/* Handle parameterized types (templates) for GNU C++.
Copyright (C) 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
2001, 2002, 2003 Free Software Foundation, Inc.
Written by Ken Raeburn (raeburn@cygnus.com) while at Watchmaker Computing.
Rewritten by Jason Merrill (jason@cygnus.com).
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2, or (at your option)
any later version.
GCC is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING. If not, write to
the Free Software Foundation, 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
/* Known bugs or deficiencies include:
all methods must be provided in header files; can't use a source
file that contains only the method templates and "just win". */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tm.h"
#include "obstack.h"
#include "tree.h"
#include "flags.h"
#include "cp-tree.h"
#include "tree-inline.h"
#include "decl.h"
#include "lex.h"
#include "output.h"
#include "except.h"
#include "toplev.h"
#include "rtl.h"
#include "timevar.h"
/* The type of functions taking a tree, and some additional data, and
returning an int. */
typedef int (*tree_fn_t) (tree, void*);
/* The PENDING_TEMPLATES is a TREE_LIST of templates whose
instantiations have been deferred, either because their definitions
were not yet available, or because we were putting off doing the work.
The TREE_PURPOSE of each entry is either a DECL (for a function or
static data member), or a TYPE (for a class) indicating what we are
hoping to instantiate. The TREE_VALUE is not used. */
static GTY(()) tree pending_templates;
static GTY(()) tree last_pending_template;
int processing_template_parmlist;
static int template_header_count;
static GTY(()) tree saved_trees;
static GTY(()) varray_type inline_parm_levels;
static size_t inline_parm_levels_used;
static GTY(()) tree current_tinst_level;
static GTY(()) tree saved_access_scope;
/* A map from local variable declarations in the body of the template
presently being instantiated to the corresponding instantiated
local variables. */
static htab_t local_specializations;
#define UNIFY_ALLOW_NONE 0
#define UNIFY_ALLOW_MORE_CV_QUAL 1
#define UNIFY_ALLOW_LESS_CV_QUAL 2
#define UNIFY_ALLOW_DERIVED 4
#define UNIFY_ALLOW_INTEGER 8
#define UNIFY_ALLOW_OUTER_LEVEL 16
#define UNIFY_ALLOW_OUTER_MORE_CV_QUAL 32
#define UNIFY_ALLOW_OUTER_LESS_CV_QUAL 64
#define UNIFY_ALLOW_MAX_CORRECTION 128
#define GTB_VIA_VIRTUAL 1 /* The base class we are examining is
virtual, or a base class of a virtual
base. */
#define GTB_IGNORE_TYPE 2 /* We don't need to try to unify the current
type with the desired type. */
static void push_access_scope (tree);
static void pop_access_scope (tree);
static int resolve_overloaded_unification (tree, tree, tree, tree,
unification_kind_t, int);
static int try_one_overload (tree, tree, tree, tree, tree,
unification_kind_t, int, bool);
static int unify (tree, tree, tree, tree, int);
static void add_pending_template (tree);
static void reopen_tinst_level (tree);
static tree classtype_mangled_name (tree);
static char* mangle_class_name_for_template (const char *, tree, tree);
static tree tsubst_initializer_list (tree, tree);
static tree get_class_bindings (tree, tree, tree);
static tree coerce_template_parms (tree, tree, tree, tsubst_flags_t, int);
static void tsubst_enum (tree, tree, tree);
static tree add_to_template_args (tree, tree);
static tree add_outermost_template_args (tree, tree);
static bool check_instantiated_args (tree, tree, tsubst_flags_t);
static int maybe_adjust_types_for_deduction (unification_kind_t, tree*, tree*);
static int type_unification_real (tree, tree, tree, tree,
int, unification_kind_t, int, int);
static void note_template_header (int);
static tree convert_nontype_argument (tree, tree);
static tree convert_template_argument (tree, tree, tree,
tsubst_flags_t, int, tree);
static tree get_bindings_overload (tree, tree, tree);
static int for_each_template_parm (tree, tree_fn_t, void*, htab_t);
static tree build_template_parm_index (int, int, int, tree, tree);
static int inline_needs_template_parms (tree);
static void push_inline_template_parms_recursive (tree, int);
static tree retrieve_specialization (tree, tree);
static tree retrieve_local_specialization (tree);
static tree register_specialization (tree, tree, tree);
static void register_local_specialization (tree, tree);
static tree reduce_template_parm_level (tree, tree, int);
static tree build_template_decl (tree, tree);
static int mark_template_parm (tree, void *);
static int template_parm_this_level_p (tree, void *);
static tree tsubst_friend_function (tree, tree);
static tree tsubst_friend_class (tree, tree);
static int can_complete_type_without_circularity (tree);
static tree get_bindings (tree, tree, tree);
static tree get_bindings_real (tree, tree, tree, int, int, int);
static int template_decl_level (tree);
static int check_cv_quals_for_unify (int, tree, tree);
static tree tsubst_template_arg (tree, tree, tsubst_flags_t, tree);
static tree tsubst_template_args (tree, tree, tsubst_flags_t, tree);
static tree tsubst_template_parms (tree, tree, tsubst_flags_t);
static void regenerate_decl_from_template (tree, tree);
static tree most_specialized (tree, tree, tree);
static tree most_specialized_class (tree, tree);
static int template_class_depth_real (tree, int);
static tree tsubst_aggr_type (tree, tree, tsubst_flags_t, tree, int);
static tree tsubst_decl (tree, tree, tree, tsubst_flags_t);
static tree tsubst_arg_types (tree, tree, tsubst_flags_t, tree);
static tree tsubst_function_type (tree, tree, tsubst_flags_t, tree);
static void check_specialization_scope (void);
static tree process_partial_specialization (tree);
static void set_current_access_from_decl (tree);
static void check_default_tmpl_args (tree, tree, int, int);
static tree tsubst_call_declarator_parms (tree, tree, tsubst_flags_t, tree);
static tree get_template_base_recursive (tree, tree, tree, tree, tree, int);
static tree get_template_base (tree, tree, tree, tree);
static int verify_class_unification (tree, tree, tree);
static tree try_class_unification (tree, tree, tree, tree);
static int coerce_template_template_parms (tree, tree, tsubst_flags_t,
tree, tree);
static tree determine_specialization (tree, tree, tree *, int);
static int template_args_equal (tree, tree);
static void tsubst_default_arguments (tree);
static tree for_each_template_parm_r (tree *, int *, void *);
static tree copy_default_args_to_explicit_spec_1 (tree, tree);
static void copy_default_args_to_explicit_spec (tree);
static int invalid_nontype_parm_type_p (tree, tsubst_flags_t);
static int eq_local_specializations (const void *, const void *);
static bool dependent_type_p_r (tree);
static tree tsubst (tree, tree, tsubst_flags_t, tree);
static tree tsubst_expr (tree, tree, tsubst_flags_t, tree);
static tree tsubst_copy (tree, tree, tsubst_flags_t, tree);
/* Make the current scope suitable for access checking when we are
processing T. T can be FUNCTION_DECL for instantiated function
template, or VAR_DECL for static member variable (need by
instantiate_decl). */
static void
push_access_scope (tree t)
{
my_friendly_assert (TREE_CODE (t) == FUNCTION_DECL
|| TREE_CODE (t) == VAR_DECL,
0);
if (DECL_CLASS_SCOPE_P (t))
push_nested_class (DECL_CONTEXT (t));
else
push_to_top_level ();
if (TREE_CODE (t) == FUNCTION_DECL)
{
saved_access_scope = tree_cons
(NULL_TREE, current_function_decl, saved_access_scope);
current_function_decl = t;
}
}
/* Restore the scope set up by push_access_scope. T is the node we
are processing. */
static void
pop_access_scope (tree t)
{
if (TREE_CODE (t) == FUNCTION_DECL)
{
current_function_decl = TREE_VALUE (saved_access_scope);
saved_access_scope = TREE_CHAIN (saved_access_scope);
}
if (DECL_CLASS_SCOPE_P (t))
pop_nested_class ();
else
pop_from_top_level ();
}
/* Do any processing required when DECL (a member template
declaration) is finished. Returns the TEMPLATE_DECL corresponding
to DECL, unless it is a specialization, in which case the DECL
itself is returned. */
tree
finish_member_template_decl (tree decl)
{
if (decl == error_mark_node)
return error_mark_node;
my_friendly_assert (DECL_P (decl), 20020812);
if (TREE_CODE (decl) == TYPE_DECL)
{
tree type;
type = TREE_TYPE (decl);
if (IS_AGGR_TYPE (type)
&& CLASSTYPE_TEMPLATE_INFO (type)
&& !CLASSTYPE_TEMPLATE_SPECIALIZATION (type))
{
tree tmpl = CLASSTYPE_TI_TEMPLATE (type);
check_member_template (tmpl);
return tmpl;
}
return NULL_TREE;
}
else if (TREE_CODE (decl) == FIELD_DECL)
error ("data member `%D' cannot be a member template", decl);
else if (DECL_TEMPLATE_INFO (decl))
{
if (!DECL_TEMPLATE_SPECIALIZATION (decl))
{
check_member_template (DECL_TI_TEMPLATE (decl));
return DECL_TI_TEMPLATE (decl);
}
else
return decl;
}
else
error ("invalid member template declaration `%D'", decl);
return error_mark_node;
}
/* Returns the template nesting level of the indicated class TYPE.
For example, in:
template <class T>
struct A
{
template <class U>
struct B {};
};
A<T>::B<U> has depth two, while A<T> has depth one.
Both A<T>::B<int> and A<int>::B<U> have depth one, if
COUNT_SPECIALIZATIONS is 0 or if they are instantiations, not
specializations.
This function is guaranteed to return 0 if passed NULL_TREE so
that, for example, `template_class_depth (current_class_type)' is
always safe. */
static int
template_class_depth_real (tree type, int count_specializations)
{
int depth;
for (depth = 0;
type && TREE_CODE (type) != NAMESPACE_DECL;
type = (TREE_CODE (type) == FUNCTION_DECL)
? CP_DECL_CONTEXT (type) : TYPE_CONTEXT (type))
{
if (TREE_CODE (type) != FUNCTION_DECL)
{
if (CLASSTYPE_TEMPLATE_INFO (type)
&& PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (type))
&& ((count_specializations
&& CLASSTYPE_TEMPLATE_SPECIALIZATION (type))
|| uses_template_parms (CLASSTYPE_TI_ARGS (type))))
++depth;
}
else
{
if (DECL_TEMPLATE_INFO (type)
&& PRIMARY_TEMPLATE_P (DECL_TI_TEMPLATE (type))
&& ((count_specializations
&& DECL_TEMPLATE_SPECIALIZATION (type))
|| uses_template_parms (DECL_TI_ARGS (type))))
++depth;
}
}
return depth;
}
/* Returns the template nesting level of the indicated class TYPE.
Like template_class_depth_real, but instantiations do not count in
the depth. */
int
template_class_depth (tree type)
{
return template_class_depth_real (type, /*count_specializations=*/0);
}
/* Returns 1 if processing DECL as part of do_pending_inlines
needs us to push template parms. */
static int
inline_needs_template_parms (tree decl)
{
if (! DECL_TEMPLATE_INFO (decl))
return 0;
return (TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (most_general_template (decl)))
> (processing_template_decl + DECL_TEMPLATE_SPECIALIZATION (decl)));
}
/* Subroutine of maybe_begin_member_template_processing.
Push the template parms in PARMS, starting from LEVELS steps into the
chain, and ending at the beginning, since template parms are listed
innermost first. */
static void
push_inline_template_parms_recursive (tree parmlist, int levels)
{
tree parms = TREE_VALUE (parmlist);
int i;
if (levels > 1)
push_inline_template_parms_recursive (TREE_CHAIN (parmlist), levels - 1);
++processing_template_decl;
current_template_parms
= tree_cons (size_int (processing_template_decl),
parms, current_template_parms);
TEMPLATE_PARMS_FOR_INLINE (current_template_parms) = 1;
begin_scope (TREE_VEC_LENGTH (parms) ? sk_template_parms : sk_template_spec,
NULL);
for (i = 0; i < TREE_VEC_LENGTH (parms); ++i)
{
tree parm = TREE_VALUE (TREE_VEC_ELT (parms, i));
my_friendly_assert (DECL_P (parm), 0);
switch (TREE_CODE (parm))
{
case TYPE_DECL:
case TEMPLATE_DECL:
pushdecl (parm);
break;
case PARM_DECL:
{
/* Make a CONST_DECL as is done in process_template_parm.
It is ugly that we recreate this here; the original
version built in process_template_parm is no longer
available. */
tree decl = build_decl (CONST_DECL, DECL_NAME (parm),
TREE_TYPE (parm));
DECL_ARTIFICIAL (decl) = 1;
TREE_CONSTANT (decl) = TREE_READONLY (decl) = 1;
DECL_INITIAL (decl) = DECL_INITIAL (parm);
SET_DECL_TEMPLATE_PARM_P (decl);
pushdecl (decl);
}
break;
default:
abort ();
}
}
}
/* Restore the template parameter context for a member template or
a friend template defined in a class definition. */
void
maybe_begin_member_template_processing (tree decl)
{
tree parms;
int levels = 0;
if (inline_needs_template_parms (decl))
{
parms = DECL_TEMPLATE_PARMS (most_general_template (decl));
levels = TMPL_PARMS_DEPTH (parms) - processing_template_decl;
if (DECL_TEMPLATE_SPECIALIZATION (decl))
{
--levels;
parms = TREE_CHAIN (parms);
}
push_inline_template_parms_recursive (parms, levels);
}
/* Remember how many levels of template parameters we pushed so that
we can pop them later. */
if (!inline_parm_levels)
VARRAY_INT_INIT (inline_parm_levels, 4, "inline_parm_levels");
if (inline_parm_levels_used == inline_parm_levels->num_elements)
VARRAY_GROW (inline_parm_levels, 2 * inline_parm_levels_used);
VARRAY_INT (inline_parm_levels, inline_parm_levels_used) = levels;
++inline_parm_levels_used;
}
/* Undo the effects of begin_member_template_processing. */
void
maybe_end_member_template_processing (void)
{
int i;
if (!inline_parm_levels_used)
return;
--inline_parm_levels_used;
for (i = 0;
i < VARRAY_INT (inline_parm_levels, inline_parm_levels_used);
++i)
{
--processing_template_decl;
current_template_parms = TREE_CHAIN (current_template_parms);
poplevel (0, 0, 0);
}
}
/* Returns nonzero iff T is a member template function. We must be
careful as in
template <class T> class C { void f(); }
Here, f is a template function, and a member, but not a member
template. This function does not concern itself with the origin of
T, only its present state. So if we have
template <class T> class C { template <class U> void f(U); }
then neither C<int>::f<char> nor C<T>::f<double> is considered
to be a member template. But, `template <class U> void
C<int>::f(U)' is considered a member template. */
int
is_member_template (tree t)
{
if (!DECL_FUNCTION_TEMPLATE_P (t))
/* Anything that isn't a function or a template function is
certainly not a member template. */
return 0;
/* A local class can't have member templates. */
if (decl_function_context (t))
return 0;
return (DECL_FUNCTION_MEMBER_P (DECL_TEMPLATE_RESULT (t))
/* If there are more levels of template parameters than
there are template classes surrounding the declaration,
then we have a member template. */
&& (TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (t)) >
template_class_depth (DECL_CONTEXT (t))));
}
#if 0 /* UNUSED */
/* Returns nonzero iff T is a member template class. See
is_member_template for a description of what precisely constitutes
a member template. */
int
is_member_template_class (tree t)
{
if (!DECL_CLASS_TEMPLATE_P (t))
/* Anything that isn't a class template, is certainly not a member
template. */
return 0;
if (!DECL_CLASS_SCOPE_P (t))
/* Anything whose context isn't a class type is surely not a
member template. */
return 0;
/* If there are more levels of template parameters than there are
template classes surrounding the declaration, then we have a
member template. */
return (TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (t)) >
template_class_depth (DECL_CONTEXT (t)));
}
#endif
/* Return a new template argument vector which contains all of ARGS,
but has as its innermost set of arguments the EXTRA_ARGS. */
static tree
add_to_template_args (tree args, tree extra_args)
{
tree new_args;
int extra_depth;
int i;
int j;
extra_depth = TMPL_ARGS_DEPTH (extra_args);
new_args = make_tree_vec (TMPL_ARGS_DEPTH (args) + extra_depth);
for (i = 1; i <= TMPL_ARGS_DEPTH (args); ++i)
SET_TMPL_ARGS_LEVEL (new_args, i, TMPL_ARGS_LEVEL (args, i));
for (j = 1; j <= extra_depth; ++j, ++i)
SET_TMPL_ARGS_LEVEL (new_args, i, TMPL_ARGS_LEVEL (extra_args, j));
return new_args;
}
/* Like add_to_template_args, but only the outermost ARGS are added to
the EXTRA_ARGS. In particular, all but TMPL_ARGS_DEPTH
(EXTRA_ARGS) levels are added. This function is used to combine
the template arguments from a partial instantiation with the
template arguments used to attain the full instantiation from the
partial instantiation. */
static tree
add_outermost_template_args (tree args, tree extra_args)
{
tree new_args;
/* If there are more levels of EXTRA_ARGS than there are ARGS,
something very fishy is going on. */
my_friendly_assert (TMPL_ARGS_DEPTH (args) >= TMPL_ARGS_DEPTH (extra_args),
0);
/* If *all* the new arguments will be the EXTRA_ARGS, just return
them. */
if (TMPL_ARGS_DEPTH (args) == TMPL_ARGS_DEPTH (extra_args))
return extra_args;
/* For the moment, we make ARGS look like it contains fewer levels. */
TREE_VEC_LENGTH (args) -= TMPL_ARGS_DEPTH (extra_args);
new_args = add_to_template_args (args, extra_args);
/* Now, we restore ARGS to its full dimensions. */
TREE_VEC_LENGTH (args) += TMPL_ARGS_DEPTH (extra_args);
return new_args;
}
/* Return the N levels of innermost template arguments from the ARGS. */
tree
get_innermost_template_args (tree args, int n)
{
tree new_args;
int extra_levels;
int i;
my_friendly_assert (n >= 0, 20000603);
/* If N is 1, just return the innermost set of template arguments. */
if (n == 1)
return TMPL_ARGS_LEVEL (args, TMPL_ARGS_DEPTH (args));
/* If we're not removing anything, just return the arguments we were
given. */
extra_levels = TMPL_ARGS_DEPTH (args) - n;
my_friendly_assert (extra_levels >= 0, 20000603);
if (extra_levels == 0)
return args;
/* Make a new set of arguments, not containing the outer arguments. */
new_args = make_tree_vec (n);
for (i = 1; i <= n; ++i)
SET_TMPL_ARGS_LEVEL (new_args, i,
TMPL_ARGS_LEVEL (args, i + extra_levels));
return new_args;
}
/* We've got a template header coming up; push to a new level for storing
the parms. */
void
begin_template_parm_list (void)
{
/* We use a non-tag-transparent scope here, which causes pushtag to
put tags in this scope, rather than in the enclosing class or
namespace scope. This is the right thing, since we want
TEMPLATE_DECLS, and not TYPE_DECLS for template classes. For a
global template class, push_template_decl handles putting the
TEMPLATE_DECL into top-level scope. For a nested template class,
e.g.:
template <class T> struct S1 {
template <class T> struct S2 {};
};
pushtag contains special code to call pushdecl_with_scope on the
TEMPLATE_DECL for S2. */
begin_scope (sk_template_parms, NULL);
++processing_template_decl;
++processing_template_parmlist;
note_template_header (0);
}
/* This routine is called when a specialization is declared. If it is
invalid to declare a specialization here, an error is reported. */
static void
check_specialization_scope (void)
{
tree scope = current_scope ();
/* [temp.expl.spec]
An explicit specialization shall be declared in the namespace of
which the template is a member, or, for member templates, in the
namespace of which the enclosing class or enclosing class
template is a member. An explicit specialization of a member
function, member class or static data member of a class template
shall be declared in the namespace of which the class template
is a member. */
if (scope && TREE_CODE (scope) != NAMESPACE_DECL)
error ("explicit specialization in non-namespace scope `%D'",
scope);
/* [temp.expl.spec]
In an explicit specialization declaration for a member of a class
template or a member template that appears in namespace scope,
the member template and some of its enclosing class templates may
remain unspecialized, except that the declaration shall not
explicitly specialize a class member template if its enclosing
class templates are not explicitly specialized as well. */
if (current_template_parms)
error ("enclosing class templates are not explicitly specialized");
}
/* We've just seen template <>. */
void
begin_specialization (void)
{
begin_scope (sk_template_spec, NULL);
note_template_header (1);
check_specialization_scope ();
}
/* Called at then end of processing a declaration preceded by
template<>. */
void
end_specialization (void)
{
finish_scope ();
reset_specialization ();
}
/* Any template <>'s that we have seen thus far are not referring to a
function specialization. */
void
reset_specialization (void)
{
processing_specialization = 0;
template_header_count = 0;
}
/* We've just seen a template header. If SPECIALIZATION is nonzero,
it was of the form template <>. */
static void
note_template_header (int specialization)
{
processing_specialization = specialization;
template_header_count++;
}
/* We're beginning an explicit instantiation. */
void
begin_explicit_instantiation (void)
{
my_friendly_assert (!processing_explicit_instantiation, 20020913);
processing_explicit_instantiation = true;
}
void
end_explicit_instantiation (void)
{
my_friendly_assert(processing_explicit_instantiation, 20020913);
processing_explicit_instantiation = false;
}
/* The TYPE is being declared. If it is a template type, that means it
is a partial specialization. Do appropriate error-checking. */
void
maybe_process_partial_specialization (tree type)
{
/* TYPE maybe an ERROR_MARK_NODE. */
tree context = TYPE_P (type) ? TYPE_CONTEXT (type) : NULL_TREE;
if (CLASS_TYPE_P (type) && CLASSTYPE_USE_TEMPLATE (type))
{
/* This is for ordinary explicit specialization and partial
specialization of a template class such as:
template <> class C<int>;
or:
template <class T> class C<T*>;
Make sure that `C<int>' and `C<T*>' are implicit instantiations. */
if (CLASSTYPE_IMPLICIT_INSTANTIATION (type)
&& !COMPLETE_TYPE_P (type))
{
tree tpl_ns = decl_namespace_context (CLASSTYPE_TI_TEMPLATE (type));
if (is_associated_namespace (current_namespace, tpl_ns))
/* Same or super-using namespace. */;
else
{
pedwarn ("specializing `%#T' in different namespace", type);
cp_pedwarn_at (" from definition of `%#D'",
CLASSTYPE_TI_TEMPLATE (type));
}
SET_CLASSTYPE_TEMPLATE_SPECIALIZATION (type);
if (processing_template_decl)
push_template_decl (TYPE_MAIN_DECL (type));
}
else if (CLASSTYPE_TEMPLATE_INSTANTIATION (type))
error ("specialization of `%T' after instantiation", type);
}
else if (CLASS_TYPE_P (type)
&& !CLASSTYPE_USE_TEMPLATE (type)
&& CLASSTYPE_TEMPLATE_INFO (type)
&& context && CLASS_TYPE_P (context)
&& CLASSTYPE_TEMPLATE_INFO (context))
{
/* This is for an explicit specialization of member class
template according to [temp.expl.spec/18]:
template <> template <class U> class C<int>::D;
The context `C<int>' must be an implicit instantiation.
Otherwise this is just a member class template declared
earlier like:
template <> class C<int> { template <class U> class D; };
template <> template <class U> class C<int>::D;
In the first case, `C<int>::D' is a specialization of `C<T>::D'
while in the second case, `C<int>::D' is a primary template
and `C<T>::D' may not exist. */
if (CLASSTYPE_IMPLICIT_INSTANTIATION (context)
&& !COMPLETE_TYPE_P (type))
{
tree t;
if (current_namespace
!= decl_namespace_context (CLASSTYPE_TI_TEMPLATE (type)))
{
pedwarn ("specializing `%#T' in different namespace", type);
cp_pedwarn_at (" from definition of `%#D'",
CLASSTYPE_TI_TEMPLATE (type));
}
/* Check for invalid specialization after instantiation:
template <> template <> class C<int>::D<int>;
template <> template <class U> class C<int>::D; */
for (t = DECL_TEMPLATE_INSTANTIATIONS
(most_general_template (CLASSTYPE_TI_TEMPLATE (type)));
t; t = TREE_CHAIN (t))
if (TREE_VALUE (t) != type
&& TYPE_CONTEXT (TREE_VALUE (t)) == context)
error ("specialization `%T' after instantiation `%T'",
type, TREE_VALUE (t));
/* Mark TYPE as a specialization. And as a result, we only
have one level of template argument for the innermost
class template. */
SET_CLASSTYPE_TEMPLATE_SPECIALIZATION (type);
CLASSTYPE_TI_ARGS (type)
= INNERMOST_TEMPLATE_ARGS (CLASSTYPE_TI_ARGS (type));
}
}
else if (processing_specialization)
error ("explicit specialization of non-template `%T'", type);
}
/* Retrieve the specialization (in the sense of [temp.spec] - a
specialization is either an instantiation or an explicit
specialization) of TMPL for the given template ARGS. If there is
no such specialization, return NULL_TREE. The ARGS are a vector of
arguments, or a vector of vectors of arguments, in the case of
templates with more than one level of parameters. */
static tree
retrieve_specialization (tree tmpl, tree args)
{
tree s;
my_friendly_assert (TREE_CODE (tmpl) == TEMPLATE_DECL, 0);
/* There should be as many levels of arguments as there are
levels of parameters. */
my_friendly_assert (TMPL_ARGS_DEPTH (args)
== TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (tmpl)),
0);
for (s = DECL_TEMPLATE_SPECIALIZATIONS (tmpl);
s != NULL_TREE;
s = TREE_CHAIN (s))
if (comp_template_args (TREE_PURPOSE (s), args))
return TREE_VALUE (s);
return NULL_TREE;
}
/* Like retrieve_specialization, but for local declarations. */
static tree
retrieve_local_specialization (tree tmpl)
{
tree spec = htab_find_with_hash (local_specializations, tmpl,
htab_hash_pointer (tmpl));
return spec ? TREE_PURPOSE (spec) : NULL_TREE;
}
/* Returns nonzero iff DECL is a specialization of TMPL. */
int
is_specialization_of (tree decl, tree tmpl)
{
tree t;
if (TREE_CODE (decl) == FUNCTION_DECL)
{
for (t = decl;
t != NULL_TREE;
t = DECL_TEMPLATE_INFO (t) ? DECL_TI_TEMPLATE (t) : NULL_TREE)
if (t == tmpl)
return 1;
}
else
{
my_friendly_assert (TREE_CODE (decl) == TYPE_DECL, 0);
for (t = TREE_TYPE (decl);
t != NULL_TREE;
t = CLASSTYPE_USE_TEMPLATE (t)
? TREE_TYPE (CLASSTYPE_TI_TEMPLATE (t)) : NULL_TREE)
if (same_type_ignoring_top_level_qualifiers_p (t, TREE_TYPE (tmpl)))
return 1;
}
return 0;
}
/* Returns nonzero iff DECL is a specialization of friend declaration
FRIEND according to [temp.friend]. */
bool
is_specialization_of_friend (tree decl, tree friend)
{
bool need_template = true;
int template_depth;
my_friendly_assert (TREE_CODE (decl) == FUNCTION_DECL, 0);
/* For [temp.friend/6] when FRIEND is an ordinary member function
of a template class, we want to check if DECL is a specialization
if this. */
if (TREE_CODE (friend) == FUNCTION_DECL
&& DECL_TEMPLATE_INFO (friend)
&& !DECL_USE_TEMPLATE (friend))
{
friend = DECL_TI_TEMPLATE (friend);
need_template = false;
}
/* There is nothing to do if this is not a template friend. */
if (TREE_CODE (friend) != TEMPLATE_DECL)
return 0;
if (is_specialization_of (decl, friend))
return 1;
/* [temp.friend/6]
A member of a class template may be declared to be a friend of a
non-template class. In this case, the corresponding member of
every specialization of the class template is a friend of the
class granting friendship.
For example, given a template friend declaration
template <class T> friend void A<T>::f();
the member function below is considered a friend
template <> struct A<int> {
void f();
};
For this type of template friend, TEMPLATE_DEPTH below will be
nonzero. To determine if DECL is a friend of FRIEND, we first
check if the enclosing class is a specialization of another. */
template_depth = template_class_depth (DECL_CONTEXT (friend));
if (template_depth
&& DECL_CLASS_SCOPE_P (decl)
&& is_specialization_of (TYPE_NAME (DECL_CONTEXT (decl)),
CLASSTYPE_TI_TEMPLATE (DECL_CONTEXT (friend))))
{
/* Next, we check the members themselves. In order to handle
a few tricky cases like
template <class T> friend void A<T>::g(T t);
template <class T> template <T t> friend void A<T>::h();
we need to figure out what ARGS is (corresponding to `T' in above
examples) from DECL for later processing. */
tree context = DECL_CONTEXT (decl);
tree args = NULL_TREE;
int current_depth = 0;
while (current_depth < template_depth)
{
if (CLASSTYPE_TEMPLATE_INFO (context))
{
if (current_depth == 0)
args = TYPE_TI_ARGS (context);
else
args = add_to_template_args (TYPE_TI_ARGS (context), args);
current_depth++;
}
context = TYPE_CONTEXT (context);
}
if (TREE_CODE (decl) == FUNCTION_DECL)
{
bool is_template;
tree friend_type;
tree decl_type;
tree friend_args_type;
tree decl_args_type;
/* Make sure that both DECL and FRIEND are templates or
non-templates. */
is_template = DECL_TEMPLATE_INFO (decl)
&& PRIMARY_TEMPLATE_P (DECL_TI_TEMPLATE (decl));
if (need_template ^ is_template)
return 0;
else if (is_template)
{
/* If both are templates, check template paramter list. */
tree friend_parms
= tsubst_template_parms (DECL_TEMPLATE_PARMS (friend),
args, tf_none);
if (!comp_template_parms
(DECL_TEMPLATE_PARMS (DECL_TI_TEMPLATE (decl)),
friend_parms))
return 0;
decl_type = TREE_TYPE (DECL_TI_TEMPLATE (decl));
}
else
decl_type = TREE_TYPE (decl);
friend_type = tsubst_function_type (TREE_TYPE (friend), args,
tf_none, NULL_TREE);
if (friend_type == error_mark_node)
return 0;
/* Check if return types match. */
if (!same_type_p (TREE_TYPE (decl_type), TREE_TYPE (friend_type)))
return 0;
/* Check if function parameter types match, ignoring the
`this' parameter. */
friend_args_type = TYPE_ARG_TYPES (friend_type);
decl_args_type = TYPE_ARG_TYPES (decl_type);
if (DECL_NONSTATIC_MEMBER_FUNCTION_P (friend))
friend_args_type = TREE_CHAIN (friend_args_type);
if (DECL_NONSTATIC_MEMBER_FUNCTION_P (decl))
decl_args_type = TREE_CHAIN (decl_args_type);
if (compparms (decl_args_type, friend_args_type))
return 1;
}
}
return 0;
}
/* Register the specialization SPEC as a specialization of TMPL with
the indicated ARGS. Returns SPEC, or an equivalent prior
declaration, if available. */
static tree
register_specialization (tree spec, tree tmpl, tree args)
{
tree s;
my_friendly_assert (TREE_CODE (tmpl) == TEMPLATE_DECL, 0);
if (TREE_CODE (spec) == FUNCTION_DECL
&& uses_template_parms (DECL_TI_ARGS (spec)))
/* This is the FUNCTION_DECL for a partial instantiation. Don't
register it; we want the corresponding TEMPLATE_DECL instead.
We use `uses_template_parms (DECL_TI_ARGS (spec))' rather than
the more obvious `uses_template_parms (spec)' to avoid problems
with default function arguments. In particular, given
something like this:
template <class T> void f(T t1, T t = T())
the default argument expression is not substituted for in an
instantiation unless and until it is actually needed. */
return spec;
/* There should be as many levels of arguments as there are
levels of parameters. */
my_friendly_assert (TMPL_ARGS_DEPTH (args)
== TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (tmpl)),
0);
for (s = DECL_TEMPLATE_SPECIALIZATIONS (tmpl);
s != NULL_TREE;
s = TREE_CHAIN (s))
{
tree fn = TREE_VALUE (s);
/* We can sometimes try to re-register a specialization that we've
already got. In particular, regenerate_decl_from_template
calls duplicate_decls which will update the specialization
list. But, we'll still get called again here anyhow. It's
more convenient to simply allow this than to try to prevent it. */
if (fn == spec)
return spec;
else if (comp_template_args (TREE_PURPOSE (s), args))
{
if (DECL_TEMPLATE_SPECIALIZATION (spec))
{
if (DECL_TEMPLATE_INSTANTIATION (fn))
{
if (TREE_USED (fn)
|| DECL_EXPLICIT_INSTANTIATION (fn))
{
error ("specialization of %D after instantiation",
fn);
return spec;
}
else
{
/* This situation should occur only if the first
specialization is an implicit instantiation,
the second is an explicit specialization, and
the implicit instantiation has not yet been
used. That situation can occur if we have
implicitly instantiated a member function and
then specialized it later.
We can also wind up here if a friend
declaration that looked like an instantiation
turns out to be a specialization:
template <class T> void foo(T);
class S { friend void foo<>(int) };
template <> void foo(int);
We transform the existing DECL in place so that
any pointers to it become pointers to the
updated declaration.
If there was a definition for the template, but
not for the specialization, we want this to
look as if there is no definition, and vice
versa. */
DECL_INITIAL (fn) = NULL_TREE;
duplicate_decls (spec, fn);
return fn;
}
}
else if (DECL_TEMPLATE_SPECIALIZATION (fn))
{
if (!duplicate_decls (spec, fn) && DECL_INITIAL (spec))
/* Dup decl failed, but this is a new
definition. Set the line number so any errors
match this new definition. */
DECL_SOURCE_LOCATION (fn) = DECL_SOURCE_LOCATION (spec);
return fn;
}
}
}
}
DECL_TEMPLATE_SPECIALIZATIONS (tmpl)
= tree_cons (args, spec, DECL_TEMPLATE_SPECIALIZATIONS (tmpl));
return spec;
}
/* Unregister the specialization SPEC as a specialization of TMPL.
Replace it with NEW_SPEC, if NEW_SPEC is non-NULL. Returns true
if the SPEC was listed as a specialization of TMPL. */
bool
reregister_specialization (tree spec, tree tmpl, tree new_spec)
{
tree* s;
for (s = &DECL_TEMPLATE_SPECIALIZATIONS (tmpl);
*s != NULL_TREE;
s = &TREE_CHAIN (*s))
if (TREE_VALUE (*s) == spec)
{
if (!new_spec)
*s = TREE_CHAIN (*s);
else
TREE_VALUE (*s) = new_spec;
return 1;
}
return 0;
}
/* Compare an entry in the local specializations hash table P1 (which
is really a pointer to a TREE_LIST) with P2 (which is really a
DECL). */
static int
eq_local_specializations (const void *p1, const void *p2)
{
return TREE_VALUE ((tree) p1) == (tree) p2;
}
/* Hash P1, an entry in the local specializations table. */
static hashval_t
hash_local_specialization (const void* p1)
{
return htab_hash_pointer (TREE_VALUE ((tree) p1));
}
/* Like register_specialization, but for local declarations. We are
registering SPEC, an instantiation of TMPL. */
static void
register_local_specialization (tree spec, tree tmpl)
{
void **slot;
slot = htab_find_slot_with_hash (local_specializations, tmpl,
htab_hash_pointer (tmpl), INSERT);
*slot = build_tree_list (spec, tmpl);
}
/* Print the list of candidate FNS in an error message. */
void
print_candidates (tree fns)
{
tree fn;
const char *str = "candidates are:";
for (fn = fns; fn != NULL_TREE; fn = TREE_CHAIN (fn))
{
tree f;
for (f = TREE_VALUE (fn); f; f = OVL_NEXT (f))
cp_error_at ("%s %+#D", str, OVL_CURRENT (f));
str = " ";
}
}
/* Returns the template (one of the functions given by TEMPLATE_ID)
which can be specialized to match the indicated DECL with the
explicit template args given in TEMPLATE_ID. The DECL may be
NULL_TREE if none is available. In that case, the functions in
TEMPLATE_ID are non-members.
If NEED_MEMBER_TEMPLATE is nonzero the function is known to be a
specialization of a member template.
The template args (those explicitly specified and those deduced)
are output in a newly created vector *TARGS_OUT.
If it is impossible to determine the result, an error message is
issued. The error_mark_node is returned to indicate failure. */
static tree
determine_specialization (tree template_id,
tree decl,
tree* targs_out,
int need_member_template)
{
tree fns;
tree targs;
tree explicit_targs;
tree candidates = NULL_TREE;
tree templates = NULL_TREE;
*targs_out = NULL_TREE;
if (template_id == error_mark_node)
return error_mark_node;
fns = TREE_OPERAND (template_id, 0);
explicit_targs = TREE_OPERAND (template_id, 1);
if (fns == error_mark_node)
return error_mark_node;
/* Check for baselinks. */
if (BASELINK_P (fns))
fns = BASELINK_FUNCTIONS (fns);
if (!is_overloaded_fn (fns))
{
error ("`%D' is not a function template", fns);
return error_mark_node;
}
for (; fns; fns = OVL_NEXT (fns))
{
tree fn = OVL_CURRENT (fns);
if (TREE_CODE (fn) == TEMPLATE_DECL)
{
tree decl_arg_types;
/* DECL might be a specialization of FN. */
/* Adjust the type of DECL in case FN is a static member. */
decl_arg_types = TYPE_ARG_TYPES (TREE_TYPE (decl));
if (DECL_STATIC_FUNCTION_P (fn)
&& DECL_NONSTATIC_MEMBER_FUNCTION_P (decl))
decl_arg_types = TREE_CHAIN (decl_arg_types);
/* Check that the number of function parameters matches.
For example,
template <class T> void f(int i = 0);
template <> void f<int>();
The specialization f<int> is invalid but is not caught
by get_bindings below. */
if (list_length (TYPE_ARG_TYPES (TREE_TYPE (fn)))
!= list_length (decl_arg_types))
continue;
/* See whether this function might be a specialization of this
template. */
targs = get_bindings (fn, decl, explicit_targs);
if (!targs)
/* We cannot deduce template arguments that when used to
specialize TMPL will produce DECL. */
continue;
/* Save this template, and the arguments deduced. */
templates = tree_cons (targs, fn, templates);
}
else if (need_member_template)
/* FN is an ordinary member function, and we need a
specialization of a member template. */
;
else if (TREE_CODE (fn) != FUNCTION_DECL)
/* We can get IDENTIFIER_NODEs here in certain erroneous
cases. */
;
else if (!DECL_FUNCTION_MEMBER_P (fn))
/* This is just an ordinary non-member function. Nothing can
be a specialization of that. */
;
else if (DECL_ARTIFICIAL (fn))
/* Cannot specialize functions that are created implicitly. */
;
else
{
tree decl_arg_types;
/* This is an ordinary member function. However, since
we're here, we can assume it's enclosing class is a
template class. For example,
template <typename T> struct S { void f(); };
template <> void S<int>::f() {}
Here, S<int>::f is a non-template, but S<int> is a
template class. If FN has the same type as DECL, we
might be in business. */
if (!DECL_TEMPLATE_INFO (fn))
/* Its enclosing class is an explicit specialization
of a template class. This is not a candidate. */
continue;
if (!same_type_p (TREE_TYPE (TREE_TYPE (decl)),
TREE_TYPE (TREE_TYPE (fn))))
/* The return types differ. */
continue;
/* Adjust the type of DECL in case FN is a static member. */
decl_arg_types = TYPE_ARG_TYPES (TREE_TYPE (decl));
if (DECL_STATIC_FUNCTION_P (fn)
&& DECL_NONSTATIC_MEMBER_FUNCTION_P (decl))
decl_arg_types = TREE_CHAIN (decl_arg_types);
if (compparms (TYPE_ARG_TYPES (TREE_TYPE (fn)),
decl_arg_types))
/* They match! */
candidates = tree_cons (NULL_TREE, fn, candidates);
}
}
if (templates && TREE_CHAIN (templates))
{
/* We have:
[temp.expl.spec]
It is possible for a specialization with a given function
signature to be instantiated from more than one function
template. In such cases, explicit specification of the
template arguments must be used to uniquely identify the
function template specialization being specialized.
Note that here, there's no suggestion that we're supposed to
determine which of the candidate templates is most
specialized. However, we, also have:
[temp.func.order]
Partial ordering of overloaded function template
declarations is used in the following contexts to select
the function template to which a function template
specialization refers:
-- when an explicit specialization refers to a function
template.
So, we do use the partial ordering rules, at least for now.
This extension can only serve to make invalid programs valid,
so it's safe. And, there is strong anecdotal evidence that
the committee intended the partial ordering rules to apply;
the EDG front-end has that behavior, and John Spicer claims
that the committee simply forgot to delete the wording in
[temp.expl.spec]. */
tree tmpl = most_specialized (templates, decl, explicit_targs);
if (tmpl && tmpl != error_mark_node)
{
targs = get_bindings (tmpl, decl, explicit_targs);
templates = tree_cons (targs, tmpl, NULL_TREE);
}
}
if (templates == NULL_TREE && candidates == NULL_TREE)
{
cp_error_at ("template-id `%D' for `%+D' does not match any template declaration",
template_id, decl);
return error_mark_node;
}
else if ((templates && TREE_CHAIN (templates))
|| (candidates && TREE_CHAIN (candidates))
|| (templates && candidates))
{
cp_error_at ("ambiguous template specialization `%D' for `%+D'",
template_id, decl);
chainon (candidates, templates);
print_candidates (candidates);
return error_mark_node;
}
/* We have one, and exactly one, match. */
if (candidates)
{
/* It was a specialization of an ordinary member function in a
template class. */
*targs_out = copy_node (DECL_TI_ARGS (TREE_VALUE (candidates)));
return DECL_TI_TEMPLATE (TREE_VALUE (candidates));
}
/* It was a specialization of a template. */
targs = DECL_TI_ARGS (DECL_TEMPLATE_RESULT (TREE_VALUE (templates)));
if (TMPL_ARGS_HAVE_MULTIPLE_LEVELS (targs))
{
*targs_out = copy_node (targs);
SET_TMPL_ARGS_LEVEL (*targs_out,
TMPL_ARGS_DEPTH (*targs_out),
TREE_PURPOSE (templates));
}
else
*targs_out = TREE_PURPOSE (templates);
return TREE_VALUE (templates);
}
/* Returns a chain of parameter types, exactly like the SPEC_TYPES,
but with the default argument values filled in from those in the
TMPL_TYPES. */
static tree
copy_default_args_to_explicit_spec_1 (tree spec_types,
tree tmpl_types)
{
tree new_spec_types;
if (!spec_types)
return NULL_TREE;
if (spec_types == void_list_node)
return void_list_node;
/* Substitute into the rest of the list. */
new_spec_types =
copy_default_args_to_explicit_spec_1 (TREE_CHAIN (spec_types),
TREE_CHAIN (tmpl_types));
/* Add the default argument for this parameter. */
return hash_tree_cons (TREE_PURPOSE (tmpl_types),
TREE_VALUE (spec_types),
new_spec_types);
}
/* DECL is an explicit specialization. Replicate default arguments
from the template it specializes. (That way, code like:
template <class T> void f(T = 3);
template <> void f(double);
void g () { f (); }
works, as required.) An alternative approach would be to look up
the correct default arguments at the call-site, but this approach
is consistent with how implicit instantiations are handled. */
static void
copy_default_args_to_explicit_spec (tree decl)
{
tree tmpl;
tree spec_types;
tree tmpl_types;
tree new_spec_types;
tree old_type;
tree new_type;
tree t;
tree object_type = NULL_TREE;
tree in_charge = NULL_TREE;
tree vtt = NULL_TREE;
/* See if there's anything we need to do. */
tmpl = DECL_TI_TEMPLATE (decl);
tmpl_types = TYPE_ARG_TYPES (TREE_TYPE (DECL_TEMPLATE_RESULT (tmpl)));
for (t = tmpl_types; t; t = TREE_CHAIN (t))
if (TREE_PURPOSE (t))
break;
if (!t)
return;
old_type = TREE_TYPE (decl);
spec_types = TYPE_ARG_TYPES (old_type);
if (DECL_NONSTATIC_MEMBER_FUNCTION_P (decl))
{
/* Remove the this pointer, but remember the object's type for
CV quals. */
object_type = TREE_TYPE (TREE_VALUE (spec_types));
spec_types = TREE_CHAIN (spec_types);
tmpl_types = TREE_CHAIN (tmpl_types);
if (DECL_HAS_IN_CHARGE_PARM_P (decl))
{
/* DECL may contain more parameters than TMPL due to the extra
in-charge parameter in constructors and destructors. */
in_charge = spec_types;
spec_types = TREE_CHAIN (spec_types);
}
if (DECL_HAS_VTT_PARM_P (decl))
{
vtt = spec_types;
spec_types = TREE_CHAIN (spec_types);
}
}
/* Compute the merged default arguments. */
new_spec_types =
copy_default_args_to_explicit_spec_1 (spec_types, tmpl_types);
/* Compute the new FUNCTION_TYPE. */
if (object_type)
{
if (vtt)
new_spec_types = hash_tree_cons (TREE_PURPOSE (vtt),
TREE_VALUE (vtt),
new_spec_types);
if (in_charge)
/* Put the in-charge parameter back. */
new_spec_types = hash_tree_cons (TREE_PURPOSE (in_charge),
TREE_VALUE (in_charge),
new_spec_types);
new_type = build_method_type_directly (object_type,
TREE_TYPE (old_type),
new_spec_types);
}
else
new_type = build_function_type (TREE_TYPE (old_type),
new_spec_types);
new_type = build_type_attribute_variant (new_type,
TYPE_ATTRIBUTES (old_type));
new_type = build_exception_variant (new_type,
TYPE_RAISES_EXCEPTIONS (old_type));
TREE_TYPE (decl) = new_type;
}
/* Check to see if the function just declared, as indicated in
DECLARATOR, and in DECL, is a specialization of a function
template. We may also discover that the declaration is an explicit
instantiation at this point.
Returns DECL, or an equivalent declaration that should be used
instead if all goes well. Issues an error message if something is
amiss. Returns error_mark_node if the error is not easily
recoverable.
FLAGS is a bitmask consisting of the following flags:
2: The function has a definition.
4: The function is a friend.
The TEMPLATE_COUNT is the number of references to qualifying
template classes that appeared in the name of the function. For
example, in
template <class T> struct S { void f(); };
void S<int>::f();
the TEMPLATE_COUNT would be 1. However, explicitly specialized
classes are not counted in the TEMPLATE_COUNT, so that in
template <class T> struct S {};
template <> struct S<int> { void f(); }
template <> void S<int>::f();
the TEMPLATE_COUNT would be 0. (Note that this declaration is
invalid; there should be no template <>.)
If the function is a specialization, it is marked as such via
DECL_TEMPLATE_SPECIALIZATION. Furthermore, its DECL_TEMPLATE_INFO
is set up correctly, and it is added to the list of specializations
for that template. */
tree
check_explicit_specialization (tree declarator,
tree decl,
int template_count,
int flags)
{
int have_def = flags & 2;
int is_friend = flags & 4;
int specialization = 0;
int explicit_instantiation = 0;
int member_specialization = 0;
tree ctype = DECL_CLASS_CONTEXT (decl);
tree dname = DECL_NAME (decl);
tmpl_spec_kind tsk;
tsk = current_tmpl_spec_kind (template_count);
switch (tsk)
{
case tsk_none:
if (processing_specialization)
{
specialization = 1;
SET_DECL_TEMPLATE_SPECIALIZATION (decl);
}
else if (TREE_CODE (declarator) == TEMPLATE_ID_EXPR)
{
if (is_friend)
/* This could be something like:
template <class T> void f(T);
class S { friend void f<>(int); } */
specialization = 1;
else
{
/* This case handles bogus declarations like template <>
template <class T> void f<int>(); */
error ("template-id `%D' in declaration of primary template",
declarator);
return decl;
}
}
break;
case tsk_invalid_member_spec:
/* The error has already been reported in
check_specialization_scope. */
return error_mark_node;
case tsk_invalid_expl_inst:
error ("template parameter list used in explicit instantiation");
/* Fall through. */
case tsk_expl_inst:
if (have_def)
error ("definition provided for explicit instantiation");
explicit_instantiation = 1;
break;
case tsk_excessive_parms:
error ("too many template parameter lists in declaration of `%D'",
decl);
return error_mark_node;
/* Fall through. */
case tsk_expl_spec:
SET_DECL_TEMPLATE_SPECIALIZATION (decl);
if (ctype)
member_specialization = 1;
else
specialization = 1;
break;
case tsk_insufficient_parms:
if (template_header_count)
{
error("too few template parameter lists in declaration of `%D'",
decl);
return decl;
}
else if (ctype != NULL_TREE
&& !TYPE_BEING_DEFINED (ctype)
&& CLASSTYPE_TEMPLATE_INSTANTIATION (ctype)
&& !is_friend)
{
/* For backwards compatibility, we accept:
template <class T> struct S { void f(); };
void S<int>::f() {} // Missing template <>
That used to be valid C++. */
if (pedantic)
pedwarn
("explicit specialization not preceded by `template <>'");
specialization = 1;
SET_DECL_TEMPLATE_SPECIALIZATION (decl);
}
break;
case tsk_template:
if (TREE_CODE (declarator) == TEMPLATE_ID_EXPR)
{
/* This case handles bogus declarations like template <>
template <class T> void f<int>(); */
if (uses_template_parms (declarator))
error ("partial specialization `%D' of function template",
declarator);
else
error ("template-id `%D' in declaration of primary template",
declarator);
return decl;
}
if (ctype && CLASSTYPE_TEMPLATE_INSTANTIATION (ctype))
/* This is a specialization of a member template, without
specialization the containing class. Something like:
template <class T> struct S {
template <class U> void f (U);
};
template <> template <class U> void S<int>::f(U) {}
That's a specialization -- but of the entire template. */
specialization = 1;
break;
default:
abort ();
}
if (specialization || member_specialization)
{
tree t = TYPE_ARG_TYPES (TREE_TYPE (decl));
for (; t; t = TREE_CHAIN (t))
if (TREE_PURPOSE (t))
{
pedwarn
("default argument specified in explicit specialization");
break;
}
if (current_lang_name == lang_name_c)
error ("template specialization with C linkage");
}
if (specialization || member_specialization || explicit_instantiation)
{
tree tmpl = NULL_TREE;
tree targs = NULL_TREE;
/* Make sure that the declarator is a TEMPLATE_ID_EXPR. */
if (TREE_CODE (declarator) != TEMPLATE_ID_EXPR)
{
tree fns;
my_friendly_assert (TREE_CODE (declarator) == IDENTIFIER_NODE, 0);
if (ctype)
fns = dname;
else
{
/* If there is no class context, the explicit instantiation
must be at namespace scope. */
my_friendly_assert (DECL_NAMESPACE_SCOPE_P (decl), 20030625);
/* Find the namespace binding, using the declaration
context. */
fns = namespace_binding (dname, CP_DECL_CONTEXT (decl));
}
declarator = lookup_template_function (fns, NULL_TREE);
}
if (declarator == error_mark_node)
return error_mark_node;
if (ctype != NULL_TREE && TYPE_BEING_DEFINED (ctype))
{
if (!explicit_instantiation)
/* A specialization in class scope. This is invalid,
but the error will already have been flagged by
check_specialization_scope. */
return error_mark_node;
else
{
/* It's not valid to write an explicit instantiation in
class scope, e.g.:
class C { template void f(); }
This case is caught by the parser. However, on
something like:
template class C { void f(); };
(which is invalid) we can get here. The error will be
issued later. */
;
}
return decl;
}
else if (ctype != NULL_TREE
&& (TREE_CODE (TREE_OPERAND (declarator, 0)) ==
IDENTIFIER_NODE))
{
/* Find the list of functions in ctype that have the same
name as the declared function. */
tree name = TREE_OPERAND (declarator, 0);
tree fns = NULL_TREE;
int idx;
if (constructor_name_p (name, ctype))
{
int is_constructor = DECL_CONSTRUCTOR_P (decl);
if (is_constructor ? !TYPE_HAS_CONSTRUCTOR (ctype)
: !TYPE_HAS_DESTRUCTOR (ctype))
{
/* From [temp.expl.spec]:
If such an explicit specialization for the member
of a class template names an implicitly-declared
special member function (clause _special_), the
program is ill-formed.
Similar language is found in [temp.explicit]. */
error ("specialization of implicitly-declared special member function");
return error_mark_node;
}
name = is_constructor ? ctor_identifier : dtor_identifier;
}
if (!DECL_CONV_FN_P (decl))
{
idx = lookup_fnfields_1 (ctype, name);
if (idx >= 0)
fns = TREE_VEC_ELT (CLASSTYPE_METHOD_VEC (ctype), idx);
}
else
{
tree methods;
/* For a type-conversion operator, we cannot do a
name-based lookup. We might be looking for `operator
int' which will be a specialization of `operator T'.
So, we find *all* the conversion operators, and then
select from them. */
fns = NULL_TREE;
methods = CLASSTYPE_METHOD_VEC (ctype);
if (methods)
for (idx = CLASSTYPE_FIRST_CONVERSION_SLOT;
idx < TREE_VEC_LENGTH (methods); ++idx)
{
tree ovl = TREE_VEC_ELT (methods, idx);
if (!ovl || !DECL_CONV_FN_P (OVL_CURRENT (ovl)))
/* There are no more conversion functions. */
break;
/* Glue all these conversion functions together
with those we already have. */
for (; ovl; ovl = OVL_NEXT (ovl))
fns = ovl_cons (OVL_CURRENT (ovl), fns);
}
}
if (fns == NULL_TREE)
{
error ("no member function `%D' declared in `%T'",
name, ctype);
return error_mark_node;
}
else
TREE_OPERAND (declarator, 0) = fns;
}
/* Figure out what exactly is being specialized at this point.
Note that for an explicit instantiation, even one for a
member function, we cannot tell apriori whether the
instantiation is for a member template, or just a member
function of a template class. Even if a member template is
being instantiated, the member template arguments may be
elided if they can be deduced from the rest of the
declaration. */
tmpl = determine_specialization (declarator, decl,
&targs,
member_specialization);
if (!tmpl || tmpl == error_mark_node)
/* We couldn't figure out what this declaration was
specializing. */
return error_mark_node;
else
{
tree gen_tmpl = most_general_template (tmpl);
if (explicit_instantiation)
{
/* We don't set DECL_EXPLICIT_INSTANTIATION here; that
is done by do_decl_instantiation later. */
int arg_depth = TMPL_ARGS_DEPTH (targs);
int parm_depth = TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (tmpl));
if (arg_depth > parm_depth)
{
/* If TMPL is not the most general template (for
example, if TMPL is a friend template that is
injected into namespace scope), then there will
be too many levels of TARGS. Remove some of them
here. */
int i;
tree new_targs;
new_targs = make_tree_vec (parm_depth);
for (i = arg_depth - parm_depth; i < arg_depth; ++i)
TREE_VEC_ELT (new_targs, i - (arg_depth - parm_depth))
= TREE_VEC_ELT (targs, i);
targs = new_targs;
}
return instantiate_template (tmpl, targs, tf_error);
}
/* If we thought that the DECL was a member function, but it
turns out to be specializing a static member function,
make DECL a static member function as well. We also have
to adjust last_function_parms to avoid confusing
start_function later. */
if (DECL_STATIC_FUNCTION_P (tmpl)
&& DECL_NONSTATIC_MEMBER_FUNCTION_P (decl))
{
revert_static_member_fn (decl);
last_function_parms = TREE_CHAIN (last_function_parms);
}
/* If this is a specialization of a member template of a
template class. In we want to return the TEMPLATE_DECL,
not the specialization of it. */
if (tsk == tsk_template)
{
SET_DECL_TEMPLATE_SPECIALIZATION (tmpl);
DECL_INITIAL (DECL_TEMPLATE_RESULT (tmpl)) = NULL_TREE;
if (have_def)
{
DECL_SOURCE_LOCATION (tmpl) = DECL_SOURCE_LOCATION (decl);
DECL_SOURCE_LOCATION (DECL_TEMPLATE_RESULT (tmpl))
= DECL_SOURCE_LOCATION (decl);
}
return tmpl;
}
/* Set up the DECL_TEMPLATE_INFO for DECL. */
DECL_TEMPLATE_INFO (decl) = tree_cons (tmpl, targs, NULL_TREE);
/* Inherit default function arguments from the template
DECL is specializing. */
copy_default_args_to_explicit_spec (decl);
/* This specialization has the same protection as the
template it specializes. */
TREE_PRIVATE (decl) = TREE_PRIVATE (gen_tmpl);
TREE_PROTECTED (decl) = TREE_PROTECTED (gen_tmpl);
if (is_friend && !have_def)
/* This is not really a declaration of a specialization.
It's just the name of an instantiation. But, it's not
a request for an instantiation, either. */
SET_DECL_IMPLICIT_INSTANTIATION (decl);
else if (DECL_CONSTRUCTOR_P (decl) || DECL_DESTRUCTOR_P (decl))
/* This is indeed a specialization. In case of constructors
and destructors, we need in-charge and not-in-charge
versions in V3 ABI. */
clone_function_decl (decl, /*update_method_vec_p=*/0);
/* Register this specialization so that we can find it
again. */
decl = register_specialization (decl, gen_tmpl, targs);
}
}
return decl;
}
/* TYPE is being declared. Verify that the use of template headers
and such is reasonable. Issue error messages if not. */
void
maybe_check_template_type (tree type)
{
if (template_header_count)
{
/* We are in the scope of some `template <...>' header. */
int context_depth
= template_class_depth_real (TYPE_CONTEXT (type),
/*count_specializations=*/1);
if (template_header_count <= context_depth)
/* This is OK; the template headers are for the context. We
are actually too lenient here; like
check_explicit_specialization we should consider the number
of template types included in the actual declaration. For
example,
template <class T> struct S {
template <class U> template <class V>
struct I {};
};
is invalid, but:
template <class T> struct S {
template <class U> struct I;
};
template <class T> template <class U.
struct S<T>::I {};
is not. */
;
else if (template_header_count > context_depth + 1)
/* There are two many template parameter lists. */
error ("too many template parameter lists in declaration of `%T'", type);
}
}
/* Returns 1 iff PARMS1 and PARMS2 are identical sets of template
parameters. These are represented in the same format used for
DECL_TEMPLATE_PARMS. */
int comp_template_parms (tree parms1, tree parms2)
{
tree p1;
tree p2;
if (parms1 == parms2)
return 1;
for (p1 = parms1, p2 = parms2;
p1 != NULL_TREE && p2 != NULL_TREE;
p1 = TREE_CHAIN (p1), p2 = TREE_CHAIN (p2))
{
tree t1 = TREE_VALUE (p1);
tree t2 = TREE_VALUE (p2);
int i;
my_friendly_assert (TREE_CODE (t1) == TREE_VEC, 0);
my_friendly_assert (TREE_CODE (t2) == TREE_VEC, 0);
if (TREE_VEC_LENGTH (t1) != TREE_VEC_LENGTH (t2))
return 0;
for (i = 0; i < TREE_VEC_LENGTH (t2); ++i)
{
tree parm1 = TREE_VALUE (TREE_VEC_ELT (t1, i));
tree parm2 = TREE_VALUE (TREE_VEC_ELT (t2, i));
if (TREE_CODE (parm1) != TREE_CODE (parm2))
return 0;
if (TREE_CODE (parm1) == TEMPLATE_TYPE_PARM)
continue;
else if (!same_type_p (TREE_TYPE (parm1), TREE_TYPE (parm2)))
return 0;
}
}
if ((p1 != NULL_TREE) != (p2 != NULL_TREE))
/* One set of parameters has more parameters lists than the
other. */
return 0;
return 1;
}
/* Complain if DECL shadows a template parameter.
[temp.local]: A template-parameter shall not be redeclared within its
scope (including nested scopes). */
void
check_template_shadow (tree decl)
{
tree olddecl;
/* If we're not in a template, we can't possibly shadow a template
parameter. */
if (!current_template_parms)
return;
/* Figure out what we're shadowing. */
if (TREE_CODE (decl) == OVERLOAD)
decl = OVL_CURRENT (decl);
olddecl = IDENTIFIER_VALUE (DECL_NAME (decl));
/* If there's no previous binding for this name, we're not shadowing
anything, let alone a template parameter. */
if (!olddecl)
return;
/* If we're not shadowing a template parameter, we're done. Note
that OLDDECL might be an OVERLOAD (or perhaps even an
ERROR_MARK), so we can't just blithely assume it to be a _DECL
node. */
if (!DECL_P (olddecl) || !DECL_TEMPLATE_PARM_P (olddecl))
return;
/* We check for decl != olddecl to avoid bogus errors for using a
name inside a class. We check TPFI to avoid duplicate errors for
inline member templates. */
if (decl == olddecl
|| TEMPLATE_PARMS_FOR_INLINE (current_template_parms))
return;
cp_error_at ("declaration of `%#D'", decl);
cp_error_at (" shadows template parm `%#D'", olddecl);
}
/* Return a new TEMPLATE_PARM_INDEX with the indicated INDEX, LEVEL,
ORIG_LEVEL, DECL, and TYPE. */
static tree
build_template_parm_index (int index,
int level,
int orig_level,
tree decl,
tree type)
{
tree t = make_node (TEMPLATE_PARM_INDEX);
TEMPLATE_PARM_IDX (t) = index;
TEMPLATE_PARM_LEVEL (t) = level;
TEMPLATE_PARM_ORIG_LEVEL (t) = orig_level;
TEMPLATE_PARM_DECL (t) = decl;
TREE_TYPE (t) = type;
TREE_CONSTANT (t) = TREE_CONSTANT (decl);
TREE_READONLY (t) = TREE_READONLY (decl);
return t;
}
/* Return a TEMPLATE_PARM_INDEX, similar to INDEX, but whose
TEMPLATE_PARM_LEVEL has been decreased by LEVELS. If such a
TEMPLATE_PARM_INDEX already exists, it is returned; otherwise, a
new one is created. */
static tree
reduce_template_parm_level (tree index, tree type, int levels)
{
if (TEMPLATE_PARM_DESCENDANTS (index) == NULL_TREE
|| (TEMPLATE_PARM_LEVEL (TEMPLATE_PARM_DESCENDANTS (index))
!= TEMPLATE_PARM_LEVEL (index) - levels))
{
tree orig_decl = TEMPLATE_PARM_DECL (index);
tree decl, t;
decl = build_decl (TREE_CODE (orig_decl), DECL_NAME (orig_decl), type);
TREE_CONSTANT (decl) = TREE_CONSTANT (orig_decl);
TREE_READONLY (decl) = TREE_READONLY (orig_decl);
DECL_ARTIFICIAL (decl) = 1;
SET_DECL_TEMPLATE_PARM_P (decl);
t = build_template_parm_index (TEMPLATE_PARM_IDX (index),
TEMPLATE_PARM_LEVEL (index) - levels,
TEMPLATE_PARM_ORIG_LEVEL (index),
decl, type);
TEMPLATE_PARM_DESCENDANTS (index) = t;
/* Template template parameters need this. */
DECL_TEMPLATE_PARMS (decl)
= DECL_TEMPLATE_PARMS (TEMPLATE_PARM_DECL (index));
}
return TEMPLATE_PARM_DESCENDANTS (index);
}
/* Process information from new template parameter NEXT and append it to the
LIST being built. */
tree
process_template_parm (tree list, tree next)
{
tree parm;
tree decl = 0;
tree defval;
int is_type, idx;
parm = next;
my_friendly_assert (TREE_CODE (parm) == TREE_LIST, 259);
defval = TREE_PURPOSE (parm);
parm = TREE_VALUE (parm);
is_type = TREE_PURPOSE (parm) == class_type_node;
if (list)
{
tree p = TREE_VALUE (tree_last (list));
if (TREE_CODE (p) == TYPE_DECL || TREE_CODE (p) == TEMPLATE_DECL)
idx = TEMPLATE_TYPE_IDX (TREE_TYPE (p));
else
idx = TEMPLATE_PARM_IDX (DECL_INITIAL (p));
++idx;
}
else
idx = 0;
if (!is_type)
{
my_friendly_assert (TREE_CODE (TREE_PURPOSE (parm)) == TREE_LIST, 260);
/* is a const-param */
parm = grokdeclarator (TREE_VALUE (parm), TREE_PURPOSE (parm),
PARM, 0, NULL);
SET_DECL_TEMPLATE_PARM_P (parm);
/* [temp.param]
The top-level cv-qualifiers on the template-parameter are
ignored when determining its type. */
TREE_TYPE (parm) = TYPE_MAIN_VARIANT (TREE_TYPE (parm));
/* A template parameter is not modifiable. */
TREE_READONLY (parm) = TREE_CONSTANT (parm) = 1;
if (invalid_nontype_parm_type_p (TREE_TYPE (parm), 1))
TREE_TYPE (parm) = void_type_node;
decl = build_decl (CONST_DECL, DECL_NAME (parm), TREE_TYPE (parm));
TREE_CONSTANT (decl) = TREE_READONLY (decl) = 1;
DECL_INITIAL (parm) = DECL_INITIAL (decl)
= build_template_parm_index (idx, processing_template_decl,
processing_template_decl,
decl, TREE_TYPE (parm));
}
else
{
tree t;
parm = TREE_VALUE (parm);
if (parm && TREE_CODE (parm) == TEMPLATE_DECL)
{
t = make_aggr_type (TEMPLATE_TEMPLATE_PARM);
/* This is for distinguishing between real templates and template
template parameters */
TREE_TYPE (parm) = t;
TREE_TYPE (DECL_TEMPLATE_RESULT (parm)) = t;
decl = parm;
}
else
{
t = make_aggr_type (TEMPLATE_TYPE_PARM);
/* parm is either IDENTIFIER_NODE or NULL_TREE */
decl = build_decl (TYPE_DECL, parm, t);
}
TYPE_NAME (t) = decl;
TYPE_STUB_DECL (t) = decl;
parm = decl;
TEMPLATE_TYPE_PARM_INDEX (t)
= build_template_parm_index (idx, processing_template_decl,
processing_template_decl,
decl, TREE_TYPE (parm));
}
DECL_ARTIFICIAL (decl) = 1;
SET_DECL_TEMPLATE_PARM_P (decl);
pushdecl (decl);
parm = build_tree_list (defval, parm);
return chainon (list, parm);
}
/* The end of a template parameter list has been reached. Process the
tree list into a parameter vector, converting each parameter into a more
useful form. Type parameters are saved as IDENTIFIER_NODEs, and others
as PARM_DECLs. */
tree
end_template_parm_list (tree parms)
{
int nparms;
tree parm, next;
tree saved_parmlist = make_tree_vec (list_length (parms));
current_template_parms
= tree_cons (size_int (processing_template_decl),
saved_parmlist, current_template_parms);
for (parm = parms, nparms = 0; parm; parm = next, nparms++)
{
next = TREE_CHAIN (parm);
TREE_VEC_ELT (saved_parmlist, nparms) = parm;
TREE_CHAIN (parm) = NULL_TREE;
}
--processing_template_parmlist;
return saved_parmlist;
}
/* end_template_decl is called after a template declaration is seen. */
void
end_template_decl (void)
{
reset_specialization ();
if (! processing_template_decl)
return;
/* This matches the pushlevel in begin_template_parm_list. */
finish_scope ();
--processing_template_decl;
current_template_parms = TREE_CHAIN (current_template_parms);
}
/* Given a template argument vector containing the template PARMS.
The innermost PARMS are given first. */
tree
current_template_args (void)
{
tree header;
tree args = NULL_TREE;
int length = TMPL_PARMS_DEPTH (current_template_parms);
int l = length;
/* If there is only one level of template parameters, we do not
create a TREE_VEC of TREE_VECs. Instead, we return a single
TREE_VEC containing the arguments. */
if (length > 1)
args = make_tree_vec (length);
for (header = current_template_parms; header; header = TREE_CHAIN (header))
{
tree a = copy_node (TREE_VALUE (header));
int i;
TREE_TYPE (a) = NULL_TREE;
for (i = TREE_VEC_LENGTH (a) - 1; i >= 0; --i)
{
tree t = TREE_VEC_ELT (a, i);
/* T will be a list if we are called from within a
begin/end_template_parm_list pair, but a vector directly
if within a begin/end_member_template_processing pair. */
if (TREE_CODE (t) == TREE_LIST)
{
t = TREE_VALUE (t);
if (TREE_CODE (t) == TYPE_DECL
|| TREE_CODE (t) == TEMPLATE_DECL)
t = TREE_TYPE (t);
else
t = DECL_INITIAL (t);
TREE_VEC_ELT (a, i) = t;
}
}
if (length > 1)
TREE_VEC_ELT (args, --l) = a;
else
args = a;
}
return args;
}
/* Return a TEMPLATE_DECL corresponding to DECL, using the indicated
template PARMS. Used by push_template_decl below. */
static tree
build_template_decl (tree decl, tree parms)
{
tree tmpl = build_lang_decl (TEMPLATE_DECL, DECL_NAME (decl), NULL_TREE);
DECL_TEMPLATE_PARMS (tmpl) = parms;
DECL_CONTEXT (tmpl) = DECL_CONTEXT (decl);
if (DECL_LANG_SPECIFIC (decl))
{
DECL_STATIC_FUNCTION_P (tmpl) = DECL_STATIC_FUNCTION_P (decl);
DECL_CONSTRUCTOR_P (tmpl) = DECL_CONSTRUCTOR_P (decl);
DECL_DESTRUCTOR_P (tmpl) = DECL_DESTRUCTOR_P (decl);
DECL_NONCONVERTING_P (tmpl) = DECL_NONCONVERTING_P (decl);
DECL_ASSIGNMENT_OPERATOR_P (tmpl) = DECL_ASSIGNMENT_OPERATOR_P (decl);
if (DECL_OVERLOADED_OPERATOR_P (decl))
SET_OVERLOADED_OPERATOR_CODE (tmpl,
DECL_OVERLOADED_OPERATOR_P (decl));
}
return tmpl;
}
struct template_parm_data
{
/* The level of the template parameters we are currently
processing. */
int level;
/* The index of the specialization argument we are currently
processing. */
int current_arg;
/* An array whose size is the number of template parameters. The
elements are nonzero if the parameter has been used in any one
of the arguments processed so far. */
int* parms;
/* An array whose size is the number of template arguments. The
elements are nonzero if the argument makes use of template
parameters of this level. */
int* arg_uses_template_parms;
};
/* Subroutine of push_template_decl used to see if each template
parameter in a partial specialization is used in the explicit
argument list. If T is of the LEVEL given in DATA (which is
treated as a template_parm_data*), then DATA->PARMS is marked
appropriately. */
static int
mark_template_parm (tree t, void* data)
{
int level;
int idx;
struct template_parm_data* tpd = (struct template_parm_data*) data;
if (TREE_CODE (t) == TEMPLATE_PARM_INDEX)
{
level = TEMPLATE_PARM_LEVEL (t);
idx = TEMPLATE_PARM_IDX (t);
}
else
{
level = TEMPLATE_TYPE_LEVEL (t);
idx = TEMPLATE_TYPE_IDX (t);
}
if (level == tpd->level)
{
tpd->parms[idx] = 1;
tpd->arg_uses_template_parms[tpd->current_arg] = 1;
}
/* Return zero so that for_each_template_parm will continue the
traversal of the tree; we want to mark *every* template parm. */
return 0;
}
/* Process the partial specialization DECL. */
static tree
process_partial_specialization (tree decl)
{
tree type = TREE_TYPE (decl);
tree maintmpl = CLASSTYPE_TI_TEMPLATE (type);
tree specargs = CLASSTYPE_TI_ARGS (type);
tree inner_args = INNERMOST_TEMPLATE_ARGS (specargs);
tree inner_parms = INNERMOST_TEMPLATE_PARMS (current_template_parms);
tree main_inner_parms = DECL_INNERMOST_TEMPLATE_PARMS (maintmpl);
int nargs = TREE_VEC_LENGTH (inner_args);
int ntparms = TREE_VEC_LENGTH (inner_parms);
int i;
int did_error_intro = 0;
struct template_parm_data tpd;
struct template_parm_data tpd2;
/* We check that each of the template parameters given in the
partial specialization is used in the argument list to the
specialization. For example:
template <class T> struct S;
template <class T> struct S<T*>;
The second declaration is OK because `T*' uses the template
parameter T, whereas
template <class T> struct S<int>;
is no good. Even trickier is:
template <class T>
struct S1
{
template <class U>
struct S2;
template <class U>
struct S2<T>;
};
The S2<T> declaration is actually invalid; it is a
full-specialization. Of course,
template <class U>
struct S2<T (*)(U)>;
or some such would have been OK. */
tpd.level = TMPL_PARMS_DEPTH (current_template_parms);
tpd.parms = alloca (sizeof (int) * ntparms);
memset (tpd.parms, 0, sizeof (int) * ntparms);
tpd.arg_uses_template_parms = alloca (sizeof (int) * nargs);
memset (tpd.arg_uses_template_parms, 0, sizeof (int) * nargs);
for (i = 0; i < nargs; ++i)
{
tpd.current_arg = i;
for_each_template_parm (TREE_VEC_ELT (inner_args, i),
&mark_template_parm,
&tpd,
NULL);
}
for (i = 0; i < ntparms; ++i)
if (tpd.parms[i] == 0)
{
/* One of the template parms was not used in the
specialization. */
if (!did_error_intro)
{
error ("template parameters not used in partial specialization:");
did_error_intro = 1;
}
error (" `%D'",
TREE_VALUE (TREE_VEC_ELT (inner_parms, i)));
}
/* [temp.class.spec]
The argument list of the specialization shall not be identical to
the implicit argument list of the primary template. */
if (comp_template_args
(inner_args,
INNERMOST_TEMPLATE_ARGS (CLASSTYPE_TI_ARGS (TREE_TYPE
(maintmpl)))))
error ("partial specialization `%T' does not specialize any template arguments", type);
/* [temp.class.spec]
A partially specialized non-type argument expression shall not
involve template parameters of the partial specialization except
when the argument expression is a simple identifier.
The type of a template parameter corresponding to a specialized
non-type argument shall not be dependent on a parameter of the
specialization. */
my_friendly_assert (nargs == DECL_NTPARMS (maintmpl), 0);
tpd2.parms = 0;
for (i = 0; i < nargs; ++i)
{
tree arg = TREE_VEC_ELT (inner_args, i);
if (/* These first two lines are the `non-type' bit. */
!TYPE_P (arg)
&& TREE_CODE (arg) != TEMPLATE_DECL
/* This next line is the `argument expression is not just a
simple identifier' condition and also the `specialized
non-type argument' bit. */
&& TREE_CODE (arg) != TEMPLATE_PARM_INDEX)
{
if (tpd.arg_uses_template_parms[i])
error ("template argument `%E' involves template parameter(s)", arg);
else
{
/* Look at the corresponding template parameter,
marking which template parameters its type depends
upon. */
tree type =
TREE_TYPE (TREE_VALUE (TREE_VEC_ELT (main_inner_parms,
i)));
if (!tpd2.parms)
{
/* We haven't yet initialized TPD2. Do so now. */
tpd2.arg_uses_template_parms
= alloca (sizeof (int) * nargs);
/* The number of parameters here is the number in the
main template, which, as checked in the assertion
above, is NARGS. */
tpd2.parms = alloca (sizeof (int) * nargs);
tpd2.level =
TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (maintmpl));
}
/* Mark the template parameters. But this time, we're
looking for the template parameters of the main
template, not in the specialization. */
tpd2.current_arg = i;
tpd2.arg_uses_template_parms[i] = 0;
memset (tpd2.parms, 0, sizeof (int) * nargs);
for_each_template_parm (type,
&mark_template_parm,
&tpd2,
NULL);
if (tpd2.arg_uses_template_parms [i])
{
/* The type depended on some template parameters.
If they are fully specialized in the
specialization, that's OK. */
int j;
for (j = 0; j < nargs; ++j)
if (tpd2.parms[j] != 0
&& tpd.arg_uses_template_parms [j])
{
error ("type `%T' of template argument `%E' depends on template parameter(s)",
type,
arg);
break;
}
}
}
}
}
if (retrieve_specialization (maintmpl, specargs))
/* We've already got this specialization. */
return decl;
DECL_TEMPLATE_SPECIALIZATIONS (maintmpl)
= tree_cons (inner_args, inner_parms,
DECL_TEMPLATE_SPECIALIZATIONS (maintmpl));
TREE_TYPE (DECL_TEMPLATE_SPECIALIZATIONS (maintmpl)) = type;
return decl;
}
/* Check that a template declaration's use of default arguments is not
invalid. Here, PARMS are the template parameters. IS_PRIMARY is
nonzero if DECL is the thing declared by a primary template.
IS_PARTIAL is nonzero if DECL is a partial specialization. */
static void
check_default_tmpl_args (tree decl, tree parms, int is_primary, int is_partial)
{
const char *msg;
int last_level_to_check;
tree parm_level;
/* [temp.param]
A default template-argument shall not be specified in a
function template declaration or a function template definition, nor
in the template-parameter-list of the definition of a member of a
class template. */
if (TREE_CODE (CP_DECL_CONTEXT (decl)) == FUNCTION_DECL)
/* You can't have a function template declaration in a local
scope, nor you can you define a member of a class template in a
local scope. */
return;
if (current_class_type
&& !TYPE_BEING_DEFINED (current_class_type)
&& DECL_LANG_SPECIFIC (decl)
/* If this is either a friend defined in the scope of the class
or a member function. */
&& (DECL_FUNCTION_MEMBER_P (decl)
? same_type_p (DECL_CONTEXT (decl), current_class_type)
: DECL_FRIEND_CONTEXT (decl)
? same_type_p (DECL_FRIEND_CONTEXT (decl), current_class_type)
: false)
/* And, if it was a member function, it really was defined in
the scope of the class. */
&& (!DECL_FUNCTION_MEMBER_P (decl)
|| DECL_INITIALIZED_IN_CLASS_P (decl)))
/* We already checked these parameters when the template was
declared, so there's no need to do it again now. This function
was defined in class scope, but we're processing it's body now
that the class is complete. */
return;
/* [temp.param]
If a template-parameter has a default template-argument, all
subsequent template-parameters shall have a default
template-argument supplied. */
for (parm_level = parms; parm_level; parm_level = TREE_CHAIN (parm_level))
{
tree inner_parms = TREE_VALUE (parm_level);
int ntparms = TREE_VEC_LENGTH (inner_parms);
int seen_def_arg_p = 0;
int i;
for (i = 0; i < ntparms; ++i)
{
tree parm = TREE_VEC_ELT (inner_parms, i);
if (TREE_PURPOSE (parm))
seen_def_arg_p = 1;
else if (seen_def_arg_p)
{
error ("no default argument for `%D'", TREE_VALUE (parm));
/* For better subsequent error-recovery, we indicate that
there should have been a default argument. */
TREE_PURPOSE (parm) = error_mark_node;
}
}
}
if (TREE_CODE (decl) != TYPE_DECL || is_partial || !is_primary)
/* For an ordinary class template, default template arguments are
allowed at the innermost level, e.g.:
template <class T = int>
struct S {};
but, in a partial specialization, they're not allowed even
there, as we have in [temp.class.spec]:
The template parameter list of a specialization shall not
contain default template argument values.
So, for a partial specialization, or for a function template,
we look at all of them. */
;
else
/* But, for a primary class template that is not a partial
specialization we look at all template parameters except the
innermost ones. */
parms = TREE_CHAIN (parms);
/* Figure out what error message to issue. */
if (TREE_CODE (decl) == FUNCTION_DECL)
msg = "default template arguments may not be used in function templates";
else if (is_partial)
msg = "default template arguments may not be used in partial specializations";
else
msg = "default argument for template parameter for class enclosing `%D'";
if (current_class_type && TYPE_BEING_DEFINED (current_class_type))
/* If we're inside a class definition, there's no need to
examine the parameters to the class itself. On the one
hand, they will be checked when the class is defined, and,
on the other, default arguments are valid in things like:
template <class T = double>
struct S { template <class U> void f(U); };
Here the default argument for `S' has no bearing on the
declaration of `f'. */
last_level_to_check = template_class_depth (current_class_type) + 1;
else
/* Check everything. */
last_level_to_check = 0;
for (parm_level = parms;
parm_level && TMPL_PARMS_DEPTH (parm_level) >= last_level_to_check;
parm_level = TREE_CHAIN (parm_level))
{
tree inner_parms = TREE_VALUE (parm_level);
int i;
int ntparms;
ntparms = TREE_VEC_LENGTH (inner_parms);
for (i = 0; i < ntparms; ++i)
if (TREE_PURPOSE (TREE_VEC_ELT (inner_parms, i)))
{
if (msg)
{
error (msg, decl);
msg = 0;
}
/* Clear out the default argument so that we are not
confused later. */
TREE_PURPOSE (TREE_VEC_ELT (inner_parms, i)) = NULL_TREE;
}
/* At this point, if we're still interested in issuing messages,
they must apply to classes surrounding the object declared. */
if (msg)
msg = "default argument for template parameter for class enclosing `%D'";
}
}
/* Worker for push_template_decl_real, called via
for_each_template_parm. DATA is really an int, indicating the
level of the parameters we are interested in. If T is a template
parameter of that level, return nonzero. */
static int
template_parm_this_level_p (tree t, void* data)
{
int this_level = *(int *)data;
int level;
if (TREE_CODE (t) == TEMPLATE_PARM_INDEX)
level = TEMPLATE_PARM_LEVEL (t);
else
level = TEMPLATE_TYPE_LEVEL (t);
return level == this_level;
}
/* Creates a TEMPLATE_DECL for the indicated DECL using the template
parameters given by current_template_args, or reuses a
previously existing one, if appropriate. Returns the DECL, or an
equivalent one, if it is replaced via a call to duplicate_decls.
If IS_FRIEND is nonzero, DECL is a friend declaration. */
tree
push_template_decl_real (tree decl, int is_friend)
{
tree tmpl;
tree args;
tree info;
tree ctx;
int primary;
int is_partial;
int new_template_p = 0;
/* See if this is a partial specialization. */
is_partial = (DECL_IMPLICIT_TYPEDEF_P (decl)
&& TREE_CODE (TREE_TYPE (decl)) != ENUMERAL_TYPE
&& CLASSTYPE_TEMPLATE_SPECIALIZATION (TREE_TYPE (decl)));
is_friend |= (TREE_CODE (decl) == FUNCTION_DECL && DECL_FRIEND_P (decl));
if (is_friend)
/* For a friend, we want the context of the friend function, not
the type of which it is a friend. */
ctx = DECL_CONTEXT (decl);
else if (CP_DECL_CONTEXT (decl)
&& TREE_CODE (CP_DECL_CONTEXT (decl)) != NAMESPACE_DECL)
/* In the case of a virtual function, we want the class in which
it is defined. */
ctx = CP_DECL_CONTEXT (decl);
else
/* Otherwise, if we're currently defining some class, the DECL
is assumed to be a member of the class. */
ctx = current_scope ();
if (ctx && TREE_CODE (ctx) == NAMESPACE_DECL)
ctx = NULL_TREE;
if (!DECL_CONTEXT (decl))
DECL_CONTEXT (decl) = FROB_CONTEXT (current_namespace);
/* See if this is a primary template. */
primary = template_parm_scope_p ();
if (primary)
{
if (current_lang_name == lang_name_c)
error ("template with C linkage");
else if (TREE_CODE (decl) == TYPE_DECL
&& ANON_AGGRNAME_P (DECL_NAME (decl)))
error ("template class without a name");
else if (TREE_CODE (decl) == FUNCTION_DECL
&& DECL_DESTRUCTOR_P (decl))
{
/* [temp.mem]
A destructor shall not be a member template. */
error ("destructor `%D' declared as member template", decl);
return error_mark_node;
}
else if ((DECL_IMPLICIT_TYPEDEF_P (decl)
&& CLASS_TYPE_P (TREE_TYPE (decl)))
|| (TREE_CODE (decl) == VAR_DECL && ctx && CLASS_TYPE_P (ctx))
|| TREE_CODE (decl) == FUNCTION_DECL)
/* OK */;
else
{
error ("template declaration of `%#D'", decl);
return error_mark_node;
}
}
/* Check to see that the rules regarding the use of default
arguments are not being violated. */
check_default_tmpl_args (decl, current_template_parms,
primary, is_partial);
if (is_partial)
return process_partial_specialization (decl);
args = current_template_args ();
if (!ctx
|| TREE_CODE (ctx) == FUNCTION_DECL
|| (CLASS_TYPE_P (ctx) && TYPE_BEING_DEFINED (ctx))
|| (is_friend && !DECL_TEMPLATE_INFO (decl)))
{
if (DECL_LANG_SPECIFIC (decl)
&& DECL_TEMPLATE_INFO (decl)
&& DECL_TI_TEMPLATE (decl))
tmpl = DECL_TI_TEMPLATE (decl);
/* If DECL is a TYPE_DECL for a class-template, then there won't
be DECL_LANG_SPECIFIC. The information equivalent to
DECL_TEMPLATE_INFO is found in TYPE_TEMPLATE_INFO instead. */
else if (DECL_IMPLICIT_TYPEDEF_P (decl)
&& TYPE_TEMPLATE_INFO (TREE_TYPE (decl))
&& TYPE_TI_TEMPLATE (TREE_TYPE (decl)))
{
/* Since a template declaration already existed for this
class-type, we must be redeclaring it here. Make sure
that the redeclaration is valid. */
redeclare_class_template (TREE_TYPE (decl),
current_template_parms);
/* We don't need to create a new TEMPLATE_DECL; just use the
one we already had. */
tmpl = TYPE_TI_TEMPLATE (TREE_TYPE (decl));
}
else
{
tmpl = build_template_decl (decl, current_template_parms);
new_template_p = 1;
if (DECL_LANG_SPECIFIC (decl)
&& DECL_TEMPLATE_SPECIALIZATION (decl))
{
/* A specialization of a member template of a template
class. */
SET_DECL_TEMPLATE_SPECIALIZATION (tmpl);
DECL_TEMPLATE_INFO (tmpl) = DECL_TEMPLATE_INFO (decl);
DECL_TEMPLATE_INFO (decl) = NULL_TREE;
}
}
}
else
{
tree a, t, current, parms;
int i;
if (TREE_CODE (decl) == TYPE_DECL)
{
if ((IS_AGGR_TYPE_CODE (TREE_CODE (TREE_TYPE (decl)))
|| TREE_CODE (TREE_TYPE (decl)) == ENUMERAL_TYPE)
&& TYPE_TEMPLATE_INFO (TREE_TYPE (decl))
&& TYPE_TI_TEMPLATE (TREE_TYPE (decl)))
tmpl = TYPE_TI_TEMPLATE (TREE_TYPE (decl));
else
{
error ("`%D' does not declare a template type", decl);
return decl;
}
}
else if (!DECL_LANG_SPECIFIC (decl) || !DECL_TEMPLATE_INFO (decl))
{
error ("template definition of non-template `%#D'", decl);
return decl;
}
else
tmpl = DECL_TI_TEMPLATE (decl);
if (is_member_template (tmpl)
&& DECL_FUNCTION_TEMPLATE_P (tmpl)
&& DECL_TEMPLATE_INFO (decl) && DECL_TI_ARGS (decl)
&& DECL_TEMPLATE_SPECIALIZATION (decl))
{
tree new_tmpl;
/* The declaration is a specialization of a member
template, declared outside the class. Therefore, the
innermost template arguments will be NULL, so we
replace them with the arguments determined by the
earlier call to check_explicit_specialization. */
args = DECL_TI_ARGS (decl);
new_tmpl
= build_template_decl (decl, current_template_parms);
DECL_TEMPLATE_RESULT (new_tmpl) = decl;
TREE_TYPE (new_tmpl) = TREE_TYPE (decl);
DECL_TI_TEMPLATE (decl) = new_tmpl;
SET_DECL_TEMPLATE_SPECIALIZATION (new_tmpl);
DECL_TEMPLATE_INFO (new_tmpl)
= tree_cons (tmpl, args, NULL_TREE);
register_specialization (new_tmpl,
most_general_template (tmpl),
args);
return decl;
}
/* Make sure the template headers we got make sense. */
parms = DECL_TEMPLATE_PARMS (tmpl);
i = TMPL_PARMS_DEPTH (parms);
if (TMPL_ARGS_DEPTH (args) != i)
{
error ("expected %d levels of template parms for `%#D', got %d",
i, decl, TMPL_ARGS_DEPTH (args));
}
else
for (current = decl; i > 0; --i, parms = TREE_CHAIN (parms))
{
a = TMPL_ARGS_LEVEL (args, i);
t = INNERMOST_TEMPLATE_PARMS (parms);
if (TREE_VEC_LENGTH (t) != TREE_VEC_LENGTH (a))
{
if (current == decl)
error ("got %d template parameters for `%#D'",
TREE_VEC_LENGTH (a), decl);
else
error ("got %d template parameters for `%#T'",
TREE_VEC_LENGTH (a), current);
error (" but %d required", TREE_VEC_LENGTH (t));
}
/* Perhaps we should also check that the parms are used in the
appropriate qualifying scopes in the declarator? */
if (current == decl)
current = ctx;
else
current = TYPE_CONTEXT (current);
}
}
DECL_TEMPLATE_RESULT (tmpl) = decl;
TREE_TYPE (tmpl) = TREE_TYPE (decl);
/* Push template declarations for global functions and types. Note
that we do not try to push a global template friend declared in a
template class; such a thing may well depend on the template
parameters of the class. */
if (new_template_p && !ctx
&& !(is_friend && template_class_depth (current_class_type) > 0))
tmpl = pushdecl_namespace_level (tmpl);
if (primary)
{
DECL_PRIMARY_TEMPLATE (tmpl) = tmpl;
if (DECL_CONV_FN_P (tmpl))
{
int depth = TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (tmpl));
/* It is a conversion operator. See if the type converted to
depends on innermost template operands. */
if (uses_template_parms_level (TREE_TYPE (TREE_TYPE (tmpl)),
depth))
DECL_TEMPLATE_CONV_FN_P (tmpl) = 1;
}
}
info = tree_cons (tmpl, args, NULL_TREE);
if (DECL_IMPLICIT_TYPEDEF_P (decl))
{
SET_TYPE_TEMPLATE_INFO (TREE_TYPE (tmpl), info);
if ((!ctx || TREE_CODE (ctx) != FUNCTION_DECL)
&& TREE_CODE (TREE_TYPE (decl)) != ENUMERAL_TYPE
/* Don't change the name if we've already set it up. */
&& !IDENTIFIER_TEMPLATE (DECL_NAME (decl)))
DECL_NAME (decl) = classtype_mangled_name (TREE_TYPE (decl));
}
else if (DECL_LANG_SPECIFIC (decl))
DECL_TEMPLATE_INFO (decl) = info;
return DECL_TEMPLATE_RESULT (tmpl);
}
tree
push_template_decl (tree decl)
{
return push_template_decl_real (decl, 0);
}
/* Called when a class template TYPE is redeclared with the indicated
template PARMS, e.g.:
template <class T> struct S;
template <class T> struct S {}; */
void
redeclare_class_template (tree type, tree parms)
{
tree tmpl;
tree tmpl_parms;
int i;
if (!TYPE_TEMPLATE_INFO (type))
{
error ("`%T' is not a template type", type);
return;
}
tmpl = TYPE_TI_TEMPLATE (type);
if (!PRIMARY_TEMPLATE_P (tmpl))
/* The type is nested in some template class. Nothing to worry
about here; there are no new template parameters for the nested
type. */
return;
parms = INNERMOST_TEMPLATE_PARMS (parms);
tmpl_parms = DECL_INNERMOST_TEMPLATE_PARMS (tmpl);
if (TREE_VEC_LENGTH (parms) != TREE_VEC_LENGTH (tmpl_parms))
{
cp_error_at ("previous declaration `%D'", tmpl);
error ("used %d template parameter%s instead of %d",
TREE_VEC_LENGTH (tmpl_parms),
TREE_VEC_LENGTH (tmpl_parms) == 1 ? "" : "s",
TREE_VEC_LENGTH (parms));
return;
}
for (i = 0; i < TREE_VEC_LENGTH (tmpl_parms); ++i)
{
tree tmpl_parm = TREE_VALUE (TREE_VEC_ELT (tmpl_parms, i));
tree parm = TREE_VALUE (TREE_VEC_ELT (parms, i));
tree tmpl_default = TREE_PURPOSE (TREE_VEC_ELT (tmpl_parms, i));
tree parm_default = TREE_PURPOSE (TREE_VEC_ELT (parms, i));
if (TREE_CODE (tmpl_parm) != TREE_CODE (parm))
{
cp_error_at ("template parameter `%#D'", tmpl_parm);
error ("redeclared here as `%#D'", parm);
return;
}
if (tmpl_default != NULL_TREE && parm_default != NULL_TREE)
{
/* We have in [temp.param]:
A template-parameter may not be given default arguments
by two different declarations in the same scope. */
error ("redefinition of default argument for `%#D'", parm);
error ("%J original definition appeared here", tmpl_parm);
return;
}
if (parm_default != NULL_TREE)
/* Update the previous template parameters (which are the ones
that will really count) with the new default value. */
TREE_PURPOSE (TREE_VEC_ELT (tmpl_parms, i)) = parm_default;
else if (tmpl_default != NULL_TREE)
/* Update the new parameters, too; they'll be used as the
parameters for any members. */
TREE_PURPOSE (TREE_VEC_ELT (parms, i)) = tmpl_default;
}
}
/* Attempt to convert the non-type template parameter EXPR to the
indicated TYPE. If the conversion is successful, return the
converted value. If the conversion is unsuccessful, return
NULL_TREE if we issued an error message, or error_mark_node if we
did not. We issue error messages for out-and-out bad template
parameters, but not simply because the conversion failed, since we
might be just trying to do argument deduction. By the time this
function is called, neither TYPE nor EXPR may make use of template
parameters. */
static tree
convert_nontype_argument (tree type, tree expr)
{
tree expr_type = TREE_TYPE (expr);
/* A template-argument for a non-type, non-template
template-parameter shall be one of:
--an integral constant-expression of integral or enumeration
type; or
--the name of a non-type template-parameter; or
--the name of an object or function with external linkage,
including function templates and function template-ids but
excluding non-static class members, expressed as id-expression;
or
--the address of an object or function with external linkage,
including function templates and function template-ids but
excluding non-static class members, expressed as & id-expression
where the & is optional if the name refers to a function or
array; or
--a pointer to member expressed as described in _expr.unary.op_. */
/* An integral constant-expression can include const variables or
enumerators. Simplify things by folding them to their values,
unless we're about to bind the declaration to a reference
parameter. */
if (INTEGRAL_TYPE_P (expr_type)
&& TREE_CODE (type) != REFERENCE_TYPE)
expr = decl_constant_value (expr);
if (is_overloaded_fn (expr))
/* OK for now. We'll check that it has external linkage later.
Check this first since if expr_type is the unknown_type_node
we would otherwise complain below. */
;
else if (TYPE_PTR_TO_MEMBER_P (expr_type))
{
if (TREE_CODE (expr) != PTRMEM_CST)
goto bad_argument;
}
else if (TYPE_PTR_P (expr_type)
|| TREE_CODE (expr_type) == ARRAY_TYPE
|| TREE_CODE (type) == REFERENCE_TYPE
/* If expr is the address of an overloaded function, we
will get the unknown_type_node at this point. */
|| expr_type == unknown_type_node)
{
tree referent;
tree e = expr;
STRIP_NOPS (e);
if (TREE_CODE (expr_type) == ARRAY_TYPE
|| (TREE_CODE (type) == REFERENCE_TYPE
&& TREE_CODE (e) != ADDR_EXPR))
referent = e;
else
{
if (TREE_CODE (e) != ADDR_EXPR)
{
bad_argument:
error ("`%E' is not a valid template argument", expr);
if (TYPE_PTR_P (expr_type))
{
if (TREE_CODE (TREE_TYPE (expr_type)) == FUNCTION_TYPE)
error ("it must be the address of a function with external linkage");
else
error ("it must be the address of an object with external linkage");
}
else if (TYPE_PTR_TO_MEMBER_P (expr_type))
error ("it must be a pointer-to-member of the form `&X::Y'");
return NULL_TREE;
}
referent = TREE_OPERAND (e, 0);
STRIP_NOPS (referent);
}
if (TREE_CODE (referent) == STRING_CST)
{
error ("string literal %E is not a valid template argument because it is the address of an object with static linkage",
referent);
return NULL_TREE;
}
if (TREE_CODE (referent) == SCOPE_REF)
referent = TREE_OPERAND (referent, 1);
if (is_overloaded_fn (referent))
/* We'll check that it has external linkage later. */
;
else if (TREE_CODE (referent) != VAR_DECL)
goto bad_argument;
else if (!DECL_EXTERNAL_LINKAGE_P (referent))
{
error ("address of non-extern `%E' cannot be used as template argument", referent);
return error_mark_node;
}
}
else if (INTEGRAL_TYPE_P (expr_type) || TYPE_PTR_TO_MEMBER_P (expr_type))
{
if (! TREE_CONSTANT (expr))
{
non_constant:
error ("non-constant `%E' cannot be used as template argument",
expr);
return NULL_TREE;
}
}
else
{
if (TYPE_P (expr))
error ("type '%T' cannot be used as a value for a non-type "
"template-parameter", expr);
else if (DECL_P (expr))
error ("invalid use of '%D' as a non-type template-argument", expr);
else
error ("invalid use of '%E' as a non-type template-argument", expr);
return NULL_TREE;
}
switch (TREE_CODE (type))
{
case INTEGER_TYPE:
case BOOLEAN_TYPE:
case ENUMERAL_TYPE:
/* For a non-type template-parameter of integral or enumeration
type, integral promotions (_conv.prom_) and integral
conversions (_conv.integral_) are applied. */
if (!INTEGRAL_TYPE_P (expr_type))
return error_mark_node;
/* It's safe to call digest_init in this case; we know we're
just converting one integral constant expression to another. */
expr = digest_init (type, expr, (tree*) 0);
if (TREE_CODE (expr) != INTEGER_CST)
/* Curiously, some TREE_CONSTANT integral expressions do not
simplify to integer constants. For example, `3 % 0',
remains a TRUNC_MOD_EXPR. */
goto non_constant;
return expr;
case OFFSET_TYPE:
{
tree e;
/* For a non-type template-parameter of type pointer to data
member, qualification conversions (_conv.qual_) are
applied. */
e = perform_qualification_conversions (type, expr);
if (TREE_CODE (e) == NOP_EXPR)
/* The call to perform_qualification_conversions will
insert a NOP_EXPR over EXPR to do express conversion,
if necessary. But, that will confuse us if we use
this (converted) template parameter to instantiate
another template; then the thing will not look like a
valid template argument. So, just make a new
constant, of the appropriate type. */
e = make_ptrmem_cst (type, PTRMEM_CST_MEMBER (expr));
return e;
}
case POINTER_TYPE:
{
tree type_pointed_to = TREE_TYPE (type);
if (TREE_CODE (type_pointed_to) == FUNCTION_TYPE)
{
/* For a non-type template-parameter of type pointer to
function, only the function-to-pointer conversion
(_conv.func_) is applied. If the template-argument
represents a set of overloaded functions (or a pointer to
such), the matching function is selected from the set
(_over.over_). */
tree fns;
tree fn;
if (TREE_CODE (expr) == ADDR_EXPR)
fns = TREE_OPERAND (expr, 0);
else
fns = expr;
fn = instantiate_type (type_pointed_to, fns, tf_none);
if (fn == error_mark_node)
return error_mark_node;
if (!DECL_EXTERNAL_LINKAGE_P (fn))
{
if (really_overloaded_fn (fns))
return error_mark_node;
else
goto bad_argument;
}
expr = build_unary_op (ADDR_EXPR, fn, 0);
my_friendly_assert (same_type_p (type, TREE_TYPE (expr)),
0);
return expr;
}
else
{
/* For a non-type template-parameter of type pointer to
object, qualification conversions (_conv.qual_) and the
array-to-pointer conversion (_conv.array_) are applied.
[Note: In particular, neither the null pointer conversion
(_conv.ptr_) nor the derived-to-base conversion
(_conv.ptr_) are applied. Although 0 is a valid
template-argument for a non-type template-parameter of
integral type, it is not a valid template-argument for a
non-type template-parameter of pointer type.]
The call to decay_conversion performs the
array-to-pointer conversion, if appropriate. */
expr = decay_conversion (expr);
if (expr == error_mark_node)
return error_mark_node;
else
return perform_qualification_conversions (type, expr);
}
}
break;
case REFERENCE_TYPE:
{
tree type_referred_to = TREE_TYPE (type);
/* If this expression already has reference type, get the
underlying object. */
if (TREE_CODE (expr_type) == REFERENCE_TYPE)
{
if (TREE_CODE (expr) == NOP_EXPR
&& TREE_CODE (TREE_OPERAND (expr, 0)) == ADDR_EXPR)
STRIP_NOPS (expr);
my_friendly_assert (TREE_CODE (expr) == ADDR_EXPR, 20000604);
expr = TREE_OPERAND (expr, 0);
expr_type = TREE_TYPE (expr);
}
if (TREE_CODE (type_referred_to) == FUNCTION_TYPE)
{
/* For a non-type template-parameter of type reference to
function, no conversions apply. If the
template-argument represents a set of overloaded
functions, the matching function is selected from the
set (_over.over_). */
tree fn;
fn = instantiate_type (type_referred_to, expr, tf_none);
if (fn == error_mark_node)
return error_mark_node;
if (!DECL_EXTERNAL_LINKAGE_P (fn))
{
if (really_overloaded_fn (expr))
/* Don't issue an error here; we might get a different
function if the overloading had worked out
differently. */
return error_mark_node;
else
goto bad_argument;
}
my_friendly_assert (same_type_p (type_referred_to,
TREE_TYPE (fn)),
0);
expr = fn;
}
else
{
/* For a non-type template-parameter of type reference to
object, no conversions apply. The type referred to by the
reference may be more cv-qualified than the (otherwise
identical) type of the template-argument. The
template-parameter is bound directly to the
template-argument, which must be an lvalue. */
if (!same_type_p (TYPE_MAIN_VARIANT (expr_type),
TYPE_MAIN_VARIANT (type_referred_to))
|| !at_least_as_qualified_p (type_referred_to,
expr_type)
|| !real_lvalue_p (expr))
return error_mark_node;
}
cxx_mark_addressable (expr);
return build_nop (type, build_address (expr));
}
break;
case RECORD_TYPE:
{
my_friendly_assert (TYPE_PTRMEMFUNC_P (type), 20010112);
/* For a non-type template-parameter of type pointer to member
function, no conversions apply. If the template-argument
represents a set of overloaded member functions, the
matching member function is selected from the set
(_over.over_). */
if (!TYPE_PTRMEMFUNC_P (expr_type) &&
expr_type != unknown_type_node)
return error_mark_node;
if (TREE_CODE (expr) == PTRMEM_CST)
{
/* A ptr-to-member constant. */
if (!same_type_p (type, expr_type))
return error_mark_node;
else
return expr;
}
if (TREE_CODE (expr) != ADDR_EXPR)
return error_mark_node;
expr = instantiate_type (type, expr, tf_none);
if (expr == error_mark_node)
return error_mark_node;
if (!same_type_p (type, TREE_TYPE (expr)))
return error_mark_node;
return expr;
}
break;
default:
/* All non-type parameters must have one of these types. */
abort ();
break;
}
return error_mark_node;
}
/* Return 1 if PARM_PARMS and ARG_PARMS matches using rule for
template template parameters. Both PARM_PARMS and ARG_PARMS are
vectors of TREE_LIST nodes containing TYPE_DECL, TEMPLATE_DECL
or PARM_DECL.
ARG_PARMS may contain more parameters than PARM_PARMS. If this is
the case, then extra parameters must have default arguments.
Consider the example:
template <class T, class Allocator = allocator> class vector;
template<template <class U> class TT> class C;
C<vector> is a valid instantiation. PARM_PARMS for the above code
contains a TYPE_DECL (for U), ARG_PARMS contains two TYPE_DECLs (for
T and Allocator) and OUTER_ARGS contains the argument that is used to
substitute the TT parameter. */
static int
coerce_template_template_parms (tree parm_parms,
tree arg_parms,
tsubst_flags_t complain,
tree in_decl,
tree outer_args)
{
int nparms, nargs, i;
tree parm, arg;
my_friendly_assert (TREE_CODE (parm_parms) == TREE_VEC, 0);
my_friendly_assert (TREE_CODE (arg_parms) == TREE_VEC, 0);
nparms = TREE_VEC_LENGTH (parm_parms);
nargs = TREE_VEC_LENGTH (arg_parms);
/* The rule here is opposite of coerce_template_parms. */
if (nargs < nparms
|| (nargs > nparms
&& TREE_PURPOSE (TREE_VEC_ELT (arg_parms, nparms)) == NULL_TREE))
return 0;
for (i = 0; i < nparms; ++i)
{
parm = TREE_VALUE (TREE_VEC_ELT (parm_parms, i));
arg = TREE_VALUE (TREE_VEC_ELT (arg_parms, i));
if (arg == NULL_TREE || arg == error_mark_node
|| parm == NULL_TREE || parm == error_mark_node)
return 0;
if (TREE_CODE (arg) != TREE_CODE (parm))
return 0;
switch (TREE_CODE (parm))
{
case TYPE_DECL:
break;
case TEMPLATE_DECL:
/* We encounter instantiations of templates like
template <template <template <class> class> class TT>
class C; */
{
tree parmparm = DECL_INNERMOST_TEMPLATE_PARMS (parm);
tree argparm = DECL_INNERMOST_TEMPLATE_PARMS (arg);
if (!coerce_template_template_parms
(parmparm, argparm, complain, in_decl, outer_args))
return 0;
}
break;
case PARM_DECL:
/* The tsubst call is used to handle cases such as
template <class T, template <T> class TT> class D;
i.e. the parameter list of TT depends on earlier parameters. */
if (!same_type_p
(tsubst (TREE_TYPE (parm), outer_args, complain, in_decl),
TREE_TYPE (arg)))
return 0;
break;
default:
abort ();
}
}
return 1;
}
/* Convert the indicated template ARG as necessary to match the
indicated template PARM. Returns the converted ARG, or
error_mark_node if the conversion was unsuccessful. Error and
warning messages are issued under control of COMPLAIN. This
conversion is for the Ith parameter in the parameter list. ARGS is
the full set of template arguments deduced so far. */
static tree
convert_template_argument (tree parm,
tree arg,
tree args,
tsubst_flags_t complain,
int i,
tree in_decl)
{
tree val;
tree inner_args;
int is_type, requires_type, is_tmpl_type, requires_tmpl_type;
inner_args = INNERMOST_TEMPLATE_ARGS (args);
if (TREE_CODE (arg) == TREE_LIST
&& TREE_CODE (TREE_VALUE (arg)) == OFFSET_REF)
{
/* The template argument was the name of some
member function. That's usually
invalid, but static members are OK. In any
case, grab the underlying fields/functions
and issue an error later if required. */
arg = TREE_VALUE (arg);
TREE_TYPE (arg) = unknown_type_node;
}
requires_tmpl_type = TREE_CODE (parm) == TEMPLATE_DECL;
requires_type = (TREE_CODE (parm) == TYPE_DECL
|| requires_tmpl_type);
is_tmpl_type = ((TREE_CODE (arg) == TEMPLATE_DECL
&& TREE_CODE (DECL_TEMPLATE_RESULT (arg)) == TYPE_DECL)
|| TREE_CODE (arg) == TEMPLATE_TEMPLATE_PARM
|| TREE_CODE (arg) == UNBOUND_CLASS_TEMPLATE);
if (is_tmpl_type
&& (TREE_CODE (arg) == TEMPLATE_TEMPLATE_PARM
|| TREE_CODE (arg) == UNBOUND_CLASS_TEMPLATE))
arg = TYPE_STUB_DECL (arg);
is_type = TYPE_P (arg) || is_tmpl_type;
if (requires_type && ! is_type && TREE_CODE (arg) == SCOPE_REF
&& TREE_CODE (TREE_OPERAND (arg, 0)) == TEMPLATE_TYPE_PARM)
{
pedwarn ("to refer to a type member of a template parameter, use `typename %E'", arg);
arg = make_typename_type (TREE_OPERAND (arg, 0),
TREE_OPERAND (arg, 1),
complain & tf_error);
is_type = 1;
}
if (is_type != requires_type)
{
if (in_decl)
{
if (complain & tf_error)
{
error ("type/value mismatch at argument %d in template parameter list for `%D'",
i + 1, in_decl);
if (is_type)
error (" expected a constant of type `%T', got `%T'",
TREE_TYPE (parm),
(is_tmpl_type ? DECL_NAME (arg) : arg));
else if (requires_tmpl_type)
error (" expected a class template, got `%E'", arg);
else
error (" expected a type, got `%E'", arg);
}
}
return error_mark_node;
}
if (is_tmpl_type ^ requires_tmpl_type)
{
if (in_decl && (complain & tf_error))
{
error ("type/value mismatch at argument %d in template parameter list for `%D'",
i + 1, in_decl);
if (is_tmpl_type)
error (" expected a type, got `%T'", DECL_NAME (arg));
else
error (" expected a class template, got `%T'", arg);
}
return error_mark_node;
}
if (is_type)
{
if (requires_tmpl_type)
{
if (TREE_CODE (TREE_TYPE (arg)) == UNBOUND_CLASS_TEMPLATE)
/* The number of argument required is not known yet.
Just accept it for now. */
val = TREE_TYPE (arg);
else
{
tree parmparm = DECL_INNERMOST_TEMPLATE_PARMS (parm);
tree argparm = DECL_INNERMOST_TEMPLATE_PARMS (arg);
if (coerce_template_template_parms (parmparm, argparm,
complain, in_decl,
inner_args))
{
val = arg;
/* TEMPLATE_TEMPLATE_PARM node is preferred over
TEMPLATE_DECL. */
if (val != error_mark_node
&& DECL_TEMPLATE_TEMPLATE_PARM_P (val))
val = TREE_TYPE (val);
}
else
{
if (in_decl && (complain & tf_error))
{
error ("type/value mismatch at argument %d in template parameter list for `%D'",
i + 1, in_decl);
error (" expected a template of type `%D', got `%D'", parm, arg);
}
val = error_mark_node;
}
}
}
else
val = groktypename (arg);
}
else
{
tree t = tsubst (TREE_TYPE (parm), args, complain, in_decl);
if (invalid_nontype_parm_type_p (t, complain))
return error_mark_node;
if (!uses_template_parms (arg) && !uses_template_parms (t))
/* We used to call digest_init here. However, digest_init
will report errors, which we don't want when complain
is zero. More importantly, digest_init will try too
hard to convert things: for example, `0' should not be
converted to pointer type at this point according to
the standard. Accepting this is not merely an
extension, since deciding whether or not these
conversions can occur is part of determining which
function template to call, or whether a given explicit
argument specification is valid. */
val = convert_nontype_argument (t, arg);
else
val = arg;
if (val == NULL_TREE)
val = error_mark_node;
else if (val == error_mark_node && (complain & tf_error))
error ("could not convert template argument `%E' to `%T'",
arg, t);
}
return val;
}
/* Convert all template arguments to their appropriate types, and
return a vector containing the innermost resulting template
arguments. If any error occurs, return error_mark_node. Error and
warning messages are issued under control of COMPLAIN.
If REQUIRE_ALL_ARGUMENTS is nonzero, all arguments must be
provided in ARGLIST, or else trailing parameters must have default
values. If REQUIRE_ALL_ARGUMENTS is zero, we will attempt argument
deduction for any unspecified trailing arguments. */
static tree
coerce_template_parms (tree parms,
tree args,
tree in_decl,
tsubst_flags_t complain,
int require_all_arguments)
{
int nparms, nargs, i, lost = 0;
tree inner_args;
tree new_args;
tree new_inner_args;
inner_args = INNERMOST_TEMPLATE_ARGS (args);
nargs = inner_args ? NUM_TMPL_ARGS (inner_args) : 0;
nparms = TREE_VEC_LENGTH (parms);
if (nargs > nparms
|| (nargs < nparms
&& require_all_arguments
&& TREE_PURPOSE (TREE_VEC_ELT (parms, nargs)) == NULL_TREE))
{
if (complain & tf_error)
{
error ("wrong number of template arguments (%d, should be %d)",
nargs, nparms);
if (in_decl)
cp_error_at ("provided for `%D'", in_decl);
}
return error_mark_node;
}
new_inner_args = make_tree_vec (nparms);
new_args = add_outermost_template_args (args, new_inner_args);
for (i = 0; i < nparms; i++)
{
tree arg;
tree parm;
/* Get the Ith template parameter. */
parm = TREE_VEC_ELT (parms, i);
/* Calculate the Ith argument. */
if (i < nargs)
arg = TREE_VEC_ELT (inner_args, i);
else if (require_all_arguments)
/* There must be a default arg in this case. */
arg = tsubst_template_arg (TREE_PURPOSE (parm), new_args,
complain, in_decl);
else
break;
my_friendly_assert (arg, 20030727);
if (arg == error_mark_node)
error ("template argument %d is invalid", i + 1);
else
arg = convert_template_argument (TREE_VALUE (parm),
arg, new_args, complain, i,
in_decl);
if (arg == error_mark_node)
lost++;
TREE_VEC_ELT (new_inner_args, i) = arg;
}
if (lost)
return error_mark_node;
return new_inner_args;
}
/* Returns 1 if template args OT and NT are equivalent. */
static int
template_args_equal (tree ot, tree nt)
{
if (nt == ot)
return 1;
if (TREE_CODE (nt) == TREE_VEC)
/* For member templates */
return TREE_CODE (ot) == TREE_VEC && comp_template_args (ot, nt);
else if (TYPE_P (nt))
return TYPE_P (ot) && same_type_p (ot, nt);
else if (TREE_CODE (ot) == TREE_VEC || TYPE_P (ot))
return 0;
else
return cp_tree_equal (ot, nt);
}
/* Returns 1 iff the OLDARGS and NEWARGS are in fact identical sets
of template arguments. Returns 0 otherwise. */
int
comp_template_args (tree oldargs, tree newargs)
{
int i;
if (TREE_VEC_LENGTH (oldargs) != TREE_VEC_LENGTH (newargs))
return 0;
for (i = 0; i < TREE_VEC_LENGTH (oldargs); ++i)
{
tree nt = TREE_VEC_ELT (newargs, i);
tree ot = TREE_VEC_ELT (oldargs, i);
if (! template_args_equal (ot, nt))
return 0;
}
return 1;
}
/* Given class template name and parameter list, produce a user-friendly name
for the instantiation. */
static char *
mangle_class_name_for_template (const char* name, tree parms, tree arglist)
{
static struct obstack scratch_obstack;
static char *scratch_firstobj;
int i, nparms;
if (!scratch_firstobj)
gcc_obstack_init (&scratch_obstack);
else
obstack_free (&scratch_obstack, scratch_firstobj);
scratch_firstobj = obstack_alloc (&scratch_obstack, 1);
#define ccat(C) obstack_1grow (&scratch_obstack, (C));
#define cat(S) obstack_grow (&scratch_obstack, (S), strlen (S))
cat (name);
ccat ('<');
nparms = TREE_VEC_LENGTH (parms);
arglist = INNERMOST_TEMPLATE_ARGS (arglist);
my_friendly_assert (nparms == TREE_VEC_LENGTH (arglist), 268);
for (i = 0; i < nparms; i++)
{
tree parm = TREE_VALUE (TREE_VEC_ELT (parms, i));
tree arg = TREE_VEC_ELT (arglist, i);
if (i)
ccat (',');
if (TREE_CODE (parm) == TYPE_DECL)
{
cat (type_as_string (arg, TFF_CHASE_TYPEDEF));
continue;
}
else if (TREE_CODE (parm) == TEMPLATE_DECL)
{
if (TREE_CODE (arg) == TEMPLATE_DECL)
{
/* Already substituted with real template. Just output
the template name here */
tree context = DECL_CONTEXT (arg);
if (context)
{
/* The template may be defined in a namespace, or
may be a member template. */
my_friendly_assert (TREE_CODE (context) == NAMESPACE_DECL
|| CLASS_TYPE_P (context),
980422);
cat(decl_as_string (DECL_CONTEXT (arg), TFF_PLAIN_IDENTIFIER));
cat("::");
}
cat (IDENTIFIER_POINTER (DECL_NAME (arg)));
}
else
/* Output the parameter declaration */
cat (type_as_string (arg, TFF_CHASE_TYPEDEF));
continue;
}
else
my_friendly_assert (TREE_CODE (parm) == PARM_DECL, 269);
/* No need to check arglist against parmlist here; we did that
in coerce_template_parms, called from lookup_template_class. */
cat (expr_as_string (arg, TFF_PLAIN_IDENTIFIER));
}
{
char *bufp = obstack_next_free (&scratch_obstack);
int offset = 0;
while (bufp[offset - 1] == ' ')
offset--;
obstack_blank_fast (&scratch_obstack, offset);
/* B<C<char> >, not B<C<char>> */
if (bufp[offset - 1] == '>')
ccat (' ');
}
ccat ('>');
ccat ('\0');
return (char *) obstack_base (&scratch_obstack);
}
static tree
classtype_mangled_name (tree t)
{
if (CLASSTYPE_TEMPLATE_INFO (t)
/* Specializations have already had their names set up in
lookup_template_class. */
&& !CLASSTYPE_TEMPLATE_SPECIALIZATION (t))
{
tree tmpl = most_general_template (CLASSTYPE_TI_TEMPLATE (t));
/* For non-primary templates, the template parameters are
implicit from their surrounding context. */
if (PRIMARY_TEMPLATE_P (tmpl))
{
tree name = DECL_NAME (tmpl);
char *mangled_name = mangle_class_name_for_template
(IDENTIFIER_POINTER (name),
DECL_INNERMOST_TEMPLATE_PARMS (tmpl),
CLASSTYPE_TI_ARGS (t));
tree id = get_identifier (mangled_name);
IDENTIFIER_TEMPLATE (id) = name;
return id;
}
}
return TYPE_IDENTIFIER (t);
}
static void
add_pending_template (tree d)
{
tree ti = (TYPE_P (d)
? CLASSTYPE_TEMPLATE_INFO (d)
: DECL_TEMPLATE_INFO (d));
tree pt;
int level;
if (TI_PENDING_TEMPLATE_FLAG (ti))
return;
/* We are called both from instantiate_decl, where we've already had a
tinst_level pushed, and instantiate_template, where we haven't.
Compensate. */
level = !(current_tinst_level && TINST_DECL (current_tinst_level) == d);
if (level)
push_tinst_level (d);
pt = tree_cons (current_tinst_level, d, NULL_TREE);
if (last_pending_template)
TREE_CHAIN (last_pending_template) = pt;
else
pending_templates = pt;
last_pending_template = pt;
TI_PENDING_TEMPLATE_FLAG (ti) = 1;
if (level)
pop_tinst_level ();
}
/* Return a TEMPLATE_ID_EXPR corresponding to the indicated FNS and
ARGLIST. Valid choices for FNS are given in the cp-tree.def
documentation for TEMPLATE_ID_EXPR. */
tree
lookup_template_function (tree fns, tree arglist)
{
tree type;
if (fns == error_mark_node || arglist == error_mark_node)
return error_mark_node;
my_friendly_assert (!arglist || TREE_CODE (arglist) == TREE_VEC, 20030726);
if (fns == NULL_TREE
|| TREE_CODE (fns) == FUNCTION_DECL)
{
error ("non-template used as template");
return error_mark_node;
}
my_friendly_assert (TREE_CODE (fns) == TEMPLATE_DECL
|| TREE_CODE (fns) == OVERLOAD
|| BASELINK_P (fns)
|| TREE_CODE (fns) == IDENTIFIER_NODE,
20020730);
if (BASELINK_P (fns))
{
BASELINK_FUNCTIONS (fns) = build (TEMPLATE_ID_EXPR,
unknown_type_node,
BASELINK_FUNCTIONS (fns),
arglist);
return fns;
}
type = TREE_TYPE (fns);
if (TREE_CODE (fns) == OVERLOAD || !type)
type = unknown_type_node;
return build (TEMPLATE_ID_EXPR, type, fns, arglist);
}
/* Within the scope of a template class S<T>, the name S gets bound
(in build_self_reference) to a TYPE_DECL for the class, not a
TEMPLATE_DECL. If DECL is a TYPE_DECL for current_class_type,
or one of its enclosing classes, and that type is a template,
return the associated TEMPLATE_DECL. Otherwise, the original
DECL is returned. */
tree
maybe_get_template_decl_from_type_decl (tree decl)
{
return (decl != NULL_TREE
&& TREE_CODE (decl) == TYPE_DECL
&& DECL_ARTIFICIAL (decl)
&& CLASS_TYPE_P (TREE_TYPE (decl))
&& CLASSTYPE_TEMPLATE_INFO (TREE_TYPE (decl)))
? CLASSTYPE_TI_TEMPLATE (TREE_TYPE (decl)) : decl;
}
/* Given an IDENTIFIER_NODE (type TEMPLATE_DECL) and a chain of
parameters, find the desired type.
D1 is the PTYPENAME terminal, and ARGLIST is the list of arguments.
IN_DECL, if non-NULL, is the template declaration we are trying to
instantiate.
If ENTERING_SCOPE is nonzero, we are about to enter the scope of
the class we are looking up.
Issue error and warning messages under control of COMPLAIN.
If the template class is really a local class in a template
function, then the FUNCTION_CONTEXT is the function in which it is
being instantiated. */
tree
lookup_template_class (tree d1,
tree arglist,
tree in_decl,
tree context,
int entering_scope,
tsubst_flags_t complain)
{
tree template = NULL_TREE, parmlist;
tree t;
timevar_push (TV_NAME_LOOKUP);
if (TREE_CODE (d1) == IDENTIFIER_NODE)
{
if (IDENTIFIER_VALUE (d1)
&& DECL_TEMPLATE_TEMPLATE_PARM_P (IDENTIFIER_VALUE (d1)))
template = IDENTIFIER_VALUE (d1);
else
{
if (context)
push_decl_namespace (context);
template = lookup_name (d1, /*prefer_type=*/0);
template = maybe_get_template_decl_from_type_decl (template);
if (context)
pop_decl_namespace ();
}
if (template)
context = DECL_CONTEXT (template);
}
else if (TREE_CODE (d1) == TYPE_DECL && IS_AGGR_TYPE (TREE_TYPE (d1)))
{
tree type = TREE_TYPE (d1);
/* If we are declaring a constructor, say A<T>::A<T>, we will get
an implicit typename for the second A. Deal with it. */
if (TREE_CODE (type) == TYPENAME_TYPE && TREE_TYPE (type))
type = TREE_TYPE (type);
if (CLASSTYPE_TEMPLATE_INFO (type))
{
template = CLASSTYPE_TI_TEMPLATE (type);
d1 = DECL_NAME (template);
}
}
else if (TREE_CODE (d1) == ENUMERAL_TYPE
|| (TYPE_P (d1) && IS_AGGR_TYPE (d1)))
{
template = TYPE_TI_TEMPLATE (d1);
d1 = DECL_NAME (template);
}
else if (TREE_CODE (d1) == TEMPLATE_DECL
&& TREE_CODE (DECL_TEMPLATE_RESULT (d1)) == TYPE_DECL)
{
template = d1;
d1 = DECL_NAME (template);
context = DECL_CONTEXT (template);
}
/* With something like `template <class T> class X class X { ... };'
we could end up with D1 having nothing but an IDENTIFIER_VALUE.
We don't want to do that, but we have to deal with the situation,
so let's give them some syntax errors to chew on instead of a
crash. Alternatively D1 might not be a template type at all. */
if (! template)
{
if (complain & tf_error)
error ("`%T' is not a template", d1);
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, error_mark_node);
}
if (TREE_CODE (template) != TEMPLATE_DECL
/* Make sure it's a user visible template, if it was named by
the user. */
|| ((complain & tf_user) && !DECL_TEMPLATE_PARM_P (template)
&& !PRIMARY_TEMPLATE_P (template)))
{
if (complain & tf_error)
{
error ("non-template type `%T' used as a template", d1);
if (in_decl)
cp_error_at ("for template declaration `%D'", in_decl);
}
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, error_mark_node);
}
complain &= ~tf_user;
if (DECL_TEMPLATE_TEMPLATE_PARM_P (template))
{
/* Create a new TEMPLATE_DECL and TEMPLATE_TEMPLATE_PARM node to store
template arguments */
tree parm;
tree arglist2;
parmlist = DECL_INNERMOST_TEMPLATE_PARMS (template);
/* Consider an example where a template template parameter declared as
template <class T, class U = std::allocator<T> > class TT
The template parameter level of T and U are one level larger than
of TT. To proper process the default argument of U, say when an
instantiation `TT<int>' is seen, we need to build the full
arguments containing {int} as the innermost level. Outer levels,
available when not appearing as default template argument, can be
obtained from `current_template_args ()'.
Suppose that TT is later substituted with std::vector. The above
instantiation is `TT<int, std::allocator<T> >' with TT at
level 1, and T at level 2, while the template arguments at level 1
becomes {std::vector} and the inner level 2 is {int}. */
if (current_template_parms)
arglist = add_to_template_args (current_template_args (), arglist);
arglist2 = coerce_template_parms (parmlist, arglist, template,
complain, /*require_all_args=*/1);
if (arglist2 == error_mark_node
|| (!uses_template_parms (arglist2)
&& check_instantiated_args (template, arglist2, complain)))
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, error_mark_node);
parm = bind_template_template_parm (TREE_TYPE (template), arglist2);
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, parm);
}
else
{
tree template_type = TREE_TYPE (template);
tree gen_tmpl;
tree type_decl;
tree found = NULL_TREE;
tree *tp;
int arg_depth;
int parm_depth;
int is_partial_instantiation;
gen_tmpl = most_general_template (template);
parmlist = DECL_TEMPLATE_PARMS (gen_tmpl);
parm_depth = TMPL_PARMS_DEPTH (parmlist);
arg_depth = TMPL_ARGS_DEPTH (arglist);
if (arg_depth == 1 && parm_depth > 1)
{
/* We've been given an incomplete set of template arguments.
For example, given:
template <class T> struct S1 {
template <class U> struct S2 {};
template <class U> struct S2<U*> {};
};
we will be called with an ARGLIST of `U*', but the
TEMPLATE will be `template <class T> template
<class U> struct S1<T>::S2'. We must fill in the missing
arguments. */
arglist
= add_outermost_template_args (TYPE_TI_ARGS (TREE_TYPE (template)),
arglist);
arg_depth = TMPL_ARGS_DEPTH (arglist);
}
/* Now we should have enough arguments. */
my_friendly_assert (parm_depth == arg_depth, 0);
/* From here on, we're only interested in the most general
template. */
template = gen_tmpl;
/* Calculate the BOUND_ARGS. These will be the args that are
actually tsubst'd into the definition to create the
instantiation. */
if (parm_depth > 1)
{
/* We have multiple levels of arguments to coerce, at once. */
int i;
int saved_depth = TMPL_ARGS_DEPTH (arglist);
tree bound_args = make_tree_vec (parm_depth);
for (i = saved_depth,
t = DECL_TEMPLATE_PARMS (template);
i > 0 && t != NULL_TREE;
--i, t = TREE_CHAIN (t))
{
tree a = coerce_template_parms (TREE_VALUE (t),
arglist, template,
complain, /*require_all_args=*/1);
/* Don't process further if one of the levels fails. */
if (a == error_mark_node)
{
/* Restore the ARGLIST to its full size. */
TREE_VEC_LENGTH (arglist) = saved_depth;
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, error_mark_node);
}
SET_TMPL_ARGS_LEVEL (bound_args, i, a);
/* We temporarily reduce the length of the ARGLIST so
that coerce_template_parms will see only the arguments
corresponding to the template parameters it is
examining. */
TREE_VEC_LENGTH (arglist)--;
}
/* Restore the ARGLIST to its full size. */
TREE_VEC_LENGTH (arglist) = saved_depth;
arglist = bound_args;
}
else
arglist
= coerce_template_parms (INNERMOST_TEMPLATE_PARMS (parmlist),
INNERMOST_TEMPLATE_ARGS (arglist),
template,
complain, /*require_all_args=*/1);
if (arglist == error_mark_node
|| (!uses_template_parms (INNERMOST_TEMPLATE_ARGS (arglist))
&& check_instantiated_args (template,
INNERMOST_TEMPLATE_ARGS (arglist),
complain)))
/* We were unable to bind the arguments. */
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, error_mark_node);
/* In the scope of a template class, explicit references to the
template class refer to the type of the template, not any
instantiation of it. For example, in:
template <class T> class C { void f(C<T>); }
the `C<T>' is just the same as `C'. Outside of the
class, however, such a reference is an instantiation. */
if (comp_template_args (TYPE_TI_ARGS (template_type),
arglist))
{
found = template_type;
if (!entering_scope && PRIMARY_TEMPLATE_P (template))
{
tree ctx;
for (ctx = current_class_type;
ctx && TREE_CODE (ctx) != NAMESPACE_DECL;
ctx = (TYPE_P (ctx)
? TYPE_CONTEXT (ctx)
: DECL_CONTEXT (ctx)))
if (TYPE_P (ctx) && same_type_p (ctx, template_type))
goto found_ctx;
/* We're not in the scope of the class, so the
TEMPLATE_TYPE is not the type we want after all. */
found = NULL_TREE;
found_ctx:;
}
}
if (found)
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, found);
for (tp = &DECL_TEMPLATE_INSTANTIATIONS (template);
*tp;
tp = &TREE_CHAIN (*tp))
if (comp_template_args (TREE_PURPOSE (*tp), arglist))
{
found = *tp;
/* Use the move-to-front heuristic to speed up future
searches. */
*tp = TREE_CHAIN (*tp);
TREE_CHAIN (found)
= DECL_TEMPLATE_INSTANTIATIONS (template);
DECL_TEMPLATE_INSTANTIATIONS (template) = found;
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, TREE_VALUE (found));
}
/* This type is a "partial instantiation" if any of the template
arguments still involve template parameters. Note that we set
IS_PARTIAL_INSTANTIATION for partial specializations as
well. */
is_partial_instantiation = uses_template_parms (arglist);
if (!is_partial_instantiation
&& !PRIMARY_TEMPLATE_P (template)
&& TREE_CODE (CP_DECL_CONTEXT (template)) == NAMESPACE_DECL)
{
found = xref_tag_from_type (TREE_TYPE (template),
DECL_NAME (template),
/*globalize=*/1);
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, found);
}
context = tsubst (DECL_CONTEXT (template), arglist,
complain, in_decl);
if (!context)
context = global_namespace;
/* Create the type. */
if (TREE_CODE (template_type) == ENUMERAL_TYPE)
{
if (!is_partial_instantiation)
{
set_current_access_from_decl (TYPE_NAME (template_type));
t = start_enum (TYPE_IDENTIFIER (template_type));
}
else
/* We don't want to call start_enum for this type, since
the values for the enumeration constants may involve
template parameters. And, no one should be interested
in the enumeration constants for such a type. */
t = make_node (ENUMERAL_TYPE);
}
else
{
t = make_aggr_type (TREE_CODE (template_type));
CLASSTYPE_DECLARED_CLASS (t)
= CLASSTYPE_DECLARED_CLASS (template_type);
SET_CLASSTYPE_IMPLICIT_INSTANTIATION (t);
TYPE_FOR_JAVA (t) = TYPE_FOR_JAVA (template_type);
/* A local class. Make sure the decl gets registered properly. */
if (context == current_function_decl)
pushtag (DECL_NAME (template), t, 0);
}
/* If we called start_enum or pushtag above, this information
will already be set up. */
if (!TYPE_NAME (t))
{
TYPE_CONTEXT (t) = FROB_CONTEXT (context);
type_decl = create_implicit_typedef (DECL_NAME (template), t);
DECL_CONTEXT (type_decl) = TYPE_CONTEXT (t);
TYPE_STUB_DECL (t) = type_decl;
DECL_SOURCE_LOCATION (type_decl)
= DECL_SOURCE_LOCATION (TYPE_STUB_DECL (template_type));
}
else
type_decl = TYPE_NAME (t);
TREE_PRIVATE (type_decl)
= TREE_PRIVATE (TYPE_STUB_DECL (template_type));
TREE_PROTECTED (type_decl)
= TREE_PROTECTED (TYPE_STUB_DECL (template_type));
/* Set up the template information. We have to figure out which
template is the immediate parent if this is a full
instantiation. */
if (parm_depth == 1 || is_partial_instantiation
|| !PRIMARY_TEMPLATE_P (template))
/* This case is easy; there are no member templates involved. */
found = template;
else
{
/* This is a full instantiation of a member template. Look
for a partial instantiation of which this is an instance. */
for (found = DECL_TEMPLATE_INSTANTIATIONS (template);
found; found = TREE_CHAIN (found))
{
int success;
tree tmpl = CLASSTYPE_TI_TEMPLATE (TREE_VALUE (found));
/* We only want partial instantiations, here, not
specializations or full instantiations. */
if (CLASSTYPE_TEMPLATE_SPECIALIZATION (TREE_VALUE (found))
|| !uses_template_parms (TREE_VALUE (found)))
continue;
/* Temporarily reduce by one the number of levels in the
ARGLIST and in FOUND so as to avoid comparing the
last set of arguments. */
TREE_VEC_LENGTH (arglist)--;
TREE_VEC_LENGTH (TREE_PURPOSE (found)) --;
/* See if the arguments match. If they do, then TMPL is
the partial instantiation we want. */
success = comp_template_args (TREE_PURPOSE (found), arglist);
/* Restore the argument vectors to their full size. */
TREE_VEC_LENGTH (arglist)++;
TREE_VEC_LENGTH (TREE_PURPOSE (found))++;
if (success)
{
found = tmpl;
break;
}
}
if (!found)
{
/* There was no partial instantiation. This happens
where C<T> is a member template of A<T> and it's used
in something like
template <typename T> struct B { A<T>::C<int> m; };
B<float>;
Create the partial instantiation.
*/
TREE_VEC_LENGTH (arglist)--;
found = tsubst (template, arglist, complain, NULL_TREE);
TREE_VEC_LENGTH (arglist)++;
}
}
SET_TYPE_TEMPLATE_INFO (t, tree_cons (found, arglist, NULL_TREE));
DECL_TEMPLATE_INSTANTIATIONS (template)
= tree_cons (arglist, t,
DECL_TEMPLATE_INSTANTIATIONS (template));
if (TREE_CODE (t) == ENUMERAL_TYPE
&& !is_partial_instantiation)
/* Now that the type has been registered on the instantiations
list, we set up the enumerators. Because the enumeration
constants may involve the enumeration type itself, we make
sure to register the type first, and then create the
constants. That way, doing tsubst_expr for the enumeration
constants won't result in recursive calls here; we'll find
the instantiation and exit above. */
tsubst_enum (template_type, t, arglist);
/* Reset the name of the type, now that CLASSTYPE_TEMPLATE_INFO
is set up. */
if (TREE_CODE (t) != ENUMERAL_TYPE)
DECL_NAME (type_decl) = classtype_mangled_name (t);
if (!is_partial_instantiation)
{
/* For backwards compatibility; code that uses
-fexternal-templates expects looking up a template to
instantiate it. I think DDD still relies on this.
(jason 8/20/1998) */
if (TREE_CODE (t) != ENUMERAL_TYPE
&& flag_external_templates
&& CLASSTYPE_INTERFACE_KNOWN (TREE_TYPE (template))
&& ! CLASSTYPE_INTERFACE_ONLY (TREE_TYPE (template)))
add_pending_template (t);
}
else
/* If the type makes use of template parameters, the
code that generates debugging information will crash. */
DECL_IGNORED_P (TYPE_STUB_DECL (t)) = 1;
POP_TIMEVAR_AND_RETURN (TV_NAME_LOOKUP, t);
}
timevar_pop (TV_NAME_LOOKUP);
}
�
struct pair_fn_data
{
tree_fn_t fn;
void *data;
htab_t visited;
};
/* Called from for_each_template_parm via walk_tree. */
static tree
for_each_template_parm_r (tree* tp, int* walk_subtrees, void* d)
{
tree t = *tp;
struct pair_fn_data *pfd = (struct pair_fn_data *) d;
tree_fn_t fn = pfd->fn;
void *data = pfd->data;
void **slot;
/* If we have already visited this tree, there's no need to walk
subtrees. Otherwise, add it to the visited table. */
slot = htab_find_slot (pfd->visited, *tp, INSERT);
if (*slot)
{
*walk_subtrees = 0;
return NULL_TREE;
}
*slot = *tp;
if (TYPE_P (t)
&& for_each_template_parm (TYPE_CONTEXT (t), fn, data, pfd->visited))
return error_mark_node;
switch (TREE_CODE (t))
{
case RECORD_TYPE:
if (TYPE_PTRMEMFUNC_P (t))
break;
/* Fall through. */
case UNION_TYPE:
case ENUMERAL_TYPE:
if (!TYPE_TEMPLATE_INFO (t))
*walk_subtrees = 0;
else if (for_each_template_parm (TREE_VALUE (TYPE_TEMPLATE_INFO (t)),
fn, data, pfd->visited))
return error_mark_node;
break;
case METHOD_TYPE:
/* Since we're not going to walk subtrees, we have to do this
explicitly here. */
if (for_each_template_parm (TYPE_METHOD_BASETYPE (t), fn, data,
pfd->visited))
return error_mark_node;
/* Fall through. */
case FUNCTION_TYPE:
/* Check the return type. */
if (for_each_template_parm (TREE_TYPE (t), fn, data, pfd->visited))
return error_mark_node;
/* Check the parameter types. Since default arguments are not
instantiated until they are needed, the TYPE_ARG_TYPES may
contain expressions that involve template parameters. But,
no-one should be looking at them yet. And, once they're
instantiated, they don't contain template parameters, so
there's no point in looking at them then, either. */
{
tree parm;
for (parm = TYPE_ARG_TYPES (t); parm; parm = TREE_CHAIN (parm))
if (for_each_template_parm (TREE_VALUE (parm), fn, data,
pfd->visited))
return error_mark_node;
/* Since we've already handled the TYPE_ARG_TYPES, we don't
want walk_tree walking into them itself. */
*walk_subtrees = 0;
}
break;
case TYPEOF_TYPE:
if (for_each_template_parm (TYPE_FIELDS (t), fn, data,
pfd->visited))
return error_mark_node;
break;
case FUNCTION_DECL:
case VAR_DECL:
if (DECL_LANG_SPECIFIC (t) && DECL_TEMPLATE_INFO (t)
&& for_each_template_parm (DECL_TI_ARGS (t), fn, data,
pfd->visited))
return error_mark_node;
/* Fall through. */
case PARM_DECL:
case CONST_DECL:
if (TREE_CODE (t) == CONST_DECL && DECL_TEMPLATE_PARM_P (t)
&& for_each_template_parm (DECL_INITIAL (t), fn, data,
pfd->visited))
return error_mark_node;
if (DECL_CONTEXT (t)
&& for_each_template_parm (DECL_CONTEXT (t), fn, data,
pfd->visited))
return error_mark_node;
break;
case BOUND_TEMPLATE_TEMPLATE_PARM:
/* Record template parameters such as `T' inside `TT<T>'. */
if (for_each_template_parm (TYPE_TI_ARGS (t), fn, data, pfd->visited))
return error_mark_node;
/* Fall through. */
case TEMPLATE_TEMPLATE_PARM:
case TEMPLATE_TYPE_PARM:
case TEMPLATE_PARM_INDEX:
if (fn && (*fn)(t, data))
return error_mark_node;
else if (!fn)
return error_mark_node;
break;
case TEMPLATE_DECL:
/* A template template parameter is encountered */
if (DECL_TEMPLATE_TEMPLATE_PARM_P (t)
&& for_each_template_parm (TREE_TYPE (t), fn, data, pfd->visited))
return error_mark_node;
/* Already substituted template template parameter */
*walk_subtrees = 0;
break;
case TYPENAME_TYPE:
if (!fn
|| for_each_template_parm (TYPENAME_TYPE_FULLNAME (t), fn,
data, pfd->visited))
return error_mark_node;
break;
case CONSTRUCTOR:
if (TREE_TYPE (t) && TYPE_PTRMEMFUNC_P (TREE_TYPE (t))
&& for_each_template_parm (TYPE_PTRMEMFUNC_FN_TYPE
(TREE_TYPE (t)), fn, data,
pfd->visited))
return error_mark_node;
break;
case INDIRECT_REF:
case COMPONENT_REF:
/* If there's no type, then this thing must be some expression
involving template parameters. */
if (!fn && !TREE_TYPE (t))
return error_mark_node;
break;
case MODOP_EXPR:
case CAST_EXPR:
case REINTERPRET_CAST_EXPR:
case CONST_CAST_EXPR:
case STATIC_CAST_EXPR:
case DYNAMIC_CAST_EXPR:
case ARROW_EXPR:
case DOTSTAR_EXPR:
case TYPEID_EXPR:
case PSEUDO_DTOR_EXPR:
if (!fn)
return error_mark_node;
break;
case BASELINK:
/* If we do not handle this case specially, we end up walking
the BINFO hierarchy, which is circular, and therefore
confuses walk_tree. */
*walk_subtrees = 0;
if (for_each_template_parm (BASELINK_FUNCTIONS (*tp), fn, data,
pfd->visited))
return error_mark_node;
break;
default:
break;
}
/* We didn't find any template parameters we liked. */
return NULL_TREE;
}
/* For each TEMPLATE_TYPE_PARM, TEMPLATE_TEMPLATE_PARM,
BOUND_TEMPLATE_TEMPLATE_PARM or TEMPLATE_PARM_INDEX in T,
call FN with the parameter and the DATA.
If FN returns nonzero, the iteration is terminated, and
for_each_template_parm returns 1. Otherwise, the iteration
continues. If FN never returns a nonzero value, the value
returned by for_each_template_parm is 0. If FN is NULL, it is
considered to be the function which always returns 1. */
static int
for_each_template_parm (tree t, tree_fn_t fn, void* data, htab_t visited)
{
struct pair_fn_data pfd;
int result;
/* Set up. */
pfd.fn = fn;
pfd.data = data;
/* Walk the tree. (Conceptually, we would like to walk without
duplicates, but for_each_template_parm_r recursively calls
for_each_template_parm, so we would need to reorganize a fair
bit to use walk_tree_without_duplicates, so we keep our own
visited list.) */
if (visited)
pfd.visited = visited;
else
pfd.visited = htab_create (37, htab_hash_pointer, htab_eq_pointer,
NULL);
result = walk_tree (&t,
for_each_template_parm_r,
&pfd,
NULL) != NULL_TREE;
/* Clean up. */
if (!visited)
htab_delete (pfd.visited);
return result;
}
/* Returns true if T depends on any template parameter. */
int
uses_template_parms (tree t)
{
return for_each_template_parm (t, 0, 0, NULL);
}
/* Returns true if T depends on any template parameter with level LEVEL. */
int
uses_template_parms_level (tree t, int level)
{
return for_each_template_parm (t, template_parm_this_level_p, &level, NULL);
}
static int tinst_depth;
extern int max_tinst_depth;
#ifdef GATHER_STATISTICS
int depth_reached;
#endif
static int tinst_level_tick;
static int last_template_error_tick;
/* We're starting to instantiate D; record the template instantiation context
for diagnostics and to restore it later. */
int
push_tinst_level (tree d)
{
tree new;
if (tinst_depth >= max_tinst_depth)
{
/* If the instantiation in question still has unbound template parms,
we don't really care if we can't instantiate it, so just return.
This happens with base instantiation for implicit `typename'. */
if (uses_template_parms (d))
return 0;
last_template_error_tick = tinst_level_tick;
error ("template instantiation depth exceeds maximum of %d (use -ftemplate-depth-NN to increase the maximum) instantiating `%D'",
max_tinst_depth, d);
print_instantiation_context ();
return 0;
}
new = build_expr_wfl (d, input_filename, input_line, 0);
TREE_CHAIN (new) = current_tinst_level;
current_tinst_level = new;
++tinst_depth;
#ifdef GATHER_STATISTICS
if (tinst_depth > depth_reached)
depth_reached = tinst_depth;
#endif
++tinst_level_tick;
return 1;
}
/* We're done instantiating this template; return to the instantiation
context. */
void
pop_tinst_level (void)
{
tree old = current_tinst_level;
/* Restore the filename and line number stashed away when we started
this instantiation. */
input_line = TINST_LINE (old);
input_filename = TINST_FILE (old);
extract_interface_info ();
current_tinst_level = TREE_CHAIN (old);
--tinst_depth;
++tinst_level_tick;
}
/* We're instantiating a deferred template; restore the template
instantiation context in which the instantiation was requested, which
is one step out from LEVEL. */
static void
reopen_tinst_level (tree level)
{
tree t;
tinst_depth = 0;
for (t = level; t; t = TREE_CHAIN (t))
++tinst_depth;
current_tinst_level = level;
pop_tinst_level ();
}
/* Return the outermost template instantiation context, for use with
-falt-external-templates. */
tree
tinst_for_decl (void)
{
tree p = current_tinst_level;
if (p)
for (; TREE_CHAIN (p) ; p = TREE_CHAIN (p))
;
return p;
}
/* DECL is a friend FUNCTION_DECL or TEMPLATE_DECL. ARGS is the
vector of template arguments, as for tsubst.
Returns an appropriate tsubst'd friend declaration. */
static tree
tsubst_friend_function (tree decl, tree args)
{
tree new_friend;
location_t saved_loc = input_location;
input_location = DECL_SOURCE_LOCATION (decl);
if (TREE_CODE (decl) == FUNCTION_DECL
&& DECL_TEMPLATE_INSTANTIATION (decl)
&& TREE_CODE (DECL_TI_TEMPLATE (decl)) != TEMPLATE_DECL)
/* This was a friend declared with an explicit template
argument list, e.g.:
friend void f<>(T);
to indicate that f was a template instantiation, not a new
function declaration. Now, we have to figure out what
instantiation of what template. */
{
tree template_id, arglist, fns;
tree new_args;
tree tmpl;
tree ns = decl_namespace_context (TYPE_MAIN_DECL (current_class_type));
/* Friend functions are looked up in the containing namespace scope.
We must enter that scope, to avoid finding member functions of the
current cless with same name. */
push_nested_namespace (ns);
fns = tsubst_expr (DECL_TI_TEMPLATE (decl), args,
tf_error | tf_warning, NULL_TREE);
pop_nested_namespace (ns);
arglist = tsubst (DECL_TI_ARGS (decl), args,
tf_error | tf_warning, NULL_TREE);
template_id = lookup_template_function (fns, arglist);
new_friend = tsubst (decl, args, tf_error | tf_warning, NULL_TREE);
tmpl = determine_specialization (template_id, new_friend,
&new_args,
/*need_member_template=*/0);
new_friend = instantiate_template (tmpl, new_args, tf_error);
goto done;
}
new_friend = tsubst (decl, args, tf_error | tf_warning, NULL_TREE);
/* The NEW_FRIEND will look like an instantiation, to the
compiler, but is not an instantiation from the point of view of
the language. For example, we might have had:
template <class T> struct S {
template <class U> friend void f(T, U);
};
Then, in S<int>, template <class U> void f(int, U) is not an
instantiation of anything. */
DECL_USE_TEMPLATE (new_friend) = 0;
if (TREE_CODE (decl) == TEMPLATE_DECL)
{
DECL_USE_TEMPLATE (DECL_TEMPLATE_RESULT (new_friend)) = 0;
DECL_SAVED_TREE (DECL_TEMPLATE_RESULT (new_friend))
= DECL_SAVED_TREE (DECL_TEMPLATE_RESULT (decl));
}
/* The mangled name for the NEW_FRIEND is incorrect. The function
is not a template instantiation and should not be mangled like
one. Therefore, we forget the mangling here; we'll recompute it
later if we need it. */
if (TREE_CODE (new_friend) != TEMPLATE_DECL)
{
SET_DECL_RTL (new_friend, NULL_RTX);
SET_DECL_ASSEMBLER_NAME (new_friend, NULL_TREE);
}
if (DECL_NAMESPACE_SCOPE_P (new_friend))
{
tree old_decl;
tree new_friend_template_info;
tree new_friend_result_template_info;
tree ns;
int new_friend_is_defn;
/* We must save some information from NEW_FRIEND before calling
duplicate decls since that function will free NEW_FRIEND if
possible. */
new_friend_template_info = DECL_TEMPLATE_INFO (new_friend);
if (TREE_CODE (new_friend) == TEMPLATE_DECL)
{
/* This declaration is a `primary' template. */
DECL_PRIMARY_TEMPLATE (new_friend) = new_friend;
new_friend_is_defn
= DECL_INITIAL (DECL_TEMPLATE_RESULT (new_friend)) != NULL_TREE;
new_friend_result_template_info
= DECL_TEMPLATE_INFO (DECL_TEMPLATE_RESULT (new_friend));
}
else
{
new_friend_is_defn = DECL_INITIAL (new_friend) != NULL_TREE;
new_friend_result_template_info = NULL_TREE;
}
/* Inside pushdecl_namespace_level, we will push into the
current namespace. However, the friend function should go
into the namespace of the template. */
ns = decl_namespace_context (new_friend);
push_nested_namespace (ns);
old_decl = pushdecl_namespace_level (new_friend);
pop_nested_namespace (ns);
if (old_decl != new_friend)
{
/* This new friend declaration matched an existing
declaration. For example, given:
template <class T> void f(T);
template <class U> class C {
template <class T> friend void f(T) {}
};
the friend declaration actually provides the definition
of `f', once C has been instantiated for some type. So,
old_decl will be the out-of-class template declaration,
while new_friend is the in-class definition.
But, if `f' was called before this point, the
instantiation of `f' will have DECL_TI_ARGS corresponding
to `T' but not to `U', references to which might appear
in the definition of `f'. Previously, the most general
template for an instantiation of `f' was the out-of-class
version; now it is the in-class version. Therefore, we
run through all specialization of `f', adding to their
DECL_TI_ARGS appropriately. In particular, they need a
new set of outer arguments, corresponding to the
arguments for this class instantiation.
The same situation can arise with something like this:
friend void f(int);
template <class T> class C {
friend void f(T) {}
};
when `C<int>' is instantiated. Now, `f(int)' is defined
in the class. */
if (!new_friend_is_defn)
/* On the other hand, if the in-class declaration does
*not* provide a definition, then we don't want to alter
existing definitions. We can just leave everything
alone. */
;
else
{
/* Overwrite whatever template info was there before, if
any, with the new template information pertaining to
the declaration. */
DECL_TEMPLATE_INFO (old_decl) = new_friend_template_info;
if (TREE_CODE (old_decl) != TEMPLATE_DECL)
reregister_specialization (new_friend,
most_general_template (old_decl),
old_decl);
else
{
tree t;
tree new_friend_args;
DECL_TEMPLATE_INFO (DECL_TEMPLATE_RESULT (old_decl))
= new_friend_result_template_info;
new_friend_args = TI_ARGS (new_friend_template_info);
for (t = DECL_TEMPLATE_SPECIALIZATIONS (old_decl);
t != NULL_TREE;
t = TREE_CHAIN (t))
{
tree spec = TREE_VALUE (t);
DECL_TI_ARGS (spec)
= add_outermost_template_args (new_friend_args,
DECL_TI_ARGS (spec));
}
/* Now, since specializations are always supposed to
hang off of the most general template, we must move
them. */
t = most_general_template (old_decl);
if (t != old_decl)
{
DECL_TEMPLATE_SPECIALIZATIONS (t)
= chainon (DECL_TEMPLATE_SPECIALIZATIONS (t),
DECL_TEMPLATE_SPECIALIZATIONS (old_decl));
DECL_TEMPLATE_SPECIALIZATIONS (old_decl) = NULL_TREE;
}
}
}
/* The information from NEW_FRIEND has been merged into OLD_DECL
by duplicate_decls. */
new_friend = old_decl;
}
}
else if (COMPLETE_TYPE_P (DECL_CONTEXT (new_friend)))
{
/* Check to see that the declaration is really present, and,
possibly obtain an improved declaration. */
tree fn = check_classfn (DECL_CONTEXT (new_friend),
new_friend, false);
if (fn)
new_friend = fn;
}
done:
input_location = saved_loc;
return new_friend;
}
/* FRIEND_TMPL is a friend TEMPLATE_DECL. ARGS is the vector of
template arguments, as for tsubst.
Returns an appropriate tsubst'd friend type or error_mark_node on
failure. */
static tree
tsubst_friend_class (tree friend_tmpl, tree args)
{
tree friend_type;
tree tmpl;
tree context;
context = DECL_CONTEXT (friend_tmpl);
if (context)
{
if (TREE_CODE (context) == NAMESPACE_DECL)
push_nested_namespace (context);
else
push_nested_class (tsubst (context, args, tf_none, NULL_TREE));
}
/* First, we look for a class template. */
tmpl = lookup_name (DECL_NAME (friend_tmpl), /*prefer_type=*/0);
/* But, if we don't find one, it might be because we're in a
situation like this:
template <class T>
struct S {
template <class U>
friend struct S;
};
Here, in the scope of (say) S<int>, `S' is bound to a TYPE_DECL
for `S<int>', not the TEMPLATE_DECL. */
if (!tmpl || !DECL_CLASS_TEMPLATE_P (tmpl))
{
tmpl = lookup_name (DECL_NAME (friend_tmpl), /*prefer_type=*/1);
tmpl = maybe_get_template_decl_from_type_decl (tmpl);
}
if (tmpl && DECL_CLASS_TEMPLATE_P (tmpl))
{
/* The friend template has already been declared. Just
check to see that the declarations match, and install any new
default parameters. We must tsubst the default parameters,
of course. We only need the innermost template parameters
because that is all that redeclare_class_template will look
at. */
if (TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (friend_tmpl))
> TMPL_ARGS_DEPTH (args))
{
tree parms;
parms = tsubst_template_parms (DECL_TEMPLATE_PARMS (friend_tmpl),
args, tf_error | tf_warning);
redeclare_class_template (TREE_TYPE (tmpl), parms);
}
friend_type = TREE_TYPE (tmpl);
}
else
{
/* The friend template has not already been declared. In this
case, the instantiation of the template class will cause the
injection of this template into the global scope. */
tmpl = tsubst (friend_tmpl, args, tf_error | tf_warning, NULL_TREE);
/* The new TMPL is not an instantiation of anything, so we
forget its origins. We don't reset CLASSTYPE_TI_TEMPLATE for
the new type because that is supposed to be the corresponding
template decl, i.e., TMPL. */
DECL_USE_TEMPLATE (tmpl) = 0;
DECL_TEMPLATE_INFO (tmpl) = NULL_TREE;
CLASSTYPE_USE_TEMPLATE (TREE_TYPE (tmpl)) = 0;
CLASSTYPE_TI_ARGS (TREE_TYPE (tmpl))
= INNERMOST_TEMPLATE_ARGS (CLASSTYPE_TI_ARGS (TREE_TYPE (tmpl)));
/* Inject this template into the global scope. */
friend_type = TREE_TYPE (pushdecl_top_level (tmpl));
}
if (context)
{
if (TREE_CODE (context) == NAMESPACE_DECL)
pop_nested_namespace (context);
else
pop_nested_class ();
}
return friend_type;
}
/* Returns zero if TYPE cannot be completed later due to circularity.
Otherwise returns one. */
static int
can_complete_type_without_circularity (tree type)
{
if (type == NULL_TREE || type == error_mark_node)
return 0;
else if (COMPLETE_TYPE_P (type))
return 1;
else if (TREE_CODE (type) == ARRAY_TYPE && TYPE_DOMAIN (type))
return can_complete_type_without_circularity (TREE_TYPE (type));
else if (CLASS_TYPE_P (type)
&& TYPE_BEING_DEFINED (TYPE_MAIN_VARIANT (type)))
return 0;
else
return 1;
}
tree
instantiate_class_template (tree type)
{
tree template, args, pattern, t, member;
tree typedecl;
tree pbinfo;
if (type == error_mark_node)
return error_mark_node;
if (TYPE_BEING_DEFINED (type)
|| COMPLETE_TYPE_P (type)
|| dependent_type_p (type))
return type;
/* Figure out which template is being instantiated. */
template = most_general_template (CLASSTYPE_TI_TEMPLATE (type));
my_friendly_assert (TREE_CODE (template) == TEMPLATE_DECL, 279);
/* Figure out which arguments are being used to do the
instantiation. */
args = CLASSTYPE_TI_ARGS (type);
/* Determine what specialization of the original template to
instantiate. */
t = most_specialized_class (template, args);
if (t == error_mark_node)
{
const char *str = "candidates are:";
error ("ambiguous class template instantiation for `%#T'", type);
for (t = DECL_TEMPLATE_SPECIALIZATIONS (template); t;
t = TREE_CHAIN (t))
{
if (get_class_bindings (TREE_VALUE (t), TREE_PURPOSE (t), args))
{
cp_error_at ("%s %+#T", str, TREE_TYPE (t));
str = " ";
}
}
TYPE_BEING_DEFINED (type) = 1;
return error_mark_node;
}
if (t)
pattern = TREE_TYPE (t);
else
pattern = TREE_TYPE (template);
/* If the template we're instantiating is incomplete, then clearly
there's nothing we can do. */
if (!COMPLETE_TYPE_P (pattern))
return type;
/* If we've recursively instantiated too many templates, stop. */
if (! push_tinst_level (type))
return type;
/* Now we're really doing the instantiation. Mark the type as in
the process of being defined. */
TYPE_BEING_DEFINED (type) = 1;
/* We may be in the middle of deferred access check. Disable
it now. */
push_deferring_access_checks (dk_no_deferred);
maybe_push_to_top_level (uses_template_parms (type));
if (t)
{
/* This TYPE is actually an instantiation of a partial
specialization. We replace the innermost set of ARGS with
the arguments appropriate for substitution. For example,
given:
template <class T> struct S {};
template <class T> struct S<T*> {};
and supposing that we are instantiating S<int*>, ARGS will
present be {int*} but we need {int}. */
tree inner_args
= get_class_bindings (TREE_VALUE (t), TREE_PURPOSE (t),
args);
/* If there were multiple levels in ARGS, replacing the
innermost level would alter CLASSTYPE_TI_ARGS, which we don't
want, so we make a copy first. */
if (TMPL_ARGS_HAVE_MULTIPLE_LEVELS (args))
{
args = copy_node (args);
SET_TMPL_ARGS_LEVEL (args, TMPL_ARGS_DEPTH (args), inner_args);
}
else
args = inner_args;
}
if (flag_external_templates)
{
if (flag_alt_external_templates)
{
CLASSTYPE_INTERFACE_ONLY (type) = interface_only;
SET_CLASSTYPE_INTERFACE_UNKNOWN_X (type, interface_unknown);
}
else
{
CLASSTYPE_INTERFACE_ONLY (type) = CLASSTYPE_INTERFACE_ONLY (pattern);
SET_CLASSTYPE_INTERFACE_UNKNOWN_X
(type, CLASSTYPE_INTERFACE_UNKNOWN (pattern));
}
}
else
{
SET_CLASSTYPE_INTERFACE_UNKNOWN (type);
}
/* Set the input location to the template definition. This is needed
if tsubsting causes an error. */
input_location = DECL_SOURCE_LOCATION (TYPE_NAME (pattern));
TYPE_HAS_CONSTRUCTOR (type) = TYPE_HAS_CONSTRUCTOR (pattern);
TYPE_HAS_DESTRUCTOR (type) = TYPE_HAS_DESTRUCTOR (pattern);
TYPE_HAS_NEW_OPERATOR (type) = TYPE_HAS_NEW_OPERATOR (pattern);
TYPE_HAS_ARRAY_NEW_OPERATOR (type) = TYPE_HAS_ARRAY_NEW_OPERATOR (pattern);
TYPE_GETS_DELETE (type) = TYPE_GETS_DELETE (pattern);
TYPE_HAS_ASSIGN_REF (type) = TYPE_HAS_ASSIGN_REF (pattern);
TYPE_HAS_CONST_ASSIGN_REF (type) = TYPE_HAS_CONST_ASSIGN_REF (pattern);
TYPE_HAS_ABSTRACT_ASSIGN_REF (type) = TYPE_HAS_ABSTRACT_ASSIGN_REF (pattern);
TYPE_HAS_INIT_REF (type) = TYPE_HAS_INIT_REF (pattern);
TYPE_HAS_CONST_INIT_REF (type) = TYPE_HAS_CONST_INIT_REF (pattern);
TYPE_HAS_DEFAULT_CONSTRUCTOR (type) = TYPE_HAS_DEFAULT_CONSTRUCTOR (pattern);
TYPE_HAS_CONVERSION (type) = TYPE_HAS_CONVERSION (pattern);
TYPE_BASE_CONVS_MAY_REQUIRE_CODE_P (type)
= TYPE_BASE_CONVS_MAY_REQUIRE_CODE_P (pattern);
TYPE_USES_MULTIPLE_INHERITANCE (type)
= TYPE_USES_MULTIPLE_INHERITANCE (pattern);
TYPE_USES_VIRTUAL_BASECLASSES (type)
= TYPE_USES_VIRTUAL_BASECLASSES (pattern);
TYPE_PACKED (type) = TYPE_PACKED (pattern);
TYPE_ALIGN (type) = TYPE_ALIGN (pattern);
TYPE_USER_ALIGN (type) = TYPE_USER_ALIGN (pattern);
TYPE_FOR_JAVA (type) = TYPE_FOR_JAVA (pattern); /* For libjava's JArray<T> */
if (ANON_AGGR_TYPE_P (pattern))
SET_ANON_AGGR_TYPE_P (type);
pbinfo = TYPE_BINFO (pattern);
#ifdef ENABLE_CHECKING
if (DECL_CLASS_SCOPE_P (TYPE_MAIN_DECL (pattern))
&& ! COMPLETE_TYPE_P (TYPE_CONTEXT (type))
&& ! TYPE_BEING_DEFINED (TYPE_CONTEXT (type)))
/* We should never instantiate a nested class before its enclosing
class; we need to look up the nested class by name before we can
instantiate it, and that lookup should instantiate the enclosing
class. */
abort ();
#endif
if (BINFO_BASETYPES (pbinfo))
{
tree base_list = NULL_TREE;
tree pbases = BINFO_BASETYPES (pbinfo);
tree paccesses = BINFO_BASEACCESSES (pbinfo);
tree context = TYPE_CONTEXT (type);
int i;
/* We must enter the scope containing the type, as that is where
the accessibility of types named in dependent bases are
looked up from. */
push_scope (context ? context : global_namespace);
/* Substitute into each of the bases to determine the actual
basetypes. */
for (i = 0; i < TREE_VEC_LENGTH (pbases); ++i)
{
tree base;
tree access;
tree pbase;
pbase = TREE_VEC_ELT (pbases, i);
access = TREE_VEC_ELT (paccesses, i);
/* Substitute to figure out the base class. */
base = tsubst (BINFO_TYPE (pbase), args, tf_error, NULL_TREE);
if (base == error_mark_node)
continue;
base_list = tree_cons (access, base, base_list);
TREE_VIA_VIRTUAL (base_list) = TREE_VIA_VIRTUAL (pbase);
}
/* The list is now in reverse order; correct that. */
base_list = nreverse (base_list);
/* Now call xref_basetypes to set up all the base-class
information. */
xref_basetypes (type, base_list);
pop_scope (context ? context : global_namespace);
}
/* Now that our base classes are set up, enter the scope of the
class, so that name lookups into base classes, etc. will work
correctly. This is precisely analogous to what we do in
begin_class_definition when defining an ordinary non-template
class. */
pushclass (type);
/* Now members are processed in the order of declaration. */
for (member = CLASSTYPE_DECL_LIST (pattern);
member; member = TREE_CHAIN (member))
{
tree t = TREE_VALUE (member);
if (TREE_PURPOSE (member))
{
if (TYPE_P (t))
{
/* Build new CLASSTYPE_NESTED_UTDS. */
tree tag = t;
tree name = TYPE_IDENTIFIER (tag);
tree newtag;
newtag = tsubst (tag, args, tf_error, NULL_TREE);
my_friendly_assert (newtag != error_mark_node, 20010206);
if (TREE_CODE (newtag) != ENUMERAL_TYPE)
{
if (TYPE_LANG_SPECIFIC (tag) && CLASSTYPE_IS_TEMPLATE (tag))
/* Unfortunately, lookup_template_class sets
CLASSTYPE_IMPLICIT_INSTANTIATION for a partial
instantiation (i.e., for the type of a member
template class nested within a template class.)
This behavior is required for
maybe_process_partial_specialization to work
correctly, but is not accurate in this case;
the TAG is not an instantiation of anything.
(The corresponding TEMPLATE_DECL is an
instantiation, but the TYPE is not.) */
CLASSTYPE_USE_TEMPLATE (newtag) = 0;
/* Now, we call pushtag to put this NEWTAG into the scope of
TYPE. We first set up the IDENTIFIER_TYPE_VALUE to avoid
pushtag calling push_template_decl. We don't have to do
this for enums because it will already have been done in
tsubst_enum. */
if (name)
SET_IDENTIFIER_TYPE_VALUE (name, newtag);
pushtag (name, newtag, /*globalize=*/0);
}
}
else if (TREE_CODE (t) == FUNCTION_DECL
|| DECL_FUNCTION_TEMPLATE_P (t))
{
/* Build new TYPE_METHODS. */
tree r;
if (TREE_CODE (t) == TEMPLATE_DECL)
++processing_template_decl;
r = tsubst (t, args, tf_error, NULL_TREE);
if (TREE_CODE (t) == TEMPLATE_DECL)
--processing_template_decl;
set_current_access_from_decl (r);
grok_special_member_properties (r);
finish_member_declaration (r);
}
else
{
/* Build new TYPE_FIELDS. */
if (TREE_CODE (t) != CONST_DECL)
{
tree r;
/* The the file and line for this declaration, to
assist in error message reporting. Since we
called push_tinst_level above, we don't need to
restore these. */
input_location = DECL_SOURCE_LOCATION (t);
if (TREE_CODE (t) == TEMPLATE_DECL)
++processing_template_decl;
r = tsubst (t, args, tf_error | tf_warning, NULL_TREE);
if (TREE_CODE (t) == TEMPLATE_DECL)
--processing_template_decl;
if (TREE_CODE (r) == VAR_DECL)
{
tree init;
if (DECL_INITIALIZED_IN_CLASS_P (r))
init = tsubst_expr (DECL_INITIAL (t), args,
tf_error | tf_warning, NULL_TREE);
else
init = NULL_TREE;
finish_static_data_member_decl
(r, init, /*asmspec_tree=*/NULL_TREE, /*flags=*/0);
if (DECL_INITIALIZED_IN_CLASS_P (r))
check_static_variable_definition (r, TREE_TYPE (r));
}
else if (TREE_CODE (r) == FIELD_DECL)
{
/* Determine whether R has a valid type and can be
completed later. If R is invalid, then it is
replaced by error_mark_node so that it will not be
added to TYPE_FIELDS. */
tree rtype = TREE_TYPE (r);
if (can_complete_type_without_circularity (rtype))
complete_type (rtype);
if (!COMPLETE_TYPE_P (rtype))
{
cxx_incomplete_type_error (r, rtype);
r = error_mark_node;
}
}
/* If it is a TYPE_DECL for a class-scoped ENUMERAL_TYPE,
such a thing will already have been added to the field
list by tsubst_enum in finish_member_declaration in the
CLASSTYPE_NESTED_UTDS case above. */
if (!(TREE_CODE (r) == TYPE_DECL
&& TREE_CODE (TREE_TYPE (r)) == ENUMERAL_TYPE
&& DECL_ARTIFICIAL (r)))
{
set_current_access_from_decl (r);
finish_member_declaration (r);
}
}
}
}
else
{
if (TYPE_P (t) || DECL_CLASS_TEMPLATE_P (t))
{
/* Build new CLASSTYPE_FRIEND_CLASSES. */
tree friend_type = t;
tree new_friend_type;
if (TREE_CODE (friend_type) == TEMPLATE_DECL)
new_friend_type = tsubst_friend_class (friend_type, args);
else if (uses_template_parms (friend_type))
new_friend_type = tsubst (friend_type, args,
tf_error | tf_warning, NULL_TREE);
else if (CLASSTYPE_USE_TEMPLATE (friend_type))
new_friend_type = friend_type;
else
{
tree ns = decl_namespace_context (TYPE_MAIN_DECL (friend_type));
/* The call to xref_tag_from_type does injection for friend
classes. */
push_nested_namespace (ns);
new_friend_type =
xref_tag_from_type (friend_type, NULL_TREE, 1);
pop_nested_namespace (ns);
}
if (TREE_CODE (friend_type) == TEMPLATE_DECL)
/* Trick make_friend_class into realizing that the friend
we're adding is a template, not an ordinary class. It's
important that we use make_friend_class since it will
perform some error-checking and output cross-reference
information. */
++processing_template_decl;
if (new_friend_type != error_mark_node)
make_friend_class (type, new_friend_type,
/*complain=*/false);
if (TREE_CODE (friend_type) == TEMPLATE_DECL)
--processing_template_decl;
}
else
{
/* Build new DECL_FRIENDLIST. */
tree r;
if (TREE_CODE (t) == TEMPLATE_DECL)
++processing_template_decl;
r = tsubst_friend_function (t, args);
if (TREE_CODE (t) == TEMPLATE_DECL)
--processing_template_decl;
add_friend (type, r, /*complain=*/false);
}
}
}
/* Set the file and line number information to whatever is given for
the class itself. This puts error messages involving generated
implicit functions at a predictable point, and the same point
that would be used for non-template classes. */
typedecl = TYPE_MAIN_DECL (type);
input_location = DECL_SOURCE_LOCATION (typedecl);
unreverse_member_declarations (type);
finish_struct_1 (type);
/* Clear this now so repo_template_used is happy. */
TYPE_BEING_DEFINED (type) = 0;
repo_template_used (type);
/* Now that the class is complete, instantiate default arguments for
any member functions. We don't do this earlier because the
default arguments may reference members of the class. */
if (!PRIMARY_TEMPLATE_P (template))
for (t = TYPE_METHODS (type); t; t = TREE_CHAIN (t))
if (TREE_CODE (t) == FUNCTION_DECL
/* Implicitly generated member functions will not have template
information; they are not instantiations, but instead are
created "fresh" for each instantiation. */
&& DECL_TEMPLATE_INFO (t))
tsubst_default_arguments (t);
popclass ();
pop_from_top_level ();
pop_deferring_access_checks ();
pop_tinst_level ();
if (TYPE_CONTAINS_VPTR_P (type))
keyed_classes = tree_cons (NULL_TREE, type, keyed_classes);
return type;
}
static tree
tsubst_template_arg (tree t, tree args, tsubst_flags_t complain, tree in_decl)
{
tree r;
if (!t)
r = t;
else if (TYPE_P (t))
r = tsubst (t, args, complain, in_decl);
else
{
r = tsubst_expr (t, args, complain, in_decl);
if (!uses_template_parms (r))
{
/* Sometimes, one of the args was an expression involving a
template constant parameter, like N - 1. Now that we've
tsubst'd, we might have something like 2 - 1. This will
confuse lookup_template_class, so we do constant folding
here. We have to unset processing_template_decl, to fool
tsubst_copy_and_build() into building an actual tree. */
/* If the TREE_TYPE of ARG is not NULL_TREE, ARG is already
as simple as it's going to get, and trying to reprocess
the trees will break. Once tsubst_expr et al DTRT for
non-dependent exprs, this code can go away, as the type
will always be set. */
if (!TREE_TYPE (r))
{
int saved_processing_template_decl = processing_template_decl;
processing_template_decl = 0;
r = tsubst_copy_and_build (r, /*args=*/NULL_TREE,
tf_error, /*in_decl=*/NULL_TREE,
/*function_p=*/false);
processing_template_decl = saved_processing_template_decl;
}
r = fold (r);
}
}
return r;
}
/* Substitute ARGS into the vector or list of template arguments T. */
static tree
tsubst_template_args (tree t, tree args, tsubst_flags_t complain, tree in_decl)
{
int len = TREE_VEC_LENGTH (t);
int need_new = 0, i;
tree *elts = alloca (len * sizeof (tree));
for (i = 0; i < len; i++)
{
tree orig_arg = TREE_VEC_ELT (t, i);
tree new_arg;
if (TREE_CODE (orig_arg) == TREE_VEC)
new_arg = tsubst_template_args (orig_arg, args, complain, in_decl);
else
new_arg = tsubst_template_arg (orig_arg, args, complain, in_decl);
if (new_arg == error_mark_node)
return error_mark_node;
elts[i] = new_arg;
if (new_arg != orig_arg)
need_new = 1;
}
if (!need_new)
return t;
t = make_tree_vec (len);
for (i = 0; i < len; i++)
TREE_VEC_ELT (t, i) = elts[i];
return t;
}
/* Return the result of substituting ARGS into the template parameters
given by PARMS. If there are m levels of ARGS and m + n levels of
PARMS, then the result will contain n levels of PARMS. For
example, if PARMS is `template <class T> template <class U>
template <T*, U, class V>' and ARGS is {{int}, {double}} then the
result will be `template <int*, double, class V>'. */
static tree
tsubst_template_parms (tree parms, tree args, tsubst_flags_t complain)
{
tree r = NULL_TREE;
tree* new_parms;
for (new_parms = &r;
TMPL_PARMS_DEPTH (parms) > TMPL_ARGS_DEPTH (args);
new_parms = &(TREE_CHAIN (*new_parms)),
parms = TREE_CHAIN (parms))
{
tree new_vec =
make_tree_vec (TREE_VEC_LENGTH (TREE_VALUE (parms)));
int i;
for (i = 0; i < TREE_VEC_LENGTH (new_vec); ++i)
{
tree tuple = TREE_VEC_ELT (TREE_VALUE (parms), i);
tree default_value = TREE_PURPOSE (tuple);
tree parm_decl = TREE_VALUE (tuple);
parm_decl = tsubst (parm_decl, args, complain, NULL_TREE);
default_value = tsubst_template_arg (default_value, args,
complain, NULL_TREE);
tuple = build_tree_list (default_value, parm_decl);
TREE_VEC_ELT (new_vec, i) = tuple;
}
*new_parms =
tree_cons (size_int (TMPL_PARMS_DEPTH (parms)
- TMPL_ARGS_DEPTH (args)),
new_vec, NULL_TREE);
}
return r;
}
/* Substitute the ARGS into the indicated aggregate (or enumeration)
type T. If T is not an aggregate or enumeration type, it is
handled as if by tsubst. IN_DECL is as for tsubst. If
ENTERING_SCOPE is nonzero, T is the context for a template which
we are presently tsubst'ing. Return the substituted value. */
static tree
tsubst_aggr_type (tree t,
tree args,
tsubst_flags_t complain,
tree in_decl,
int entering_scope)
{
if (t == NULL_TREE)
return NULL_TREE;
switch (TREE_CODE (t))
{
case RECORD_TYPE:
if (TYPE_PTRMEMFUNC_P (t))
return tsubst (TYPE_PTRMEMFUNC_FN_TYPE (t), args, complain, in_decl);
/* else fall through */
case ENUMERAL_TYPE:
case UNION_TYPE:
if (TYPE_TEMPLATE_INFO (t))
{
tree argvec;
tree context;
tree r;
/* First, determine the context for the type we are looking
up. */
context = TYPE_CONTEXT (t);
if (context)
context = tsubst_aggr_type (context, args, complain,
in_decl, /*entering_scope=*/1);
/* Then, figure out what arguments are appropriate for the
type we are trying to find. For example, given:
template <class T> struct S;
template <class T, class U> void f(T, U) { S<U> su; }
and supposing that we are instantiating f<int, double>,
then our ARGS will be {int, double}, but, when looking up
S we only want {double}. */
argvec = tsubst_template_args (TYPE_TI_ARGS (t), args,
complain, in_decl);
if (argvec == error_mark_node)
return error_mark_node;
r = lookup_template_class (t, argvec, in_decl, context,
entering_scope, complain);
return cp_build_qualified_type_real (r, TYPE_QUALS (t), complain);
}
else
/* This is not a template type, so there's nothing to do. */
return t;
default:
return tsubst (t, args, complain, in_decl);
}
}
/* Substitute into the default argument ARG (a default argument for
FN), which has the indicated TYPE. */
tree
tsubst_default_argument (tree fn, tree type, tree arg)
{
/* This default argument came from a template. Instantiate the
default argument here, not in tsubst. In the case of
something like:
template <class T>
struct S {
static T t();
void f(T = t());
};
we must be careful to do name lookup in the scope of S<T>,
rather than in the current class.
??? current_class_type affects a lot more than name lookup. This is
very fragile. Fortunately, it will go away when we do 2-phase name
binding properly. */
/* FN is already the desired FUNCTION_DECL. */
push_access_scope (fn);
arg = tsubst_expr (arg, DECL_TI_ARGS (fn),
tf_error | tf_warning, NULL_TREE);
pop_access_scope (fn);
/* Make sure the default argument is reasonable. */
arg = check_default_argument (type, arg);
return arg;
}
/* Substitute into all the default arguments for FN. */
static void
tsubst_default_arguments (tree fn)
{
tree arg;
tree tmpl_args;
tmpl_args = DECL_TI_ARGS (fn);
/* If this function is not yet instantiated, we certainly don't need
its default arguments. */
if (uses_template_parms (tmpl_args))
return;
for (arg = TYPE_ARG_TYPES (TREE_TYPE (fn));
arg;
arg = TREE_CHAIN (arg))
if (TREE_PURPOSE (arg))
TREE_PURPOSE (arg) = tsubst_default_argument (fn,
TREE_VALUE (arg),
TREE_PURPOSE (arg));
}
/* Substitute the ARGS into the T, which is a _DECL. TYPE is the
(already computed) substitution of ARGS into TREE_TYPE (T), if
appropriate. Return the result of the substitution. Issue error
and warning messages under control of COMPLAIN. */
static tree
tsubst_decl (tree t, tree args, tree type, tsubst_flags_t complain)
{
location_t saved_loc;
tree r = NULL_TREE;
tree in_decl = t;
/* Set the filename and linenumber to improve error-reporting. */
saved_loc = input_location;
input_location = DECL_SOURCE_LOCATION (t);
switch (TREE_CODE (t))
{
case TEMPLATE_DECL:
{
/* We can get here when processing a member template function
of a template class. */
tree decl = DECL_TEMPLATE_RESULT (t);
tree spec;
int is_template_template_parm = DECL_TEMPLATE_TEMPLATE_PARM_P (t);
if (!is_template_template_parm)
{
/* We might already have an instance of this template.
The ARGS are for the surrounding class type, so the
full args contain the tsubst'd args for the context,
plus the innermost args from the template decl. */
tree tmpl_args = DECL_CLASS_TEMPLATE_P (t)
? CLASSTYPE_TI_ARGS (TREE_TYPE (t))
: DECL_TI_ARGS (DECL_TEMPLATE_RESULT (t));
tree full_args;
full_args = tsubst_template_args (tmpl_args, args,
complain, in_decl);
/* tsubst_template_args doesn't copy the vector if
nothing changed. But, *something* should have
changed. */
my_friendly_assert (full_args != tmpl_args, 0);
spec = retrieve_specialization (t, full_args);
if (spec != NULL_TREE)
{
r = spec;
break;
}
}
/* Make a new template decl. It will be similar to the
original, but will record the current template arguments.
We also create a new function declaration, which is just
like the old one, but points to this new template, rather
than the old one. */
r = copy_decl (t);
my_friendly_assert (DECL_LANG_SPECIFIC (r) != 0, 0);
TREE_CHAIN (r) = NULL_TREE;
if (is_template_template_parm)
{
tree new_decl = tsubst (decl, args, complain, in_decl);
DECL_TEMPLATE_RESULT (r) = new_decl;
TREE_TYPE (r) = TREE_TYPE (new_decl);
break;
}
DECL_CONTEXT (r)
= tsubst_aggr_type (DECL_CONTEXT (t), args,
complain, in_decl,
/*entering_scope=*/1);
DECL_TEMPLATE_INFO (r) = build_tree_list (t, args);
if (TREE_CODE (decl) == TYPE_DECL)
{
tree new_type = tsubst (TREE_TYPE (t), args, complain, in_decl);
TREE_TYPE (r) = new_type;
CLASSTYPE_TI_TEMPLATE (new_type) = r;
DECL_TEMPLATE_RESULT (r) = TYPE_MAIN_DECL (new_type);
DECL_TI_ARGS (r) = CLASSTYPE_TI_ARGS (new_type);
}
else
{
tree new_decl = tsubst (decl, args, complain, in_decl);
if (new_decl == error_mark_node)
return error_mark_node;
DECL_TEMPLATE_RESULT (r) = new_decl;
DECL_TI_TEMPLATE (new_decl) = r;
TREE_TYPE (r) = TREE_TYPE (new_decl);
DECL_TI_ARGS (r) = DECL_TI_ARGS (new_decl);
}
SET_DECL_IMPLICIT_INSTANTIATION (r);
DECL_TEMPLATE_INSTANTIATIONS (r) = NULL_TREE;
DECL_TEMPLATE_SPECIALIZATIONS (r) = NULL_TREE;
/* The template parameters for this new template are all the
template parameters for the old template, except the
outermost level of parameters. */
DECL_TEMPLATE_PARMS (r)
= tsubst_template_parms (DECL_TEMPLATE_PARMS (t), args,
complain);
if (PRIMARY_TEMPLATE_P (t))
DECL_PRIMARY_TEMPLATE (r) = r;
if (TREE_CODE (decl) != TYPE_DECL)
/* Record this non-type partial instantiation. */
register_specialization (r, t,
DECL_TI_ARGS (DECL_TEMPLATE_RESULT (r)));
}
break;
case FUNCTION_DECL:
{
tree ctx;
tree argvec = NULL_TREE;
tree *friends;
tree gen_tmpl;
int member;
int args_depth;
int parms_depth;
/* Nobody should be tsubst'ing into non-template functions. */
my_friendly_assert (DECL_TEMPLATE_INFO (t) != NULL_TREE, 0);
if (TREE_CODE (DECL_TI_TEMPLATE (t)) == TEMPLATE_DECL)
{
tree spec;
bool dependent_p;
/* If T is not dependent, just return it. We have to
increment PROCESSING_TEMPLATE_DECL because
value_dependent_expression_p assumes that nothing is
dependent when PROCESSING_TEMPLATE_DECL is zero. */
++processing_template_decl;
dependent_p = value_dependent_expression_p (t);
--processing_template_decl;
if (!dependent_p)
return t;
/* Calculate the most general template of which R is a
specialization, and the complete set of arguments used to
specialize R. */
gen_tmpl = most_general_template (DECL_TI_TEMPLATE (t));
argvec = tsubst_template_args (DECL_TI_ARGS
(DECL_TEMPLATE_RESULT (gen_tmpl)),
args, complain, in_decl);
/* Check to see if we already have this specialization. */
spec = retrieve_specialization (gen_tmpl, argvec);
if (spec)
{
r = spec;
break;
}
/* We can see more levels of arguments than parameters if
there was a specialization of a member template, like
this:
template <class T> struct S { template <class U> void f(); }
template <> template <class U> void S<int>::f(U);
Here, we'll be substituting into the specialization,
because that's where we can find the code we actually
want to generate, but we'll have enough arguments for
the most general template.
We also deal with the peculiar case:
template <class T> struct S {
template <class U> friend void f();
};
template <class U> void f() {}
template S<int>;
template void f<double>();
Here, the ARGS for the instantiation of will be {int,
double}. But, we only need as many ARGS as there are
levels of template parameters in CODE_PATTERN. We are
careful not to get fooled into reducing the ARGS in
situations like:
template <class T> struct S { template <class U> void f(U); }
template <class T> template <> void S<T>::f(int) {}
which we can spot because the pattern will be a
specialization in this case. */
args_depth = TMPL_ARGS_DEPTH (args);
parms_depth =
TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (DECL_TI_TEMPLATE (t)));
if (args_depth > parms_depth
&& !DECL_TEMPLATE_SPECIALIZATION (t))
args = get_innermost_template_args (args, parms_depth);
}
else
{
/* This special case arises when we have something like this:
template <class T> struct S {
friend void f<int>(int, double);
};
Here, the DECL_TI_TEMPLATE for the friend declaration
will be an IDENTIFIER_NODE. We are being called from
tsubst_friend_function, and we want only to create a
new decl (R) with appropriate types so that we can call
determine_specialization. */
gen_tmpl = NULL_TREE;
}
if (DECL_CLASS_SCOPE_P (t))
{
if (DECL_NAME (t) == constructor_name (DECL_CONTEXT (t)))
member = 2;
else
member = 1;
ctx = tsubst_aggr_type (DECL_CONTEXT (t), args,
complain, t, /*entering_scope=*/1);
}
else
{
member = 0;
ctx = DECL_CONTEXT (t);
}
type = tsubst (type, args, complain, in_decl);
if (type == error_mark_node)
return error_mark_node;
/* We do NOT check for matching decls pushed separately at this
point, as they may not represent instantiations of this
template, and in any case are considered separate under the
discrete model. */
r = copy_decl (t);
DECL_USE_TEMPLATE (r) = 0;
TREE_TYPE (r) = type;
/* Clear out the mangled name and RTL for the instantiation. */
SET_DECL_ASSEMBLER_NAME (r, NULL_TREE);
SET_DECL_RTL (r, NULL_RTX);
DECL_CONTEXT (r) = ctx;
if (member && DECL_CONV_FN_P (r))
/* Type-conversion operator. Reconstruct the name, in
case it's the name of one of the template's parameters. */
DECL_NAME (r) = mangle_conv_op_name_for_type (TREE_TYPE (type));
DECL_ARGUMENTS (r) = tsubst (DECL_ARGUMENTS (t), args,
complain, t);
DECL_RESULT (r) = NULL_TREE;
TREE_STATIC (r) = 0;
TREE_PUBLIC (r) = TREE_PUBLIC (t);
DECL_EXTERNAL (r) = 1;
DECL_INTERFACE_KNOWN (r) = 0;
DECL_DEFER_OUTPUT (r) = 0;
TREE_CHAIN (r) = NULL_TREE;
DECL_PENDING_INLINE_INFO (r) = 0;
DECL_PENDING_INLINE_P (r) = 0;
DECL_SAVED_TREE (r) = NULL_TREE;
TREE_USED (r) = 0;
if (DECL_CLONED_FUNCTION (r))
{
DECL_CLONED_FUNCTION (r) = tsubst (DECL_CLONED_FUNCTION (t),
args, complain, t);
TREE_CHAIN (r) = TREE_CHAIN (DECL_CLONED_FUNCTION (r));
TREE_CHAIN (DECL_CLONED_FUNCTION (r)) = r;
}
/* Set up the DECL_TEMPLATE_INFO for R. There's no need to do
this in the special friend case mentioned above where
GEN_TMPL is NULL. */
if (gen_tmpl)
{
DECL_TEMPLATE_INFO (r)
= tree_cons (gen_tmpl, argvec, NULL_TREE);
SET_DECL_IMPLICIT_INSTANTIATION (r);
register_specialization (r, gen_tmpl, argvec);
/* We're not supposed to instantiate default arguments
until they are called, for a template. But, for a
declaration like:
template <class T> void f ()
{ extern void g(int i = T()); }
we should do the substitution when the template is
instantiated. We handle the member function case in
instantiate_class_template since the default arguments
might refer to other members of the class. */
if (!member
&& !PRIMARY_TEMPLATE_P (gen_tmpl)
&& !uses_template_parms (argvec))
tsubst_default_arguments (r);
}
/* Copy the list of befriending classes. */
for (friends = &DECL_BEFRIENDING_CLASSES (r);
*friends;
friends = &TREE_CHAIN (*friends))
{
*friends = copy_node (*friends);
TREE_VALUE (*friends) = tsubst (TREE_VALUE (*friends),
args, complain,
in_decl);
}
if (DECL_CONSTRUCTOR_P (r) || DECL_DESTRUCTOR_P (r))
{
maybe_retrofit_in_chrg (r);
if (DECL_CONSTRUCTOR_P (r))
grok_ctor_properties (ctx, r);
/* If this is an instantiation of a member template, clone it.
If it isn't, that'll be handled by
clone_constructors_and_destructors. */
if (PRIMARY_TEMPLATE_P (gen_tmpl))
clone_function_decl (r, /*update_method_vec_p=*/0);
}
else if (IDENTIFIER_OPNAME_P (DECL_NAME (r)))
grok_op_properties (r, DECL_FRIEND_P (r),
(complain & tf_error) != 0);
}
break;
case PARM_DECL:
{
r = copy_node (t);
if (DECL_TEMPLATE_PARM_P (t))
SET_DECL_TEMPLATE_PARM_P (r);
TREE_TYPE (r) = type;
c_apply_type_quals_to_decl (cp_type_quals (type), r);
if (DECL_INITIAL (r))
{
if (TREE_CODE (DECL_INITIAL (r)) != TEMPLATE_PARM_INDEX)
DECL_INITIAL (r) = TREE_TYPE (r);
else
DECL_INITIAL (r) = tsubst (DECL_INITIAL (r), args,
complain, in_decl);
}
DECL_CONTEXT (r) = NULL_TREE;
if (!DECL_TEMPLATE_PARM_P (r))
DECL_ARG_TYPE (r) = type_passed_as (type);
if (TREE_CHAIN (t))
TREE_CHAIN (r) = tsubst (TREE_CHAIN (t), args,
complain, TREE_CHAIN (t));
}
break;
case FIELD_DECL:
{
r = copy_decl (t);
TREE_TYPE (r) = type;
c_apply_type_quals_to_decl (cp_type_quals (type), r);
/* We don't have to set DECL_CONTEXT here; it is set by
finish_member_declaration. */
DECL_INITIAL (r) = tsubst_expr (DECL_INITIAL (t), args,
complain, in_decl);
TREE_CHAIN (r) = NULL_TREE;
if (VOID_TYPE_P (type))
cp_error_at ("instantiation of `%D' as type `%T'", r, type);
}
break;
case USING_DECL:
{
r = copy_node (t);
/* It is not a dependent using decl any more. */
TREE_TYPE (r) = void_type_node;
DECL_INITIAL (r)
= tsubst_copy (DECL_INITIAL (t), args, complain, in_decl);
DECL_NAME (r)
= tsubst_copy (DECL_NAME (t), args, complain, in_decl);
TREE_CHAIN (r) = NULL_TREE;
}
break;
case TYPE_DECL:
if (TREE_CODE (type) == TEMPLATE_TEMPLATE_PARM
|| t == TYPE_MAIN_DECL (TREE_TYPE (t)))
{
/* If this is the canonical decl, we don't have to mess with
instantiations, and often we can't (for typename, template
type parms and such). Note that TYPE_NAME is not correct for
the above test if we've copied the type for a typedef. */
r = TYPE_NAME (type);
break;
}
/* Fall through. */
case VAR_DECL:
{
tree argvec = NULL_TREE;
tree gen_tmpl = NULL_TREE;
tree spec;
tree tmpl = NULL_TREE;
tree ctx;
int local_p;
/* Assume this is a non-local variable. */
local_p = 0;
if (TYPE_P (CP_DECL_CONTEXT (t)))
ctx = tsubst_aggr_type (DECL_CONTEXT (t), args,
complain,
in_decl, /*entering_scope=*/1);
else if (DECL_NAMESPACE_SCOPE_P (t))
ctx = DECL_CONTEXT (t);
else
{
/* Subsequent calls to pushdecl will fill this in. */
ctx = NULL_TREE;
local_p = 1;
}
/* Check to see if we already have this specialization. */
if (!local_p)
{
tmpl = DECL_TI_TEMPLATE (t);
gen_tmpl = most_general_template (tmpl);
argvec = tsubst (DECL_TI_ARGS (t), args, complain, in_decl);
spec = retrieve_specialization (gen_tmpl, argvec);
}
else
spec = retrieve_local_specialization (t);
if (spec)
{
r = spec;
break;
}
r = copy_decl (t);
if (TREE_CODE (r) == VAR_DECL)
{
type = complete_type (type);
DECL_INITIALIZED_BY_CONSTANT_EXPRESSION_P (r)
= DECL_INITIALIZED_BY_CONSTANT_EXPRESSION_P (t);
}
else if (DECL_SELF_REFERENCE_P (t))
SET_DECL_SELF_REFERENCE_P (r);
TREE_TYPE (r) = type;
c_apply_type_quals_to_decl (cp_type_quals (type), r);
DECL_CONTEXT (r) = ctx;
/* Clear out the mangled name and RTL for the instantiation. */
SET_DECL_ASSEMBLER_NAME (r, NULL_TREE);
SET_DECL_RTL (r, NULL_RTX);
/* Don't try to expand the initializer until someone tries to use
this variable; otherwise we run into circular dependencies. */
DECL_INITIAL (r) = NULL_TREE;
SET_DECL_RTL (r, NULL_RTX);
DECL_SIZE (r) = DECL_SIZE_UNIT (r) = 0;
/* Even if the original location is out of scope, the newly
substituted one is not. */
if (TREE_CODE (r) == VAR_DECL)
{
DECL_DEAD_FOR_LOCAL (r) = 0;
DECL_INITIALIZED_P (r) = 0;
}
if (!local_p)
{
/* A static data member declaration is always marked
external when it is declared in-class, even if an
initializer is present. We mimic the non-template
processing here. */
DECL_EXTERNAL (r) = 1;
register_specialization (r, gen_tmpl, argvec);
DECL_TEMPLATE_INFO (r) = tree_cons (tmpl, argvec, NULL_TREE);
SET_DECL_IMPLICIT_INSTANTIATION (r);
}
else
register_local_specialization (r, t);
TREE_CHAIN (r) = NULL_TREE;
if (TREE_CODE (r) == VAR_DECL && VOID_TYPE_P (type))
cp_error_at ("instantiation of `%D' as type `%T'", r, type);
/* Compute the size, alignment, etc. of R. */
layout_decl (r, 0);
}
break;
default:
abort ();
}
/* Restore the file and line information. */
input_location = saved_loc;
return r;
}
/* Substitute into the ARG_TYPES of a function type. */
static tree
tsubst_arg_types (tree arg_types,
tree args,
tsubst_flags_t complain,
tree in_decl)
{
tree remaining_arg_types;
tree type;
if (!arg_types || arg_types == void_list_node)
return arg_types;
remaining_arg_types = tsubst_arg_types (TREE_CHAIN (arg_types),
args, complain, in_decl);
if (remaining_arg_types == error_mark_node)
return error_mark_node;
type = tsubst (TREE_VALUE (arg_types), args, complain, in_decl);
if (type == error_mark_node)
return error_mark_node;
if (VOID_TYPE_P (type))
{
if (complain & tf_error)
{
error ("invalid parameter type `%T'", type);
if (in_decl)
cp_error_at ("in declaration `%D'", in_decl);
}
return error_mark_node;
}
/* Do array-to-pointer, function-to-pointer conversion, and ignore
top-level qualifiers as required. */
type = TYPE_MAIN_VARIANT (type_decays_to (type));
/* Note that we do not substitute into default arguments here. The
standard mandates that they be instantiated only when needed,
which is done in build_over_call. */
return hash_tree_cons (TREE_PURPOSE (arg_types), type,
remaining_arg_types);
}
/* Substitute into a FUNCTION_TYPE or METHOD_TYPE. This routine does
*not* handle the exception-specification for FNTYPE, because the
initial substitution of explicitly provided template parameters
during argument deduction forbids substitution into the
exception-specification:
[temp.deduct]
All references in the function type of the function template to the
corresponding template parameters are replaced by the specified tem-
plate argument values. If a substitution in a template parameter or
in the function type of the function template results in an invalid
type, type deduction fails. [Note: The equivalent substitution in
exception specifications is done only when the function is instanti-
ated, at which point a program is ill-formed if the substitution
results in an invalid type.] */
static tree
tsubst_function_type (tree t,
tree args,
tsubst_flags_t complain,
tree in_decl)
{
tree return_type;
tree arg_types;
tree fntype;
/* The TYPE_CONTEXT is not used for function/method types. */
my_friendly_assert (TYPE_CONTEXT (t) == NULL_TREE, 0);
/* Substitute the return type. */
return_type = tsubst (TREE_TYPE (t), args, complain, in_decl);
if (return_type == error_mark_node)
return error_mark_node;
/* Substitute the argument types. */
arg_types = tsubst_arg_types (TYPE_ARG_TYPES (t), args,
complain, in_decl);
if (arg_types == error_mark_node)
return error_mark_node;
/* Construct a new type node and return it. */
if (TREE_CODE (t) == FUNCTION_TYPE)
fntype = build_function_type (return_type, arg_types);
else
{
tree r = TREE_TYPE (TREE_VALUE (arg_types));
if (! IS_AGGR_TYPE (r))
{
/* [temp.deduct]
Type deduction may fail for any of the following
reasons:
-- Attempting to create "pointer to member of T" when T
is not a class type. */
if (complain & tf_error)
error ("creating pointer to member function of non-class type `%T'",
r);
return error_mark_node;
}
fntype = build_method_type_directly (r, return_type,
TREE_CHAIN (arg_types));
}
fntype = cp_build_qualified_type_real (fntype, TYPE_QUALS (t), complain);
fntype = build_type_attribute_variant (fntype, TYPE_ATTRIBUTES (t));
return fntype;
}
/* Substitute into the PARMS of a call-declarator. */
static tree
tsubst_call_declarator_parms (tree parms,
tree args,
tsubst_flags_t complain,
tree in_decl)
{
tree new_parms;
tree type;
tree defarg;
if (!parms || parms == void_list_node)
return parms;
new_parms = tsubst_call_declarator_parms (TREE_CHAIN (parms),
args, complain, in_decl);
/* Figure out the type of this parameter. */
type = tsubst (TREE_VALUE (parms), args, complain, in_decl);
/* Figure out the default argument as well. Note that we use
tsubst_expr since the default argument is really an expression. */
defarg = tsubst_expr (TREE_PURPOSE (parms), args, complain, in_decl);
/* Chain this parameter on to the front of those we have already
processed. We don't use hash_tree_cons because that function
doesn't check TREE_PARMLIST. */
new_parms = tree_cons (defarg, type, new_parms);
/* And note that these are parameters. */
TREE_PARMLIST (new_parms) = 1;
return new_parms;
}
/* Take the tree structure T and replace template parameters used
therein with the argument vector ARGS. IN_DECL is an associated
decl for diagnostics. If an error occurs, returns ERROR_MARK_NODE.
Issue error and warning messages under control of COMPLAIN. Note
that we must be relatively non-tolerant of extensions here, in
order to preserve conformance; if we allow substitutions that
should not be allowed, we may allow argument deductions that should
not succeed, and therefore report ambiguous overload situations
where there are none. In theory, we could allow the substitution,
but indicate that it should have failed, and allow our caller to
make sure that the right thing happens, but we don't try to do this
yet.
This function is used for dealing with types, decls and the like;
for expressions, use tsubst_expr or tsubst_copy. */
static tree
tsubst (tree t, tree args, tsubst_flags_t complain, tree in_decl)
{
tree type, r;
if (t == NULL_TREE || t == error_mark_node
|| t == integer_type_node
|| t == void_type_node
|| t == char_type_node
|| TREE_CODE (t) == NAMESPACE_DECL)
return t;
if (TREE_CODE (t) == IDENTIFIER_NODE)
type = IDENTIFIER_TYPE_VALUE (t);
else
type = TREE_TYPE (t);
my_friendly_assert (type != unknown_type_node, 20030716);
if (type && TREE_CODE (t) != FUNCTION_DECL
&& TREE_CODE (t) != TYPENAME_TYPE
&& TREE_CODE (t) != TEMPLATE_DECL
&& TREE_CODE (t) != IDENTIFIER_NODE
&& TREE_CODE (t) != FUNCTION_TYPE
&& TREE_CODE (t) != METHOD_TYPE)
type = tsubst (type, args, complain, in_decl);
if (type == error_mark_node)
return error_mark_node;
if (DECL_P (t))
return tsubst_decl (t, args, type, complain);
switch (TREE_CODE (t))
{
case RECORD_TYPE:
case UNION_TYPE:
case ENUMERAL_TYPE:
return tsubst_aggr_type (t, args, complain, in_decl,
/*entering_scope=*/0);
case ERROR_MARK:
case IDENTIFIER_NODE:
case VOID_TYPE:
case REAL_TYPE:
case COMPLEX_TYPE:
case VECTOR_TYPE:
case BOOLEAN_TYPE:
case INTEGER_CST:
case REAL_CST:
case STRING_CST:
return t;
case INTEGER_TYPE:
if (t == integer_type_node)
return t;
if (TREE_CODE (TYPE_MIN_VALUE (t)) == INTEGER_CST
&& TREE_CODE (TYPE_MAX_VALUE (t)) == INTEGER_CST)
return t;
{
tree max, omax = TREE_OPERAND (TYPE_MAX_VALUE (t), 0);
/* The array dimension behaves like a non-type template arg,
in that we want to fold it as much as possible. */
max = tsubst_template_arg (omax, args, complain, in_decl);
if (!processing_template_decl)
max = decl_constant_value (max);
if (processing_template_decl
/* When providing explicit arguments to a template
function, but leaving some arguments for subsequent
deduction, MAX may be template-dependent even if we're
not PROCESSING_TEMPLATE_DECL. We still need to check for
template parms, though; MAX won't be an INTEGER_CST for
dynamic arrays, either. */
|| (TREE_CODE (max) != INTEGER_CST
&& uses_template_parms (max)))
{
tree itype = make_node (INTEGER_TYPE);
TYPE_MIN_VALUE (itype) = size_zero_node;
TYPE_MAX_VALUE (itype) = build_min (MINUS_EXPR, sizetype, max,
integer_one_node);
return itype;
}
if (integer_zerop (omax))
{
/* Still allow an explicit array of size zero. */
if (pedantic)
pedwarn ("creating array with size zero");
}
else if (integer_zerop (max)
|| (TREE_CODE (max) == INTEGER_CST
&& INT_CST_LT (max, integer_zero_node)))
{
/* [temp.deduct]
Type deduction may fail for any of the following
reasons:
Attempting to create an array with a size that is
zero or negative. */
if (complain & tf_error)
error ("creating array with size zero (`%E')", max);
return error_mark_node;
}
return compute_array_index_type (NULL_TREE, max);
}
case TEMPLATE_TYPE_PARM:
case TEMPLATE_TEMPLATE_PARM:
case BOUND_TEMPLATE_TEMPLATE_PARM:
case TEMPLATE_PARM_INDEX:
{
int idx;
int level;
int levels;
r = NULL_TREE;
if (TREE_CODE (t) == TEMPLATE_TYPE_PARM
|| TREE_CODE (t) == TEMPLATE_TEMPLATE_PARM
|| TREE_CODE (t) == BOUND_TEMPLATE_TEMPLATE_PARM)
{
idx = TEMPLATE_TYPE_IDX (t);
level = TEMPLATE_TYPE_LEVEL (t);
}
else
{
idx = TEMPLATE_PARM_IDX (t);
level = TEMPLATE_PARM_LEVEL (t);
}
if (TREE_VEC_LENGTH (args) > 0)
{
tree arg = NULL_TREE;
levels = TMPL_ARGS_DEPTH (args);
if (level <= levels)
arg = TMPL_ARG (args, level, idx);
if (arg == error_mark_node)
return error_mark_node;
else if (arg != NULL_TREE)
{
if (TREE_CODE (t) == TEMPLATE_TYPE_PARM)
{
my_friendly_assert (TYPE_P (arg), 0);
return cp_build_qualified_type_real
(arg, cp_type_quals (arg) | cp_type_quals (t),
complain | tf_ignore_bad_quals);
}
else if (TREE_CODE (t) == BOUND_TEMPLATE_TEMPLATE_PARM)
{
/* We are processing a type constructed from
a template template parameter */
tree argvec = tsubst (TYPE_TI_ARGS (t),
args, complain, in_decl);
if (argvec == error_mark_node)
return error_mark_node;
/* We can get a TEMPLATE_TEMPLATE_PARM here when
we are resolving nested-types in the signature of
a member function templates.
Otherwise ARG is a TEMPLATE_DECL and is the real
template to be instantiated. */
if (TREE_CODE (arg) == TEMPLATE_TEMPLATE_PARM)
arg = TYPE_NAME (arg);
r = lookup_template_class (arg,
argvec, in_decl,
DECL_CONTEXT (arg),
/*entering_scope=*/0,
complain);
return cp_build_qualified_type_real
(r, TYPE_QUALS (t), complain);
}
else
/* TEMPLATE_TEMPLATE_PARM or TEMPLATE_PARM_INDEX. */
return arg;
}
}
else
abort ();
if (level == 1)
/* This can happen during the attempted tsubst'ing in
unify. This means that we don't yet have any information
about the template parameter in question. */
return t;
/* If we get here, we must have been looking at a parm for a
more deeply nested template. Make a new version of this
template parameter, but with a lower level. */
switch (TREE_CODE (t))
{
case TEMPLATE_TYPE_PARM:
case TEMPLATE_TEMPLATE_PARM:
case BOUND_TEMPLATE_TEMPLATE_PARM:
if (cp_type_quals (t))
{
r = tsubst (TYPE_MAIN_VARIANT (t), args, complain, in_decl);
r = cp_build_qualified_type_real
(r, cp_type_quals (t),
complain | (TREE_CODE (t) == TEMPLATE_TYPE_PARM
? tf_ignore_bad_quals : 0));
}
else
{
r = copy_type (t);
TEMPLATE_TYPE_PARM_INDEX (r)
= reduce_template_parm_level (TEMPLATE_TYPE_PARM_INDEX (t),
r, levels);
TYPE_STUB_DECL (r) = TYPE_NAME (r) = TEMPLATE_TYPE_DECL (r);
TYPE_MAIN_VARIANT (r) = r;
TYPE_POINTER_TO (r) = NULL_TREE;
TYPE_REFERENCE_TO (r) = NULL_TREE;
if (TREE_CODE (t) == BOUND_TEMPLATE_TEMPLATE_PARM)
{
tree argvec = tsubst (TYPE_TI_ARGS (t), args,
complain, in_decl);
if (argvec == error_mark_node)
return error_mark_node;
TEMPLATE_TEMPLATE_PARM_TEMPLATE_INFO (r)
= tree_cons (TYPE_TI_TEMPLATE (t), argvec, NULL_TREE);
}
}
break;
case TEMPLATE_PARM_INDEX:
r = reduce_template_parm_level (t, type, levels);
break;
default:
abort ();
}
return r;
}
case TREE_LIST:
{
tree purpose, value, chain, result;
if (t == void_list_node)
return t;
purpose = TREE_PURPOSE (t);
if (purpose)
{
purpose = tsubst (purpose, args, complain, in_decl);
if (purpose == error_mark_node)
return error_mark_node;
}
value = TREE_VALUE (t);
if (value)
{
value = tsubst (value, args, complain, in_decl);
if (value == error_mark_node)
return error_mark_node;
}
chain = TREE_CHAIN (t);
if (chain && chain != void_type_node)
{
chain = tsubst (chain, args, complain, in_decl);
if (chain == error_mark_node)
return error_mark_node;
}
if (purpose == TREE_PURPOSE (t)
&& value == TREE_VALUE (t)
&& chain == TREE_CHAIN (t))
return t;
if (TREE_PARMLIST (t))
{
result = tree_cons (purpose, value, chain);
TREE_PARMLIST (result) = 1;
}
else
result = hash_tree_cons (purpose, value, chain);
return result;
}
case TREE_VEC:
if (type != NULL_TREE)
{
/* A binfo node. We always need to make a copy, of the node
itself and of its BINFO_BASETYPES. */
t = copy_node (t);
/* Make sure type isn't a typedef copy. */
type = BINFO_TYPE (TYPE_BINFO (type));
TREE_TYPE (t) = complete_type (type);
if (IS_AGGR_TYPE (type))
{
BINFO_VTABLE (t) = TYPE_BINFO_VTABLE (type);
BINFO_VIRTUALS (t) = TYPE_BINFO_VIRTUALS (type);
if (TYPE_BINFO_BASETYPES (type) != NULL_TREE)
BINFO_BASETYPES (t) = copy_node (TYPE_BINFO_BASETYPES (type));
}
return t;
}
/* Otherwise, a vector of template arguments. */
return tsubst_template_args (t, args, complain, in_decl);
case POINTER_TYPE:
case REFERENCE_TYPE:
{
enum tree_code code;
if (type == TREE_TYPE (t) && TREE_CODE (type) != METHOD_TYPE)
return t;
code = TREE_CODE (t);
/* [temp.deduct]
Type deduction may fail for any of the following
reasons:
-- Attempting to create a pointer to reference type.
-- Attempting to create a reference to a reference type or
a reference to void. */
if (TREE_CODE (type) == REFERENCE_TYPE
|| (code == REFERENCE_TYPE && TREE_CODE (type) == VOID_TYPE))
{
static location_t last_loc;
/* We keep track of the last time we issued this error
message to avoid spewing a ton of messages during a
single bad template instantiation. */
if (complain & tf_error
&& (last_loc.line != input_line
|| last_loc.file != input_filename))
{
if (TREE_CODE (type) == VOID_TYPE)
error ("forming reference to void");
else
error ("forming %s to reference type `%T'",
(code == POINTER_TYPE) ? "pointer" : "reference",
type);
last_loc = input_location;
}
return error_mark_node;
}
else if (code == POINTER_TYPE)
{
r = build_pointer_type (type);
if (TREE_CODE (type) == METHOD_TYPE)
r = build_ptrmemfunc_type (r);
}
else
r = build_reference_type (type);
r = cp_build_qualified_type_real (r, TYPE_QUALS (t), complain);
if (r != error_mark_node)
/* Will this ever be needed for TYPE_..._TO values? */
layout_type (r);
return r;
}
case OFFSET_TYPE:
{
r = tsubst (TYPE_OFFSET_BASETYPE (t), args, complain, in_decl);
if (r == error_mark_node || !IS_AGGR_TYPE (r))
{
/* [temp.deduct]
Type deduction may fail for any of the following
reasons:
-- Attempting to create "pointer to member of T" when T
is not a class type. */
if (complain & tf_error)
error ("creating pointer to member of non-class type `%T'", r);
return error_mark_node;
}
if (TREE_CODE (type) == REFERENCE_TYPE)
{
if (complain & tf_error)
error ("creating pointer to member reference type `%T'", type);
return error_mark_node;
}
my_friendly_assert (TREE_CODE (type) != METHOD_TYPE, 20011231);
if (TREE_CODE (type) == FUNCTION_TYPE)
{
/* This is really a method type. The cv qualifiers of the
this pointer should _not_ be determined by the cv
qualifiers of the class type. They should be held
somewhere in the FUNCTION_TYPE, but we don't do that at
the moment. Consider
typedef void (Func) () const;
template <typename T1> void Foo (Func T1::*);
*/
tree method_type;
method_type = build_method_type_directly (TYPE_MAIN_VARIANT (r),
TREE_TYPE (type),
TYPE_ARG_TYPES (type));
return build_ptrmemfunc_type (build_pointer_type (method_type));
}
else
return cp_build_qualified_type_real (build_ptrmem_type (r, type),
TYPE_QUALS (t),
complain);
}
case FUNCTION_TYPE:
case METHOD_TYPE:
{
tree fntype;
tree raises;
fntype = tsubst_function_type (t, args, complain, in_decl);
if (fntype == error_mark_node)
return error_mark_node;
/* Substitute the exception specification. */
raises = TYPE_RAISES_EXCEPTIONS (t);
if (raises)
{
tree list = NULL_TREE;
if (! TREE_VALUE (raises))
list = raises;
else
for (; raises != NULL_TREE; raises = TREE_CHAIN (raises))
{
tree spec = TREE_VALUE (raises);
spec = tsubst (spec, args, complain, in_decl);
if (spec == error_mark_node)
return spec;
list = add_exception_specifier (list, spec, complain);
}
fntype = build_exception_variant (fntype, list);
}
return fntype;
}
case ARRAY_TYPE:
{
tree domain = tsubst (TYPE_DOMAIN (t), args, complain, in_decl);
if (domain == error_mark_node)
return error_mark_node;
/* As an optimization, we avoid regenerating the array type if
it will obviously be the same as T. */
if (type == TREE_TYPE (t) && domain == TYPE_DOMAIN (t))
return t;
/* These checks should match the ones in grokdeclarator.
[temp.deduct]
The deduction may fail for any of the following reasons:
-- Attempting to create an array with an element type that
is void, a function type, or a reference type. */
if (TREE_CODE (type) == VOID_TYPE
|| TREE_CODE (type) == FUNCTION_TYPE
|| TREE_CODE (type) == REFERENCE_TYPE)
{
if (complain & tf_error)
error ("creating array of `%T'", type);
return error_mark_node;
}
r = build_cplus_array_type (type, domain);
return r;
}
case PLUS_EXPR:
case MINUS_EXPR:
{
tree e1 = tsubst (TREE_OPERAND (t, 0), args, complain, in_decl);
tree e2 = tsubst (TREE_OPERAND (t, 1), args, complain, in_decl);
if (e1 == error_mark_node || e2 == error_mark_node)
return error_mark_node;
return fold (build (TREE_CODE (t), TREE_TYPE (t), e1, e2));
}
case NEGATE_EXPR:
case NOP_EXPR:
{
tree e = tsubst (TREE_OPERAND (t, 0), args, complain, in_decl);
if (e == error_mark_node)
return error_mark_node;
return fold (build (TREE_CODE (t), TREE_TYPE (t), e));
}
case TYPENAME_TYPE:
{
tree ctx = tsubst_aggr_type (TYPE_CONTEXT (t), args, complain,
in_decl, /*entering_scope=*/1);
tree f = tsubst_copy (TYPENAME_TYPE_FULLNAME (t), args,
complain, in_decl);
if (ctx == error_mark_node || f == error_mark_node)
return error_mark_node;
if (!IS_AGGR_TYPE (ctx))
{
if (complain & tf_error)
error ("`%T' is not a class, struct, or union type",
ctx);
return error_mark_node;
}
else if (!uses_template_parms (ctx) && !TYPE_BEING_DEFINED (ctx))
{
/* Normally, make_typename_type does not require that the CTX
have complete type in order to allow things like:
template <class T> struct S { typename S<T>::X Y; };
But, such constructs have already been resolved by this
point, so here CTX really should have complete type, unless
it's a partial instantiation. */
ctx = complete_type (ctx);
if (!COMPLETE_TYPE_P (ctx))
{
if (complain & tf_error)
cxx_incomplete_type_error (NULL_TREE, ctx);
return error_mark_node;
}
}
f = make_typename_type (ctx, f,
(complain & tf_error) | tf_keep_type_decl);
if (f == error_mark_node)
return f;
if (TREE_CODE (f) == TYPE_DECL)
{
complain |= tf_ignore_bad_quals;
f = TREE_TYPE (f);
}
return cp_build_qualified_type_real
(f, cp_type_quals (f) | cp_type_quals (t), complain);
}
case UNBOUND_CLASS_TEMPLATE:
{
tree ctx = tsubst_aggr_type (TYPE_CONTEXT (t), args, complain,
in_decl, /*entering_scope=*/1);
tree name = TYPE_IDENTIFIER (t);
if (ctx == error_mark_node || name == error_mark_node)
return error_mark_node;
return make_unbound_class_template (ctx, name, complain);
}
case INDIRECT_REF:
{
tree e = tsubst (TREE_OPERAND (t, 0), args, complain, in_decl);
if (e == error_mark_node)
return error_mark_node;
return make_pointer_declarator (type, e);
}
case ADDR_EXPR:
{
tree e = tsubst (TREE_OPERAND (t, 0), args, complain, in_decl);
if (e == error_mark_node)
return error_mark_node;
return make_reference_declarator (type, e);
}
case ARRAY_REF:
{
tree e1 = tsubst (TREE_OPERAND (t, 0), args, complain, in_decl);
tree e2 = tsubst_expr (TREE_OPERAND (t, 1), args, complain, in_decl);
if (e1 == error_mark_node || e2 == error_mark_node)
return error_mark_node;
return build_nt (ARRAY_REF, e1, e2);
}
case CALL_EXPR:
{
tree e1 = tsubst (TREE_OPERAND (t, 0), args, complain, in_decl);
tree e2 = (tsubst_call_declarator_parms
(CALL_DECLARATOR_PARMS (t), args, complain, in_decl));
tree e3 = tsubst (CALL_DECLARATOR_EXCEPTION_SPEC (t), args,
complain, in_decl);
if (e1 == error_mark_node || e2 == error_mark_node
|| e3 == error_mark_node)
return error_mark_node;
return make_call_declarator (e1, e2, CALL_DECLARATOR_QUALS (t), e3);
}
case SCOPE_REF:
{
tree e1 = tsubst (TREE_OPERAND (t, 0), args, complain, in_decl);
tree e2 = tsubst (TREE_OPERAND (t, 1), args, complain, in_decl);
if (e1 == error_mark_node || e2 == error_mark_node)
return error_mark_node;
return build_nt (TREE_CODE (t), e1, e2);
}
case TYPEOF_TYPE:
{
tree e1 = tsubst_expr (TYPE_FIELDS (t), args, complain, in_decl);
if (e1 == error_mark_node)
return error_mark_node;
return cp_build_qualified_type_real (TREE_TYPE (e1),
cp_type_quals (t)
| cp_type_quals (TREE_TYPE (e1)),
complain);
}
default:
sorry ("use of `%s' in template",
tree_code_name [(int) TREE_CODE (t)]);
return error_mark_node;
}
}
/* Like tsubst_expr for a BASELINK. OBJECT_TYPE, if non-NULL, is the
type of the expression on the left-hand side of the "." or "->"
operator. */
static tree
tsubst_baselink (tree baselink, tree object_type,
tree args, tsubst_flags_t complain, tree in_decl)
{
tree name;
tree qualifying_scope;
tree fns;
tree template_args = 0;
bool template_id_p = false;
/* A baselink indicates a function from a base class. The
BASELINK_ACCESS_BINFO and BASELINK_BINFO are going to have
non-dependent types; otherwise, the lookup could not have
succeeded. However, they may indicate bases of the template
class, rather than the instantiated class.
In addition, lookups that were not ambiguous before may be
ambiguous now. Therefore, we perform the lookup again. */
qualifying_scope = BINFO_TYPE (BASELINK_ACCESS_BINFO (baselink));
fns = BASELINK_FUNCTIONS (baselink);
if (TREE_CODE (fns) == TEMPLATE_ID_EXPR)
{
template_id_p = true;
template_args = TREE_OPERAND (fns, 1);
fns = TREE_OPERAND (fns, 0);
if (template_args)
template_args = tsubst_template_args (template_args, args,
complain, in_decl);
}
name = DECL_NAME (get_first_fn (fns));
baselink = lookup_fnfields (qualifying_scope, name, /*protect=*/1);
if (BASELINK_P (baselink) && template_id_p)
BASELINK_FUNCTIONS (baselink)
= build_nt (TEMPLATE_ID_EXPR,
BASELINK_FUNCTIONS (baselink),
template_args);
if (!object_type)
object_type = current_class_type;
return adjust_result_of_qualified_name_lookup (baselink,
qualifying_scope,
object_type);
}
/* Like tsubst_expr for a SCOPE_REF, given by QUALIFIED_ID. DONE is
true if the qualified-id will be a postfix-expression in-and-of
itself; false if more of the postfix-expression follows the
QUALIFIED_ID. ADDRESS_P is true if the qualified-id is the operand
of "&". */
static tree
tsubst_qualified_id (tree qualified_id, tree args,
tsubst_flags_t complain, tree in_decl,
bool done, bool address_p)
{
tree expr;
tree scope;
tree name;
bool is_template;
tree template_args;
my_friendly_assert (TREE_CODE (qualified_id) == SCOPE_REF, 20030706);
/* Figure out what name to look up. */
name = TREE_OPERAND (qualified_id, 1);
if (TREE_CODE (name) == TEMPLATE_ID_EXPR)
{
is_template = true;
template_args = TREE_OPERAND (name, 1);
if (template_args)
template_args = tsubst_template_args (template_args, args,
complain, in_decl);
name = TREE_OPERAND (name, 0);
}
else
{
is_template = false;
template_args = NULL_TREE;
}
/* Substitute into the qualifying scope. When there are no ARGS, we
are just trying to simplify a non-dependent expression. In that
case the qualifying scope may be dependent, and, in any case,
substituting will not help. */
scope = TREE_OPERAND (qualified_id, 0);
if (args)
{
scope = tsubst (scope, args, complain, in_decl);
expr = tsubst_copy (name, args, complain, in_decl);
}
else
expr = name;
my_friendly_assert (!dependent_type_p (scope), 20030729);
if (!BASELINK_P (name) && !DECL_P (expr))
{
expr = lookup_qualified_name (scope, expr, /*is_type_p=*/0, false);
if (TREE_CODE (TREE_CODE (expr) == TEMPLATE_DECL
? DECL_TEMPLATE_RESULT (expr) : expr) == TYPE_DECL)
{
if (complain & tf_error)
error ("`%E' names a type, but a non-type is expected",
qualified_id);
return error_mark_node;
}
}
if (DECL_P (expr))
check_accessibility_of_qualified_id (expr, /*object_type=*/NULL_TREE,
scope);
/* Remember that there was a reference to this entity. */
if (DECL_P (expr))
{
mark_used (expr);
if (!args && TREE_CODE (expr) == VAR_DECL)
expr = DECL_INITIAL (expr);
}
if (is_template)
expr = lookup_template_function (expr, template_args);
if (expr == error_mark_node && complain & tf_error)
qualified_name_lookup_error (scope, TREE_OPERAND (qualified_id, 1));
else if (TYPE_P (scope))
{
expr = (adjust_result_of_qualified_name_lookup
(expr, scope, current_class_type));
expr = finish_qualified_id_expr (scope, expr, done, address_p);
}
return expr;
}
/* Like tsubst, but deals with expressions. This function just replaces
template parms; to finish processing the resultant expression, use
tsubst_expr. */
static tree
tsubst_copy (tree t, tree args, tsubst_flags_t complain, tree in_decl)
{
enum tree_code code;
tree r;
if (t == NULL_TREE || t == error_mark_node)
return t;
code = TREE_CODE (t);
switch (code)
{
case PARM_DECL:
r = retrieve_local_specialization (t);
my_friendly_assert (r != NULL, 20020903);
return r;
case CONST_DECL:
{
tree enum_type;
tree v;
if (DECL_TEMPLATE_PARM_P (t))
return tsubst_copy (DECL_INITIAL (t), args, complain, in_decl);
/* There is no need to substitute into namespace-scope
enumerators. */
if (DECL_NAMESPACE_SCOPE_P (t))
return t;
/* Unfortunately, we cannot just call lookup_name here.
Consider:
template <int I> int f() {
enum E { a = I };
struct S { void g() { E e = a; } };
};
When we instantiate f<7>::S::g(), say, lookup_name is not
clever enough to find f<7>::a. */
enum_type
= tsubst_aggr_type (TREE_TYPE (t), args, complain, in_decl,
/*entering_scope=*/0);
for (v = TYPE_VALUES (enum_type);
v != NULL_TREE;
v = TREE_CHAIN (v))
if (TREE_PURPOSE (v) == DECL_NAME (t))
return TREE_VALUE (v);
/* We didn't find the name. That should never happen; if
name-lookup found it during preliminary parsing, we
should find it again here during instantiation. */
abort ();
}
return t;
case FIELD_DECL:
if (DECL_CONTEXT (t))
{
tree ctx;
ctx = tsubst_aggr_type (DECL_CONTEXT (t), args, complain, in_decl,
/*entering_scope=*/1);
if (ctx != DECL_CONTEXT (t))
return lookup_field (ctx, DECL_NAME (t), 0, false);
}
return t;
case VAR_DECL:
case FUNCTION_DECL:
if ((DECL_LANG_SPECIFIC (t) && DECL_TEMPLATE_INFO (t))
|| local_variable_p (t))
t = tsubst (t, args, complain, in_decl);
mark_used (t);
return t;
case BASELINK:
return tsubst_baselink (t, current_class_type, args, complain, in_decl);
case TEMPLATE_DECL:
if (DECL_TEMPLATE_TEMPLATE_PARM_P (t))
return tsubst (TREE_TYPE (DECL_TEMPLATE_RESULT (t)),
args, complain, in_decl);
else if (is_member_template (t))
return tsubst (t, args, complain, in_decl);
else if (DECL_CLASS_SCOPE_P (t)
&& uses_template_parms (DECL_CONTEXT (t)))
{
/* Template template argument like the following example need
special treatment:
template <template <class> class TT> struct C {};
template <class T> struct D {
template <class U> struct E {};
C<E> c; // #1
};
D<int> d; // #2
We are processing the template argument `E' in #1 for
the template instantiation #2. Originally, `E' is a
TEMPLATE_DECL with `D<T>' as its DECL_CONTEXT. Now we
have to substitute this with one having context `D<int>'. */
tree context = tsubst (DECL_CONTEXT (t), args, complain, in_decl);
return lookup_field (context, DECL_NAME(t), 0, false);
}
else
/* Ordinary template template argument. */
return t;
case CAST_EXPR:
case REINTERPRET_CAST_EXPR:
case CONST_CAST_EXPR:
case STATIC_CAST_EXPR:
case DYNAMIC_CAST_EXPR:
case NOP_EXPR:
return build1
(code, tsubst (TREE_TYPE (t), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl));
case INDIRECT_REF:
case NEGATE_EXPR:
case TRUTH_NOT_EXPR:
case BIT_NOT_EXPR:
case ADDR_EXPR:
case CONVERT_EXPR: /* Unary + */
case SIZEOF_EXPR:
case ALIGNOF_EXPR:
case ARROW_EXPR:
case THROW_EXPR:
case TYPEID_EXPR:
case REALPART_EXPR:
case IMAGPART_EXPR:
return build1
(code, tsubst (TREE_TYPE (t), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl));
case COMPONENT_REF:
{
tree object;
tree name;
object = tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl);
name = TREE_OPERAND (t, 1);
if (TREE_CODE (name) == BIT_NOT_EXPR)
{
name = tsubst_copy (TREE_OPERAND (name, 0), args,
complain, in_decl);
name = build1 (BIT_NOT_EXPR, NULL_TREE, name);
}
else if (TREE_CODE (name) == SCOPE_REF
&& TREE_CODE (TREE_OPERAND (name, 1)) == BIT_NOT_EXPR)
{
tree base = tsubst_copy (TREE_OPERAND (name, 0), args,
complain, in_decl);
name = TREE_OPERAND (name, 1);
name = tsubst_copy (TREE_OPERAND (name, 0), args,
complain, in_decl);
name = build1 (BIT_NOT_EXPR, NULL_TREE, name);
name = build_nt (SCOPE_REF, base, name);
}
else if (TREE_CODE (name) == BASELINK)
name = tsubst_baselink (name,
non_reference (TREE_TYPE (object)),
args, complain,
in_decl);
else
name = tsubst_copy (name, args, complain, in_decl);
return build_nt (COMPONENT_REF, object, name);
}
case PLUS_EXPR:
case MINUS_EXPR:
case MULT_EXPR:
case TRUNC_DIV_EXPR:
case CEIL_DIV_EXPR:
case FLOOR_DIV_EXPR:
case ROUND_DIV_EXPR:
case EXACT_DIV_EXPR:
case BIT_AND_EXPR:
case BIT_IOR_EXPR:
case BIT_XOR_EXPR:
case TRUNC_MOD_EXPR:
case FLOOR_MOD_EXPR:
case TRUTH_ANDIF_EXPR:
case TRUTH_ORIF_EXPR:
case TRUTH_AND_EXPR:
case TRUTH_OR_EXPR:
case RSHIFT_EXPR:
case LSHIFT_EXPR:
case RROTATE_EXPR:
case LROTATE_EXPR:
case EQ_EXPR:
case NE_EXPR:
case MAX_EXPR:
case MIN_EXPR:
case LE_EXPR:
case GE_EXPR:
case LT_EXPR:
case GT_EXPR:
case ARRAY_REF:
case COMPOUND_EXPR:
case SCOPE_REF:
case DOTSTAR_EXPR:
case MEMBER_REF:
case PREDECREMENT_EXPR:
case PREINCREMENT_EXPR:
case POSTDECREMENT_EXPR:
case POSTINCREMENT_EXPR:
return build_nt
(code, tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 1), args, complain, in_decl));
case CALL_EXPR:
return build_nt (code,
tsubst_copy (TREE_OPERAND (t, 0), args,
complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 1), args, complain,
in_decl),
NULL_TREE);
case STMT_EXPR:
/* This processing should really occur in tsubst_expr. However,
tsubst_expr does not recurse into expressions, since it
assumes that there aren't any statements inside them. So, we
need to expand the STMT_EXPR here. */
if (!processing_template_decl)
{
tree stmt_expr = begin_stmt_expr ();
tsubst_expr (STMT_EXPR_STMT (t), args,
complain | tf_stmt_expr_cmpd, in_decl);
return finish_stmt_expr (stmt_expr, false);
}
return t;
case COND_EXPR:
case MODOP_EXPR:
case PSEUDO_DTOR_EXPR:
{
r = build_nt
(code, tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 1), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 2), args, complain, in_decl));
return r;
}
case NEW_EXPR:
{
r = build_nt
(code, tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 1), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 2), args, complain, in_decl));
NEW_EXPR_USE_GLOBAL (r) = NEW_EXPR_USE_GLOBAL (t);
return r;
}
case DELETE_EXPR:
{
r = build_nt
(code, tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl),
tsubst_copy (TREE_OPERAND (t, 1), args, complain, in_decl));
DELETE_EXPR_USE_GLOBAL (r) = DELETE_EXPR_USE_GLOBAL (t);
DELETE_EXPR_USE_VEC (r) = DELETE_EXPR_USE_VEC (t);
return r;
}
case TEMPLATE_ID_EXPR:
{
/* Substituted template arguments */
tree fn = TREE_OPERAND (t, 0);
tree targs = TREE_OPERAND (t, 1);
fn = tsubst_copy (fn, args, complain, in_decl);
if (targs)
targs = tsubst_template_args (targs, args, complain, in_decl);
return lookup_template_function (fn, targs);
}
case TREE_LIST:
{
tree purpose, value, chain;
if (t == void_list_node)
return t;
purpose = TREE_PURPOSE (t);
if (purpose)
purpose = tsubst_copy (purpose, args, complain, in_decl);
value = TREE_VALUE (t);
if (value)
value = tsubst_copy (value, args, complain, in_decl);
chain = TREE_CHAIN (t);
if (chain && chain != void_type_node)
chain = tsubst_copy (chain, args, complain, in_decl);
if (purpose == TREE_PURPOSE (t)
&& value == TREE_VALUE (t)
&& chain == TREE_CHAIN (t))
return t;
return tree_cons (purpose, value, chain);
}
case RECORD_TYPE:
case UNION_TYPE:
case ENUMERAL_TYPE:
case INTEGER_TYPE:
case TEMPLATE_TYPE_PARM:
case TEMPLATE_TEMPLATE_PARM:
case BOUND_TEMPLATE_TEMPLATE_PARM:
case TEMPLATE_PARM_INDEX:
case POINTER_TYPE:
case REFERENCE_TYPE:
case OFFSET_TYPE:
case FUNCTION_TYPE:
case METHOD_TYPE:
case ARRAY_TYPE:
case TYPENAME_TYPE:
case UNBOUND_CLASS_TEMPLATE:
case TYPEOF_TYPE:
case TYPE_DECL:
return tsubst (t, args, complain, in_decl);
case IDENTIFIER_NODE:
if (IDENTIFIER_TYPENAME_P (t))
{
tree new_type = tsubst (TREE_TYPE (t), args, complain, in_decl);
return mangle_conv_op_name_for_type (new_type);
}
else
return t;
case CONSTRUCTOR:
{
r = build_constructor
(tsubst (TREE_TYPE (t), args, complain, in_decl),
tsubst_copy (CONSTRUCTOR_ELTS (t), args, complain, in_decl));
TREE_HAS_CONSTRUCTOR (r) = TREE_HAS_CONSTRUCTOR (t);
return r;
}
case VA_ARG_EXPR:
return build_x_va_arg (tsubst_copy (TREE_OPERAND (t, 0), args, complain,
in_decl),
tsubst (TREE_TYPE (t), args, complain, in_decl));
default:
return t;
}
}
/* Like tsubst_copy for expressions, etc. but also does semantic
processing. */
static tree
tsubst_expr (tree t, tree args, tsubst_flags_t complain, tree in_decl)
{
tree stmt, tmp;
tsubst_flags_t stmt_expr
= complain & (tf_stmt_expr_cmpd | tf_stmt_expr_body);
complain ^= stmt_expr;
if (t == NULL_TREE || t == error_mark_node)
return t;
if (processing_template_decl)
return tsubst_copy (t, args, complain, in_decl);
if (!STATEMENT_CODE_P (TREE_CODE (t)))
return tsubst_copy_and_build (t, args, complain, in_decl,
/*function_p=*/false);
switch (TREE_CODE (t))
{
case CTOR_INITIALIZER:
prep_stmt (t);
finish_mem_initializers (tsubst_initializer_list
(TREE_OPERAND (t, 0), args));
break;
case RETURN_STMT:
prep_stmt (t);
finish_return_stmt (tsubst_expr (RETURN_STMT_EXPR (t),
args, complain, in_decl));
break;
case EXPR_STMT:
{
tree r;
prep_stmt (t);
r = tsubst_expr (EXPR_STMT_EXPR (t), args, complain, in_decl);
if (stmt_expr & tf_stmt_expr_body && !TREE_CHAIN (t))
finish_stmt_expr_expr (r);
else
finish_expr_stmt (r);
break;
}
case USING_STMT:
prep_stmt (t);
do_using_directive (tsubst_expr (USING_STMT_NAMESPACE (t),
args, complain, in_decl));
break;
case DECL_STMT:
{
tree decl;
tree init;
prep_stmt (t);
decl = DECL_STMT_DECL (t);
if (TREE_CODE (decl) == LABEL_DECL)
finish_label_decl (DECL_NAME (decl));
else if (TREE_CODE (decl) == USING_DECL)
{
tree scope = DECL_INITIAL (decl);
tree name = DECL_NAME (decl);
tree decl;
scope = tsubst_expr (scope, args, complain, in_decl);
decl = lookup_qualified_name (scope, name,
/*is_type_p=*/false,
/*complain=*/false);
if (decl == error_mark_node)
qualified_name_lookup_error (scope, name);
else
do_local_using_decl (decl);
}
else
{
init = DECL_INITIAL (decl);
decl = tsubst (decl, args, complain, in_decl);
if (decl != error_mark_node)
{
if (init)
DECL_INITIAL (decl) = error_mark_node;
/* By marking the declaration as instantiated, we avoid
trying to instantiate it. Since instantiate_decl can't
handle local variables, and since we've already done
all that needs to be done, that's the right thing to
do. */
if (TREE_CODE (decl) == VAR_DECL)
DECL_TEMPLATE_INSTANTIATED (decl) = 1;
if (TREE_CODE (decl) == VAR_DECL
&& ANON_AGGR_TYPE_P (TREE_TYPE (decl)))
/* Anonymous aggregates are a special case. */
finish_anon_union (decl);
else
{
maybe_push_decl (decl);
if (TREE_CODE (decl) == VAR_DECL
&& DECL_PRETTY_FUNCTION_P (decl))
{
/* For __PRETTY_FUNCTION__ we have to adjust the
initializer. */
const char *const name
= cxx_printable_name (current_function_decl, 2);
init = cp_fname_init (name, &TREE_TYPE (decl));
}
else
init = tsubst_expr (init, args, complain, in_decl);
cp_finish_decl (decl, init, NULL_TREE, 0);
}
}
}
/* A DECL_STMT can also be used as an expression, in the condition
clause of an if/for/while construct. If we aren't followed by
another statement, return our decl. */
if (TREE_CHAIN (t) == NULL_TREE)
return decl;
}
break;
case FOR_STMT:
{
prep_stmt (t);
stmt = begin_for_stmt ();
tsubst_expr (FOR_INIT_STMT (t), args, complain, in_decl);
finish_for_init_stmt (stmt);
finish_for_cond (tsubst_expr (FOR_COND (t),
args, complain, in_decl),
stmt);
tmp = tsubst_expr (FOR_EXPR (t), args, complain, in_decl);
finish_for_expr (tmp, stmt);
tsubst_expr (FOR_BODY (t), args, complain, in_decl);
finish_for_stmt (stmt);
}
break;
case WHILE_STMT:
{
prep_stmt (t);
stmt = begin_while_stmt ();
finish_while_stmt_cond (tsubst_expr (WHILE_COND (t),
args, complain, in_decl),
stmt);
tsubst_expr (WHILE_BODY (t), args, complain, in_decl);
finish_while_stmt (stmt);
}
break;
case DO_STMT:
{
prep_stmt (t);
stmt = begin_do_stmt ();
tsubst_expr (DO_BODY (t), args, complain, in_decl);
finish_do_body (stmt);
finish_do_stmt (tsubst_expr (DO_COND (t),
args, complain, in_decl),
stmt);
}
break;
case IF_STMT:
{
prep_stmt (t);
stmt = begin_if_stmt ();
finish_if_stmt_cond (tsubst_expr (IF_COND (t),
args, complain, in_decl),
stmt);
if (tmp = THEN_CLAUSE (t), tmp)
{
tsubst_expr (tmp, args, complain, in_decl);
finish_then_clause (stmt);
}
if (tmp = ELSE_CLAUSE (t), tmp)
{
begin_else_clause ();
tsubst_expr (tmp, args, complain, in_decl);
finish_else_clause (stmt);
}
finish_if_stmt ();
}
break;
case COMPOUND_STMT:
{
prep_stmt (t);
if (COMPOUND_STMT_BODY_BLOCK (t))
stmt = begin_function_body ();
else
stmt = begin_compound_stmt (COMPOUND_STMT_NO_SCOPE (t));
tsubst_expr (COMPOUND_BODY (t), args,
complain | ((stmt_expr & tf_stmt_expr_cmpd) << 1),
in_decl);
if (COMPOUND_STMT_BODY_BLOCK (t))
finish_function_body (stmt);
else
finish_compound_stmt (stmt);
}
break;
case BREAK_STMT:
prep_stmt (t);
finish_break_stmt ();
break;
case CONTINUE_STMT:
prep_stmt (t);
finish_continue_stmt ();
break;
case SWITCH_STMT:
{
tree val;
prep_stmt (t);
stmt = begin_switch_stmt ();
val = tsubst_expr (SWITCH_COND (t), args, complain, in_decl);
finish_switch_cond (val, stmt);
tsubst_expr (SWITCH_BODY (t), args, complain, in_decl);
finish_switch_stmt (stmt);
}
break;
case CASE_LABEL:
prep_stmt (t);
finish_case_label (tsubst_expr (CASE_LOW (t), args, complain, in_decl),
tsubst_expr (CASE_HIGH (t), args, complain,
in_decl));
break;
case LABEL_STMT:
input_line = STMT_LINENO (t);
finish_label_stmt (DECL_NAME (LABEL_STMT_LABEL (t)));
break;
case FILE_STMT:
input_filename = FILE_STMT_FILENAME (t);
add_stmt (build_nt (FILE_STMT, FILE_STMT_FILENAME_NODE (t)));
break;
case GOTO_STMT:
prep_stmt (t);
tmp = GOTO_DESTINATION (t);
if (TREE_CODE (tmp) != LABEL_DECL)
/* Computed goto's must be tsubst'd into. On the other hand,
non-computed gotos must not be; the identifier in question
will have no binding. */
tmp = tsubst_expr (tmp, args, complain, in_decl);
else
tmp = DECL_NAME (tmp);
finish_goto_stmt (tmp);
break;
case ASM_STMT:
prep_stmt (t);
tmp = finish_asm_stmt
(ASM_CV_QUAL (t),
tsubst_expr (ASM_STRING (t), args, complain, in_decl),
tsubst_expr (ASM_OUTPUTS (t), args, complain, in_decl),
tsubst_expr (ASM_INPUTS (t), args, complain, in_decl),
tsubst_expr (ASM_CLOBBERS (t), args, complain, in_decl));
ASM_INPUT_P (tmp) = ASM_INPUT_P (t);
break;
case TRY_BLOCK:
prep_stmt (t);
if (CLEANUP_P (t))
{
stmt = begin_try_block ();
tsubst_expr (TRY_STMTS (t), args, complain, in_decl);
finish_cleanup_try_block (stmt);
finish_cleanup (tsubst_expr (TRY_HANDLERS (t), args,
complain, in_decl),
stmt);
}
else
{
if (FN_TRY_BLOCK_P (t))
stmt = begin_function_try_block ();
else
stmt = begin_try_block ();
tsubst_expr (TRY_STMTS (t), args, complain, in_decl);
if (FN_TRY_BLOCK_P (t))
finish_function_try_block (stmt);
else
finish_try_block (stmt);
tsubst_expr (TRY_HANDLERS (t), args, complain, in_decl);
if (FN_TRY_BLOCK_P (t))
finish_function_handler_sequence (stmt);
else
finish_handler_sequence (stmt);
}
break;
case HANDLER:
{
tree decl;
prep_stmt (t);
stmt = begin_handler ();
if (HANDLER_PARMS (t))
{
decl = DECL_STMT_DECL (HANDLER_PARMS (t));
decl = tsubst (decl, args, complain, in_decl);
/* Prevent instantiate_decl from trying to instantiate
this variable. We've already done all that needs to be
done. */
DECL_TEMPLATE_INSTANTIATED (decl) = 1;
}
else
decl = NULL_TREE;
finish_handler_parms (decl, stmt);
tsubst_expr (HANDLER_BODY (t), args, complain, in_decl);
finish_handler (stmt);
}
break;
case TAG_DEFN:
prep_stmt (t);
tsubst (TREE_TYPE (t), args, complain, NULL_TREE);
break;
default:
abort ();
}
return tsubst_expr (TREE_CHAIN (t), args, complain | stmt_expr, in_decl);
}
/* T is a postfix-expression that is not being used in a function
call. Return the substituted version of T. */
static tree
tsubst_non_call_postfix_expression (tree t, tree args,
tsubst_flags_t complain,
tree in_decl)
{
if (TREE_CODE (t) == SCOPE_REF)
t = tsubst_qualified_id (t, args, complain, in_decl,
/*done=*/false, /*address_p=*/false);
else
t = tsubst_copy_and_build (t, args, complain, in_decl,
/*function_p=*/false);
return t;
}
/* Like tsubst but deals with expressions and performs semantic
analysis. FUNCTION_P is true if T is the "F" in "F (ARGS)". */
tree
tsubst_copy_and_build (tree t,
tree args,
tsubst_flags_t complain,
tree in_decl,
bool function_p)
{
#define RECUR(NODE) \
tsubst_copy_and_build (NODE, args, complain, in_decl, /*function_p=*/false)
tree op1;
if (t == NULL_TREE || t == error_mark_node)
return t;
switch (TREE_CODE (t))
{
case USING_DECL:
t = DECL_NAME (t);
/* Fallthrough. */
case IDENTIFIER_NODE:
{
tree decl;
cp_id_kind idk;
tree qualifying_class;
bool non_constant_expression_p;
const char *error_msg;
if (IDENTIFIER_TYPENAME_P (t))
{
tree new_type = tsubst (TREE_TYPE (t), args, complain, in_decl);
t = mangle_conv_op_name_for_type (new_type);
}
/* Look up the name. */
decl = lookup_name (t, 0);
/* By convention, expressions use ERROR_MARK_NODE to indicate
failure, not NULL_TREE. */
if (decl == NULL_TREE)
decl = error_mark_node;
decl = finish_id_expression (t, decl, NULL_TREE,
&idk,
&qualifying_class,
/*constant_expression_p=*/false,
/*allow_non_constant_expression_p=*/false,
&non_constant_expression_p,
&error_msg);
if (error_msg)
error (error_msg);
if (!function_p && TREE_CODE (decl) == IDENTIFIER_NODE)
decl = unqualified_name_lookup_error (decl);
return decl;
}
case TEMPLATE_ID_EXPR:
{
tree object;
tree template = RECUR (TREE_OPERAND (t, 0));
tree targs = TREE_OPERAND (t, 1);
if (targs)
targs = tsubst_template_args (targs, args, complain, in_decl);
if (TREE_CODE (template) == COMPONENT_REF)
{
object = TREE_OPERAND (template, 0);
template = TREE_OPERAND (template, 1);
}
else
object = NULL_TREE;
template = lookup_template_function (template, targs);
if (object)
return build (COMPONENT_REF, TREE_TYPE (template),
object, template);
else
return template;
}
case INDIRECT_REF:
return build_x_indirect_ref (RECUR (TREE_OPERAND (t, 0)), "unary *");
case CAST_EXPR:
return build_functional_cast
(tsubst (TREE_TYPE (t), args, complain, in_decl),
RECUR (TREE_OPERAND (t, 0)));
case REINTERPRET_CAST_EXPR:
return build_reinterpret_cast
(tsubst (TREE_TYPE (t), args, complain, in_decl),
RECUR (TREE_OPERAND (t, 0)));
case CONST_CAST_EXPR:
return build_const_cast
(tsubst (TREE_TYPE (t), args, complain, in_decl),
RECUR (TREE_OPERAND (t, 0)));
case DYNAMIC_CAST_EXPR:
return build_dynamic_cast
(tsubst (TREE_TYPE (t), args, complain, in_decl),
RECUR (TREE_OPERAND (t, 0)));
case STATIC_CAST_EXPR:
return build_static_cast
(tsubst (TREE_TYPE (t), args, complain, in_decl),
RECUR (TREE_OPERAND (t, 0)));
case POSTDECREMENT_EXPR:
case POSTINCREMENT_EXPR:
op1 = tsubst_non_call_postfix_expression (TREE_OPERAND (t, 0),
args, complain, in_decl);
return build_x_unary_op (TREE_CODE (t), op1);
case PREDECREMENT_EXPR:
case PREINCREMENT_EXPR:
case NEGATE_EXPR:
case BIT_NOT_EXPR:
case ABS_EXPR:
case TRUTH_NOT_EXPR:
case CONVERT_EXPR: /* Unary + */
case REALPART_EXPR:
case IMAGPART_EXPR:
return build_x_unary_op (TREE_CODE (t), RECUR (TREE_OPERAND (t, 0)));
case ADDR_EXPR:
op1 = TREE_OPERAND (t, 0);
if (TREE_CODE (op1) == SCOPE_REF)
op1 = tsubst_qualified_id (op1, args, complain, in_decl,
/*done=*/true, /*address_p=*/true);
else
op1 = tsubst_non_call_postfix_expression (op1, args, complain,
in_decl);
if (TREE_CODE (op1) == LABEL_DECL)
return finish_label_address_expr (DECL_NAME (op1));
return build_x_unary_op (ADDR_EXPR, op1);
case PLUS_EXPR:
case MINUS_EXPR:
case MULT_EXPR:
case TRUNC_DIV_EXPR:
case CEIL_DIV_EXPR:
case FLOOR_DIV_EXPR:
case ROUND_DIV_EXPR:
case EXACT_DIV_EXPR:
case BIT_AND_EXPR:
case BIT_IOR_EXPR:
case BIT_XOR_EXPR:
case TRUNC_MOD_EXPR:
case FLOOR_MOD_EXPR:
case TRUTH_ANDIF_EXPR:
case TRUTH_ORIF_EXPR:
case TRUTH_AND_EXPR:
case TRUTH_OR_EXPR:
case RSHIFT_EXPR:
case LSHIFT_EXPR:
case RROTATE_EXPR:
case LROTATE_EXPR:
case EQ_EXPR:
case NE_EXPR:
case MAX_EXPR:
case MIN_EXPR:
case LE_EXPR:
case GE_EXPR:
case LT_EXPR:
case GT_EXPR:
case MEMBER_REF:
case DOTSTAR_EXPR:
return build_x_binary_op
(TREE_CODE (t),
RECUR (TREE_OPERAND (t, 0)),
RECUR (TREE_OPERAND (t, 1)));
case SCOPE_REF:
return tsubst_qualified_id (t, args, complain, in_decl, /*done=*/true,
/*address_p=*/false);
case ARRAY_REF:
if (tsubst_copy (TREE_OPERAND (t, 0), args, complain, in_decl)
== NULL_TREE)
/* new-type-id */
return build_nt (ARRAY_REF, NULL_TREE, RECUR (TREE_OPERAND (t, 1)));
op1 = tsubst_non_call_postfix_expression (TREE_OPERAND (t, 0),
args, complain, in_decl);
/* Remember that there was a reference to this entity. */
if (DECL_P (op1))
mark_used (op1);
return grok_array_decl (op1, RECUR (TREE_OPERAND (t, 1)));
case SIZEOF_EXPR:
case ALIGNOF_EXPR:
op1 = TREE_OPERAND (t, 0);
if (!args)
{
/* When there are no ARGS, we are trying to evaluate a
non-dependent expression from the parser. Trying to do
the substitutions may not work. */
if (!TYPE_P (op1))
op1 = TREE_TYPE (op1);
}
else
{
++skip_evaluation;
op1 = RECUR (op1);
--skip_evaluation;
}
if (TYPE_P (op1))
return cxx_sizeof_or_alignof_type (op1, TREE_CODE (t), true);
else
return cxx_sizeof_or_alignof_expr (op1, TREE_CODE (t));
case MODOP_EXPR:
return build_x_modify_expr
(RECUR (TREE_OPERAND (t, 0)),
TREE_CODE (TREE_OPERAND (t, 1)),
RECUR (TREE_OPERAND (t, 2)));
case ARROW_EXPR:
op1 = tsubst_non_call_postfix_expression (TREE_OPERAND (t, 0),
args, complain, in_decl);
/* Remember that there was a reference to this entity. */
if (DECL_P (op1))
mark_used (op1);
return build_x_arrow (op1);
case NEW_EXPR:
return build_new
(RECUR (TREE_OPERAND (t, 0)),
RECUR (TREE_OPERAND (t, 1)),
RECUR (TREE_OPERAND (t, 2)),
NEW_EXPR_USE_GLOBAL (t));
case DELETE_EXPR:
return delete_sanity
(RECUR (TREE_OPERAND (t, 0)),
RECUR (TREE_OPERAND (t, 1)),
DELETE_EXPR_USE_VEC (t),
DELETE_EXPR_USE_GLOBAL (t));
case COMPOUND_EXPR:
return build_x_compound_expr (RECUR (TREE_OPERAND (t, 0)),
RECUR (TREE_OPERAND (t, 1)));
case CALL_EXPR:
{
tree function;
tree call_args;
bool qualified_p;
bool koenig_p;
function = TREE_OPERAND (t, 0);
/* When we parsed the expression, we determined whether or
not Koenig lookup should be performed. */
koenig_p = KOENIG_LOOKUP_P (t);
if (TREE_CODE (function) == SCOPE_REF)
{
qualified_p = true;
function = tsubst_qualified_id (function, args, complain, in_decl,
/*done=*/false,
/*address_p=*/false);
}
else
{
qualified_p = (TREE_CODE (function) == COMPONENT_REF
&& (TREE_CODE (TREE_OPERAND (function, 1))
== SCOPE_REF));
function = tsubst_copy_and_build (function, args, complain,
in_decl,
!qualified_p);
if (BASELINK_P (function))
qualified_p = true;
}
call_args = RECUR (TREE_OPERAND (t, 1));
if (koenig_p
&& (is_overloaded_fn (function)
|| DECL_P (function)
|| TREE_CODE (function) == IDENTIFIER_NODE))
function = perform_koenig_lookup (function, call_args);
if (TREE_CODE (function) == IDENTIFIER_NODE)
{
unqualified_name_lookup_error (function);
return error_mark_node;
}
/* Remember that there was a reference to this entity. */
if (DECL_P (function))
mark_used (function);
function = convert_from_reference (function);
if (TREE_CODE (function) == OFFSET_REF)
return build_offset_ref_call_from_tree (function, call_args);
if (TREE_CODE (function) == COMPONENT_REF)
return (build_new_method_call
(TREE_OPERAND (function, 0),
TREE_OPERAND (function, 1),
call_args, NULL_TREE,
qualified_p ? LOOKUP_NONVIRTUAL : LOOKUP_NORMAL));
return finish_call_expr (function, call_args,
/*disallow_virtual=*/qualified_p,
koenig_p);
}
case COND_EXPR:
return build_x_conditional_expr
(RECUR (TREE_OPERAND (t, 0)),
RECUR (TREE_OPERAND (t, 1)),
RECUR (TREE_OPERAND (t, 2)));
case PSEUDO_DTOR_EXPR:
return finish_pseudo_destructor_expr
(RECUR (TREE_OPERAND (t, 0)),
RECUR (TREE_OPERAND (t, 1)),
RECUR (TREE_OPERAND (t, 2)));
case TREE_LIST:
{
tree purpose, value, chain;
if (t == void_list_node)
return t;
purpose = TREE_PURPOSE (t);
if (purpose)
purpose = RECUR (purpose);
value = TREE_VALUE (t);
if (value)
value = RECUR (value);
chain = TREE_CHAIN (t);
if (chain && chain != void_type_node)
chain = RECUR (chain);
if (purpose == TREE_PURPOSE (t)
&& value == TREE_VALUE (t)
&& chain == TREE_CHAIN (t))
return t;
return tree_cons (purpose, value, chain);
}
case COMPONENT_REF:
{
tree object;
tree member;
object = tsubst_non_call_postfix_expression (TREE_OPERAND (t, 0),
args, complain, in_decl);
/* Remember that there was a reference to this entity. */
if (DECL_P (object))
mark_used (object);
member = TREE_OPERAND (t, 1);
if (BASELINK_P (member))
member = tsubst_baselink (member,
non_reference (TREE_TYPE (object)),
args, complain, in_decl);
else
member = tsubst_copy (member, args, complain, in_decl);
if (!CLASS_TYPE_P (TREE_TYPE (object)))
{
if (TREE_CODE (member) == BIT_NOT_EXPR)
return finish_pseudo_destructor_expr (object,
NULL_TREE,
TREE_TYPE (object));
else if (TREE_CODE (member) == SCOPE_REF
&& (TREE_CODE (TREE_OPERAND (member, 1)) == BIT_NOT_EXPR))
return finish_pseudo_destructor_expr (object,
object,
TREE_TYPE (object));
}
else if (TREE_CODE (member) == SCOPE_REF
&& TREE_CODE (TREE_OPERAND (member, 1)) == TEMPLATE_ID_EXPR)
{
tree tmpl;
tree args;
/* Lookup the template functions now that we know what the
scope is. */
tmpl = TREE_OPERAND (TREE_OPERAND (member, 1), 0);
args = TREE_OPERAND (TREE_OPERAND (member, 1), 1);
member = lookup_qualified_name (TREE_OPERAND (member, 0), tmpl,
/*is_type_p=*/false,
/*complain=*/false);
if (BASELINK_P (member))
BASELINK_FUNCTIONS (member)
= build_nt (TEMPLATE_ID_EXPR, BASELINK_FUNCTIONS (member),
args);
else
{
qualified_name_lookup_error (TREE_TYPE (object), tmpl);
return error_mark_node;
}
}
else if (TREE_CODE (member) == FIELD_DECL)
return finish_non_static_data_member (member, object, NULL_TREE);
return finish_class_member_access_expr (object, member);
}
case THROW_EXPR:
return build_throw
(RECUR (TREE_OPERAND (t, 0)));
case CONSTRUCTOR:
{
tree r;
tree elts;
tree type = tsubst (TREE_TYPE (t), args, complain, in_decl);
bool purpose_p;
/* digest_init will do the wrong thing if we let it. */
if (type && TYPE_PTRMEMFUNC_P (type))
return t;
r = NULL_TREE;
/* We do not want to process the purpose of aggregate
initializers as they are identifier nodes which will be
looked up by digest_init. */
purpose_p = !(type && IS_AGGR_TYPE (type));
for (elts = CONSTRUCTOR_ELTS (t);
elts;
elts = TREE_CHAIN (elts))
{
tree purpose = TREE_PURPOSE (elts);
tree value = TREE_VALUE (elts);
if (purpose && purpose_p)
purpose = RECUR (purpose);
value = RECUR (value);
r = tree_cons (purpose, value, r);
}
r = build_constructor (NULL_TREE, nreverse (r));
TREE_HAS_CONSTRUCTOR (r) = TREE_HAS_CONSTRUCTOR (t);
if (type)
return digest_init (type, r, 0);
return r;
}
case TYPEID_EXPR:
{
tree operand_0 = RECUR (TREE_OPERAND (t, 0));
if (TYPE_P (operand_0))
return get_typeid (operand_0);
return build_typeid (operand_0);
}
case PARM_DECL:
return convert_from_reference (tsubst_copy (t, args, complain, in_decl));
case VAR_DECL:
if (args)
t = tsubst_copy (t, args, complain, in_decl);
else
/* If there are no ARGS, then we are evaluating a
non-dependent expression. If the expression is
non-dependent, the variable must be a constant. */
t = DECL_INITIAL (t);
return convert_from_reference (t);
case VA_ARG_EXPR:
return build_x_va_arg (RECUR (TREE_OPERAND (t, 0)),
tsubst_copy (TREE_TYPE (t), args, complain,
in_decl));
default:
return tsubst_copy (t, args, complain, in_decl);
}
#undef RECUR
}
/* Verify that the instantiated ARGS are valid. For type arguments,
make sure that the type's linkage is ok. For non-type arguments,
make sure they are constants if they are integral or enumerations.
Emit an error under control of COMPLAIN, and return TRUE on error. */
static bool
check_instantiated_args (tree tmpl, tree args, tsubst_flags_t complain)
{
int ix, len = DECL_NTPARMS (tmpl);
bool result = false;
for (ix = 0; ix != len; ix++)
{
tree t = TREE_VEC_ELT (args, ix);
if (TYPE_P (t))
{
/* [basic.link]: A name with no linkage (notably, the name
of a class or enumeration declared in a local scope)
shall not be used to declare an entity with linkage.
This implies that names with no linkage cannot be used as
template arguments. */
tree nt = no_linkage_check (t);
if (nt)
{
if (!(complain & tf_error))
/*OK*/;
else if (TYPE_ANONYMOUS_P (nt))
error ("`%T' uses anonymous type", t);
else
error ("`%T' uses local type `%T'", t, nt);
result = true;
}
/* In order to avoid all sorts of complications, we do not
allow variably-modified types as template arguments. */
else if (variably_modified_type_p (t))
{
if (complain & tf_error)
error ("`%T' is a variably modified type", t);
result = true;
}
}
/* A non-type argument of integral or enumerated type must be a
constant. */
else if (TREE_TYPE (t)
&& INTEGRAL_OR_ENUMERATION_TYPE_P (TREE_TYPE (t))
&& !TREE_CONSTANT (t))
{
if (complain & tf_error)
error ("integral expression `%E' is not constant", t);
result = true;
}
}
if (result && complain & tf_error)
error (" trying to instantiate `%D'", tmpl);
return result;
}
/* Instantiate the indicated variable or function template TMPL with
the template arguments in TARG_PTR. */
tree
instantiate_template (tree tmpl, tree targ_ptr, tsubst_flags_t complain)
{
tree fndecl;
tree gen_tmpl;
tree spec;
if (tmpl == error_mark_node)
return error_mark_node;
my_friendly_assert (TREE_CODE (tmpl) == TEMPLATE_DECL, 283);
/* If this function is a clone, handle it specially. */
if (DECL_CLONED_FUNCTION_P (tmpl))
{
tree spec = instantiate_template (DECL_CLONED_FUNCTION (tmpl), targ_ptr,
complain);
tree clone;
/* Look for the clone. */
for (clone = TREE_CHAIN (spec);
clone && DECL_CLONED_FUNCTION_P (clone);
clone = TREE_CHAIN (clone))
if (DECL_NAME (clone) == DECL_NAME (tmpl))
return clone;
/* We should always have found the clone by now. */
abort ();
return NULL_TREE;
}
/* Check to see if we already have this specialization. */
spec = retrieve_specialization (tmpl, targ_ptr);
if (spec != NULL_TREE)
return spec;
gen_tmpl = most_general_template (tmpl);
if (tmpl != gen_tmpl)
{
/* The TMPL is a partial instantiation. To get a full set of
arguments we must add the arguments used to perform the
partial instantiation. */
targ_ptr = add_outermost_template_args (DECL_TI_ARGS (tmpl),
targ_ptr);
/* Check to see if we already have this specialization. */
spec = retrieve_specialization (gen_tmpl, targ_ptr);
if (spec != NULL_TREE)
return spec;
}
if (check_instantiated_args (gen_tmpl, INNERMOST_TEMPLATE_ARGS (targ_ptr),
complain))
return error_mark_node;
/* We are building a FUNCTION_DECL, during which the access of its
parameters and return types have to be checked. However this
FUNCTION_DECL which is the desired context for access checking
is not built yet. We solve this chicken-and-egg problem by
deferring all checks until we have the FUNCTION_DECL. */
push_deferring_access_checks (dk_deferred);
/* substitute template parameters */
fndecl = tsubst (DECL_TEMPLATE_RESULT (gen_tmpl),
targ_ptr, complain, gen_tmpl);
/* Now we know the specialization, compute access previously
deferred. */
push_access_scope (fndecl);
perform_deferred_access_checks ();
pop_access_scope (fndecl);
pop_deferring_access_checks ();
/* The DECL_TI_TEMPLATE should always be the immediate parent
template, not the most general template. */
DECL_TI_TEMPLATE (fndecl) = tmpl;
if (flag_external_templates)
add_pending_template (fndecl);
/* If we've just instantiated the main entry point for a function,
instantiate all the alternate entry points as well. We do this
by cloning the instantiation of the main entry point, not by
instantiating the template clones. */
if (TREE_CHAIN (gen_tmpl) && DECL_CLONED_FUNCTION_P (TREE_CHAIN (gen_tmpl)))
clone_function_decl (fndecl, /*update_method_vec_p=*/0);
return fndecl;
}
/* The FN is a TEMPLATE_DECL for a function. The ARGS are the
arguments that are being used when calling it. TARGS is a vector
into which the deduced template arguments are placed.
Return zero for success, 2 for an incomplete match that doesn't resolve
all the types, and 1 for complete failure. An error message will be
printed only for an incomplete match.
If FN is a conversion operator, or we are trying to produce a specific
specialization, RETURN_TYPE is the return type desired.
The EXPLICIT_TARGS are explicit template arguments provided via a
template-id.
The parameter STRICT is one of:
DEDUCE_CALL:
We are deducing arguments for a function call, as in
[temp.deduct.call].
DEDUCE_CONV:
We are deducing arguments for a conversion function, as in
[temp.deduct.conv].
DEDUCE_EXACT:
We are deducing arguments when doing an explicit instantiation
as in [temp.explicit], when determining an explicit specialization
as in [temp.expl.spec], or when taking the address of a function
template, as in [temp.deduct.funcaddr].
DEDUCE_ORDER:
We are deducing arguments when calculating the partial
ordering between specializations of function or class
templates, as in [temp.func.order] and [temp.class.order].
LEN is the number of parms to consider before returning success, or -1
for all. This is used in partial ordering to avoid comparing parms for
which no actual argument was passed, since they are not considered in
overload resolution (and are explicitly excluded from consideration in
partial ordering in [temp.func.order]/6). */
int
fn_type_unification (tree fn,
tree explicit_targs,
tree targs,
tree args,
tree return_type,
unification_kind_t strict,
int len)
{
tree parms;
tree fntype;
int result;
my_friendly_assert (TREE_CODE (fn) == TEMPLATE_DECL, 0);
fntype = TREE_TYPE (fn);
if (explicit_targs)
{
/* [temp.deduct]
The specified template arguments must match the template
parameters in kind (i.e., type, nontype, template), and there
must not be more arguments than there are parameters;
otherwise type deduction fails.
Nontype arguments must match the types of the corresponding
nontype template parameters, or must be convertible to the
types of the corresponding nontype parameters as specified in
_temp.arg.nontype_, otherwise type deduction fails.
All references in the function type of the function template
to the corresponding template parameters are replaced by the
specified template argument values. If a substitution in a
template parameter or in the function type of the function
template results in an invalid type, type deduction fails. */
int i;
tree converted_args;
bool incomplete;
converted_args
= (coerce_template_parms (DECL_INNERMOST_TEMPLATE_PARMS (fn),
explicit_targs, NULL_TREE, tf_none,
/*require_all_arguments=*/0));
if (converted_args == error_mark_node)
return 1;
/* Substitute the explicit args into the function type. This is
necessary so that, for instance, explicitly declared function
arguments can match null pointed constants. If we were given
an incomplete set of explicit args, we must not do semantic
processing during substitution as we could create partial
instantiations. */
incomplete = NUM_TMPL_ARGS (explicit_targs) != NUM_TMPL_ARGS (targs);
processing_template_decl += incomplete;
fntype = tsubst (fntype, converted_args, tf_none, NULL_TREE);
processing_template_decl -= incomplete;
if (fntype == error_mark_node)
return 1;
/* Place the explicitly specified arguments in TARGS. */
for (i = NUM_TMPL_ARGS (converted_args); i--;)
TREE_VEC_ELT (targs, i) = TREE_VEC_ELT (converted_args, i);
}
parms = TYPE_ARG_TYPES (fntype);
/* Never do unification on the 'this' parameter. */
if (DECL_NONSTATIC_MEMBER_FUNCTION_P (fn))
parms = TREE_CHAIN (parms);
if (return_type)
{
/* We've been given a return type to match, prepend it. */
parms = tree_cons (NULL_TREE, TREE_TYPE (fntype), parms);
args = tree_cons (NULL_TREE, return_type, args);
if (len >= 0)
++len;
}
/* We allow incomplete unification without an error message here
because the standard doesn't seem to explicitly prohibit it. Our
callers must be ready to deal with unification failures in any
event. */
result = type_unification_real (DECL_INNERMOST_TEMPLATE_PARMS (fn),
targs, parms, args, /*subr=*/0,
strict, /*allow_incomplete*/1, len);
if (result == 0)
/* All is well so far. Now, check:
[temp.deduct]
When all template arguments have been deduced, all uses of
template parameters in nondeduced contexts are replaced with
the corresponding deduced argument values. If the
substitution results in an invalid type, as described above,
type deduction fails. */
if (tsubst (TREE_TYPE (fn), targs, tf_none, NULL_TREE)
== error_mark_node)
return 1;
return result;
}
/* Adjust types before performing type deduction, as described in
[temp.deduct.call] and [temp.deduct.conv]. The rules in these two
sections are symmetric. PARM is the type of a function parameter
or the return type of the conversion function. ARG is the type of
the argument passed to the call, or the type of the value
initialized with the result of the conversion function. */
static int
maybe_adjust_types_for_deduction (unification_kind_t strict,
tree* parm,
tree* arg)
{
int result = 0;
switch (strict)
{
case DEDUCE_CALL:
break;
case DEDUCE_CONV:
{
/* Swap PARM and ARG throughout the remainder of this
function; the handling is precisely symmetric since PARM
will initialize ARG rather than vice versa. */
tree* temp = parm;
parm = arg;
arg = temp;
break;
}
case DEDUCE_EXACT:
/* There is nothing to do in this case. */
return 0;
case DEDUCE_ORDER:
/* DR 214. [temp.func.order] is underspecified, and leads to no
ordering between things like `T *' and `T const &' for `U *'.
The former has T=U and the latter T=U*. The former looks more
specialized and John Spicer considers it well-formed (the EDG
compiler accepts it).
John also confirms that deduction should proceed as in a function
call. Which implies the usual ARG and PARM conversions as DEDUCE_CALL.
However, in ordering, ARG can have REFERENCE_TYPE, but no argument
to an actual call can have such a type.
If both ARG and PARM are REFERENCE_TYPE, we change neither.
If only ARG is a REFERENCE_TYPE, we look through that and then
proceed as with DEDUCE_CALL (which could further convert it). */
if (TREE_CODE (*arg) == REFERENCE_TYPE)
{
if (TREE_CODE (*parm) == REFERENCE_TYPE)
return 0;
*arg = TREE_TYPE (*arg);
}
break;
default:
abort ();
}
if (TREE_CODE (*parm) != REFERENCE_TYPE)
{
/* [temp.deduct.call]
If P is not a reference type:
--If A is an array type, the pointer type produced by the
array-to-pointer standard conversion (_conv.array_) is
used in place of A for type deduction; otherwise,
--If A is a function type, the pointer type produced by
the function-to-pointer standard conversion
(_conv.func_) is used in place of A for type deduction;
otherwise,
--If A is a cv-qualified type, the top level
cv-qualifiers of A's type are ignored for type
deduction. */
if (TREE_CODE (*arg) == ARRAY_TYPE)
*arg = build_pointer_type (TREE_TYPE (*arg));
else if (TREE_CODE (*arg) == FUNCTION_TYPE)
*arg = build_pointer_type (*arg);
else
*arg = TYPE_MAIN_VARIANT (*arg);
}
/* [temp.deduct.call]
If P is a cv-qualified type, the top level cv-qualifiers
of P's type are ignored for type deduction. If P is a
reference type, the type referred to by P is used for
type deduction. */
*parm = TYPE_MAIN_VARIANT (*parm);
if (TREE_CODE (*parm) == REFERENCE_TYPE)
{
*parm = TREE_TYPE (*parm);
result |= UNIFY_ALLOW_OUTER_MORE_CV_QUAL;
}
/* DR 322. For conversion deduction, remove a reference type on parm
too (which has been swapped into ARG). */
if (strict == DEDUCE_CONV && TREE_CODE (*arg) == REFERENCE_TYPE)
*arg = TREE_TYPE (*arg);
return result;
}
/* Most parms like fn_type_unification.
If SUBR is 1, we're being called recursively (to unify the
arguments of a function or method parameter of a function
template). */
static int
type_unification_real (tree tparms,
tree targs,
tree xparms,
tree xargs,
int subr,
unification_kind_t strict,
int allow_incomplete,
int xlen)
{
tree parm, arg;
int i;
int ntparms = TREE_VEC_LENGTH (tparms);
int sub_strict;
int saw_undeduced = 0;
tree parms, args;
int len;
my_friendly_assert (TREE_CODE (tparms) == TREE_VEC, 289);
my_friendly_assert (xparms == NULL_TREE
|| TREE_CODE (xparms) == TREE_LIST, 290);
my_friendly_assert (!xargs || TREE_CODE (xargs) == TREE_LIST, 291);
my_friendly_assert (ntparms > 0, 292);
switch (strict)
{
case DEDUCE_CALL:
sub_strict = (UNIFY_ALLOW_OUTER_LEVEL | UNIFY_ALLOW_MORE_CV_QUAL
| UNIFY_ALLOW_DERIVED);
break;
case DEDUCE_CONV:
sub_strict = UNIFY_ALLOW_LESS_CV_QUAL;
break;
case DEDUCE_EXACT:
sub_strict = UNIFY_ALLOW_NONE;
break;
case DEDUCE_ORDER:
sub_strict = UNIFY_ALLOW_NONE;
break;
default:
abort ();
}
if (xlen == 0)
return 0;
again:
parms = xparms;
args = xargs;
len = xlen;
while (parms
&& parms != void_list_node
&& args
&& args != void_list_node)
{
parm = TREE_VALUE (parms);
parms = TREE_CHAIN (parms);
arg = TREE_VALUE (args);
args = TREE_CHAIN (args);
if (arg == error_mark_node)
return 1;
if (arg == unknown_type_node)
/* We can't deduce anything from this, but we might get all the
template args from other function args. */
continue;
/* Conversions will be performed on a function argument that
corresponds with a function parameter that contains only
non-deducible template parameters and explicitly specified
template parameters. */
if (! uses_template_parms (parm))
{
tree type;
if (!TYPE_P (arg))
type = TREE_TYPE (arg);
else
{
type = arg;
arg = NULL_TREE;
}
if (strict == DEDUCE_EXACT || strict == DEDUCE_ORDER)
{
if (same_type_p (parm, type))
continue;
}
else
/* It might work; we shouldn't check now, because we might
get into infinite recursion. Overload resolution will
handle it. */
continue;
return 1;
}
if (!TYPE_P (arg))
{
my_friendly_assert (TREE_TYPE (arg) != NULL_TREE, 293);
if (type_unknown_p (arg))
{
/* [temp.deduct.type] A template-argument can be deduced from
a pointer to function or pointer to member function
argument if the set of overloaded functions does not
contain function templates and at most one of a set of
overloaded functions provides a unique match. */
if (resolve_overloaded_unification
(tparms, targs, parm, arg, strict, sub_strict)
!= 0)
return 1;
continue;
}
arg = TREE_TYPE (arg);
if (arg == error_mark_node)
return 1;
}
{
int arg_strict = sub_strict;
if (!subr)
arg_strict |= maybe_adjust_types_for_deduction (strict, &parm, &arg);
if (unify (tparms, targs, parm, arg, arg_strict))
return 1;
}
/* Are we done with the interesting parms? */
if (--len == 0)
goto done;
}
/* Fail if we've reached the end of the parm list, and more args
are present, and the parm list isn't variadic. */
if (args && args != void_list_node && parms == void_list_node)
return 1;
/* Fail if parms are left and they don't have default values. */
if (parms
&& parms != void_list_node
&& TREE_PURPOSE (parms) == NULL_TREE)
return 1;
done:
if (!subr)
for (i = 0; i < ntparms; i++)
if (TREE_VEC_ELT (targs, i) == NULL_TREE)
{
tree tparm = TREE_VALUE (TREE_VEC_ELT (tparms, i));
/* If this is an undeduced nontype parameter that depends on
a type parameter, try another pass; its type may have been
deduced from a later argument than the one from which
this parameter can be deduced. */
if (TREE_CODE (tparm) == PARM_DECL
&& uses_template_parms (TREE_TYPE (tparm))
&& !saw_undeduced++)
goto again;
if (!allow_incomplete)
error ("incomplete type unification");
return 2;
}
return 0;
}
/* Subroutine of type_unification_real. Args are like the variables at the
call site. ARG is an overloaded function (or template-id); we try
deducing template args from each of the overloads, and if only one
succeeds, we go with that. Modifies TARGS and returns 0 on success. */
static int
resolve_overloaded_unification (tree tparms,
tree targs,
tree parm,
tree arg,
unification_kind_t strict,
int sub_strict)
{
tree tempargs = copy_node (targs);
int good = 0;
bool addr_p;
if (TREE_CODE (arg) == ADDR_EXPR)
{
arg = TREE_OPERAND (arg, 0);
addr_p = true;
}
else
addr_p = false;
if (TREE_CODE (arg) == COMPONENT_REF)
/* Handle `&x' where `x' is some static or non-static member
function name. */
arg = TREE_OPERAND (arg, 1);
if (TREE_CODE (arg) == OFFSET_REF)
arg = TREE_OPERAND (arg, 1);
/* Strip baselink information. */
if (BASELINK_P (arg))
arg = BASELINK_FUNCTIONS (arg);
if (TREE_CODE (arg) == TEMPLATE_ID_EXPR)
{
/* If we got some explicit template args, we need to plug them into
the affected templates before we try to unify, in case the
explicit args will completely resolve the templates in question. */
tree expl_subargs = TREE_OPERAND (arg, 1);
arg = TREE_OPERAND (arg, 0);
for (; arg; arg = OVL_NEXT (arg))
{
tree fn = OVL_CURRENT (arg);
tree subargs, elem;
if (TREE_CODE (fn) != TEMPLATE_DECL)
continue;
subargs = get_bindings_overload (fn, DECL_TEMPLATE_RESULT (fn),
expl_subargs);
if (subargs)
{
elem = tsubst (TREE_TYPE (fn), subargs, tf_none, NULL_TREE);
good += try_one_overload (tparms, targs, tempargs, parm,
elem, strict, sub_strict, addr_p);
}
}
}
else if (TREE_CODE (arg) == OVERLOAD
|| TREE_CODE (arg) == FUNCTION_DECL)
{
for (; arg; arg = OVL_NEXT (arg))
good += try_one_overload (tparms, targs, tempargs, parm,
TREE_TYPE (OVL_CURRENT (arg)),
strict, sub_strict, addr_p);
}
else
abort ();
/* [temp.deduct.type] A template-argument can be deduced from a pointer
to function or pointer to member function argument if the set of
overloaded functions does not contain function templates and at most
one of a set of overloaded functions provides a unique match.
So if we found multiple possibilities, we return success but don't
deduce anything. */
if (good == 1)
{
int i = TREE_VEC_LENGTH (targs);
for (; i--; )
if (TREE_VEC_ELT (tempargs, i))
TREE_VEC_ELT (targs, i) = TREE_VEC_ELT (tempargs, i);
}
if (good)
return 0;
return 1;
}
/* Subroutine of resolve_overloaded_unification; does deduction for a single
overload. Fills TARGS with any deduced arguments, or error_mark_node if
different overloads deduce different arguments for a given parm.
ADDR_P is true if the expression for which deduction is being
performed was of the form "& fn" rather than simply "fn".
Returns 1 on success. */
static int
try_one_overload (tree tparms,
tree orig_targs,
tree targs,
tree parm,
tree arg,
unification_kind_t strict,
int sub_strict,
bool addr_p)
{
int nargs;
tree tempargs;
int i;
/* [temp.deduct.type] A template-argument can be deduced from a pointer
to function or pointer to member function argument if the set of
overloaded functions does not contain function templates and at most
one of a set of overloaded functions provides a unique match.
So if this is a template, just return success. */
if (uses_template_parms (arg))
return 1;
if (TREE_CODE (arg) == METHOD_TYPE)
arg = build_ptrmemfunc_type (build_pointer_type (arg));
else if (addr_p)
arg = build_pointer_type (arg);
sub_strict |= maybe_adjust_types_for_deduction (strict, &parm, &arg);
/* We don't copy orig_targs for this because if we have already deduced
some template args from previous args, unify would complain when we
try to deduce a template parameter for the same argument, even though
there isn't really a conflict. */
nargs = TREE_VEC_LENGTH (targs);
tempargs = make_tree_vec (nargs);
if (unify (tparms, tempargs, parm, arg, sub_strict) != 0)
return 0;
/* First make sure we didn't deduce anything that conflicts with
explicitly specified args. */
for (i = nargs; i--; )
{
tree elt = TREE_VEC_ELT (tempargs, i);
tree oldelt = TREE_VEC_ELT (orig_targs, i);
if (elt == NULL_TREE)
continue;
else if (uses_template_parms (elt))
{
/* Since we're unifying against ourselves, we will fill in template
args used in the function parm list with our own template parms.
Discard them. */
TREE_VEC_ELT (tempargs, i) = NULL_TREE;
continue;
}
else if (oldelt && ! template_args_equal (oldelt, elt))
return 0;
}
for (i = nargs; i--; )
{
tree elt = TREE_VEC_ELT (tempargs, i);
if (elt)
TREE_VEC_ELT (targs, i) = elt;
}
return 1;
}
/* Verify that nondeduce template argument agrees with the type
obtained from argument deduction. Return nonzero if the
verification fails.
For example:
struct A { typedef int X; };
template <class T, class U> struct C {};
template <class T> struct C<T, typename T::X> {};
Then with the instantiation `C<A, int>', we can deduce that
`T' is `A' but unify () does not check whether `typename T::X'
is `int'. This function ensure that they agree.
TARGS, PARMS are the same as the arguments of unify.
ARGS contains template arguments from all levels. */
static int
verify_class_unification (tree targs, tree parms, tree args)
{
parms = tsubst (parms, add_outermost_template_args (args, targs),
tf_none, NULL_TREE);
if (parms == error_mark_node)
return 1;
return !comp_template_args (parms, INNERMOST_TEMPLATE_ARGS (args));
}
/* PARM is a template class (perhaps with unbound template
parameters). ARG is a fully instantiated type. If ARG can be
bound to PARM, return ARG, otherwise return NULL_TREE. TPARMS and
TARGS are as for unify. */
static tree
try_class_unification (tree tparms, tree targs, tree parm, tree arg)
{
tree copy_of_targs;
if (!CLASSTYPE_TEMPLATE_INFO (arg)
|| (most_general_template (CLASSTYPE_TI_TEMPLATE (arg))
!= most_general_template (CLASSTYPE_TI_TEMPLATE (parm))))
return NULL_TREE;
/* We need to make a new template argument vector for the call to
unify. If we used TARGS, we'd clutter it up with the result of
the attempted unification, even if this class didn't work out.
We also don't want to commit ourselves to all the unifications
we've already done, since unification is supposed to be done on
an argument-by-argument basis. In other words, consider the
following pathological case:
template <int I, int J, int K>
struct S {};
template <int I, int J>
struct S<I, J, 2> : public S<I, I, I>, S<J, J, J> {};
template <int I, int J, int K>
void f(S<I, J, K>, S<I, I, I>);
void g() {
S<0, 0, 0> s0;
S<0, 1, 2> s2;
f(s0, s2);
}
Now, by the time we consider the unification involving `s2', we
already know that we must have `f<0, 0, 0>'. But, even though
`S<0, 1, 2>' is derived from `S<0, 0, 0>', the code is invalid
because there are two ways to unify base classes of S<0, 1, 2>
with S<I, I, I>. If we kept the already deduced knowledge, we
would reject the possibility I=1. */
copy_of_targs = make_tree_vec (TREE_VEC_LENGTH (targs));
/* If unification failed, we're done. */
if (unify (tparms, copy_of_targs, CLASSTYPE_TI_ARGS (parm),
CLASSTYPE_TI_ARGS (arg), UNIFY_ALLOW_NONE))
return NULL_TREE;
return arg;
}
/* Subroutine of get_template_base. RVAL, if non-NULL, is a base we
have already discovered to be satisfactory. ARG_BINFO is the binfo
for the base class of ARG that we are currently examining. */
static tree
get_template_base_recursive (tree tparms,
tree targs,
tree parm,
tree arg_binfo,
tree rval,
int flags)
{
tree binfos;
int i, n_baselinks;
tree arg = BINFO_TYPE (arg_binfo);
if (!(flags & GTB_IGNORE_TYPE))
{
tree r = try_class_unification (tparms, targs,
parm, arg);
/* If there is more than one satisfactory baseclass, then:
[temp.deduct.call]
If they yield more than one possible deduced A, the type
deduction fails.
applies. */
if (r && rval && !same_type_p (r, rval))
return error_mark_node;
else if (r)
rval = r;
}
binfos = BINFO_BASETYPES (arg_binfo);
n_baselinks = binfos ? TREE_VEC_LENGTH (binfos) : 0;
/* Process base types. */
for (i = 0; i < n_baselinks; i++)
{
tree base_binfo = TREE_VEC_ELT (binfos, i);
int this_virtual;
/* Skip this base, if we've already seen it. */
if (BINFO_MARKED (base_binfo))
continue;
this_virtual =
(flags & GTB_VIA_VIRTUAL) || TREE_VIA_VIRTUAL (base_binfo);
/* When searching for a non-virtual, we cannot mark virtually
found binfos. */
if (! this_virtual)
BINFO_MARKED (base_binfo) = 1;
rval = get_template_base_recursive (tparms, targs,
parm,
base_binfo,
rval,
GTB_VIA_VIRTUAL * this_virtual);
/* If we discovered more than one matching base class, we can
stop now. */
if (rval == error_mark_node)
return error_mark_node;
}
return rval;
}
/* Given a template type PARM and a class type ARG, find the unique
base type in ARG that is an instance of PARM. We do not examine
ARG itself; only its base-classes. If there is no appropriate base
class, return NULL_TREE. If there is more than one, return
error_mark_node. PARM may be the type of a partial specialization,
as well as a plain template type. Used by unify. */
static tree
get_template_base (tree tparms, tree targs, tree parm, tree arg)
{
tree rval;
tree arg_binfo;
my_friendly_assert (IS_AGGR_TYPE_CODE (TREE_CODE (arg)), 92);
arg_binfo = TYPE_BINFO (complete_type (arg));
rval = get_template_base_recursive (tparms, targs,
parm, arg_binfo,
NULL_TREE,
GTB_IGNORE_TYPE);
/* Since get_template_base_recursive marks the bases classes, we
must unmark them here. */
dfs_walk (arg_binfo, dfs_unmark, markedp, 0);
return rval;
}
/* Returns the level of DECL, which declares a template parameter. */
static int
template_decl_level (tree decl)
{
switch (TREE_CODE (decl))
{
case TYPE_DECL:
case TEMPLATE_DECL:
return TEMPLATE_TYPE_LEVEL (TREE_TYPE (decl));
case PARM_DECL:
return TEMPLATE_PARM_LEVEL (DECL_INITIAL (decl));
default:
abort ();
return 0;
}
}
/* Decide whether ARG can be unified with PARM, considering only the
cv-qualifiers of each type, given STRICT as documented for unify.
Returns nonzero iff the unification is OK on that basis.*/
static int
check_cv_quals_for_unify (int strict, tree arg, tree parm)
{
int arg_quals = cp_type_quals (arg);
int parm_quals = cp_type_quals (parm);
if (TREE_CODE (parm) == TEMPLATE_TYPE_PARM)
{
/* If the cvr quals of parm will not unify with ARG, they'll be
ignored in instantiation, so we have to do the same here. */
if (TREE_CODE (arg) == REFERENCE_TYPE)
parm_quals &= ~(TYPE_QUAL_CONST | TYPE_QUAL_VOLATILE);
if (!POINTER_TYPE_P (arg) &&
TREE_CODE (arg) != TEMPLATE_TYPE_PARM)
parm_quals &= ~TYPE_QUAL_RESTRICT;
}
if (!(strict & (UNIFY_ALLOW_MORE_CV_QUAL | UNIFY_ALLOW_OUTER_MORE_CV_QUAL))
&& (arg_quals & parm_quals) != parm_quals)
return 0;
if (!(strict & (UNIFY_ALLOW_LESS_CV_QUAL | UNIFY_ALLOW_OUTER_LESS_CV_QUAL))
&& (parm_quals & arg_quals) != arg_quals)
return 0;
return 1;
}
/* Takes parameters as for type_unification. Returns 0 if the
type deduction succeeds, 1 otherwise. The parameter STRICT is a
bitwise or of the following flags:
UNIFY_ALLOW_NONE:
Require an exact match between PARM and ARG.
UNIFY_ALLOW_MORE_CV_QUAL:
Allow the deduced ARG to be more cv-qualified (by qualification
conversion) than ARG.
UNIFY_ALLOW_LESS_CV_QUAL:
Allow the deduced ARG to be less cv-qualified than ARG.
UNIFY_ALLOW_DERIVED:
Allow the deduced ARG to be a template base class of ARG,
or a pointer to a template base class of the type pointed to by
ARG.
UNIFY_ALLOW_INTEGER:
Allow any integral type to be deduced. See the TEMPLATE_PARM_INDEX
case for more information.
UNIFY_ALLOW_OUTER_LEVEL:
This is the outermost level of a deduction. Used to determine validity
of qualification conversions. A valid qualification conversion must
have const qualified pointers leading up to the inner type which
requires additional CV quals, except at the outer level, where const
is not required [conv.qual]. It would be normal to set this flag in
addition to setting UNIFY_ALLOW_MORE_CV_QUAL.
UNIFY_ALLOW_OUTER_MORE_CV_QUAL:
This is the outermost level of a deduction, and PARM can be more CV
qualified at this point.
UNIFY_ALLOW_OUTER_LESS_CV_QUAL:
This is the outermost level of a deduction, and PARM can be less CV
qualified at this point.
UNIFY_ALLOW_MAX_CORRECTION:
This is an INTEGER_TYPE's maximum value. Used if the range may
have been derived from a size specification, such as an array size.
If the size was given by a nontype template parameter N, the maximum
value will have the form N-1. The flag says that we can (and indeed
must) unify N with (ARG + 1), an exception to the normal rules on
folding PARM. */
static int
unify (tree tparms, tree targs, tree parm, tree arg, int strict)
{
int idx;
tree targ;
tree tparm;
int strict_in = strict;
/* I don't think this will do the right thing with respect to types.
But the only case I've seen it in so far has been array bounds, where
signedness is the only information lost, and I think that will be
okay. */
while (TREE_CODE (parm) == NOP_EXPR)
parm = TREE_OPERAND (parm, 0);
if (arg == error_mark_node)
return 1;
if (arg == unknown_type_node)
/* We can't deduce anything from this, but we might get all the
template args from other function args. */
return 0;
/* If PARM uses template parameters, then we can't bail out here,
even if ARG == PARM, since we won't record unifications for the
template parameters. We might need them if we're trying to
figure out which of two things is more specialized. */
if (arg == parm && !uses_template_parms (parm))
return 0;
/* Immediately reject some pairs that won't unify because of
cv-qualification mismatches. */
if (TREE_CODE (arg) == TREE_CODE (parm)
&& TYPE_P (arg)
/* It is the elements of the array which hold the cv quals of an array
type, and the elements might be template type parms. We'll check
when we recurse. */
&& TREE_CODE (arg) != ARRAY_TYPE
/* We check the cv-qualifiers when unifying with template type
parameters below. We want to allow ARG `const T' to unify with
PARM `T' for example, when computing which of two templates
is more specialized, for example. */
&& TREE_CODE (arg) != TEMPLATE_TYPE_PARM
&& !check_cv_quals_for_unify (strict_in, arg, parm))
return 1;
if (!(strict & UNIFY_ALLOW_OUTER_LEVEL)
&& TYPE_P (parm) && !CP_TYPE_CONST_P (parm))
strict &= ~UNIFY_ALLOW_MORE_CV_QUAL;
strict &= ~UNIFY_ALLOW_OUTER_LEVEL;
strict &= ~UNIFY_ALLOW_DERIVED;
strict &= ~UNIFY_ALLOW_OUTER_MORE_CV_QUAL;
strict &= ~UNIFY_ALLOW_OUTER_LESS_CV_QUAL;
strict &= ~UNIFY_ALLOW_MAX_CORRECTION;
switch (TREE_CODE (parm))
{
case TYPENAME_TYPE:
case SCOPE_REF:
case UNBOUND_CLASS_TEMPLATE:
/* In a type which contains a nested-name-specifier, template
argument values cannot be deduced for template parameters used
within the nested-name-specifier. */
return 0;
case TEMPLATE_TYPE_PARM:
case TEMPLATE_TEMPLATE_PARM:
case BOUND_TEMPLATE_TEMPLATE_PARM:
tparm = TREE_VALUE (TREE_VEC_ELT (tparms, 0));
if (TEMPLATE_TYPE_LEVEL (parm)
!= template_decl_level (tparm))
/* The PARM is not one we're trying to unify. Just check
to see if it matches ARG. */
return (TREE_CODE (arg) == TREE_CODE (parm)
&& same_type_p (parm, arg)) ? 0 : 1;
idx = TEMPLATE_TYPE_IDX (parm);
targ = TREE_VEC_ELT (targs, idx);
tparm = TREE_VALUE (TREE_VEC_ELT (tparms, idx));
/* Check for mixed types and values. */
if ((TREE_CODE (parm) == TEMPLATE_TYPE_PARM
&& TREE_CODE (tparm) != TYPE_DECL)
|| (TREE_CODE (parm) == TEMPLATE_TEMPLATE_PARM
&& TREE_CODE (tparm) != TEMPLATE_DECL))
return 1;
if (TREE_CODE (parm) == BOUND_TEMPLATE_TEMPLATE_PARM)
{
/* ARG must be constructed from a template class or a template
template parameter. */
if (TREE_CODE (arg) != BOUND_TEMPLATE_TEMPLATE_PARM
&& (TREE_CODE (arg) != RECORD_TYPE || !CLASSTYPE_TEMPLATE_INFO (arg)))
return 1;
{
tree parmtmpl = TYPE_TI_TEMPLATE (parm);
tree parmvec = TYPE_TI_ARGS (parm);
tree argvec = TYPE_TI_ARGS (arg);
tree argtmplvec
= DECL_INNERMOST_TEMPLATE_PARMS (TYPE_TI_TEMPLATE (arg));
int i;
/* The parameter and argument roles have to be switched here
in order to handle default arguments properly. For example,
template<template <class> class TT> void f(TT<int>)
should be able to accept vector<int> which comes from
template <class T, class Allocator = allocator>
class vector. */
if (coerce_template_parms (argtmplvec, parmvec, parmtmpl, 0, 1)
== error_mark_node)
return 1;
/* Deduce arguments T, i from TT<T> or TT<i>.
We check each element of PARMVEC and ARGVEC individually
rather than the whole TREE_VEC since they can have
different number of elements. */
for (i = 0; i < TREE_VEC_LENGTH (parmvec); ++i)
{
tree t = TREE_VEC_ELT (parmvec, i);
if (unify (tparms, targs, t,
TREE_VEC_ELT (argvec, i),
UNIFY_ALLOW_NONE))
return 1;
}
}
arg = TYPE_TI_TEMPLATE (arg);
/* Fall through to deduce template name. */
}
if (TREE_CODE (parm) == TEMPLATE_TEMPLATE_PARM
|| TREE_CODE (parm) == BOUND_TEMPLATE_TEMPLATE_PARM)
{
/* Deduce template name TT from TT, TT<>, TT<T> and TT<i>. */
/* Simple cases: Value already set, does match or doesn't. */
if (targ != NULL_TREE && template_args_equal (targ, arg))
return 0;
else if (targ)
return 1;
}
else
{
/* If PARM is `const T' and ARG is only `int', we don't have
a match unless we are allowing additional qualification.
If ARG is `const int' and PARM is just `T' that's OK;
that binds `const int' to `T'. */
if (!check_cv_quals_for_unify (strict_in | UNIFY_ALLOW_LESS_CV_QUAL,
arg, parm))
return 1;
/* Consider the case where ARG is `const volatile int' and
PARM is `const T'. Then, T should be `volatile int'. */
arg = cp_build_qualified_type_real
(arg, cp_type_quals (arg) & ~cp_type_quals (parm), tf_none);
if (arg == error_mark_node)
return 1;
/* Simple cases: Value already set, does match or doesn't. */
if (targ != NULL_TREE && same_type_p (targ, arg))
return 0;
else if (targ)
return 1;
/* Make sure that ARG is not a variable-sized array. (Note
that were talking about variable-sized arrays (like
`int[n]'), rather than arrays of unknown size (like
`int[]').) We'll get very confused by such a type since
the bound of the array will not be computable in an
instantiation. Besides, such types are not allowed in
ISO C++, so we can do as we please here. */
if (variably_modified_type_p (arg))
return 1;
}
TREE_VEC_ELT (targs, idx) = arg;
return 0;
case TEMPLATE_PARM_INDEX:
tparm = TREE_VALUE (TREE_VEC_ELT (tparms, 0));
if (TEMPLATE_PARM_LEVEL (parm)
!= template_decl_level (tparm))
/* The PARM is not one we're trying to unify. Just check
to see if it matches ARG. */
return !(TREE_CODE (arg) == TREE_CODE (parm)
&& cp_tree_equal (parm, arg));
idx = TEMPLATE_PARM_IDX (parm);
targ = TREE_VEC_ELT (targs, idx);
if (targ)
return !cp_tree_equal (targ, arg);
/* [temp.deduct.type] If, in the declaration of a function template
with a non-type template-parameter, the non-type
template-parameter is used in an expression in the function
parameter-list and, if the corresponding template-argument is
deduced, the template-argument type shall match the type of the
template-parameter exactly, except that a template-argument
deduced from an array bound may be of any integral type.
The non-type parameter might use already deduced type parameters. */
tparm = tsubst (TREE_TYPE (parm), targs, 0, NULL_TREE);
if (!TREE_TYPE (arg))
/* Template-parameter dependent expression. Just accept it for now.
It will later be processed in convert_template_argument. */
;
else if (same_type_p (TREE_TYPE (arg), tparm))
/* OK */;
else if ((strict & UNIFY_ALLOW_INTEGER)
&& (TREE_CODE (tparm) == INTEGER_TYPE
|| TREE_CODE (tparm) == BOOLEAN_TYPE))
/* OK */;
else if (uses_template_parms (tparm))
/* We haven't deduced the type of this parameter yet. Try again
later. */
return 0;
else
return 1;
TREE_VEC_ELT (targs, idx) = arg;
return 0;
case PTRMEM_CST:
{
/* A pointer-to-member constant can be unified only with
another constant. */
if (TREE_CODE (arg) != PTRMEM_CST)
return 1;
/* Just unify the class member. It would be useless (and possibly
wrong, depending on the strict flags) to unify also
PTRMEM_CST_CLASS, because we want to be sure that both parm and
arg refer to the same variable, even if through different
classes. For instance:
struct A { int x; };
struct B : A { };
Unification of &A::x and &B::x must succeed. */
return unify (tparms, targs, PTRMEM_CST_MEMBER (parm),
PTRMEM_CST_MEMBER (arg), strict);
}
case POINTER_TYPE:
{
if (TREE_CODE (arg) != POINTER_TYPE)
return 1;
/* [temp.deduct.call]
A can be another pointer or pointer to member type that can
be converted to the deduced A via a qualification
conversion (_conv.qual_).
We pass down STRICT here rather than UNIFY_ALLOW_NONE.
This will allow for additional cv-qualification of the
pointed-to types if appropriate. */
if (TREE_CODE (TREE_TYPE (arg)) == RECORD_TYPE)
/* The derived-to-base conversion only persists through one
level of pointers. */
strict |= (strict_in & UNIFY_ALLOW_DERIVED);
return unify (tparms, targs, TREE_TYPE (parm),
TREE_TYPE (arg), strict);
}
case REFERENCE_TYPE:
if (TREE_CODE (arg) != REFERENCE_TYPE)
return 1;
return unify (tparms, targs, TREE_TYPE (parm), TREE_TYPE (arg),
strict & UNIFY_ALLOW_MORE_CV_QUAL);
case ARRAY_TYPE:
if (TREE_CODE (arg) != ARRAY_TYPE)
return 1;
if ((TYPE_DOMAIN (parm) == NULL_TREE)
!= (TYPE_DOMAIN (arg) == NULL_TREE))
return 1;
if (TYPE_DOMAIN (parm) != NULL_TREE
&& unify (tparms, targs, TYPE_DOMAIN (parm),
TYPE_DOMAIN (arg), UNIFY_ALLOW_NONE) != 0)
return 1;
return unify (tparms, targs, TREE_TYPE (parm), TREE_TYPE (arg),
strict & UNIFY_ALLOW_MORE_CV_QUAL);
case REAL_TYPE:
case COMPLEX_TYPE:
case VECTOR_TYPE:
case INTEGER_TYPE:
case BOOLEAN_TYPE:
case VOID_TYPE:
if (TREE_CODE (arg) != TREE_CODE (parm))
return 1;
if (TREE_CODE (parm) == INTEGER_TYPE
&& TREE_CODE (TYPE_MAX_VALUE (parm)) != INTEGER_CST)
{
if (TYPE_MIN_VALUE (parm) && TYPE_MIN_VALUE (arg)
&& unify (tparms, targs, TYPE_MIN_VALUE (parm),
TYPE_MIN_VALUE (arg), UNIFY_ALLOW_INTEGER))
return 1;
if (TYPE_MAX_VALUE (parm) && TYPE_MAX_VALUE (arg)
&& unify (tparms, targs, TYPE_MAX_VALUE (parm),
TYPE_MAX_VALUE (arg),
UNIFY_ALLOW_INTEGER | UNIFY_ALLOW_MAX_CORRECTION))
return 1;
}
/* We have already checked cv-qualification at the top of the
function. */
else if (!same_type_ignoring_top_level_qualifiers_p (arg, parm))
return 1;
/* As far as unification is concerned, this wins. Later checks
will invalidate it if necessary. */
return 0;
/* Types INTEGER_CST and MINUS_EXPR can come from array bounds. */
/* Type INTEGER_CST can come from ordinary constant template args. */
case INTEGER_CST:
while (TREE_CODE (arg) == NOP_EXPR)
arg = TREE_OPERAND (arg, 0);
if (TREE_CODE (arg) != INTEGER_CST)
return 1;
return !tree_int_cst_equal (parm, arg);
case TREE_VEC:
{
int i;
if (TREE_CODE (arg) != TREE_VEC)
return 1;
if (TREE_VEC_LENGTH (parm) != TREE_VEC_LENGTH (arg))
return 1;
for (i = 0; i < TREE_VEC_LENGTH (parm); ++i)
if (unify (tparms, targs,
TREE_VEC_ELT (parm, i), TREE_VEC_ELT (arg, i),
UNIFY_ALLOW_NONE))
return 1;
return 0;
}
case RECORD_TYPE:
case UNION_TYPE:
if (TREE_CODE (arg) != TREE_CODE (parm))
return 1;
if (TYPE_PTRMEMFUNC_P (parm))
{
if (!TYPE_PTRMEMFUNC_P (arg))
return 1;
return unify (tparms, targs,
TYPE_PTRMEMFUNC_FN_TYPE (parm),
TYPE_PTRMEMFUNC_FN_TYPE (arg),
strict);
}
if (CLASSTYPE_TEMPLATE_INFO (parm))
{
tree t = NULL_TREE;
if (strict_in & UNIFY_ALLOW_DERIVED)
{
/* First, we try to unify the PARM and ARG directly. */
t = try_class_unification (tparms, targs,
parm, arg);
if (!t)
{
/* Fallback to the special case allowed in
[temp.deduct.call]:
If P is a class, and P has the form
template-id, then A can be a derived class of
the deduced A. Likewise, if P is a pointer to
a class of the form template-id, A can be a
pointer to a derived class pointed to by the
deduced A. */
t = get_template_base (tparms, targs,
parm, arg);
if (! t || t == error_mark_node)
return 1;
}
}
else if (CLASSTYPE_TEMPLATE_INFO (arg)
&& (CLASSTYPE_TI_TEMPLATE (parm)
== CLASSTYPE_TI_TEMPLATE (arg)))
/* Perhaps PARM is something like S<U> and ARG is S<int>.
Then, we should unify `int' and `U'. */
t = arg;
else
/* There's no chance of unification succeeding. */
return 1;
return unify (tparms, targs, CLASSTYPE_TI_ARGS (parm),
CLASSTYPE_TI_ARGS (t), UNIFY_ALLOW_NONE);
}
else if (!same_type_ignoring_top_level_qualifiers_p (parm, arg))
return 1;
return 0;
case METHOD_TYPE:
case FUNCTION_TYPE:
if (TREE_CODE (arg) != TREE_CODE (parm))
return 1;
if (unify (tparms, targs, TREE_TYPE (parm),
TREE_TYPE (arg), UNIFY_ALLOW_NONE))
return 1;
return type_unification_real (tparms, targs, TYPE_ARG_TYPES (parm),
TYPE_ARG_TYPES (arg), 1,
DEDUCE_EXACT, 0, -1);
case OFFSET_TYPE:
if (TREE_CODE (arg) != OFFSET_TYPE)
return 1;
if (unify (tparms, targs, TYPE_OFFSET_BASETYPE (parm),
TYPE_OFFSET_BASETYPE (arg), UNIFY_ALLOW_NONE))
return 1;
return unify (tparms, targs, TREE_TYPE (parm), TREE_TYPE (arg),
strict);
case CONST_DECL:
if (DECL_TEMPLATE_PARM_P (parm))
return unify (tparms, targs, DECL_INITIAL (parm), arg, strict);
if (arg != decl_constant_value (parm))
return 1;
return 0;
case FIELD_DECL:
case TEMPLATE_DECL:
/* Matched cases are handled by the ARG == PARM test above. */
return 1;
case MINUS_EXPR:
if (tree_int_cst_equal (TREE_OPERAND (parm, 1), integer_one_node)
&& (strict_in & UNIFY_ALLOW_MAX_CORRECTION))
{
/* We handle this case specially, since it comes up with
arrays. In particular, something like:
template <int N> void f(int (&x)[N]);
Here, we are trying to unify the range type, which
looks like [0 ... (N - 1)]. */
tree t, t1, t2;
t1 = TREE_OPERAND (parm, 0);
t2 = TREE_OPERAND (parm, 1);
t = fold (build (PLUS_EXPR, integer_type_node, arg, t2));
return unify (tparms, targs, t1, t, strict);
}
/* else fall through */
default:
if (IS_EXPR_CODE_CLASS (TREE_CODE_CLASS (TREE_CODE (parm))))
{
/* We're looking at an expression. This can happen with
something like:
template <int I>
void foo(S<I>, S<I + 2>);
This is a "nondeduced context":
[deduct.type]
The nondeduced contexts are:
--A type that is a template-id in which one or more of
the template-arguments is an expression that references
a template-parameter.
In these cases, we assume deduction succeeded, but don't
actually infer any unifications. */
if (!uses_template_parms (parm)
&& !template_args_equal (parm, arg))
return 1;
else
return 0;
}
else
sorry ("use of `%s' in template type unification",
tree_code_name [(int) TREE_CODE (parm)]);
return 1;
}
}
�
/* Called if RESULT is explicitly instantiated, or is a member of an
explicitly instantiated class, or if using -frepo and the
instantiation of RESULT has been assigned to this file. */
void
mark_decl_instantiated (tree result, int extern_p)
{
/* We used to set this unconditionally; we moved that to
do_decl_instantiation so it wouldn't get set on members of
explicit class template instantiations. But we still need to set
it here for the 'extern template' case in order to suppress
implicit instantiations. */
if (extern_p)
SET_DECL_EXPLICIT_INSTANTIATION (result);
/* If this entity has already been written out, it's too late to
make any modifications. */
if (TREE_ASM_WRITTEN (result))
return;
if (TREE_CODE (result) != FUNCTION_DECL)
/* The TREE_PUBLIC flag for function declarations will have been
set correctly by tsubst. */
TREE_PUBLIC (result) = 1;
/* This might have been set by an earlier implicit instantiation. */
DECL_COMDAT (result) = 0;
if (! extern_p)
{
DECL_INTERFACE_KNOWN (result) = 1;
DECL_NOT_REALLY_EXTERN (result) = 1;
/* Always make artificials weak. */
if (DECL_ARTIFICIAL (result) && flag_weak)
comdat_linkage (result);
/* For WIN32 we also want to put explicit instantiations in
linkonce sections. */
else if (TREE_PUBLIC (result))
maybe_make_one_only (result);
}
if (TREE_CODE (result) == FUNCTION_DECL)
defer_fn (result);
}
/* Given two function templates PAT1 and PAT2, return:
DEDUCE should be DEDUCE_EXACT or DEDUCE_ORDER.
1 if PAT1 is more specialized than PAT2 as described in [temp.func.order].
-1 if PAT2 is more specialized than PAT1.
0 if neither is more specialized.
LEN is passed through to fn_type_unification. */
int
more_specialized (tree pat1, tree pat2, int deduce, int len)
{
tree targs;
int winner = 0;
/* If template argument deduction succeeds, we substitute the
resulting arguments into non-deduced contexts. While doing that,
we must be aware that we may encounter dependent types. */
++processing_template_decl;
targs = get_bindings_real (pat1, DECL_TEMPLATE_RESULT (pat2),
NULL_TREE, 0, deduce, len);
if (targs)
--winner;
targs = get_bindings_real (pat2, DECL_TEMPLATE_RESULT (pat1),
NULL_TREE, 0, deduce, len);
if (targs)
++winner;
--processing_template_decl;
return winner;
}
/* Given two class template specialization list nodes PAT1 and PAT2, return:
1 if PAT1 is more specialized than PAT2 as described in [temp.class.order].
-1 if PAT2 is more specialized than PAT1.
0 if neither is more specialized.
FULL_ARGS is the full set of template arguments that triggers this
partial ordering. */
int
more_specialized_class (tree pat1, tree pat2, tree full_args)
{
tree targs;
int winner = 0;
targs = get_class_bindings (TREE_VALUE (pat1), TREE_PURPOSE (pat1),
add_outermost_template_args (full_args, TREE_PURPOSE (pat2)));
if (targs)
--winner;
targs = get_class_bindings (TREE_VALUE (pat2), TREE_PURPOSE (pat2),
add_outermost_template_args (full_args, TREE_PURPOSE (pat1)));
if (targs)
++winner;
return winner;
}
/* Return the template arguments that will produce the function signature
DECL from the function template FN, with the explicit template
arguments EXPLICIT_ARGS. If CHECK_RETTYPE is 1, the return type must
also match. Return NULL_TREE if no satisfactory arguments could be
found. DEDUCE and LEN are passed through to fn_type_unification. */
static tree
get_bindings_real (tree fn,
tree decl,
tree explicit_args,
int check_rettype,
int deduce,
int len)
{
int ntparms = DECL_NTPARMS (fn);
tree targs = make_tree_vec (ntparms);
tree decl_type;
tree decl_arg_types;
int i;
/* Substitute the explicit template arguments into the type of DECL.
The call to fn_type_unification will handle substitution into the
FN. */
decl_type = TREE_TYPE (decl);
if (explicit_args && uses_template_parms (decl_type))
{
tree tmpl;
tree converted_args;
if (DECL_TEMPLATE_INFO (decl))
tmpl = DECL_TI_TEMPLATE (decl);
else
/* We can get here for some invalid specializations. */
return NULL_TREE;
converted_args
= (coerce_template_parms (DECL_INNERMOST_TEMPLATE_PARMS (tmpl),
explicit_args, NULL_TREE,
tf_none, /*require_all_arguments=*/0));
if (converted_args == error_mark_node)
return NULL_TREE;
decl_type = tsubst (decl_type, converted_args, tf_none, NULL_TREE);
if (decl_type == error_mark_node)
return NULL_TREE;
}
decl_arg_types = TYPE_ARG_TYPES (decl_type);
/* Never do unification on the 'this' parameter. */
if (DECL_NONSTATIC_MEMBER_FUNCTION_P (decl))
decl_arg_types = TREE_CHAIN (decl_arg_types);
i = fn_type_unification (fn, explicit_args, targs,
decl_arg_types,
(check_rettype || DECL_CONV_FN_P (fn)
? TREE_TYPE (decl_type) : NULL_TREE),
deduce, len);
if (i != 0)
return NULL_TREE;
return targs;
}
/* For most uses, we want to check the return type. */
static tree
get_bindings (tree fn, tree decl, tree explicit_args)
{
return get_bindings_real (fn, decl, explicit_args, 1, DEDUCE_EXACT, -1);
}
/* But for resolve_overloaded_unification, we only care about the parameter
types. */
static tree
get_bindings_overload (tree fn, tree decl, tree explicit_args)
{
return get_bindings_real (fn, decl, explicit_args, 0, DEDUCE_EXACT, -1);
}
/* Return the innermost template arguments that, when applied to a
template specialization whose innermost template parameters are
TPARMS, and whose specialization arguments are PARMS, yield the
ARGS.
For example, suppose we have:
template <class T, class U> struct S {};
template <class T> struct S<T*, int> {};
Then, suppose we want to get `S<double*, int>'. The TPARMS will be
{T}, the PARMS will be {T*, int} and the ARGS will be {double*,
int}. The resulting vector will be {double}, indicating that `T'
is bound to `double'. */
static tree
get_class_bindings (tree tparms, tree parms, tree args)
{
int i, ntparms = TREE_VEC_LENGTH (tparms);
tree vec = make_tree_vec (ntparms);
if (unify (tparms, vec, parms, INNERMOST_TEMPLATE_ARGS (args),
UNIFY_ALLOW_NONE))
return NULL_TREE;
for (i = 0; i < ntparms; ++i)
if (! TREE_VEC_ELT (vec, i))
return NULL_TREE;
if (verify_class_unification (vec, parms, args))
return NULL_TREE;
return vec;
}
/* In INSTANTIATIONS is a list of <INSTANTIATION, TEMPLATE> pairs.
Pick the most specialized template, and return the corresponding
instantiation, or if there is no corresponding instantiation, the
template itself. If there is no most specialized template,
error_mark_node is returned. If there are no templates at all,
NULL_TREE is returned. */
tree
most_specialized_instantiation (tree instantiations)
{
tree fn, champ;
int fate;
if (!instantiations)
return NULL_TREE;
champ = instantiations;
for (fn = TREE_CHAIN (instantiations); fn; fn = TREE_CHAIN (fn))
{
fate = more_specialized (TREE_VALUE (champ), TREE_VALUE (fn),
DEDUCE_EXACT, -1);
if (fate == 1)
;
else
{
if (fate == 0)
{
fn = TREE_CHAIN (fn);
if (! fn)
return error_mark_node;
}
champ = fn;
}
}
for (fn = instantiations; fn && fn != champ; fn = TREE_CHAIN (fn))
{
fate = more_specialized (TREE_VALUE (champ), TREE_VALUE (fn),
DEDUCE_EXACT, -1);
if (fate != 1)
return error_mark_node;
}
return TREE_PURPOSE (champ) ? TREE_PURPOSE (champ) : TREE_VALUE (champ);
}
/* Return the most specialized of the list of templates in FNS that can
produce an instantiation matching DECL, given the explicit template
arguments EXPLICIT_ARGS. */
static tree
most_specialized (tree fns, tree decl, tree explicit_args)
{
tree candidates = NULL_TREE;
tree fn, args;
for (fn = fns; fn; fn = TREE_CHAIN (fn))
{
tree candidate = TREE_VALUE (fn);
args = get_bindings (candidate, decl, explicit_args);
if (args)
candidates = tree_cons (NULL_TREE, candidate, candidates);
}
return most_specialized_instantiation (candidates);
}
/* If DECL is a specialization of some template, return the most
general such template. Otherwise, returns NULL_TREE.
For example, given:
template <class T> struct S { template <class U> void f(U); };
if TMPL is `template <class U> void S<int>::f(U)' this will return
the full template. This function will not trace past partial
specializations, however. For example, given in addition:
template <class T> struct S<T*> { template <class U> void f(U); };
if TMPL is `template <class U> void S<int*>::f(U)' this will return
`template <class T> template <class U> S<T*>::f(U)'. */
tree
most_general_template (tree decl)
{
/* If DECL is a FUNCTION_DECL, find the TEMPLATE_DECL of which it is
an immediate specialization. */
if (TREE_CODE (decl) == FUNCTION_DECL)
{
if (DECL_TEMPLATE_INFO (decl)) {
decl = DECL_TI_TEMPLATE (decl);
/* The DECL_TI_TEMPLATE can be an IDENTIFIER_NODE for a
template friend. */
if (TREE_CODE (decl) != TEMPLATE_DECL)
return NULL_TREE;
} else
return NULL_TREE;
}
/* Look for more and more general templates. */
while (DECL_TEMPLATE_INFO (decl))
{
/* The DECL_TI_TEMPLATE can be an IDENTIFIER_NODE in some cases.
(See cp-tree.h for details.) */
if (TREE_CODE (DECL_TI_TEMPLATE (decl)) != TEMPLATE_DECL)
break;
if (CLASS_TYPE_P (TREE_TYPE (decl))
&& CLASSTYPE_TEMPLATE_SPECIALIZATION (TREE_TYPE (decl)))
break;
/* Stop if we run into an explicitly specialized class template. */
if (!DECL_NAMESPACE_SCOPE_P (decl)
&& DECL_CONTEXT (decl)
&& CLASSTYPE_TEMPLATE_SPECIALIZATION (DECL_CONTEXT (decl)))
break;
decl = DECL_TI_TEMPLATE (decl);
}
return decl;
}
/* Return the most specialized of the class template specializations
of TMPL which can produce an instantiation matching ARGS, or
error_mark_node if the choice is ambiguous. */
static tree
most_specialized_class (tree tmpl, tree args)
{
tree list = NULL_TREE;
tree t;
tree champ;
int fate;
tmpl = most_general_template (tmpl);
for (t = DECL_TEMPLATE_SPECIALIZATIONS (tmpl); t; t = TREE_CHAIN (t))
{
tree spec_args
= get_class_bindings (TREE_VALUE (t), TREE_PURPOSE (t), args);
if (spec_args)
{
list = tree_cons (TREE_PURPOSE (t), TREE_VALUE (t), list);
TREE_TYPE (list) = TREE_TYPE (t);
}
}
if (! list)
return NULL_TREE;
t = list;
champ = t;
t = TREE_CHAIN (t);
for (; t; t = TREE_CHAIN (t))
{
fate = more_specialized_class (champ, t, args);
if (fate == 1)
;
else
{
if (fate == 0)
{
t = TREE_CHAIN (t);
if (! t)
return error_mark_node;
}
champ = t;
}
}
for (t = list; t && t != champ; t = TREE_CHAIN (t))
{
fate = more_specialized_class (champ, t, args);
if (fate != 1)
return error_mark_node;
}
return champ;
}
/* Explicitly instantiate DECL. */
void
do_decl_instantiation (tree decl, tree storage)
{
tree result = NULL_TREE;
int extern_p = 0;
if (!decl)
/* An error occurred, for which grokdeclarator has already issued
an appropriate message. */
return;
else if (! DECL_LANG_SPECIFIC (decl))
{
error ("explicit instantiation of non-template `%#D'", decl);
return;
}
else if (TREE_CODE (decl) == VAR_DECL)
{
/* There is an asymmetry here in the way VAR_DECLs and
FUNCTION_DECLs are handled by grokdeclarator. In the case of
the latter, the DECL we get back will be marked as a
template instantiation, and the appropriate
DECL_TEMPLATE_INFO will be set up. This does not happen for
VAR_DECLs so we do the lookup here. Probably, grokdeclarator
should handle VAR_DECLs as it currently handles
FUNCTION_DECLs. */
result = lookup_field (DECL_CONTEXT (decl), DECL_NAME (decl), 0, false);
if (!result || TREE_CODE (result) != VAR_DECL)
{
error ("no matching template for `%D' found", decl);
return;
}
}
else if (TREE_CODE (decl) != FUNCTION_DECL)
{
error ("explicit instantiation of `%#D'", decl);
return;
}
else
result = decl;
/* Check for various error cases. Note that if the explicit
instantiation is valid the RESULT will currently be marked as an
*implicit* instantiation; DECL_EXPLICIT_INSTANTIATION is not set
until we get here. */
if (DECL_TEMPLATE_SPECIALIZATION (result))
{
/* DR 259 [temp.spec].
Both an explicit instantiation and a declaration of an explicit
specialization shall not appear in a program unless the explicit
instantiation follows a declaration of the explicit specialization.
For a given set of template parameters, if an explicit
instantiation of a template appears after a declaration of an
explicit specialization for that template, the explicit
instantiation has no effect. */
return;
}
else if (DECL_EXPLICIT_INSTANTIATION (result))
{
/* [temp.spec]
No program shall explicitly instantiate any template more
than once.
We check DECL_INTERFACE_KNOWN so as not to complain when the first
instantiation was `extern' and the second is not, and EXTERN_P for
the opposite case. If -frepo, chances are we already got marked
as an explicit instantiation because of the repo file. */
if (DECL_INTERFACE_KNOWN (result) && !extern_p && !flag_use_repository)
pedwarn ("duplicate explicit instantiation of `%#D'", result);
/* If we've already instantiated the template, just return now. */
if (DECL_INTERFACE_KNOWN (result))
return;
}
else if (!DECL_IMPLICIT_INSTANTIATION (result))
{
error ("no matching template for `%D' found", result);
return;
}
else if (!DECL_TEMPLATE_INFO (result))
{
pedwarn ("explicit instantiation of non-template `%#D'", result);
return;
}
if (flag_external_templates)
return;
if (storage == NULL_TREE)
;
else if (storage == ridpointers[(int) RID_EXTERN])
{
if (pedantic && !in_system_header)
pedwarn ("ISO C++ forbids the use of `extern' on explicit instantiations");
extern_p = 1;
}
else
error ("storage class `%D' applied to template instantiation",
storage);
SET_DECL_EXPLICIT_INSTANTIATION (result);
mark_decl_instantiated (result, extern_p);
repo_template_instantiated (result, extern_p);
if (! extern_p)
instantiate_decl (result, /*defer_ok=*/1);
}
void
mark_class_instantiated (tree t, int extern_p)
{
SET_CLASSTYPE_EXPLICIT_INSTANTIATION (t);
SET_CLASSTYPE_INTERFACE_KNOWN (t);
CLASSTYPE_INTERFACE_ONLY (t) = extern_p;
TYPE_DECL_SUPPRESS_DEBUG (TYPE_NAME (t)) = extern_p;
if (! extern_p)
{
CLASSTYPE_DEBUG_REQUESTED (t) = 1;
rest_of_type_compilation (t, 1);
}
}
/* Called from do_type_instantiation through binding_table_foreach to
do recursive instantiation for the type bound in ENTRY. */
static void
bt_instantiate_type_proc (binding_entry entry, void *data)
{
tree storage = *(tree *) data;
if (IS_AGGR_TYPE (entry->type)
&& !uses_template_parms (CLASSTYPE_TI_ARGS (entry->type)))
do_type_instantiation (TYPE_MAIN_DECL (entry->type), storage, 0);
}
/* Perform an explicit instantiation of template class T. STORAGE, if
non-null, is the RID for extern, inline or static. COMPLAIN is
nonzero if this is called from the parser, zero if called recursively,
since the standard is unclear (as detailed below). */
void
do_type_instantiation (tree t, tree storage, tsubst_flags_t complain)
{
int extern_p = 0;
int nomem_p = 0;
int static_p = 0;
if (TREE_CODE (t) == TYPE_DECL)
t = TREE_TYPE (t);
if (! CLASS_TYPE_P (t) || ! CLASSTYPE_TEMPLATE_INFO (t))
{
error ("explicit instantiation of non-template type `%T'", t);
return;
}
complete_type (t);
/* With -fexternal-templates, explicit instantiations are treated the same
as implicit ones. */
if (flag_external_templates)
return;
if (!COMPLETE_TYPE_P (t))
{
if (complain & tf_error)
error ("explicit instantiation of `%#T' before definition of template",
t);
return;
}
if (storage != NULL_TREE)
{
if (pedantic && !in_system_header)
pedwarn("ISO C++ forbids the use of `%s' on explicit instantiations",
IDENTIFIER_POINTER (storage));
if (storage == ridpointers[(int) RID_INLINE])
nomem_p = 1;
else if (storage == ridpointers[(int) RID_EXTERN])
extern_p = 1;
else if (storage == ridpointers[(int) RID_STATIC])
static_p = 1;
else
{
error ("storage class `%D' applied to template instantiation",
storage);
extern_p = 0;
}
}
if (CLASSTYPE_TEMPLATE_SPECIALIZATION (t))
{
/* DR 259 [temp.spec].
Both an explicit instantiation and a declaration of an explicit
specialization shall not appear in a program unless the explicit
instantiation follows a declaration of the explicit specialization.
For a given set of template parameters, if an explicit
instantiation of a template appears after a declaration of an
explicit specialization for that template, the explicit
instantiation has no effect. */
return;
}
else if (CLASSTYPE_EXPLICIT_INSTANTIATION (t))
{
/* [temp.spec]
No program shall explicitly instantiate any template more
than once.
If CLASSTYPE_INTERFACE_ONLY, then the first explicit instantiation
was `extern'. If EXTERN_P then the second is. If -frepo, chances
are we already got marked as an explicit instantiation because of the
repo file. All these cases are OK. */
if (!CLASSTYPE_INTERFACE_ONLY (t) && !extern_p && !flag_use_repository
&& (complain & tf_error))
pedwarn ("duplicate explicit instantiation of `%#T'", t);
/* If we've already instantiated the template, just return now. */
if (!CLASSTYPE_INTERFACE_ONLY (t))
return;
}
mark_class_instantiated (t, extern_p);
repo_template_instantiated (t, extern_p);
if (nomem_p)
return;
{
tree tmp;
/* In contrast to implicit instantiation, where only the
declarations, and not the definitions, of members are
instantiated, we have here:
[temp.explicit]
The explicit instantiation of a class template specialization
implies the instantiation of all of its members not
previously explicitly specialized in the translation unit
containing the explicit instantiation.
Of course, we can't instantiate member template classes, since
we don't have any arguments for them. Note that the standard
is unclear on whether the instantiation of the members are
*explicit* instantiations or not. We choose to be generous,
and not set DECL_EXPLICIT_INSTANTIATION. Therefore, we allow
the explicit instantiation of a class where some of the members
have no definition in the current translation unit. */
if (! static_p)
for (tmp = TYPE_METHODS (t); tmp; tmp = TREE_CHAIN (tmp))
if (TREE_CODE (tmp) == FUNCTION_DECL
&& DECL_TEMPLATE_INSTANTIATION (tmp))
{
mark_decl_instantiated (tmp, extern_p);
repo_template_instantiated (tmp, extern_p);
if (! extern_p)
instantiate_decl (tmp, /*defer_ok=*/1);
}
for (tmp = TYPE_FIELDS (t); tmp; tmp = TREE_CHAIN (tmp))
if (TREE_CODE (tmp) == VAR_DECL && DECL_TEMPLATE_INSTANTIATION (tmp))
{
mark_decl_instantiated (tmp, extern_p);
repo_template_instantiated (tmp, extern_p);
if (! extern_p)
instantiate_decl (tmp, /*defer_ok=*/1);
}
if (CLASSTYPE_NESTED_UTDS (t))
binding_table_foreach (CLASSTYPE_NESTED_UTDS (t),
bt_instantiate_type_proc, &storage);
}
}
/* Given a function DECL, which is a specialization of TMPL, modify
DECL to be a re-instantiation of TMPL with the same template
arguments. TMPL should be the template into which tsubst'ing
should occur for DECL, not the most general template.
One reason for doing this is a scenario like this:
template <class T>
void f(const T&, int i);
void g() { f(3, 7); }
template <class T>
void f(const T& t, const int i) { }
Note that when the template is first instantiated, with
instantiate_template, the resulting DECL will have no name for the
first parameter, and the wrong type for the second. So, when we go
to instantiate the DECL, we regenerate it. */
static void
regenerate_decl_from_template (tree decl, tree tmpl)
{
/* The most general version of TMPL. */
tree gen_tmpl;
/* The arguments used to instantiate DECL, from the most general
template. */
tree args;
tree code_pattern;
tree new_decl;
bool unregistered;
args = DECL_TI_ARGS (decl);
code_pattern = DECL_TEMPLATE_RESULT (tmpl);
/* Unregister the specialization so that when we tsubst we will not
just return DECL. We don't have to unregister DECL from TMPL
because if would only be registered there if it were a partial
instantiation of a specialization, which it isn't: it's a full
instantiation. */
gen_tmpl = most_general_template (tmpl);
unregistered = reregister_specialization (decl, gen_tmpl,
/*new_spec=*/NULL_TREE);
/* If the DECL was not unregistered then something peculiar is
happening: we created a specialization but did not call
register_specialization for it. */
my_friendly_assert (unregistered, 0);
/* Make sure that we can see identifiers, and compute access
correctly. */
push_access_scope (decl);
/* Do the substitution to get the new declaration. */
new_decl = tsubst (code_pattern, args, tf_error, NULL_TREE);
if (TREE_CODE (decl) == VAR_DECL)
{
/* Set up DECL_INITIAL, since tsubst doesn't. */
if (!DECL_INITIALIZED_IN_CLASS_P (decl))
DECL_INITIAL (new_decl) =
tsubst_expr (DECL_INITIAL (code_pattern), args,
tf_error, DECL_TI_TEMPLATE (decl));
}
else if (TREE_CODE (decl) == FUNCTION_DECL)
{
/* Convince duplicate_decls to use the DECL_ARGUMENTS from the
new decl. */
DECL_INITIAL (new_decl) = error_mark_node;
/* And don't complain about a duplicate definition. */
DECL_INITIAL (decl) = NULL_TREE;
}
pop_access_scope (decl);
/* The immediate parent of the new template is still whatever it was
before, even though tsubst sets DECL_TI_TEMPLATE up as the most
general template. We also reset the DECL_ASSEMBLER_NAME since
tsubst always calculates the name as if the function in question
were really a template instance, and sometimes, with friend
functions, this is not so. See tsubst_friend_function for
details. */
DECL_TI_TEMPLATE (new_decl) = DECL_TI_TEMPLATE (decl);
COPY_DECL_ASSEMBLER_NAME (decl, new_decl);
COPY_DECL_RTL (decl, new_decl);
DECL_USE_TEMPLATE (new_decl) = DECL_USE_TEMPLATE (decl);
/* Call duplicate decls to merge the old and new declarations. */
duplicate_decls (new_decl, decl);
/* Now, re-register the specialization. */
register_specialization (decl, gen_tmpl, args);
}
/* Return the TEMPLATE_DECL into which DECL_TI_ARGS(DECL) should be
substituted to get DECL. */
tree
template_for_substitution (tree decl)
{
tree tmpl = DECL_TI_TEMPLATE (decl);
/* Set TMPL to the template whose DECL_TEMPLATE_RESULT is the pattern
for the instantiation. This is not always the most general
template. Consider, for example:
template <class T>
struct S { template <class U> void f();
template <> void f<int>(); };
and an instantiation of S<double>::f<int>. We want TD to be the
specialization S<T>::f<int>, not the more general S<T>::f<U>. */
while (/* An instantiation cannot have a definition, so we need a
more general template. */
DECL_TEMPLATE_INSTANTIATION (tmpl)
/* We must also deal with friend templates. Given:
template <class T> struct S {
template <class U> friend void f() {};
};
S<int>::f<U> say, is not an instantiation of S<T>::f<U>,
so far as the language is concerned, but that's still
where we get the pattern for the instantiation from. On
other hand, if the definition comes outside the class, say:
template <class T> struct S {
template <class U> friend void f();
};
template <class U> friend void f() {}
we don't need to look any further. That's what the check for
DECL_INITIAL is for. */
|| (TREE_CODE (decl) == FUNCTION_DECL
&& DECL_FRIEND_PSEUDO_TEMPLATE_INSTANTIATION (tmpl)
&& !DECL_INITIAL (DECL_TEMPLATE_RESULT (tmpl))))
{
/* The present template, TD, should not be a definition. If it
were a definition, we should be using it! Note that we
cannot restructure the loop to just keep going until we find
a template with a definition, since that might go too far if
a specialization was declared, but not defined. */
my_friendly_assert (!(TREE_CODE (decl) == VAR_DECL
&& !DECL_IN_AGGR_P (DECL_TEMPLATE_RESULT (tmpl))),
0);
/* Fetch the more general template. */
tmpl = DECL_TI_TEMPLATE (tmpl);
}
return tmpl;
}
/* Produce the definition of D, a _DECL generated from a template. If
DEFER_OK is nonzero, then we don't have to actually do the
instantiation now; we just have to do it sometime. */
tree
instantiate_decl (tree d, int defer_ok)
{
tree tmpl = DECL_TI_TEMPLATE (d);
tree gen_args;
tree args;
tree td;
tree code_pattern;
tree spec;
tree gen_tmpl;
int pattern_defined;
int need_push;
location_t saved_loc = input_location;
/* This function should only be used to instantiate templates for
functions and static member variables. */
my_friendly_assert (TREE_CODE (d) == FUNCTION_DECL
|| TREE_CODE (d) == VAR_DECL, 0);
/* Variables are never deferred; if instantiation is required, they
are instantiated right away. That allows for better code in the
case that an expression refers to the value of the variable --
if the variable has a constant value the referring expression can
take advantage of that fact. */
if (TREE_CODE (d) == VAR_DECL)
defer_ok = 0;
/* Don't instantiate cloned functions. Instead, instantiate the
functions they cloned. */
if (TREE_CODE (d) == FUNCTION_DECL && DECL_CLONED_FUNCTION_P (d))
d = DECL_CLONED_FUNCTION (d);
if (DECL_TEMPLATE_INSTANTIATED (d))
/* D has already been instantiated. It might seem reasonable to
check whether or not D is an explicit instantiation, and, if so,
stop here. But when an explicit instantiation is deferred
until the end of the compilation, DECL_EXPLICIT_INSTANTIATION
is set, even though we still need to do the instantiation. */
return d;
/* If we already have a specialization of this declaration, then
there's no reason to instantiate it. Note that
retrieve_specialization gives us both instantiations and
specializations, so we must explicitly check
DECL_TEMPLATE_SPECIALIZATION. */
gen_tmpl = most_general_template (tmpl);
gen_args = DECL_TI_ARGS (d);
spec = retrieve_specialization (gen_tmpl, gen_args);
if (spec != NULL_TREE && DECL_TEMPLATE_SPECIALIZATION (spec))
return spec;
/* This needs to happen before any tsubsting. */
if (! push_tinst_level (d))
return d;
timevar_push (TV_PARSE);
/* We may be in the middle of deferred access check. Disable it now. */
push_deferring_access_checks (dk_no_deferred);
/* Our caller does not expect collection to happen, which it might if
we decide to compile the function to rtl now. Arrange for a new
gc context to be created if so. */
function_depth++;
/* Set TD to the template whose DECL_TEMPLATE_RESULT is the pattern
for the instantiation. */
td = template_for_substitution (d);
code_pattern = DECL_TEMPLATE_RESULT (td);
if ((DECL_NAMESPACE_SCOPE_P (d) && !DECL_INITIALIZED_IN_CLASS_P (d))
|| DECL_TEMPLATE_SPECIALIZATION (td))
/* In the case of a friend template whose definition is provided
outside the class, we may have too many arguments. Drop the
ones we don't need. The same is true for specializations. */
args = get_innermost_template_args
(gen_args, TMPL_PARMS_DEPTH (DECL_TEMPLATE_PARMS (td)));
else
args = gen_args;
if (TREE_CODE (d) == FUNCTION_DECL)
pattern_defined = (DECL_SAVED_TREE (code_pattern) != NULL_TREE);
else
pattern_defined = ! DECL_IN_AGGR_P (code_pattern);
input_location = DECL_SOURCE_LOCATION (d);
if (pattern_defined)
{
/* Let the repository code that this template definition is
available.
The repository doesn't need to know about cloned functions
because they never actually show up in the object file. It
does need to know about the clones; those are the symbols
that the linker will be emitting error messages about. */
if (DECL_MAYBE_IN_CHARGE_CONSTRUCTOR_P (d)
|| DECL_MAYBE_IN_CHARGE_DESTRUCTOR_P (d))
{
tree t;
for (t = TREE_CHAIN (d);
t && DECL_CLONED_FUNCTION_P (t);
t = TREE_CHAIN (t))
repo_template_used (t);
}
else
repo_template_used (d);
if (flag_external_templates && ! DECL_INTERFACE_KNOWN (d))
{
if (flag_alt_external_templates)
{
if (interface_unknown)
warn_if_unknown_interface (d);
}
else if (DECL_INTERFACE_KNOWN (code_pattern))
{
DECL_INTERFACE_KNOWN (d) = 1;
DECL_NOT_REALLY_EXTERN (d) = ! DECL_EXTERNAL (code_pattern);
}
else
warn_if_unknown_interface (code_pattern);
}
if (at_eof)
import_export_decl (d);
}
if (!defer_ok)
{
/* Recheck the substitutions to obtain any warning messages
about ignoring cv qualifiers. */
tree gen = DECL_TEMPLATE_RESULT (gen_tmpl);
tree type = TREE_TYPE (gen);
/* Make sure that we can see identifiers, and compute access
correctly. D is already the target FUNCTION_DECL with the
right context. */
push_access_scope (d);
if (TREE_CODE (gen) == FUNCTION_DECL)
{
tsubst (DECL_ARGUMENTS (gen), gen_args, tf_error | tf_warning, d);
tsubst (TYPE_RAISES_EXCEPTIONS (type), gen_args,
tf_error | tf_warning, d);
/* Don't simply tsubst the function type, as that will give
duplicate warnings about poor parameter qualifications.
The function arguments are the same as the decl_arguments
without the top level cv qualifiers. */
type = TREE_TYPE (type);
}
tsubst (type, gen_args, tf_error | tf_warning, d);
pop_access_scope (d);
}
if (TREE_CODE (d) == VAR_DECL && DECL_INITIALIZED_IN_CLASS_P (d)
&& DECL_INITIAL (d) == NULL_TREE)
/* We should have set up DECL_INITIAL in instantiate_class_template. */
abort ();
/* Reject all external templates except inline functions. */
else if (DECL_INTERFACE_KNOWN (d)
&& ! DECL_NOT_REALLY_EXTERN (d)
&& ! (TREE_CODE (d) == FUNCTION_DECL
&& DECL_INLINE (d)))
goto out;
/* Defer all other templates, unless we have been explicitly
forbidden from doing so. We restore the source position here
because it's used by add_pending_template. */
else if (! pattern_defined || defer_ok)
{
input_location = saved_loc;
if (at_eof && !pattern_defined
&& DECL_EXPLICIT_INSTANTIATION (d))
/* [temp.explicit]
The definition of a non-exported function template, a
non-exported member function template, or a non-exported
member function or static data member of a class template
shall be present in every translation unit in which it is
explicitly instantiated. */
pedwarn
("explicit instantiation of `%D' but no definition available", d);
add_pending_template (d);
goto out;
}
need_push = !global_bindings_p ();
if (need_push)
push_to_top_level ();
/* Regenerate the declaration in case the template has been modified
by a subsequent redeclaration. */
regenerate_decl_from_template (d, td);
/* We already set the file and line above. Reset them now in case
they changed as a result of calling
regenerate_decl_from_template. */
input_location = DECL_SOURCE_LOCATION (d);
if (TREE_CODE (d) == VAR_DECL)
{
/* Clear out DECL_RTL; whatever was there before may not be right
since we've reset the type of the declaration. */
SET_DECL_RTL (d, NULL_RTX);
DECL_IN_AGGR_P (d) = 0;
import_export_decl (d);
DECL_EXTERNAL (d) = ! DECL_NOT_REALLY_EXTERN (d);
if (DECL_EXTERNAL (d))
{
/* The fact that this code is executing indicates that:
(1) D is a template static data member, for which a
definition is available.
(2) An implicit or explicit instantiation has occurred.
(3) We are not going to emit a definition of the static
data member at this time.
This situation is peculiar, but it occurs on platforms
without weak symbols when performing an implicit
instantiation. There, we cannot implicitly instantiate a
defined static data member in more than one translation
unit, so import_export_decl marks the declaration as
external; we must rely on explicit instantiation. */
}
else
{
/* Mark D as instantiated so that recursive calls to
instantiate_decl do not try to instantiate it again. */
DECL_TEMPLATE_INSTANTIATED (d) = 1;
cp_finish_decl (d,
(!DECL_INITIALIZED_IN_CLASS_P (d)
? DECL_INITIAL (d) : NULL_TREE),
NULL_TREE, 0);
}
}
else if (TREE_CODE (d) == FUNCTION_DECL)
{
htab_t saved_local_specializations;
tree subst_decl;
tree tmpl_parm;
tree spec_parm;
/* Mark D as instantiated so that recursive calls to
instantiate_decl do not try to instantiate it again. */
DECL_TEMPLATE_INSTANTIATED (d) = 1;
/* Save away the current list, in case we are instantiating one
template from within the body of another. */
saved_local_specializations = local_specializations;
/* Set up the list of local specializations. */
local_specializations = htab_create (37,
hash_local_specialization,
eq_local_specializations,
NULL);
/* Set up context. */
import_export_decl (d);
start_function (NULL_TREE, d, NULL_TREE, SF_PRE_PARSED);
/* Create substitution entries for the parameters. */
subst_decl = DECL_TEMPLATE_RESULT (template_for_substitution (d));
tmpl_parm = DECL_ARGUMENTS (subst_decl);
spec_parm = DECL_ARGUMENTS (d);
if (DECL_NONSTATIC_MEMBER_FUNCTION_P (d))
{
register_local_specialization (spec_parm, tmpl_parm);
spec_parm = skip_artificial_parms_for (d, spec_parm);
tmpl_parm = skip_artificial_parms_for (subst_decl, tmpl_parm);
}
while (tmpl_parm)
{
register_local_specialization (spec_parm, tmpl_parm);
tmpl_parm = TREE_CHAIN (tmpl_parm);
spec_parm = TREE_CHAIN (spec_parm);
}
my_friendly_assert (!spec_parm, 20020813);
/* Substitute into the body of the function. */
tsubst_expr (DECL_SAVED_TREE (code_pattern), args,
tf_error | tf_warning, tmpl);
/* We don't need the local specializations any more. */
htab_delete (local_specializations);
local_specializations = saved_local_specializations;
/* Finish the function. */
d = finish_function (0);
expand_or_defer_fn (d);
}
/* We're not deferring instantiation any more. */
TI_PENDING_TEMPLATE_FLAG (DECL_TEMPLATE_INFO (d)) = 0;
if (need_push)
pop_from_top_level ();
out:
input_location = saved_loc;
pop_deferring_access_checks ();
pop_tinst_level ();
function_depth--;
timevar_pop (TV_PARSE);
return d;
}
/* Run through the list of templates that we wish we could
instantiate, and instantiate any we can. */
int
instantiate_pending_templates (void)
{
tree *t;
tree last = NULL_TREE;
int instantiated_something = 0;
int reconsider;
location_t saved_loc = input_location;
do
{
reconsider = 0;
t = &pending_templates;
while (*t)
{
tree instantiation = TREE_VALUE (*t);
reopen_tinst_level (TREE_PURPOSE (*t));
if (TYPE_P (instantiation))
{
tree fn;
if (!COMPLETE_TYPE_P (instantiation))
{
instantiate_class_template (instantiation);
if (CLASSTYPE_TEMPLATE_INSTANTIATION (instantiation))
for (fn = TYPE_METHODS (instantiation);
fn;
fn = TREE_CHAIN (fn))
if (! DECL_ARTIFICIAL (fn))
instantiate_decl (fn, /*defer_ok=*/0);
if (COMPLETE_TYPE_P (instantiation))
{
instantiated_something = 1;
reconsider = 1;
}
}
if (COMPLETE_TYPE_P (instantiation))
/* If INSTANTIATION has been instantiated, then we don't
need to consider it again in the future. */
*t = TREE_CHAIN (*t);
else
{
last = *t;
t = &TREE_CHAIN (*t);
}
}
else
{
if (!DECL_TEMPLATE_SPECIALIZATION (instantiation)
&& !DECL_TEMPLATE_INSTANTIATED (instantiation))
{
instantiation = instantiate_decl (instantiation,
/*defer_ok=*/0);
if (DECL_TEMPLATE_INSTANTIATED (instantiation))
{
instantiated_something = 1;
reconsider = 1;
}
}
if (DECL_TEMPLATE_SPECIALIZATION (instantiation)
|| DECL_TEMPLATE_INSTANTIATED (instantiation))
/* If INSTANTIATION has been instantiated, then we don't
need to consider it again in the future. */
*t = TREE_CHAIN (*t);
else
{
last = *t;
t = &TREE_CHAIN (*t);
}
}
tinst_depth = 0;
current_tinst_level = NULL_TREE;
}
last_pending_template = last;
}
while (reconsider);
input_location = saved_loc;
return instantiated_something;
}
/* Substitute ARGVEC into T, which is a list of initializers for
either base class or a non-static data member. The TREE_PURPOSEs
are DECLs, and the TREE_VALUEs are the initializer values. Used by
instantiate_decl. */
static tree
tsubst_initializer_list (tree t, tree argvec)
{
tree inits = NULL_TREE;
for (; t; t = TREE_CHAIN (t))
{
tree decl;
tree init;
tree val;
decl = tsubst_copy (TREE_PURPOSE (t), argvec, tf_error | tf_warning,
NULL_TREE);
decl = expand_member_init (decl);
if (decl && !DECL_P (decl))
in_base_initializer = 1;
init = tsubst_expr (TREE_VALUE (t), argvec, tf_error | tf_warning,
NULL_TREE);
if (!init)
;
else if (TREE_CODE (init) == TREE_LIST)
for (val = init; val; val = TREE_CHAIN (val))
TREE_VALUE (val) = convert_from_reference (TREE_VALUE (val));
else if (init != void_type_node)
init = convert_from_reference (init);
in_base_initializer = 0;
if (decl)
{
init = build_tree_list (decl, init);
TREE_CHAIN (init) = inits;
inits = init;
}
}
return inits;
}
/* Set CURRENT_ACCESS_SPECIFIER based on the protection of DECL. */
static void
set_current_access_from_decl (tree decl)
{
if (TREE_PRIVATE (decl))
current_access_specifier = access_private_node;
else if (TREE_PROTECTED (decl))
current_access_specifier = access_protected_node;
else
current_access_specifier = access_public_node;
}
/* Instantiate an enumerated type. TAG is the template type, NEWTAG
is the instantiation (which should have been created with
start_enum) and ARGS are the template arguments to use. */
static void
tsubst_enum (tree tag, tree newtag, tree args)
{
tree e;
for (e = TYPE_VALUES (tag); e; e = TREE_CHAIN (e))
{
tree value;
tree decl;
decl = TREE_VALUE (e);
/* Note that in a template enum, the TREE_VALUE is the
CONST_DECL, not the corresponding INTEGER_CST. */
value = tsubst_expr (DECL_INITIAL (decl),
args, tf_error | tf_warning,
NULL_TREE);
/* Give this enumeration constant the correct access. */
set_current_access_from_decl (decl);
/* Actually build the enumerator itself. */
build_enumerator (DECL_NAME (decl), value, newtag);
}
finish_enum (newtag);
DECL_SOURCE_LOCATION (TYPE_NAME (newtag))
= DECL_SOURCE_LOCATION (TYPE_NAME (tag));
}
/* DECL is a FUNCTION_DECL that is a template specialization. Return
its type -- but without substituting the innermost set of template
arguments. So, innermost set of template parameters will appear in
the type. */
tree
get_mostly_instantiated_function_type (tree decl)
{
tree fn_type;
tree tmpl;
tree targs;
tree tparms;
int parm_depth;
tmpl = most_general_template (DECL_TI_TEMPLATE (decl));
targs = DECL_TI_ARGS (decl);
tparms = DECL_TEMPLATE_PARMS (tmpl);
parm_depth = TMPL_PARMS_DEPTH (tparms);
/* There should be as many levels of arguments as there are levels
of parameters. */
my_friendly_assert (parm_depth == TMPL_ARGS_DEPTH (targs), 0);
fn_type = TREE_TYPE (tmpl);
if (parm_depth == 1)
/* No substitution is necessary. */
;
else
{
int i;
tree partial_args;
/* Replace the innermost level of the TARGS with NULL_TREEs to
let tsubst know not to substitute for those parameters. */
partial_args = make_tree_vec (TREE_VEC_LENGTH (targs));
for (i = 1; i < TMPL_ARGS_DEPTH (targs); ++i)
SET_TMPL_ARGS_LEVEL (partial_args, i,
TMPL_ARGS_LEVEL (targs, i));
SET_TMPL_ARGS_LEVEL (partial_args,
TMPL_ARGS_DEPTH (targs),
make_tree_vec (DECL_NTPARMS (tmpl)));
/* Make sure that we can see identifiers, and compute access
correctly. We can just use the context of DECL for the
partial substitution here. It depends only on outer template
parameters, regardless of whether the innermost level is
specialized or not. */
push_access_scope (decl);
++processing_template_decl;
/* Now, do the (partial) substitution to figure out the
appropriate function type. */
fn_type = tsubst (fn_type, partial_args, tf_error, NULL_TREE);
--processing_template_decl;
/* Substitute into the template parameters to obtain the real
innermost set of parameters. This step is important if the
innermost set of template parameters contains value
parameters whose types depend on outer template parameters. */
TREE_VEC_LENGTH (partial_args)--;
tparms = tsubst_template_parms (tparms, partial_args, tf_error);
pop_access_scope (decl);
}
return fn_type;
}
/* Return truthvalue if we're processing a template different from
the last one involved in diagnostics. */
int
problematic_instantiation_changed (void)
{
return last_template_error_tick != tinst_level_tick;
}
/* Remember current template involved in diagnostics. */
void
record_last_problematic_instantiation (void)
{
last_template_error_tick = tinst_level_tick;
}
tree
current_instantiation (void)
{
return current_tinst_level;
}
/* [temp.param] Check that template non-type parm TYPE is of an allowable
type. Return zero for ok, nonzero for disallowed. Issue error and
warning messages under control of COMPLAIN. */
static int
invalid_nontype_parm_type_p (tree type, tsubst_flags_t complain)
{
if (INTEGRAL_TYPE_P (type))
return 0;
else if (POINTER_TYPE_P (type))
return 0;
else if (TYPE_PTR_TO_MEMBER_P (type))
return 0;
else if (TREE_CODE (type) == TEMPLATE_TYPE_PARM)
return 0;
else if (TREE_CODE (type) == TYPENAME_TYPE)
return 0;
if (complain & tf_error)
error ("`%#T' is not a valid type for a template constant parameter",
type);
return 1;
}
/* Returns TRUE if TYPE is dependent, in the sense of [temp.dep.type].
Assumes that TYPE really is a type, and not the ERROR_MARK_NODE.*/
static bool
dependent_type_p_r (tree type)
{
tree scope;
/* [temp.dep.type]
A type is dependent if it is:
-- a template parameter. */
if (TREE_CODE (type) == TEMPLATE_TYPE_PARM)
return true;
/* -- a qualified-id with a nested-name-specifier which contains a
class-name that names a dependent type or whose unqualified-id
names a dependent type. */
if (TREE_CODE (type) == TYPENAME_TYPE)
return true;
/* -- a cv-qualified type where the cv-unqualified type is
dependent. */
type = TYPE_MAIN_VARIANT (type);
/* -- a compound type constructed from any dependent type. */
if (TYPE_PTR_TO_MEMBER_P (type))
return (dependent_type_p (TYPE_PTRMEM_CLASS_TYPE (type))
|| dependent_type_p (TYPE_PTRMEM_POINTED_TO_TYPE
(type)));
else if (TREE_CODE (type) == POINTER_TYPE
|| TREE_CODE (type) == REFERENCE_TYPE)
return dependent_type_p (TREE_TYPE (type));
else if (TREE_CODE (type) == FUNCTION_TYPE
|| TREE_CODE (type) == METHOD_TYPE)
{
tree arg_type;
if (dependent_type_p (TREE_TYPE (type)))
return true;
for (arg_type = TYPE_ARG_TYPES (type);
arg_type;
arg_type = TREE_CHAIN (arg_type))
if (dependent_type_p (TREE_VALUE (arg_type)))
return true;
return false;
}
/* -- an array type constructed from any dependent type or whose
size is specified by a constant expression that is
value-dependent. */
if (TREE_CODE (type) == ARRAY_TYPE)
{
if (TYPE_DOMAIN (type)
&& ((value_dependent_expression_p
(TYPE_MAX_VALUE (TYPE_DOMAIN (type))))
|| (type_dependent_expression_p
(TYPE_MAX_VALUE (TYPE_DOMAIN (type))))))
return true;
return dependent_type_p (TREE_TYPE (type));
}
/* -- a template-id in which either the template name is a template
parameter ... */
if (TREE_CODE (type) == BOUND_TEMPLATE_TEMPLATE_PARM)
return true;
/* ... or any of the template arguments is a dependent type or
an expression that is type-dependent or value-dependent. */
else if (CLASS_TYPE_P (type) && CLASSTYPE_TEMPLATE_INFO (type)
&& (any_dependent_template_arguments_p
(INNERMOST_TEMPLATE_ARGS (CLASSTYPE_TI_ARGS (type)))))
return true;
/* All TYPEOF_TYPEs are dependent; if the argument of the `typeof'
expression is not type-dependent, then it should already been
have resolved. */
if (TREE_CODE (type) == TYPEOF_TYPE)
return true;
/* The standard does not specifically mention types that are local
to template functions or local classes, but they should be
considered dependent too. For example:
template <int I> void f() {
enum E { a = I };
S<sizeof (E)> s;
}
The size of `E' cannot be known until the value of `I' has been
determined. Therefore, `E' must be considered dependent. */
scope = TYPE_CONTEXT (type);
if (scope && TYPE_P (scope))
return dependent_type_p (scope);
else if (scope && TREE_CODE (scope) == FUNCTION_DECL)
return type_dependent_expression_p (scope);
/* Other types are non-dependent. */
return false;
}
/* Returns TRUE if TYPE is dependent, in the sense of
[temp.dep.type]. */
bool
dependent_type_p (tree type)
{
/* If there are no template parameters in scope, then there can't be
any dependent types. */
if (!processing_template_decl)
return false;
/* If the type is NULL, we have not computed a type for the entity
in question; in that case, the type is dependent. */
if (!type)
return true;
/* Erroneous types can be considered non-dependent. */
if (type == error_mark_node)
return false;
/* If we have not already computed the appropriate value for TYPE,
do so now. */
if (!TYPE_DEPENDENT_P_VALID (type))
{
TYPE_DEPENDENT_P (type) = dependent_type_p_r (type);
TYPE_DEPENDENT_P_VALID (type) = 1;
}
return TYPE_DEPENDENT_P (type);
}
/* Returns TRUE if EXPRESSION is dependent, according to CRITERION. */
static bool
dependent_scope_ref_p (tree expression, bool criterion (tree))
{
tree scope;
tree name;
my_friendly_assert (TREE_CODE (expression) == SCOPE_REF, 20030714);
if (!TYPE_P (TREE_OPERAND (expression, 0)))
return true;
scope = TREE_OPERAND (expression, 0);
name = TREE_OPERAND (expression, 1);
/* [temp.dep.expr]
An id-expression is type-dependent if it contains a
nested-name-specifier that contains a class-name that names a
dependent type. */
/* The suggested resolution to Core Issue 2 implies that if the
qualifying type is the current class, then we must peek
inside it. */
if (DECL_P (name)
&& currently_open_class (scope)
&& !criterion (name))
return false;
if (dependent_type_p (scope))
return true;
return false;
}
/* Returns TRUE if the EXPRESSION is value-dependent, in the sense of
[temp.dep.constexpr] */
bool
value_dependent_expression_p (tree expression)
{
if (!processing_template_decl)
return false;
/* A name declared with a dependent type. */
if (TREE_CODE (expression) == IDENTIFIER_NODE
|| (DECL_P (expression)
&& type_dependent_expression_p (expression)))
return true;
/* A non-type template parameter. */
if ((TREE_CODE (expression) == CONST_DECL
&& DECL_TEMPLATE_PARM_P (expression))
|| TREE_CODE (expression) == TEMPLATE_PARM_INDEX)
return true;
/* A constant with integral or enumeration type and is initialized
with an expression that is value-dependent. */
if (TREE_CODE (expression) == VAR_DECL
&& DECL_INITIAL (expression)
&& INTEGRAL_OR_ENUMERATION_TYPE_P (TREE_TYPE (expression))
&& value_dependent_expression_p (DECL_INITIAL (expression)))
return true;
/* These expressions are value-dependent if the type to which the
cast occurs is dependent or the expression being casted is
value-dependent. */
if (TREE_CODE (expression) == DYNAMIC_CAST_EXPR
|| TREE_CODE (expression) == STATIC_CAST_EXPR
|| TREE_CODE (expression) == CONST_CAST_EXPR
|| TREE_CODE (expression) == REINTERPRET_CAST_EXPR
|| TREE_CODE (expression) == CAST_EXPR)
{
if (dependent_type_p (TREE_TYPE (expression)))
return true;
/* A functional cast has a list of operands. */
expression = TREE_OPERAND (expression, 0);
if (TREE_CODE (expression) == TREE_LIST)
{
do
{
if (value_dependent_expression_p (TREE_VALUE (expression)))
return true;
expression = TREE_CHAIN (expression);
}
while (expression);
return false;
}
else
return value_dependent_expression_p (expression);
}
/* A `sizeof' expression is value-dependent if the operand is
type-dependent. */
if (TREE_CODE (expression) == SIZEOF_EXPR
|| TREE_CODE (expression) == ALIGNOF_EXPR)
{
expression = TREE_OPERAND (expression, 0);
if (TYPE_P (expression))
return dependent_type_p (expression);
return type_dependent_expression_p (expression);
}
if (TREE_CODE (expression) == SCOPE_REF)
return dependent_scope_ref_p (expression, value_dependent_expression_p);
if (TREE_CODE (expression) == COMPONENT_REF)
return (value_dependent_expression_p (TREE_OPERAND (expression, 0))
|| value_dependent_expression_p (TREE_OPERAND (expression, 1)));
/* A constant expression is value-dependent if any subexpression is
value-dependent. */
if (IS_EXPR_CODE_CLASS (TREE_CODE_CLASS (TREE_CODE (expression))))
{
switch (TREE_CODE_CLASS (TREE_CODE (expression)))
{
case '1':
return (value_dependent_expression_p
(TREE_OPERAND (expression, 0)));
case '<':
case '2':
return ((value_dependent_expression_p
(TREE_OPERAND (expression, 0)))
|| (value_dependent_expression_p
(TREE_OPERAND (expression, 1))));
case 'e':
{
int i;
for (i = 0; i < first_rtl_op (TREE_CODE (expression)); ++i)
/* In some cases, some of the operands may be missing.
(For example, in the case of PREDECREMENT_EXPR, the
amount to increment by may be missing.) That doesn't
make the expression dependent. */
if (TREE_OPERAND (expression, i)
&& (value_dependent_expression_p
(TREE_OPERAND (expression, i))))
return true;
return false;
}
}
}
/* The expression is not value-dependent. */
return false;
}
/* Returns TRUE if the EXPRESSION is type-dependent, in the sense of
[temp.dep.expr]. */
bool
type_dependent_expression_p (tree expression)
{
if (!processing_template_decl)
return false;
if (expression == error_mark_node)
return false;
/* An unresolved name is always dependent. */
if (TREE_CODE (expression) == IDENTIFIER_NODE)
return true;
/* Some expression forms are never type-dependent. */
if (TREE_CODE (expression) == PSEUDO_DTOR_EXPR
|| TREE_CODE (expression) == SIZEOF_EXPR
|| TREE_CODE (expression) == ALIGNOF_EXPR
|| TREE_CODE (expression) == TYPEID_EXPR
|| TREE_CODE (expression) == DELETE_EXPR
|| TREE_CODE (expression) == VEC_DELETE_EXPR
|| TREE_CODE (expression) == THROW_EXPR)
return false;
/* The types of these expressions depends only on the type to which
the cast occurs. */
if (TREE_CODE (expression) == DYNAMIC_CAST_EXPR
|| TREE_CODE (expression) == STATIC_CAST_EXPR
|| TREE_CODE (expression) == CONST_CAST_EXPR
|| TREE_CODE (expression) == REINTERPRET_CAST_EXPR
|| TREE_CODE (expression) == CAST_EXPR)
return dependent_type_p (TREE_TYPE (expression));
/* The types of these expressions depends only on the type created
by the expression. */
if (TREE_CODE (expression) == NEW_EXPR
|| TREE_CODE (expression) == VEC_NEW_EXPR)
{
/* For NEW_EXPR tree nodes created inside a template, either
the object type itself or a TREE_LIST may appear as the
operand 1. */
tree type = TREE_OPERAND (expression, 1);
if (TREE_CODE (type) == TREE_LIST)
/* This is an array type. We need to check array dimensions
as well. */
return dependent_type_p (TREE_VALUE (TREE_PURPOSE (type)))
|| value_dependent_expression_p
(TREE_OPERAND (TREE_VALUE (type), 1));
else
return dependent_type_p (type);
}
if (TREE_CODE (expression) == SCOPE_REF
&& dependent_scope_ref_p (expression,
type_dependent_expression_p))
return true;
if (TREE_CODE (expression) == FUNCTION_DECL
&& DECL_LANG_SPECIFIC (expression)
&& DECL_TEMPLATE_INFO (expression)
&& (any_dependent_template_arguments_p
(INNERMOST_TEMPLATE_ARGS (DECL_TI_ARGS (expression)))))
return true;
if (TREE_TYPE (expression) == unknown_type_node)
{
if (TREE_CODE (expression) == ADDR_EXPR)
return type_dependent_expression_p (TREE_OPERAND (expression, 0));
if (TREE_CODE (expression) == COMPONENT_REF)
{
if (type_dependent_expression_p (TREE_OPERAND (expression, 0)))
return true;
expression = TREE_OPERAND (expression, 1);
if (TREE_CODE (expression) == IDENTIFIER_NODE)
return false;
}
if (TREE_CODE (expression) == BASELINK)
expression = BASELINK_FUNCTIONS (expression);
if (TREE_CODE (expression) == TEMPLATE_ID_EXPR)
{
if (any_dependent_template_arguments_p
(TREE_OPERAND (expression, 1)))
return true;
expression = TREE_OPERAND (expression, 0);
}
if (TREE_CODE (expression) == OVERLOAD)
{
while (expression)
{
if (type_dependent_expression_p (OVL_CURRENT (expression)))
return true;
expression = OVL_NEXT (expression);
}
return false;
}
abort ();
}
return (dependent_type_p (TREE_TYPE (expression)));
}
/* Returns TRUE if ARGS (a TREE_LIST of arguments to a function call)
contains a type-dependent expression. */
bool
any_type_dependent_arguments_p (tree args)
{
while (args)
{
tree arg = TREE_VALUE (args);
if (type_dependent_expression_p (arg))
return true;
args = TREE_CHAIN (args);
}
return false;
}
/* Returns TRUE if the ARG (a template argument) is dependent. */
static bool
dependent_template_arg_p (tree arg)
{
if (!processing_template_decl)
return false;
if (TREE_CODE (arg) == TEMPLATE_DECL
|| TREE_CODE (arg) == TEMPLATE_TEMPLATE_PARM)
return dependent_template_p (arg);
else if (TYPE_P (arg))
return dependent_type_p (arg);
else
return (type_dependent_expression_p (arg)
|| value_dependent_expression_p (arg));
}
/* Returns true if ARGS (a collection of template arguments) contains
any dependent arguments. */
bool
any_dependent_template_arguments_p (tree args)
{
int i;
if (!args)
return false;
for (i = 0; i < TREE_VEC_LENGTH (args); ++i)
if (dependent_template_arg_p (TREE_VEC_ELT (args, i)))
return true;
return false;
}
/* Returns TRUE if the template TMPL is dependent. */
bool
dependent_template_p (tree tmpl)
{
/* Template template parameters are dependent. */
if (DECL_TEMPLATE_TEMPLATE_PARM_P (tmpl)
|| TREE_CODE (tmpl) == TEMPLATE_TEMPLATE_PARM)
return true;
/* So are qualified names that have not been looked up. */
if (TREE_CODE (tmpl) == SCOPE_REF)
return true;
/* So are member templates of dependent classes. */
if (TYPE_P (CP_DECL_CONTEXT (tmpl)))
return dependent_type_p (DECL_CONTEXT (tmpl));
return false;
}
/* Returns TRUE if the specialization TMPL<ARGS> is dependent. */
bool
dependent_template_id_p (tree tmpl, tree args)
{
return (dependent_template_p (tmpl)
|| any_dependent_template_arguments_p (args));
}
/* TYPE is a TYPENAME_TYPE. Returns the ordinary TYPE to which the
TYPENAME_TYPE corresponds. Returns ERROR_MARK_NODE if no such TYPE
can be found. Note that this function peers inside uninstantiated
templates and therefore should be used only in extremely limited
situations. */
tree
resolve_typename_type (tree type, bool only_current_p)
{
tree scope;
tree name;
tree decl;
int quals;
my_friendly_assert (TREE_CODE (type) == TYPENAME_TYPE,
20010702);
scope = TYPE_CONTEXT (type);
name = TYPE_IDENTIFIER (type);
/* If the SCOPE is itself a TYPENAME_TYPE, then we need to resolve
it first before we can figure out what NAME refers to. */
if (TREE_CODE (scope) == TYPENAME_TYPE)
scope = resolve_typename_type (scope, only_current_p);
/* If we don't know what SCOPE refers to, then we cannot resolve the
TYPENAME_TYPE. */
if (scope == error_mark_node || TREE_CODE (scope) == TYPENAME_TYPE)
return error_mark_node;
/* If the SCOPE is a template type parameter, we have no way of
resolving the name. */
if (TREE_CODE (scope) == TEMPLATE_TYPE_PARM)
return type;
/* If the SCOPE is not the current instantiation, there's no reason
to look inside it. */
if (only_current_p && !currently_open_class (scope))
return error_mark_node;
/* If SCOPE is a partial instantiation, it will not have a valid
TYPE_FIELDS list, so use the original template. */
scope = CLASSTYPE_PRIMARY_TEMPLATE_TYPE (scope);
/* Enter the SCOPE so that name lookup will be resolved as if we
were in the class definition. In particular, SCOPE will no
longer be considered a dependent type. */
push_scope (scope);
/* Look up the declaration. */
decl = lookup_member (scope, name, /*protect=*/0, /*want_type=*/true);
/* Obtain the set of qualifiers applied to the TYPE. */
quals = cp_type_quals (type);
/* For a TYPENAME_TYPE like "typename X::template Y<T>", we want to
find a TEMPLATE_DECL. Otherwise, we want to find a TYPE_DECL. */
if (!decl)
type = error_mark_node;
else if (TREE_CODE (TYPENAME_TYPE_FULLNAME (type)) == IDENTIFIER_NODE
&& TREE_CODE (decl) == TYPE_DECL)
type = TREE_TYPE (decl);
else if (TREE_CODE (TYPENAME_TYPE_FULLNAME (type)) == TEMPLATE_ID_EXPR
&& DECL_CLASS_TEMPLATE_P (decl))
{
tree tmpl;
tree args;
/* Obtain the template and the arguments. */
tmpl = TREE_OPERAND (TYPENAME_TYPE_FULLNAME (type), 0);
args = TREE_OPERAND (TYPENAME_TYPE_FULLNAME (type), 1);
/* Instantiate the template. */
type = lookup_template_class (tmpl, args, NULL_TREE, NULL_TREE,
/*entering_scope=*/0, tf_error | tf_user);
}
else
type = error_mark_node;
/* Qualify the resulting type. */
if (type != error_mark_node && quals)
type = cp_build_qualified_type (type, quals);
/* Leave the SCOPE. */
pop_scope (scope);
return type;
}
/* EXPR is an expression which is not type-dependent. Return a proxy
for EXPR that can be used to compute the types of larger
expressions containing EXPR. */
tree
build_non_dependent_expr (tree expr)
{
/* Preserve null pointer constants so that the type of things like
"p == 0" where "p" is a pointer can be determined. */
if (null_ptr_cst_p (expr))
return expr;
/* Preserve OVERLOADs; the functions must be available to resolve
types. */
if (TREE_CODE (expr) == OVERLOAD)
return expr;
/* Preserve string constants; conversions from string constants to
"char *" are allowed, even though normally a "const char *"
cannot be used to initialize a "char *". */
if (TREE_CODE (expr) == STRING_CST)
return expr;
if (TREE_CODE (expr) == COND_EXPR)
return build (COND_EXPR,
TREE_TYPE (expr),
TREE_OPERAND (expr, 0),
(TREE_OPERAND (expr, 1)
? build_non_dependent_expr (TREE_OPERAND (expr, 1))
: build_non_dependent_expr (TREE_OPERAND (expr, 0))),
build_non_dependent_expr (TREE_OPERAND (expr, 2)));
if (TREE_CODE (expr) == COMPOUND_EXPR
&& !COMPOUND_EXPR_OVERLOADED (expr))
return build (COMPOUND_EXPR,
TREE_TYPE (expr),
TREE_OPERAND (expr, 0),
build_non_dependent_expr (TREE_OPERAND (expr, 1)));
/* Otherwise, build a NON_DEPENDENT_EXPR.
REFERENCE_TYPEs are not stripped for expressions in templates
because doing so would play havoc with mangling. Consider, for
example:
template <typename T> void f<T& g>() { g(); }
In the body of "f", the expression for "g" will have
REFERENCE_TYPE, even though the standard says that it should
not. The reason is that we must preserve the syntactic form of
the expression so that mangling (say) "f<g>" inside the body of
"f" works out correctly. Therefore, the REFERENCE_TYPE is
stripped here. */
return build1 (NON_DEPENDENT_EXPR, non_reference (TREE_TYPE (expr)), expr);
}
/* ARGS is a TREE_LIST of expressions as arguments to a function call.
Return a new TREE_LIST with the various arguments replaced with
equivalent non-dependent expressions. */
tree
build_non_dependent_args (tree args)
{
tree a;
tree new_args;
new_args = NULL_TREE;
for (a = args; a; a = TREE_CHAIN (a))
new_args = tree_cons (NULL_TREE,
build_non_dependent_expr (TREE_VALUE (a)),
new_args);
return nreverse (new_args);
}
#include "gt-cp-pt.h"