometimes the C code is not enough to fully describe the type
structure. Extra information can be provided with GTY
options
and additional markers. Some options take a parameter, which may be
either a string or a type name, depending on the parameter. If an
option takes no parameter, it is acceptable either to omit the
parameter entirely, or to provide an empty string as a parameter. For
example, GTY ((skip))
and GTY ((skip ("")))
are
equivalent.
When the parameter is a string, often it is a fragment of C code. Four special escapes may be used in these strings, to refer to pieces of the data structure being marked:
%h
The current structure.
%1
The structure that immediately contains the current structure.
%0
The outermost structure that contains the current structure.
%a
A partial expression of the form [i1][i2]…
that indexes
the array item currently being marked.
For instance, suppose that you have a structure of the form
struct A { … }; struct B { struct A foo[12]; };
and b
is a variable of type struct B
. When marking
‘b.foo[11]’, %h
would expand to ‘b.foo[11]’,
%0
and %1
would both expand to ‘b’, and %a
would expand to ‘[11]’.
As in ordinary C, adjacent strings will be concatenated; this is helpful when you have a complicated expression.
GTY ((chain_next ("TREE_CODE (&%h.generic) == INTEGER_TYPE" " ? TYPE_NEXT_VARIANT (&%h.generic)" " : TREE_CHAIN (&%h.generic)")))
The available options are:
length ("expression")
There are two places the type machinery will need to be explicitly told the length of an array of non-atomic objects. The first case is when a structure ends in a variable-length array, like this:
struct GTY(()) rtvec_def {
int num_elem; /* number of elements */
rtx GTY ((length ("%h.num_elem"))) elem[1];
};
In this case, the length
option is used to override the specified
array length (which should usually be 1
). The parameter of the
option is a fragment of C code that calculates the length.
The second case is when a structure or a global variable contains a pointer to an array, like this:
struct gimple_omp_for_iter * GTY((length ("%h.collapse"))) iter;
In this case, iter
has been allocated by writing something like
x->iter = ggc_alloc_cleared_vec_gimple_omp_for_iter (collapse);
and the collapse
provides the length of the field.
This second use of length
also works on global variables, like:
static GTY((length("reg_known_value_size"))) rtx *reg_known_value;
Note that the length
option is only meant for use with arrays of
non-atomic objects, that is, objects that contain pointers pointing to
other GTY-managed objects. For other GC-allocated arrays and strings
you should use atomic
.
skip
If skip
is applied to a field, the type machinery will ignore it.
This is somewhat dangerous; the only safe use is in a union when one
field really isn’t ever used.
Use this to mark types that need to be marked by user gc routines, but are not refered to in a template argument. So if you have some user gc type T1 and a non user gc type T2 you can give T2 the for_user option so that the marking functions for T1 can call non mangled functions to mark T2.
desc ("expression")
tag ("constant")
default
The type machinery needs to be told which field of a union
is
currently active. This is done by giving each field a constant
tag
value, and then specifying a discriminator using desc
.
The value of the expression given by desc
is compared against
each tag
value, each of which should be different. If no
tag
is matched, the field marked with default
is used if
there is one, otherwise no field in the union will be marked.
In the desc
option, the “current structure” is the union that
it discriminates. Use %1
to mean the structure containing it.
There are no escapes available to the tag
option, since it is a
constant.
For example,
struct GTY(()) tree_binding { struct tree_common common; union tree_binding_u { tree GTY ((tag ("0"))) scope; struct cp_binding_level * GTY ((tag ("1"))) level; } GTY ((desc ("BINDING_HAS_LEVEL_P ((tree)&%0)"))) xscope; tree value; };
In this example, the value of BINDING_HAS_LEVEL_P when applied to a
struct tree_binding *
is presumed to be 0 or 1. If 1, the type
mechanism will treat the field level
as being present and if 0,
will treat the field scope
as being present.
The desc
and tag
options can also be used for inheritance
to denote which subclass an instance is. See Inheritance and GTY
for more information.
cache
When the cache
option is applied to a global variable gt_clear_cache is
called on that variable between the mark and sweep phases of garbage
collection. The gt_clear_cache function is free to mark blocks as used, or to
clear pointers in the variable.
deletable
deletable
, when applied to a global variable, indicates that when
garbage collection runs, there’s no need to mark anything pointed to
by this variable, it can just be set to NULL
instead. This is used
to keep a list of free structures around for re-use.
maybe_undef
When applied to a field, maybe_undef
indicates that it’s OK if
the structure that this fields points to is never defined, so long as
this field is always NULL
. This is used to avoid requiring
backends to define certain optional structures. It doesn’t work with
language frontends.
nested_ptr (type, "to expression", "from expression")
The type machinery expects all pointers to point to the start of an
object. Sometimes for abstraction purposes it’s convenient to have
a pointer which points inside an object. So long as it’s possible to
convert the original object to and from the pointer, such pointers
can still be used. type is the type of the original object,
the to expression returns the pointer given the original object,
and the from expression returns the original object given
the pointer. The pointer will be available using the %h
escape.
chain_next ("expression")
chain_prev ("expression")
chain_circular ("expression")
It’s helpful for the type machinery to know if objects are often
chained together in long lists; this lets it generate code that uses
less stack space by iterating along the list instead of recursing down
it. chain_next
is an expression for the next item in the list,
chain_prev
is an expression for the previous item. For singly
linked lists, use only chain_next
; for doubly linked lists, use
both. The machinery requires that taking the next item of the
previous item gives the original item. chain_circular
is similar
to chain_next
, but can be used for circular single linked lists.
reorder ("function name")
Some data structures depend on the relative ordering of pointers. If
the precompiled header machinery needs to change that ordering, it
will call the function referenced by the reorder
option, before
changing the pointers in the object that’s pointed to by the field the
option applies to. The function must take four arguments, with the
signature ‘void *, void *, gt_pointer_operator, void *’.
The first parameter is a pointer to the structure that contains the
object being updated, or the object itself if there is no containing
structure. The second parameter is a cookie that should be ignored.
The third parameter is a routine that, given a pointer, will update it
to its correct new value. The fourth parameter is a cookie that must
be passed to the second parameter.
PCH cannot handle data structures that depend on the absolute values
of pointers. reorder
functions can be expensive. When
possible, it is better to depend on properties of the data, like an ID
number or the hash of a string instead.
atomic
The atomic
option can only be used with pointers. It informs
the GC machinery that the memory that the pointer points to does not
contain any pointers, and hence it should be treated by the GC and PCH
machinery as an “atomic” block of memory that does not need to be
examined when scanning memory for pointers. In particular, the
machinery will not scan that memory for pointers to mark them as
reachable (when marking pointers for GC) or to relocate them (when
writing a PCH file).
The atomic
option differs from the skip
option.
atomic
keeps the memory under Garbage Collection, but makes the
GC ignore the contents of the memory. skip
is more drastic in
that it causes the pointer and the memory to be completely ignored by
the Garbage Collector. So, memory marked as atomic
is
automatically freed when no longer reachable, while memory marked as
skip
is not.
The atomic
option must be used with great care, because all
sorts of problem can occur if used incorrectly, that is, if the memory
the pointer points to does actually contain a pointer.
Here is an example of how to use it:
struct GTY(()) my_struct { int number_of_elements; unsigned int * GTY ((atomic)) elements; };
In this case, elements
is a pointer under GC, and the memory it
points to needs to be allocated using the Garbage Collector, and will
be freed automatically by the Garbage Collector when it is no longer
referenced. But the memory that the pointer points to is an array of
unsigned int
elements, and the GC must not try to scan it to
find pointers to mark or relocate, which is why it is marked with the
atomic
option.
Note that, currently, global variables can not be marked with
atomic
; only fields of a struct can. This is a known
limitation. It would be useful to be able to mark global pointers
with atomic
to make the PCH machinery aware of them so that
they are saved and restored correctly to PCH files.
special ("name")
The special
option is used to mark types that have to be dealt
with by special case machinery. The parameter is the name of the
special case. See gengtype.c for further details. Avoid
adding new special cases unless there is no other alternative.
user
The user
option indicates that the code to mark structure
fields is completely handled by user-provided routines. See section
User GC for details on what functions need to be provided.
Next: Inheritance and GTY, Up: Type Information [Contents][Index]