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/****************************************************************************
* *
* GNAT COMPILER COMPONENTS *
* *
* U T I L S *
* *
* C Implementation File *
* *
* Copyright (C) 1992-2012, Free Software Foundation, Inc. *
* *
* GNAT is free software; you can redistribute it and/or modify it under *
* terms of the GNU General Public License as published by the Free Soft- *
* ware Foundation; either version 3, or (at your option) any later ver- *
* sion. GNAT is distributed in the hope that it will be useful, but WITH- *
* OUT 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 COPYING3. If not see *
* <http://www.gnu.org/licenses/>. *
* *
* GNAT was originally developed by the GNAT team at New York University. *
* Extensive contributions were provided by Ada Core Technologies Inc. *
* *
****************************************************************************/
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tm.h"
#include "tree.h"
#include "flags.h"
#include "toplev.h"
#include "diagnostic-core.h"
#include "output.h"
#include "ggc.h"
#include "debug.h"
#include "convert.h"
#include "target.h"
#include "common/common-target.h"
#include "langhooks.h"
#include "cgraph.h"
#include "diagnostic.h"
#include "tree-dump.h"
#include "tree-inline.h"
#include "tree-iterator.h"
#include "ada.h"
#include "types.h"
#include "atree.h"
#include "elists.h"
#include "namet.h"
#include "nlists.h"
#include "stringt.h"
#include "uintp.h"
#include "fe.h"
#include "sinfo.h"
#include "einfo.h"
#include "ada-tree.h"
#include "gigi.h"
/* If nonzero, pretend we are allocating at global level. */
int force_global;
/* The default alignment of "double" floating-point types, i.e. floating
point types whose size is equal to 64 bits, or 0 if this alignment is
not specifically capped. */
int double_float_alignment;
/* The default alignment of "double" or larger scalar types, i.e. scalar
types whose size is greater or equal to 64 bits, or 0 if this alignment
is not specifically capped. */
int double_scalar_alignment;
/* Tree nodes for the various types and decls we create. */
tree gnat_std_decls[(int) ADT_LAST];
/* Functions to call for each of the possible raise reasons. */
tree gnat_raise_decls[(int) LAST_REASON_CODE + 1];
/* Likewise, but with extra info for each of the possible raise reasons. */
tree gnat_raise_decls_ext[(int) LAST_REASON_CODE + 1];
/* Forward declarations for handlers of attributes. */
static tree handle_const_attribute (tree *, tree, tree, int, bool *);
static tree handle_nothrow_attribute (tree *, tree, tree, int, bool *);
static tree handle_pure_attribute (tree *, tree, tree, int, bool *);
static tree handle_novops_attribute (tree *, tree, tree, int, bool *);
static tree handle_nonnull_attribute (tree *, tree, tree, int, bool *);
static tree handle_sentinel_attribute (tree *, tree, tree, int, bool *);
static tree handle_noreturn_attribute (tree *, tree, tree, int, bool *);
static tree handle_leaf_attribute (tree *, tree, tree, int, bool *);
static tree handle_malloc_attribute (tree *, tree, tree, int, bool *);
static tree handle_type_generic_attribute (tree *, tree, tree, int, bool *);
static tree handle_vector_size_attribute (tree *, tree, tree, int, bool *);
static tree handle_vector_type_attribute (tree *, tree, tree, int, bool *);
/* Fake handler for attributes we don't properly support, typically because
they'd require dragging a lot of the common-c front-end circuitry. */
static tree fake_attribute_handler (tree *, tree, tree, int, bool *);
/* Table of machine-independent internal attributes for Ada. We support
this minimal set of attributes to accommodate the needs of builtins. */
const struct attribute_spec gnat_internal_attribute_table[] =
{
/* { name, min_len, max_len, decl_req, type_req, fn_type_req, handler,
affects_type_identity } */
{ "const", 0, 0, true, false, false, handle_const_attribute,
false },
{ "nothrow", 0, 0, true, false, false, handle_nothrow_attribute,
false },
{ "pure", 0, 0, true, false, false, handle_pure_attribute,
false },
{ "no vops", 0, 0, true, false, false, handle_novops_attribute,
false },
{ "nonnull", 0, -1, false, true, true, handle_nonnull_attribute,
false },
{ "sentinel", 0, 1, false, true, true, handle_sentinel_attribute,
false },
{ "noreturn", 0, 0, true, false, false, handle_noreturn_attribute,
false },
{ "leaf", 0, 0, true, false, false, handle_leaf_attribute,
false },
{ "malloc", 0, 0, true, false, false, handle_malloc_attribute,
false },
{ "type generic", 0, 0, false, true, true, handle_type_generic_attribute,
false },
{ "vector_size", 1, 1, false, true, false, handle_vector_size_attribute,
false },
{ "vector_type", 0, 0, false, true, false, handle_vector_type_attribute,
false },
{ "may_alias", 0, 0, false, true, false, NULL, false },
/* ??? format and format_arg are heavy and not supported, which actually
prevents support for stdio builtins, which we however declare as part
of the common builtins.def contents. */
{ "format", 3, 3, false, true, true, fake_attribute_handler, false },
{ "format_arg", 1, 1, false, true, true, fake_attribute_handler, false },
{ NULL, 0, 0, false, false, false, NULL, false }
};
/* Associates a GNAT tree node to a GCC tree node. It is used in
`save_gnu_tree', `get_gnu_tree' and `present_gnu_tree'. See documentation
of `save_gnu_tree' for more info. */
static GTY((length ("max_gnat_nodes"))) tree *associate_gnat_to_gnu;
#define GET_GNU_TREE(GNAT_ENTITY) \
associate_gnat_to_gnu[(GNAT_ENTITY) - First_Node_Id]
#define SET_GNU_TREE(GNAT_ENTITY,VAL) \
associate_gnat_to_gnu[(GNAT_ENTITY) - First_Node_Id] = (VAL)
#define PRESENT_GNU_TREE(GNAT_ENTITY) \
(associate_gnat_to_gnu[(GNAT_ENTITY) - First_Node_Id] != NULL_TREE)
/* Associates a GNAT entity to a GCC tree node used as a dummy, if any. */
static GTY((length ("max_gnat_nodes"))) tree *dummy_node_table;
#define GET_DUMMY_NODE(GNAT_ENTITY) \
dummy_node_table[(GNAT_ENTITY) - First_Node_Id]
#define SET_DUMMY_NODE(GNAT_ENTITY,VAL) \
dummy_node_table[(GNAT_ENTITY) - First_Node_Id] = (VAL)
#define PRESENT_DUMMY_NODE(GNAT_ENTITY) \
(dummy_node_table[(GNAT_ENTITY) - First_Node_Id] != NULL_TREE)
/* This variable keeps a table for types for each precision so that we only
allocate each of them once. Signed and unsigned types are kept separate.
Note that these types are only used when fold-const requests something
special. Perhaps we should NOT share these types; we'll see how it
goes later. */
static GTY(()) tree signed_and_unsigned_types[2 * MAX_BITS_PER_WORD + 1][2];
/* Likewise for float types, but record these by mode. */
static GTY(()) tree float_types[NUM_MACHINE_MODES];
/* For each binding contour we allocate a binding_level structure to indicate
the binding depth. */
struct GTY((chain_next ("%h.chain"))) gnat_binding_level {
/* The binding level containing this one (the enclosing binding level). */
struct gnat_binding_level *chain;
/* The BLOCK node for this level. */
tree block;
/* If nonzero, the setjmp buffer that needs to be updated for any
variable-sized definition within this context. */
tree jmpbuf_decl;
};
/* The binding level currently in effect. */
static GTY(()) struct gnat_binding_level *current_binding_level;
/* A chain of gnat_binding_level structures awaiting reuse. */
static GTY((deletable)) struct gnat_binding_level *free_binding_level;
/* The context to be used for global declarations. */
static GTY(()) tree global_context;
/* An array of global declarations. */
static GTY(()) VEC(tree,gc) *global_decls;
/* An array of builtin function declarations. */
static GTY(()) VEC(tree,gc) *builtin_decls;
/* An array of global renaming pointers. */
static GTY(()) VEC(tree,gc) *global_renaming_pointers;
/* A chain of unused BLOCK nodes. */
static GTY((deletable)) tree free_block_chain;
static int pad_type_hash_marked_p (const void *p);
static hashval_t pad_type_hash_hash (const void *p);
static int pad_type_hash_eq (const void *p1, const void *p2);
/* A hash table of padded types. It is modelled on the generic type
hash table in tree.c, which must thus be used as a reference. */
struct GTY(()) pad_type_hash {
unsigned long hash;
tree type;
};
static GTY ((if_marked ("pad_type_hash_marked_p"),
param_is (struct pad_type_hash)))
htab_t pad_type_hash_table;
static tree merge_sizes (tree, tree, tree, bool, bool);
static tree compute_related_constant (tree, tree);
static tree split_plus (tree, tree *);
static tree float_type_for_precision (int, enum machine_mode);
static tree convert_to_fat_pointer (tree, tree);
static bool potential_alignment_gap (tree, tree, tree);
static void process_attributes (tree, struct attrib *);
/* Initialize data structures of the utils.c module. */
void
init_gnat_utils (void)
{
/* Initialize the association of GNAT nodes to GCC trees. */
associate_gnat_to_gnu = ggc_alloc_cleared_vec_tree (max_gnat_nodes);
/* Initialize the association of GNAT nodes to GCC trees as dummies. */
dummy_node_table = ggc_alloc_cleared_vec_tree (max_gnat_nodes);
/* Initialize the hash table of padded types. */
pad_type_hash_table = htab_create_ggc (512, pad_type_hash_hash,
pad_type_hash_eq, 0);
}
/* Destroy data structures of the utils.c module. */
void
destroy_gnat_utils (void)
{
/* Destroy the association of GNAT nodes to GCC trees. */
ggc_free (associate_gnat_to_gnu);
associate_gnat_to_gnu = NULL;
/* Destroy the association of GNAT nodes to GCC trees as dummies. */
ggc_free (dummy_node_table);
dummy_node_table = NULL;
/* Destroy the hash table of padded types. */
htab_delete (pad_type_hash_table);
pad_type_hash_table = NULL;
/* Invalidate the global renaming pointers. */
invalidate_global_renaming_pointers ();
}
/* GNAT_ENTITY is a GNAT tree node for an entity. Associate GNU_DECL, a GCC
tree node, with GNAT_ENTITY. If GNU_DECL is not a ..._DECL node, abort.
If NO_CHECK is true, the latter check is suppressed.
If GNU_DECL is zero, reset a previous association. */
void
save_gnu_tree (Entity_Id gnat_entity, tree gnu_decl, bool no_check)
{
/* Check that GNAT_ENTITY is not already defined and that it is being set
to something which is a decl. If that is not the case, this usually
means GNAT_ENTITY is defined twice, but occasionally is due to some
Gigi problem. */
gcc_assert (!(gnu_decl
&& (PRESENT_GNU_TREE (gnat_entity)
|| (!no_check && !DECL_P (gnu_decl)))));
SET_GNU_TREE (gnat_entity, gnu_decl);
}
/* GNAT_ENTITY is a GNAT tree node for an entity. Return the GCC tree node
that was associated with it. If there is no such tree node, abort.
In some cases, such as delayed elaboration or expressions that need to
be elaborated only once, GNAT_ENTITY is really not an entity. */
tree
get_gnu_tree (Entity_Id gnat_entity)
{
gcc_assert (PRESENT_GNU_TREE (gnat_entity));
return GET_GNU_TREE (gnat_entity);
}
/* Return nonzero if a GCC tree has been associated with GNAT_ENTITY. */
bool
present_gnu_tree (Entity_Id gnat_entity)
{
return PRESENT_GNU_TREE (gnat_entity);
}
/* Make a dummy type corresponding to GNAT_TYPE. */
tree
make_dummy_type (Entity_Id gnat_type)
{
Entity_Id gnat_underlying = Gigi_Equivalent_Type (gnat_type);
tree gnu_type;
/* If there is an equivalent type, get its underlying type. */
if (Present (gnat_underlying))
gnat_underlying = Gigi_Equivalent_Type (Underlying_Type (gnat_underlying));
/* If there was no equivalent type (can only happen when just annotating
types) or underlying type, go back to the original type. */
if (No (gnat_underlying))
gnat_underlying = gnat_type;
/* If it there already a dummy type, use that one. Else make one. */
if (PRESENT_DUMMY_NODE (gnat_underlying))
return GET_DUMMY_NODE (gnat_underlying);
/* If this is a record, make a RECORD_TYPE or UNION_TYPE; else make
an ENUMERAL_TYPE. */
gnu_type = make_node (Is_Record_Type (gnat_underlying)
? tree_code_for_record_type (gnat_underlying)
: ENUMERAL_TYPE);
TYPE_NAME (gnu_type) = get_entity_name (gnat_type);
TYPE_DUMMY_P (gnu_type) = 1;
TYPE_STUB_DECL (gnu_type)
= create_type_stub_decl (TYPE_NAME (gnu_type), gnu_type);
if (Is_By_Reference_Type (gnat_underlying))
TYPE_BY_REFERENCE_P (gnu_type) = 1;
SET_DUMMY_NODE (gnat_underlying, gnu_type);
return gnu_type;
}
/* Return the dummy type that was made for GNAT_TYPE, if any. */
tree
get_dummy_type (Entity_Id gnat_type)
{
return GET_DUMMY_NODE (gnat_type);
}
/* Build dummy fat and thin pointer types whose designated type is specified
by GNAT_DESIG_TYPE/GNU_DESIG_TYPE and attach them to the latter. */
void
build_dummy_unc_pointer_types (Entity_Id gnat_desig_type, tree gnu_desig_type)
{
tree gnu_template_type, gnu_ptr_template, gnu_array_type, gnu_ptr_array;
tree gnu_fat_type, fields, gnu_object_type;
gnu_template_type = make_node (RECORD_TYPE);
TYPE_NAME (gnu_template_type) = create_concat_name (gnat_desig_type, "XUB");
TYPE_DUMMY_P (gnu_template_type) = 1;
gnu_ptr_template = build_pointer_type (gnu_template_type);
gnu_array_type = make_node (ENUMERAL_TYPE);
TYPE_NAME (gnu_array_type) = create_concat_name (gnat_desig_type, "XUA");
TYPE_DUMMY_P (gnu_array_type) = 1;
gnu_ptr_array = build_pointer_type (gnu_array_type);
gnu_fat_type = make_node (RECORD_TYPE);
/* Build a stub DECL to trigger the special processing for fat pointer types
in gnat_pushdecl. */
TYPE_NAME (gnu_fat_type)
= create_type_stub_decl (create_concat_name (gnat_desig_type, "XUP"),
gnu_fat_type);
fields = create_field_decl (get_identifier ("P_ARRAY"), gnu_ptr_array,
gnu_fat_type, NULL_TREE, NULL_TREE, 0, 0);
DECL_CHAIN (fields)
= create_field_decl (get_identifier ("P_BOUNDS"), gnu_ptr_template,
gnu_fat_type, NULL_TREE, NULL_TREE, 0, 0);
finish_fat_pointer_type (gnu_fat_type, fields);
SET_TYPE_UNCONSTRAINED_ARRAY (gnu_fat_type, gnu_desig_type);
/* Suppress debug info until after the type is completed. */
TYPE_DECL_SUPPRESS_DEBUG (TYPE_STUB_DECL (gnu_fat_type)) = 1;
gnu_object_type = make_node (RECORD_TYPE);
TYPE_NAME (gnu_object_type) = create_concat_name (gnat_desig_type, "XUT");
TYPE_DUMMY_P (gnu_object_type) = 1;
TYPE_POINTER_TO (gnu_desig_type) = gnu_fat_type;
TYPE_OBJECT_RECORD_TYPE (gnu_desig_type) = gnu_object_type;
}
/* Return true if we are in the global binding level. */
bool
global_bindings_p (void)
{
return force_global || current_function_decl == NULL_TREE;
}
/* Enter a new binding level. */
void
gnat_pushlevel (void)
{
struct gnat_binding_level *newlevel = NULL;
/* Reuse a struct for this binding level, if there is one. */
if (free_binding_level)
{
newlevel = free_binding_level;
free_binding_level = free_binding_level->chain;
}
else
newlevel = ggc_alloc_gnat_binding_level ();
/* Use a free BLOCK, if any; otherwise, allocate one. */
if (free_block_chain)
{
newlevel->block = free_block_chain;
free_block_chain = BLOCK_CHAIN (free_block_chain);
BLOCK_CHAIN (newlevel->block) = NULL_TREE;
}
else
newlevel->block = make_node (BLOCK);
/* Point the BLOCK we just made to its parent. */
if (current_binding_level)
BLOCK_SUPERCONTEXT (newlevel->block) = current_binding_level->block;
BLOCK_VARS (newlevel->block) = NULL_TREE;
BLOCK_SUBBLOCKS (newlevel->block) = NULL_TREE;
TREE_USED (newlevel->block) = 1;
/* Add this level to the front of the chain (stack) of active levels. */
newlevel->chain = current_binding_level;
newlevel->jmpbuf_decl = NULL_TREE;
current_binding_level = newlevel;
}
/* Set SUPERCONTEXT of the BLOCK for the current binding level to FNDECL
and point FNDECL to this BLOCK. */
void
set_current_block_context (tree fndecl)
{
BLOCK_SUPERCONTEXT (current_binding_level->block) = fndecl;
DECL_INITIAL (fndecl) = current_binding_level->block;
set_block_for_group (current_binding_level->block);
}
/* Set the jmpbuf_decl for the current binding level to DECL. */
void
set_block_jmpbuf_decl (tree decl)
{
current_binding_level->jmpbuf_decl = decl;
}
/* Get the jmpbuf_decl, if any, for the current binding level. */
tree
get_block_jmpbuf_decl (void)
{
return current_binding_level->jmpbuf_decl;
}
/* Exit a binding level. Set any BLOCK into the current code group. */
void
gnat_poplevel (void)
{
struct gnat_binding_level *level = current_binding_level;
tree block = level->block;
BLOCK_VARS (block) = nreverse (BLOCK_VARS (block));
BLOCK_SUBBLOCKS (block) = blocks_nreverse (BLOCK_SUBBLOCKS (block));
/* If this is a function-level BLOCK don't do anything. Otherwise, if there
are no variables free the block and merge its subblocks into those of its
parent block. Otherwise, add it to the list of its parent. */
if (TREE_CODE (BLOCK_SUPERCONTEXT (block)) == FUNCTION_DECL)
;
else if (BLOCK_VARS (block) == NULL_TREE)
{
BLOCK_SUBBLOCKS (level->chain->block)
= block_chainon (BLOCK_SUBBLOCKS (block),
BLOCK_SUBBLOCKS (level->chain->block));
BLOCK_CHAIN (block) = free_block_chain;
free_block_chain = block;
}
else
{
BLOCK_CHAIN (block) = BLOCK_SUBBLOCKS (level->chain->block);
BLOCK_SUBBLOCKS (level->chain->block) = block;
TREE_USED (block) = 1;
set_block_for_group (block);
}
/* Free this binding structure. */
current_binding_level = level->chain;
level->chain = free_binding_level;
free_binding_level = level;
}
/* Exit a binding level and discard the associated BLOCK. */
void
gnat_zaplevel (void)
{
struct gnat_binding_level *level = current_binding_level;
tree block = level->block;
BLOCK_CHAIN (block) = free_block_chain;
free_block_chain = block;
/* Free this binding structure. */
current_binding_level = level->chain;
level->chain = free_binding_level;
free_binding_level = level;
}
/* Record DECL as belonging to the current lexical scope and use GNAT_NODE
for location information and flag propagation. */
void
gnat_pushdecl (tree decl, Node_Id gnat_node)
{
/* If DECL is public external or at top level, it has global context. */
if ((TREE_PUBLIC (decl) && DECL_EXTERNAL (decl)) || global_bindings_p ())
{
if (!global_context)
global_context = build_translation_unit_decl (NULL_TREE);
DECL_CONTEXT (decl) = global_context;
}
else
{
DECL_CONTEXT (decl) = current_function_decl;
/* Functions imported in another function are not really nested.
For really nested functions mark them initially as needing
a static chain for uses of that flag before unnesting;
lower_nested_functions will then recompute it. */
if (TREE_CODE (decl) == FUNCTION_DECL && !TREE_PUBLIC (decl))
DECL_STATIC_CHAIN (decl) = 1;
}
TREE_NO_WARNING (decl) = (No (gnat_node) || Warnings_Off (gnat_node));
/* Set the location of DECL and emit a declaration for it. */
if (Present (gnat_node))
Sloc_to_locus (Sloc (gnat_node), &DECL_SOURCE_LOCATION (decl));
add_decl_expr (decl, gnat_node);
/* Put the declaration on the list. The list of declarations is in reverse
order. The list will be reversed later. Put global declarations in the
globals list and local ones in the current block. But skip TYPE_DECLs
for UNCONSTRAINED_ARRAY_TYPE in both cases, as they will cause trouble
with the debugger and aren't needed anyway. */
if (!(TREE_CODE (decl) == TYPE_DECL
&& TREE_CODE (TREE_TYPE (decl)) == UNCONSTRAINED_ARRAY_TYPE))
{
if (DECL_EXTERNAL (decl))
{
if (TREE_CODE (decl) == FUNCTION_DECL && DECL_BUILT_IN (decl))
VEC_safe_push (tree, gc, builtin_decls, decl);
}
else if (global_bindings_p ())
VEC_safe_push (tree, gc, global_decls, decl);
else
{
DECL_CHAIN (decl) = BLOCK_VARS (current_binding_level->block);
BLOCK_VARS (current_binding_level->block) = decl;
}
}
/* For the declaration of a type, set its name if it either is not already
set or if the previous type name was not derived from a source name.
We'd rather have the type named with a real name and all the pointer
types to the same object have the same POINTER_TYPE node. Code in the
equivalent function of c-decl.c makes a copy of the type node here, but
that may cause us trouble with incomplete types. We make an exception
for fat pointer types because the compiler automatically builds them
for unconstrained array types and the debugger uses them to represent
both these and pointers to these. */
if (TREE_CODE (decl) == TYPE_DECL && DECL_NAME (decl))
{
tree t = TREE_TYPE (decl);
if (!(TYPE_NAME (t) && TREE_CODE (TYPE_NAME (t)) == TYPE_DECL))
{
/* Array and pointer types aren't "tagged" types so we force the
type to be associated with its typedef in the DWARF back-end,
in order to make sure that the latter is always preserved. */
if (!DECL_ARTIFICIAL (decl)
&& (TREE_CODE (t) == ARRAY_TYPE
|| TREE_CODE (t) == POINTER_TYPE))
{
tree tt = build_distinct_type_copy (t);
if (TREE_CODE (t) == POINTER_TYPE)
TYPE_NEXT_PTR_TO (t) = tt;
TYPE_NAME (tt) = DECL_NAME (decl);
TYPE_STUB_DECL (tt) = TYPE_STUB_DECL (t);
DECL_ORIGINAL_TYPE (decl) = tt;
}
}
else if (TYPE_IS_FAT_POINTER_P (t))
{
/* We need a variant for the placeholder machinery to work. */
tree tt = build_variant_type_copy (t);
TYPE_NAME (tt) = decl;
TREE_USED (tt) = TREE_USED (t);
TREE_TYPE (decl) = tt;
if (DECL_ORIGINAL_TYPE (TYPE_NAME (t)))
DECL_ORIGINAL_TYPE (decl) = DECL_ORIGINAL_TYPE (TYPE_NAME (t));
else
DECL_ORIGINAL_TYPE (decl) = t;
DECL_ARTIFICIAL (decl) = 0;
t = NULL_TREE;
}
else if (DECL_ARTIFICIAL (TYPE_NAME (t)) && !DECL_ARTIFICIAL (decl))
;
else
t = NULL_TREE;
/* Propagate the name to all the anonymous variants. This is needed
for the type qualifiers machinery to work properly. */
if (t)
for (t = TYPE_MAIN_VARIANT (t); t; t = TYPE_NEXT_VARIANT (t))
if (!(TYPE_NAME (t) && TREE_CODE (TYPE_NAME (t)) == TYPE_DECL))
TYPE_NAME (t) = decl;
}
}
/* Create a record type that contains a SIZE bytes long field of TYPE with a
starting bit position so that it is aligned to ALIGN bits, and leaving at
least ROOM bytes free before the field. BASE_ALIGN is the alignment the
record is guaranteed to get. */
tree
make_aligning_type (tree type, unsigned int align, tree size,
unsigned int base_align, int room)
{
/* We will be crafting a record type with one field at a position set to be
the next multiple of ALIGN past record'address + room bytes. We use a
record placeholder to express record'address. */
tree record_type = make_node (RECORD_TYPE);
tree record = build0 (PLACEHOLDER_EXPR, record_type);
tree record_addr_st
= convert (sizetype, build_unary_op (ADDR_EXPR, NULL_TREE, record));
/* The diagram below summarizes the shape of what we manipulate:
<--------- pos ---------->
{ +------------+-------------+-----------------+
record =>{ |############| ... | field (type) |
{ +------------+-------------+-----------------+
|<-- room -->|<- voffset ->|<---- size ----->|
o o
| |
record_addr vblock_addr
Every length is in sizetype bytes there, except "pos" which has to be
set as a bit position in the GCC tree for the record. */
tree room_st = size_int (room);
tree vblock_addr_st = size_binop (PLUS_EXPR, record_addr_st, room_st);
tree voffset_st, pos, field;
tree name = TYPE_NAME (type);
if (TREE_CODE (name) == TYPE_DECL)
name = DECL_NAME (name);
name = concat_name (name, "ALIGN");
TYPE_NAME (record_type) = name;
/* Compute VOFFSET and then POS. The next byte position multiple of some
alignment after some address is obtained by "and"ing the alignment minus
1 with the two's complement of the address. */
voffset_st = size_binop (BIT_AND_EXPR,
fold_build1 (NEGATE_EXPR, sizetype, vblock_addr_st),
size_int ((align / BITS_PER_UNIT) - 1));
/* POS = (ROOM + VOFFSET) * BIT_PER_UNIT, in bitsizetype. */
pos = size_binop (MULT_EXPR,
convert (bitsizetype,
size_binop (PLUS_EXPR, room_st, voffset_st)),
bitsize_unit_node);
/* Craft the GCC record representation. We exceptionally do everything
manually here because 1) our generic circuitry is not quite ready to
handle the complex position/size expressions we are setting up, 2) we
have a strong simplifying factor at hand: we know the maximum possible
value of voffset, and 3) we have to set/reset at least the sizes in
accordance with this maximum value anyway, as we need them to convey
what should be "alloc"ated for this type.
Use -1 as the 'addressable' indication for the field to prevent the
creation of a bitfield. We don't need one, it would have damaging
consequences on the alignment computation, and create_field_decl would
make one without this special argument, for instance because of the
complex position expression. */
field = create_field_decl (get_identifier ("F"), type, record_type, size,
pos, 1, -1);
TYPE_FIELDS (record_type) = field;
TYPE_ALIGN (record_type) = base_align;
TYPE_USER_ALIGN (record_type) = 1;
TYPE_SIZE (record_type)
= size_binop (PLUS_EXPR,
size_binop (MULT_EXPR, convert (bitsizetype, size),
bitsize_unit_node),
bitsize_int (align + room * BITS_PER_UNIT));
TYPE_SIZE_UNIT (record_type)
= size_binop (PLUS_EXPR, size,
size_int (room + align / BITS_PER_UNIT));
SET_TYPE_MODE (record_type, BLKmode);
relate_alias_sets (record_type, type, ALIAS_SET_COPY);
/* Declare it now since it will never be declared otherwise. This is
necessary to ensure that its subtrees are properly marked. */
create_type_decl (name, record_type, NULL, true, false, Empty);
return record_type;
}
/* TYPE is a RECORD_TYPE, UNION_TYPE or QUAL_UNION_TYPE that is being used
as the field type of a packed record if IN_RECORD is true, or as the
component type of a packed array if IN_RECORD is false. See if we can
rewrite it either as a type that has a non-BLKmode, which we can pack
tighter in the packed record case, or as a smaller type. If so, return
the new type. If not, return the original type. */
tree
make_packable_type (tree type, bool in_record)
{
unsigned HOST_WIDE_INT size = tree_low_cst (TYPE_SIZE (type), 1);
unsigned HOST_WIDE_INT new_size;
tree new_type, old_field, field_list = NULL_TREE;
unsigned int align;
/* No point in doing anything if the size is zero. */
if (size == 0)
return type;
new_type = make_node (TREE_CODE (type));
/* Copy the name and flags from the old type to that of the new.
Note that we rely on the pointer equality created here for
TYPE_NAME to look through conversions in various places. */
TYPE_NAME (new_type) = TYPE_NAME (type);
TYPE_JUSTIFIED_MODULAR_P (new_type) = TYPE_JUSTIFIED_MODULAR_P (type);
TYPE_CONTAINS_TEMPLATE_P (new_type) = TYPE_CONTAINS_TEMPLATE_P (type);
if (TREE_CODE (type) == RECORD_TYPE)
TYPE_PADDING_P (new_type) = TYPE_PADDING_P (type);
/* If we are in a record and have a small size, set the alignment to
try for an integral mode. Otherwise set it to try for a smaller
type with BLKmode. */
if (in_record && size <= MAX_FIXED_MODE_SIZE)
{
align = ceil_pow2 (size);
TYPE_ALIGN (new_type) = align;
new_size = (size + align - 1) & -align;
}
else
{
unsigned HOST_WIDE_INT align;
/* Do not try to shrink the size if the RM size is not constant. */
if (TYPE_CONTAINS_TEMPLATE_P (type)
|| !host_integerp (TYPE_ADA_SIZE (type), 1))
return type;
/* Round the RM size up to a unit boundary to get the minimal size
for a BLKmode record. Give up if it's already the size. */
new_size = TREE_INT_CST_LOW (TYPE_ADA_SIZE (type));
new_size = (new_size + BITS_PER_UNIT - 1) & -BITS_PER_UNIT;
if (new_size == size)
return type;
align = new_size & -new_size;
TYPE_ALIGN (new_type) = MIN (TYPE_ALIGN (type), align);
}
TYPE_USER_ALIGN (new_type) = 1;
/* Now copy the fields, keeping the position and size as we don't want
to change the layout by propagating the packedness downwards. */
for (old_field = TYPE_FIELDS (type); old_field;
old_field = DECL_CHAIN (old_field))
{
tree new_field_type = TREE_TYPE (old_field);
tree new_field, new_size;
if (RECORD_OR_UNION_TYPE_P (new_field_type)
&& !TYPE_FAT_POINTER_P (new_field_type)
&& host_integerp (TYPE_SIZE (new_field_type), 1))
new_field_type = make_packable_type (new_field_type, true);
/* However, for the last field in a not already packed record type
that is of an aggregate type, we need to use the RM size in the
packable version of the record type, see finish_record_type. */
if (!DECL_CHAIN (old_field)
&& !TYPE_PACKED (type)
&& RECORD_OR_UNION_TYPE_P (new_field_type)
&& !TYPE_FAT_POINTER_P (new_field_type)
&& !TYPE_CONTAINS_TEMPLATE_P (new_field_type)
&& TYPE_ADA_SIZE (new_field_type))
new_size = TYPE_ADA_SIZE (new_field_type);
else
new_size = DECL_SIZE (old_field);
new_field
= create_field_decl (DECL_NAME (old_field), new_field_type, new_type,
new_size, bit_position (old_field),
TYPE_PACKED (type),
!DECL_NONADDRESSABLE_P (old_field));
DECL_INTERNAL_P (new_field) = DECL_INTERNAL_P (old_field);
SET_DECL_ORIGINAL_FIELD_TO_FIELD (new_field, old_field);
if (TREE_CODE (new_type) == QUAL_UNION_TYPE)
DECL_QUALIFIER (new_field) = DECL_QUALIFIER (old_field);
DECL_CHAIN (new_field) = field_list;
field_list = new_field;
}
finish_record_type (new_type, nreverse (field_list), 2, false);
relate_alias_sets (new_type, type, ALIAS_SET_COPY);
SET_DECL_PARALLEL_TYPE (TYPE_STUB_DECL (new_type),
DECL_PARALLEL_TYPE (TYPE_STUB_DECL (type)));
/* If this is a padding record, we never want to make the size smaller
than what was specified. For QUAL_UNION_TYPE, also copy the size. */
if (TYPE_IS_PADDING_P (type) || TREE_CODE (type) == QUAL_UNION_TYPE)
{
TYPE_SIZE (new_type) = TYPE_SIZE (type);
TYPE_SIZE_UNIT (new_type) = TYPE_SIZE_UNIT (type);
new_size = size;
}
else
{
TYPE_SIZE (new_type) = bitsize_int (new_size);
TYPE_SIZE_UNIT (new_type)
= size_int ((new_size + BITS_PER_UNIT - 1) / BITS_PER_UNIT);
}
if (!TYPE_CONTAINS_TEMPLATE_P (type))
SET_TYPE_ADA_SIZE (new_type, TYPE_ADA_SIZE (type));
compute_record_mode (new_type);
/* Try harder to get a packable type if necessary, for example
in case the record itself contains a BLKmode field. */
if (in_record && TYPE_MODE (new_type) == BLKmode)
SET_TYPE_MODE (new_type,
mode_for_size_tree (TYPE_SIZE (new_type), MODE_INT, 1));
/* If neither the mode nor the size has shrunk, return the old type. */
if (TYPE_MODE (new_type) == BLKmode && new_size >= size)
return type;
return new_type;
}
/* Given a type TYPE, return a new type whose size is appropriate for SIZE.
If TYPE is the best type, return it. Otherwise, make a new type. We
only support new integral and pointer types. FOR_BIASED is true if
we are making a biased type. */
tree
make_type_from_size (tree type, tree size_tree, bool for_biased)
{
unsigned HOST_WIDE_INT size;
bool biased_p;
tree new_type;
/* If size indicates an error, just return TYPE to avoid propagating
the error. Likewise if it's too large to represent. */
if (!size_tree || !host_integerp (size_tree, 1))
return type;
size = tree_low_cst (size_tree, 1);
switch (TREE_CODE (type))
{
case INTEGER_TYPE:
case ENUMERAL_TYPE:
case BOOLEAN_TYPE:
biased_p = (TREE_CODE (type) == INTEGER_TYPE
&& TYPE_BIASED_REPRESENTATION_P (type));
/* Integer types with precision 0 are forbidden. */
if (size == 0)
size = 1;
/* Only do something if the type isn't a packed array type and doesn't
already have the proper size and the size isn't too large. */
if (TYPE_IS_PACKED_ARRAY_TYPE_P (type)
|| (TYPE_PRECISION (type) == size && biased_p == for_biased)
|| size > LONG_LONG_TYPE_SIZE)
break;
biased_p |= for_biased;
if (TYPE_UNSIGNED (type) || biased_p)
new_type = make_unsigned_type (size);
else
new_type = make_signed_type (size);
TREE_TYPE (new_type) = TREE_TYPE (type) ? TREE_TYPE (type) : type;
SET_TYPE_RM_MIN_VALUE (new_type,
convert (TREE_TYPE (new_type),
TYPE_MIN_VALUE (type)));
SET_TYPE_RM_MAX_VALUE (new_type,
convert (TREE_TYPE (new_type),
TYPE_MAX_VALUE (type)));
/* Copy the name to show that it's essentially the same type and
not a subrange type. */
TYPE_NAME (new_type) = TYPE_NAME (type);
TYPE_BIASED_REPRESENTATION_P (new_type) = biased_p;
SET_TYPE_RM_SIZE (new_type, bitsize_int (size));
return new_type;
case RECORD_TYPE:
/* Do something if this is a fat pointer, in which case we
may need to return the thin pointer. */
if (TYPE_FAT_POINTER_P (type) && size < POINTER_SIZE * 2)
{
enum machine_mode p_mode = mode_for_size (size, MODE_INT, 0);
if (!targetm.valid_pointer_mode (p_mode))
p_mode = ptr_mode;
return
build_pointer_type_for_mode
(TYPE_OBJECT_RECORD_TYPE (TYPE_UNCONSTRAINED_ARRAY (type)),
p_mode, 0);
}
break;
case POINTER_TYPE:
/* Only do something if this is a thin pointer, in which case we
may need to return the fat pointer. */
if (TYPE_IS_THIN_POINTER_P (type) && size >= POINTER_SIZE * 2)
return
build_pointer_type (TYPE_UNCONSTRAINED_ARRAY (TREE_TYPE (type)));
break;
default:
break;
}
return type;
}
/* See if the data pointed to by the hash table slot is marked. */
static int
pad_type_hash_marked_p (const void *p)
{
const_tree const type = ((const struct pad_type_hash *) p)->type;
return ggc_marked_p (type);
}
/* Return the cached hash value. */
static hashval_t
pad_type_hash_hash (const void *p)
{
return ((const struct pad_type_hash *) p)->hash;
}
/* Return 1 iff the padded types are equivalent. */
static int
pad_type_hash_eq (const void *p1, const void *p2)
{
const struct pad_type_hash *const t1 = (const struct pad_type_hash *) p1;
const struct pad_type_hash *const t2 = (const struct pad_type_hash *) p2;
tree type1, type2;
if (t1->hash != t2->hash)
return 0;
type1 = t1->type;
type2 = t2->type;
/* We consider that the padded types are equivalent if they pad the same
type and have the same size, alignment and RM size. Taking the mode
into account is redundant since it is determined by the others. */
return
TREE_TYPE (TYPE_FIELDS (type1)) == TREE_TYPE (TYPE_FIELDS (type2))
&& TYPE_SIZE (type1) == TYPE_SIZE (type2)
&& TYPE_ALIGN (type1) == TYPE_ALIGN (type2)
&& TYPE_ADA_SIZE (type1) == TYPE_ADA_SIZE (type2);
}
/* Ensure that TYPE has SIZE and ALIGN. Make and return a new padded type
if needed. We have already verified that SIZE and TYPE are large enough.
GNAT_ENTITY is used to name the resulting record and to issue a warning.
IS_COMPONENT_TYPE is true if this is being done for the component type of
an array. IS_USER_TYPE is true if the original type needs to be completed.
DEFINITION is true if this type is being defined. SET_RM_SIZE is true if
the RM size of the resulting type is to be set to SIZE too. */
tree
maybe_pad_type (tree type, tree size, unsigned int align,
Entity_Id gnat_entity, bool is_component_type,
bool is_user_type, bool definition, bool set_rm_size)
{
tree orig_size = TYPE_SIZE (type);
tree record, field;
/* If TYPE is a padded type, see if it agrees with any size and alignment
we were given. If so, return the original type. Otherwise, strip
off the padding, since we will either be returning the inner type
or repadding it. If no size or alignment is specified, use that of
the original padded type. */
if (TYPE_IS_PADDING_P (type))
{
if ((!size
|| operand_equal_p (round_up (size,
MAX (align, TYPE_ALIGN (type))),
round_up (TYPE_SIZE (type),
MAX (align, TYPE_ALIGN (type))),
0))
&& (align == 0 || align == TYPE_ALIGN (type)))
return type;
if (!size)
size = TYPE_SIZE (type);
if (align == 0)
align = TYPE_ALIGN (type);
type = TREE_TYPE (TYPE_FIELDS (type));
orig_size = TYPE_SIZE (type);
}
/* If the size is either not being changed or is being made smaller (which
is not done here and is only valid for bitfields anyway), show the size
isn't changing. Likewise, clear the alignment if it isn't being
changed. Then return if we aren't doing anything. */
if (size
&& (operand_equal_p (size, orig_size, 0)
|| (TREE_CODE (orig_size) == INTEGER_CST
&& tree_int_cst_lt (size, orig_size))))
size = NULL_TREE;
if (align == TYPE_ALIGN (type))
align = 0;
if (align == 0 && !size)
return type;
/* If requested, complete the original type and give it a name. */
if (is_user_type)
create_type_decl (get_entity_name (gnat_entity), type,
NULL, !Comes_From_Source (gnat_entity),
!(TYPE_NAME (type)
&& TREE_CODE (TYPE_NAME (type)) == TYPE_DECL
&& DECL_IGNORED_P (TYPE_NAME (type))),
gnat_entity);
/* We used to modify the record in place in some cases, but that could
generate incorrect debugging information. So make a new record
type and name. */
record = make_node (RECORD_TYPE);
TYPE_PADDING_P (record) = 1;
if (Present (gnat_entity))
TYPE_NAME (record) = create_concat_name (gnat_entity, "PAD");
TYPE_ALIGN (record) = align;
TYPE_SIZE (record) = size ? size : orig_size;
TYPE_SIZE_UNIT (record)
= convert (sizetype,
size_binop (CEIL_DIV_EXPR, TYPE_SIZE (record),
bitsize_unit_node));
/* If we are changing the alignment and the input type is a record with
BLKmode and a small constant size, try to make a form that has an
integral mode. This might allow the padding record to also have an
integral mode, which will be much more efficient. There is no point
in doing so if a size is specified unless it is also a small constant
size and it is incorrect to do so if we cannot guarantee that the mode
will be naturally aligned since the field must always be addressable.
??? This might not always be a win when done for a stand-alone object:
since the nominal and the effective type of the object will now have
different modes, a VIEW_CONVERT_EXPR will be required for converting
between them and it might be hard to overcome afterwards, including
at the RTL level when the stand-alone object is accessed as a whole. */
if (align != 0
&& RECORD_OR_UNION_TYPE_P (type)
&& TYPE_MODE (type) == BLKmode
&& !TYPE_BY_REFERENCE_P (type)
&& TREE_CODE (orig_size) == INTEGER_CST
&& !TREE_OVERFLOW (orig_size)
&& compare_tree_int (orig_size, MAX_FIXED_MODE_SIZE) <= 0
&& (!size
|| (TREE_CODE (size) == INTEGER_CST
&& compare_tree_int (size, MAX_FIXED_MODE_SIZE) <= 0)))
{
tree packable_type = make_packable_type (type, true);
if (TYPE_MODE (packable_type) != BLKmode
&& align >= TYPE_ALIGN (packable_type))
type = packable_type;
}
/* Now create the field with the original size. */
field = create_field_decl (get_identifier ("F"), type, record, orig_size,
bitsize_zero_node, 0, 1);
DECL_INTERNAL_P (field) = 1;
/* Do not emit debug info until after the auxiliary record is built. */
finish_record_type (record, field, 1, false);
/* Set the RM size if requested. */
if (set_rm_size)
{
SET_TYPE_ADA_SIZE (record, size ? size : orig_size);
/* If the padded type is complete and has constant size, we canonicalize
it by means of the hash table. This is consistent with the language
semantics and ensures that gigi and the middle-end have a common view
of these padded types. */
if (TREE_CONSTANT (TYPE_SIZE (record)))
{
hashval_t hashcode;
struct pad_type_hash in, *h;
void **loc;
hashcode = iterative_hash_object (TYPE_HASH (type), 0);
hashcode = iterative_hash_expr (TYPE_SIZE (record), hashcode);
hashcode = iterative_hash_hashval_t (TYPE_ALIGN (record), hashcode);
hashcode = iterative_hash_expr (TYPE_ADA_SIZE (record), hashcode);
in.hash = hashcode;
in.type = record;
h = (struct pad_type_hash *)
htab_find_with_hash (pad_type_hash_table, &in, hashcode);
if (h)
{
record = h->type;
goto built;
}
h = ggc_alloc_pad_type_hash ();
h->hash = hashcode;
h->type = record;
loc = htab_find_slot_with_hash (pad_type_hash_table, h, hashcode,
INSERT);
*loc = (void *)h;
}
}
/* Unless debugging information isn't being written for the input type,
write a record that shows what we are a subtype of and also make a
variable that indicates our size, if still variable. */
if (TREE_CODE (orig_size) != INTEGER_CST
&& TYPE_NAME (record)
&& TYPE_NAME (type)
&& !(TREE_CODE (TYPE_NAME (type)) == TYPE_DECL
&& DECL_IGNORED_P (TYPE_NAME (type))))
{
tree marker = make_node (RECORD_TYPE);
tree name = TYPE_NAME (record);
tree orig_name = TYPE_NAME (type);
if (TREE_CODE (name) == TYPE_DECL)
name = DECL_NAME (name);
if (TREE_CODE (orig_name) == TYPE_DECL)
orig_name = DECL_NAME (orig_name);
TYPE_NAME (marker) = concat_name (name, "XVS");
finish_record_type (marker,
create_field_decl (orig_name,
build_reference_type (type),
marker, NULL_TREE, NULL_TREE,
0, 0),
0, true);
add_parallel_type (record, marker);
if (definition && size && TREE_CODE (size) != INTEGER_CST)
TYPE_SIZE_UNIT (marker)
= create_var_decl (concat_name (name, "XVZ"), NULL_TREE, sizetype,
TYPE_SIZE_UNIT (record), false, false, false,
false, NULL, gnat_entity);
}
rest_of_record_type_compilation (record);
built:
/* If the size was widened explicitly, maybe give a warning. Take the
original size as the maximum size of the input if there was an
unconstrained record involved and round it up to the specified alignment,
if one was specified. But don't do it if we are just annotating types
and the type is tagged, since tagged types aren't fully laid out in this
mode. */
if (!size
|| TREE_CODE (size) == COND_EXPR
|| TREE_CODE (size) == MAX_EXPR
|| No (gnat_entity)
|| (type_annotate_only && Is_Tagged_Type (Etype (gnat_entity))))
return record;
if (CONTAINS_PLACEHOLDER_P (orig_size))
orig_size = max_size (orig_size, true);
if (align)
orig_size = round_up (orig_size, align);
if (!operand_equal_p (size, orig_size, 0)
&& !(TREE_CODE (size) == INTEGER_CST
&& TREE_CODE (orig_size) == INTEGER_CST
&& (TREE_OVERFLOW (size)
|| TREE_OVERFLOW (orig_size)
|| tree_int_cst_lt (size, orig_size))))
{
Node_Id gnat_error_node = Empty;
if (Is_Packed_Array_Type (gnat_entity))
gnat_entity = Original_Array_Type (gnat_entity);
if ((Ekind (gnat_entity) == E_Component
|| Ekind (gnat_entity) == E_Discriminant)
&& Present (Component_Clause (gnat_entity)))
gnat_error_node = Last_Bit (Component_Clause (gnat_entity));
else if (Present (Size_Clause (gnat_entity)))
gnat_error_node = Expression (Size_Clause (gnat_entity));
/* Generate message only for entities that come from source, since
if we have an entity created by expansion, the message will be
generated for some other corresponding source entity. */
if (Comes_From_Source (gnat_entity))
{
if (Present (gnat_error_node))
post_error_ne_tree ("{^ }bits of & unused?",
gnat_error_node, gnat_entity,
size_diffop (size, orig_size));
else if (is_component_type)
post_error_ne_tree ("component of& padded{ by ^ bits}?",
gnat_entity, gnat_entity,
size_diffop (size, orig_size));
}
}
return record;
}
/* Relate the alias sets of GNU_NEW_TYPE and GNU_OLD_TYPE according to OP.
If this is a multi-dimensional array type, do this recursively.
OP may be
- ALIAS_SET_COPY: the new set is made a copy of the old one.
- ALIAS_SET_SUPERSET: the new set is made a superset of the old one.
- ALIAS_SET_SUBSET: the new set is made a subset of the old one. */
void
relate_alias_sets (tree gnu_new_type, tree gnu_old_type, enum alias_set_op op)
{
/* Remove any padding from GNU_OLD_TYPE. It doesn't matter in the case
of a one-dimensional array, since the padding has the same alias set
as the field type, but if it's a multi-dimensional array, we need to
see the inner types. */
while (TREE_CODE (gnu_old_type) == RECORD_TYPE
&& (TYPE_JUSTIFIED_MODULAR_P (gnu_old_type)
|| TYPE_PADDING_P (gnu_old_type)))
gnu_old_type = TREE_TYPE (TYPE_FIELDS (gnu_old_type));
/* Unconstrained array types are deemed incomplete and would thus be given
alias set 0. Retrieve the underlying array type. */
if (TREE_CODE (gnu_old_type) == UNCONSTRAINED_ARRAY_TYPE)
gnu_old_type
= TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (gnu_old_type))));
if (TREE_CODE (gnu_new_type) == UNCONSTRAINED_ARRAY_TYPE)
gnu_new_type
= TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (gnu_new_type))));
if (TREE_CODE (gnu_new_type) == ARRAY_TYPE
&& TREE_CODE (TREE_TYPE (gnu_new_type)) == ARRAY_TYPE
&& TYPE_MULTI_ARRAY_P (TREE_TYPE (gnu_new_type)))
relate_alias_sets (TREE_TYPE (gnu_new_type), TREE_TYPE (gnu_old_type), op);
switch (op)
{
case ALIAS_SET_COPY:
/* The alias set shouldn't be copied between array types with different
aliasing settings because this can break the aliasing relationship
between the array type and its element type. */
#ifndef ENABLE_CHECKING
if (flag_strict_aliasing)
#endif
gcc_assert (!(TREE_CODE (gnu_new_type) == ARRAY_TYPE
&& TREE_CODE (gnu_old_type) == ARRAY_TYPE
&& TYPE_NONALIASED_COMPONENT (gnu_new_type)
!= TYPE_NONALIASED_COMPONENT (gnu_old_type)));
TYPE_ALIAS_SET (gnu_new_type) = get_alias_set (gnu_old_type);
break;
case ALIAS_SET_SUBSET:
case ALIAS_SET_SUPERSET:
{
alias_set_type old_set = get_alias_set (gnu_old_type);
alias_set_type new_set = get_alias_set (gnu_new_type);
/* Do nothing if the alias sets conflict. This ensures that we
never call record_alias_subset several times for the same pair
or at all for alias set 0. */
if (!alias_sets_conflict_p (old_set, new_set))
{
if (op == ALIAS_SET_SUBSET)
record_alias_subset (old_set, new_set);
else
record_alias_subset (new_set, old_set);
}
}
break;
default:
gcc_unreachable ();
}
record_component_aliases (gnu_new_type);
}
/* Record TYPE as a builtin type for Ada. NAME is the name of the type.
ARTIFICIAL_P is true if it's a type that was generated by the compiler. */
void
record_builtin_type (const char *name, tree type, bool artificial_p)
{
tree type_decl = build_decl (input_location,
TYPE_DECL, get_identifier (name), type);
DECL_ARTIFICIAL (type_decl) = artificial_p;
TYPE_ARTIFICIAL (type) = artificial_p;
gnat_pushdecl (type_decl, Empty);
if (debug_hooks->type_decl)
debug_hooks->type_decl (type_decl, false);
}
/* Given a record type RECORD_TYPE and a list of FIELD_DECL nodes FIELD_LIST,
finish constructing the record type as a fat pointer type. */
void
finish_fat_pointer_type (tree record_type, tree field_list)
{
/* Make sure we can put it into a register. */
TYPE_ALIGN (record_type) = MIN (BIGGEST_ALIGNMENT, 2 * POINTER_SIZE);
/* Show what it really is. */
TYPE_FAT_POINTER_P (record_type) = 1;
/* Do not emit debug info for it since the types of its fields may still be
incomplete at this point. */
finish_record_type (record_type, field_list, 0, false);
/* Force type_contains_placeholder_p to return true on it. Although the
PLACEHOLDER_EXPRs are referenced only indirectly, this isn't a pointer
type but the representation of the unconstrained array. */
TYPE_CONTAINS_PLACEHOLDER_INTERNAL (record_type) = 2;
}
/* Given a record type RECORD_TYPE and a list of FIELD_DECL nodes FIELD_LIST,
finish constructing the record or union type. If REP_LEVEL is zero, this
record has no representation clause and so will be entirely laid out here.
If REP_LEVEL is one, this record has a representation clause and has been
laid out already; only set the sizes and alignment. If REP_LEVEL is two,
this record is derived from a parent record and thus inherits its layout;
only make a pass on the fields to finalize them. DEBUG_INFO_P is true if
we need to write debug information about this type. */
void
finish_record_type (tree record_type, tree field_list, int rep_level,
bool debug_info_p)
{
enum tree_code code = TREE_CODE (record_type);
tree name = TYPE_NAME (record_type);
tree ada_size = bitsize_zero_node;
tree size = bitsize_zero_node;
bool had_size = TYPE_SIZE (record_type) != 0;
bool had_size_unit = TYPE_SIZE_UNIT (record_type) != 0;
bool had_align = TYPE_ALIGN (record_type) != 0;
tree field;
TYPE_FIELDS (record_type) = field_list;
/* Always attach the TYPE_STUB_DECL for a record type. It is required to
generate debug info and have a parallel type. */
if (name && TREE_CODE (name) == TYPE_DECL)
name = DECL_NAME (name);
TYPE_STUB_DECL (record_type) = create_type_stub_decl (name, record_type);
/* Globally initialize the record first. If this is a rep'ed record,
that just means some initializations; otherwise, layout the record. */
if (rep_level > 0)
{
TYPE_ALIGN (record_type) = MAX (BITS_PER_UNIT, TYPE_ALIGN (record_type));
if (!had_size_unit)
TYPE_SIZE_UNIT (record_type) = size_zero_node;
if (!had_size)
TYPE_SIZE (record_type) = bitsize_zero_node;
/* For all-repped records with a size specified, lay the QUAL_UNION_TYPE
out just like a UNION_TYPE, since the size will be fixed. */
else if (code == QUAL_UNION_TYPE)
code = UNION_TYPE;
}
else
{
/* Ensure there isn't a size already set. There can be in an error
case where there is a rep clause but all fields have errors and
no longer have a position. */
TYPE_SIZE (record_type) = 0;
/* Ensure we use the traditional GCC layout for bitfields when we need
to pack the record type or have a representation clause. The other
possible layout (Microsoft C compiler), if available, would prevent
efficient packing in almost all cases. */
#ifdef TARGET_MS_BITFIELD_LAYOUT
if (TARGET_MS_BITFIELD_LAYOUT && TYPE_PACKED (record_type))
decl_attributes (&record_type,
tree_cons (get_identifier ("gcc_struct"),
NULL_TREE, NULL_TREE),
ATTR_FLAG_TYPE_IN_PLACE);
#endif
layout_type (record_type);
}
/* At this point, the position and size of each field is known. It was
either set before entry by a rep clause, or by laying out the type above.
We now run a pass over the fields (in reverse order for QUAL_UNION_TYPEs)
to compute the Ada size; the GCC size and alignment (for rep'ed records
that are not padding types); and the mode (for rep'ed records). We also
clear the DECL_BIT_FIELD indication for the cases we know have not been
handled yet, and adjust DECL_NONADDRESSABLE_P accordingly. */
if (code == QUAL_UNION_TYPE)
field_list = nreverse (field_list);
for (field = field_list; field; field = DECL_CHAIN (field))
{
tree type = TREE_TYPE (field);
tree pos = bit_position (field);
tree this_size = DECL_SIZE (field);
tree this_ada_size;
if (RECORD_OR_UNION_TYPE_P (type)
&& !TYPE_FAT_POINTER_P (type)
&& !TYPE_CONTAINS_TEMPLATE_P (type)
&& TYPE_ADA_SIZE (type))
this_ada_size = TYPE_ADA_SIZE (type);
else
this_ada_size = this_size;
/* Clear DECL_BIT_FIELD for the cases layout_decl does not handle. */
if (DECL_BIT_FIELD (field)
&& operand_equal_p (this_size, TYPE_SIZE (type), 0))
{
unsigned int align = TYPE_ALIGN (type);
/* In the general case, type alignment is required. */
if (value_factor_p (pos, align))
{
/* The enclosing record type must be sufficiently aligned.
Otherwise, if no alignment was specified for it and it
has been laid out already, bump its alignment to the
desired one if this is compatible with its size. */
if (TYPE_ALIGN (record_type) >= align)
{
DECL_ALIGN (field) = MAX (DECL_ALIGN (field), align);
DECL_BIT_FIELD (field) = 0;
}
else if (!had_align
&& rep_level == 0
&& value_factor_p (TYPE_SIZE (record_type), align))
{
TYPE_ALIGN (record_type) = align;
DECL_ALIGN (field) = MAX (DECL_ALIGN (field), align);
DECL_BIT_FIELD (field) = 0;
}
}
/* In the non-strict alignment case, only byte alignment is. */
if (!STRICT_ALIGNMENT
&& DECL_BIT_FIELD (field)
&& value_factor_p (pos, BITS_PER_UNIT))
DECL_BIT_FIELD (field) = 0;
}
/* If we still have DECL_BIT_FIELD set at this point, we know that the
field is technically not addressable. Except that it can actually
be addressed if it is BLKmode and happens to be properly aligned. */
if (DECL_BIT_FIELD (field)
&& !(DECL_MODE (field) == BLKmode
&& value_factor_p (pos, BITS_PER_UNIT)))
DECL_NONADDRESSABLE_P (field) = 1;
/* A type must be as aligned as its most aligned field that is not
a bit-field. But this is already enforced by layout_type. */
if (rep_level > 0 && !DECL_BIT_FIELD (field))
TYPE_ALIGN (record_type)
= MAX (TYPE_ALIGN (record_type), DECL_ALIGN (field));
switch (code)
{
case UNION_TYPE:
ada_size = size_binop (MAX_EXPR, ada_size, this_ada_size);
size = size_binop (MAX_EXPR, size, this_size);
break;
case QUAL_UNION_TYPE:
ada_size
= fold_build3 (COND_EXPR, bitsizetype, DECL_QUALIFIER (field),
this_ada_size, ada_size);
size = fold_build3 (COND_EXPR, bitsizetype, DECL_QUALIFIER (field),
this_size, size);
break;
case RECORD_TYPE:
/* Since we know here that all fields are sorted in order of
increasing bit position, the size of the record is one
higher than the ending bit of the last field processed
unless we have a rep clause, since in that case we might
have a field outside a QUAL_UNION_TYPE that has a higher ending
position. So use a MAX in that case. Also, if this field is a
QUAL_UNION_TYPE, we need to take into account the previous size in
the case of empty variants. */
ada_size
= merge_sizes (ada_size, pos, this_ada_size,
TREE_CODE (type) == QUAL_UNION_TYPE, rep_level > 0);
size
= merge_sizes (size, pos, this_size,
TREE_CODE (type) == QUAL_UNION_TYPE, rep_level > 0);
break;
default:
gcc_unreachable ();
}
}
if (code == QUAL_UNION_TYPE)
nreverse (field_list);
if (rep_level < 2)
{
/* If this is a padding record, we never want to make the size smaller
than what was specified in it, if any. */
if (TYPE_IS_PADDING_P (record_type) && TYPE_SIZE (record_type))
size = TYPE_SIZE (record_type);
/* Now set any of the values we've just computed that apply. */
if (!TYPE_FAT_POINTER_P (record_type)
&& !TYPE_CONTAINS_TEMPLATE_P (record_type))
SET_TYPE_ADA_SIZE (record_type, ada_size);
if (rep_level > 0)
{
tree size_unit = had_size_unit
? TYPE_SIZE_UNIT (record_type)
: convert (sizetype,
size_binop (CEIL_DIV_EXPR, size,
bitsize_unit_node));
unsigned int align = TYPE_ALIGN (record_type);
TYPE_SIZE (record_type) = variable_size (round_up (size, align));
TYPE_SIZE_UNIT (record_type)
= variable_size (round_up (size_unit, align / BITS_PER_UNIT));
compute_record_mode (record_type);
}
}
if (debug_info_p)
rest_of_record_type_compilation (record_type);
}
/* Append PARALLEL_TYPE on the chain of parallel types of TYPE. */
void
add_parallel_type (tree type, tree parallel_type)
{
tree decl = TYPE_STUB_DECL (type);
while (DECL_PARALLEL_TYPE (decl))
decl = TYPE_STUB_DECL (DECL_PARALLEL_TYPE (decl));
SET_DECL_PARALLEL_TYPE (decl, parallel_type);
}
/* Return true if TYPE has a parallel type. */
static bool
has_parallel_type (tree type)
{
tree decl = TYPE_STUB_DECL (type);
return DECL_PARALLEL_TYPE (decl) != NULL_TREE;
}
/* Wrap up compilation of RECORD_TYPE, i.e. output all the debug information
associated with it. It need not be invoked directly in most cases since
finish_record_type takes care of doing so, but this can be necessary if
a parallel type is to be attached to the record type. */
void
rest_of_record_type_compilation (tree record_type)
{
bool var_size = false;
tree field;
/* If this is a padded type, the bulk of the debug info has already been
generated for the field's type. */
if (TYPE_IS_PADDING_P (record_type))
return;
/* If the type already has a parallel type (XVS type), then we're done. */
if (has_parallel_type (record_type))
return;
for (field = TYPE_FIELDS (record_type); field; field = DECL_CHAIN (field))
{
/* We need to make an XVE/XVU record if any field has variable size,
whether or not the record does. For example, if we have a union,
it may be that all fields, rounded up to the alignment, have the
same size, in which case we'll use that size. But the debug
output routines (except Dwarf2) won't be able to output the fields,
so we need to make the special record. */
if (TREE_CODE (DECL_SIZE (field)) != INTEGER_CST
/* If a field has a non-constant qualifier, the record will have
variable size too. */
|| (TREE_CODE (record_type) == QUAL_UNION_TYPE
&& TREE_CODE (DECL_QUALIFIER (field)) != INTEGER_CST))
{
var_size = true;
break;
}
}
/* If this record type is of variable size, make a parallel record type that
will tell the debugger how the former is laid out (see exp_dbug.ads). */
if (var_size)
{
tree new_record_type
= make_node (TREE_CODE (record_type) == QUAL_UNION_TYPE
? UNION_TYPE : TREE_CODE (record_type));
tree orig_name = TYPE_NAME (record_type), new_name;
tree last_pos = bitsize_zero_node;
tree old_field, prev_old_field = NULL_TREE;
if (TREE_CODE (orig_name) == TYPE_DECL)
orig_name = DECL_NAME (orig_name);
new_name
= concat_name (orig_name, TREE_CODE (record_type) == QUAL_UNION_TYPE
? "XVU" : "XVE");
TYPE_NAME (new_record_type) = new_name;
TYPE_ALIGN (new_record_type) = BIGGEST_ALIGNMENT;
TYPE_STUB_DECL (new_record_type)
= create_type_stub_decl (new_name, new_record_type);
DECL_IGNORED_P (TYPE_STUB_DECL (new_record_type))
= DECL_IGNORED_P (TYPE_STUB_DECL (record_type));
TYPE_SIZE (new_record_type) = size_int (TYPE_ALIGN (record_type));
TYPE_SIZE_UNIT (new_record_type)
= size_int (TYPE_ALIGN (record_type) / BITS_PER_UNIT);
/* Now scan all the fields, replacing each field with a new
field corresponding to the new encoding. */
for (old_field = TYPE_FIELDS (record_type); old_field;
old_field = DECL_CHAIN (old_field))
{
tree field_type = TREE_TYPE (old_field);
tree field_name = DECL_NAME (old_field);
tree new_field;
tree curpos = bit_position (old_field);
bool var = false;
unsigned int align = 0;
tree pos;
/* See how the position was modified from the last position.
There are two basic cases we support: a value was added
to the last position or the last position was rounded to
a boundary and they something was added. Check for the
first case first. If not, see if there is any evidence
of rounding. If so, round the last position and try
again.
If this is a union, the position can be taken as zero. */
/* Some computations depend on the shape of the position expression,
so strip conversions to make sure it's exposed. */
curpos = remove_conversions (curpos, true);
if (TREE_CODE (new_record_type) == UNION_TYPE)
pos = bitsize_zero_node, align = 0;
else
pos = compute_related_constant (curpos, last_pos);
if (!pos && TREE_CODE (curpos) == MULT_EXPR
&& host_integerp (TREE_OPERAND (curpos, 1), 1))
{
tree offset = TREE_OPERAND (curpos, 0);
align = tree_low_cst (TREE_OPERAND (curpos, 1), 1);
/* An offset which is a bitwise AND with a negative power of 2
means an alignment corresponding to this power of 2. Note
that, as sizetype is sign-extended but nonetheless unsigned,
we don't directly use tree_int_cst_sgn. */
offset = remove_conversions (offset, true);
if (TREE_CODE (offset) == BIT_AND_EXPR
&& host_integerp (TREE_OPERAND (offset, 1), 0)
&& TREE_INT_CST_HIGH (TREE_OPERAND (offset, 1)) < 0)
{
unsigned int pow
= - tree_low_cst (TREE_OPERAND (offset, 1), 0);
if (exact_log2 (pow) > 0)
align *= pow;
}
pos = compute_related_constant (curpos,
round_up (last_pos, align));
}
else if (!pos && TREE_CODE (curpos) == PLUS_EXPR
&& TREE_CODE (TREE_OPERAND (curpos, 1)) == INTEGER_CST
&& TREE_CODE (TREE_OPERAND (curpos, 0)) == MULT_EXPR
&& host_integerp (TREE_OPERAND
(TREE_OPERAND (curpos, 0), 1),
1))
{
align
= tree_low_cst
(TREE_OPERAND (TREE_OPERAND (curpos, 0), 1), 1);
pos = compute_related_constant (curpos,
round_up (last_pos, align));
}
else if (potential_alignment_gap (prev_old_field, old_field,
pos))
{
align = TYPE_ALIGN (field_type);
pos = compute_related_constant (curpos,
round_up (last_pos, align));
}
/* If we can't compute a position, set it to zero.
??? We really should abort here, but it's too much work
to get this correct for all cases. */
if (!pos)
pos = bitsize_zero_node;
/* See if this type is variable-sized and make a pointer type
and indicate the indirection if so. Beware that the debug
back-end may adjust the position computed above according
to the alignment of the field type, i.e. the pointer type
in this case, if we don't preventively counter that. */
if (TREE_CODE (DECL_SIZE (old_field)) != INTEGER_CST)
{
field_type = build_pointer_type (field_type);
if (align != 0 && TYPE_ALIGN (field_type) > align)
{
field_type = copy_node (field_type);
TYPE_ALIGN (field_type) = align;
}
var = true;
}
/* Make a new field name, if necessary. */
if (var || align != 0)
{
char suffix[16];
if (align != 0)
sprintf (suffix, "XV%c%u", var ? 'L' : 'A',
align / BITS_PER_UNIT);
else
strcpy (suffix, "XVL");
field_name = concat_name (field_name, suffix);
}
new_field
= create_field_decl (field_name, field_type, new_record_type,
DECL_SIZE (old_field), pos, 0, 0);
DECL_CHAIN (new_field) = TYPE_FIELDS (new_record_type);
TYPE_FIELDS (new_record_type) = new_field;
/* If old_field is a QUAL_UNION_TYPE, take its size as being
zero. The only time it's not the last field of the record
is when there are other components at fixed positions after
it (meaning there was a rep clause for every field) and we
want to be able to encode them. */
last_pos = size_binop (PLUS_EXPR, bit_position (old_field),
(TREE_CODE (TREE_TYPE (old_field))
== QUAL_UNION_TYPE)
? bitsize_zero_node
: DECL_SIZE (old_field));
prev_old_field = old_field;
}
TYPE_FIELDS (new_record_type) = nreverse (TYPE_FIELDS (new_record_type));
add_parallel_type (record_type, new_record_type);
}
}
/* Utility function of above to merge LAST_SIZE, the previous size of a record
with FIRST_BIT and SIZE that describe a field. SPECIAL is true if this
represents a QUAL_UNION_TYPE in which case we must look for COND_EXPRs and
replace a value of zero with the old size. If HAS_REP is true, we take the
MAX of the end position of this field with LAST_SIZE. In all other cases,
we use FIRST_BIT plus SIZE. Return an expression for the size. */
static tree
merge_sizes (tree last_size, tree first_bit, tree size, bool special,
bool has_rep)
{
tree type = TREE_TYPE (last_size);
tree new_size;
if (!special || TREE_CODE (size) != COND_EXPR)
{
new_size = size_binop (PLUS_EXPR, first_bit, size);
if (has_rep)
new_size = size_binop (MAX_EXPR, last_size, new_size);
}
else
new_size = fold_build3 (COND_EXPR, type, TREE_OPERAND (size, 0),
integer_zerop (TREE_OPERAND (size, 1))
? last_size : merge_sizes (last_size, first_bit,
TREE_OPERAND (size, 1),
1, has_rep),
integer_zerop (TREE_OPERAND (size, 2))
? last_size : merge_sizes (last_size, first_bit,
TREE_OPERAND (size, 2),
1, has_rep));
/* We don't need any NON_VALUE_EXPRs and they can confuse us (especially
when fed through substitute_in_expr) into thinking that a constant
size is not constant. */
while (TREE_CODE (new_size) == NON_LVALUE_EXPR)
new_size = TREE_OPERAND (new_size, 0);
return new_size;
}
/* Utility function of above to see if OP0 and OP1, both of SIZETYPE, are
related by the addition of a constant. Return that constant if so. */
static tree
compute_related_constant (tree op0, tree op1)
{
tree op0_var, op1_var;
tree op0_con = split_plus (op0, &op0_var);
tree op1_con = split_plus (op1, &op1_var);
tree result = size_binop (MINUS_EXPR, op0_con, op1_con);
if (operand_equal_p (op0_var, op1_var, 0))
return result;
else if (operand_equal_p (op0, size_binop (PLUS_EXPR, op1_var, result), 0))
return result;
else
return 0;
}
/* Utility function of above to split a tree OP which may be a sum, into a
constant part, which is returned, and a variable part, which is stored
in *PVAR. *PVAR may be bitsize_zero_node. All operations must be of
bitsizetype. */
static tree
split_plus (tree in, tree *pvar)
{
/* Strip conversions in order to ease the tree traversal and maximize the
potential for constant or plus/minus discovery. We need to be careful
to always return and set *pvar to bitsizetype trees, but it's worth
the effort. */
in = remove_conversions (in, false);
*pvar = convert (bitsizetype, in);
if (TREE_CODE (in) == INTEGER_CST)
{
*pvar = bitsize_zero_node;
return convert (bitsizetype, in);
}
else if (TREE_CODE (in) == PLUS_EXPR || TREE_CODE (in) == MINUS_EXPR)
{
tree lhs_var, rhs_var;
tree lhs_con = split_plus (TREE_OPERAND (in, 0), &lhs_var);
tree rhs_con = split_plus (TREE_OPERAND (in, 1), &rhs_var);
if (lhs_var == TREE_OPERAND (in, 0)
&& rhs_var == TREE_OPERAND (in, 1))
return bitsize_zero_node;
*pvar = size_binop (TREE_CODE (in), lhs_var, rhs_var);
return size_binop (TREE_CODE (in), lhs_con, rhs_con);
}
else
return bitsize_zero_node;
}
/* Return a FUNCTION_TYPE node. RETURN_TYPE is the type returned by the
subprogram. If it is VOID_TYPE, then we are dealing with a procedure,
otherwise we are dealing with a function. PARAM_DECL_LIST is a list of
PARM_DECL nodes that are the subprogram parameters. CICO_LIST is the
copy-in/copy-out list to be stored into the TYPE_CICO_LIST field.
RETURN_UNCONSTRAINED_P is true if the function returns an unconstrained
object. RETURN_BY_DIRECT_REF_P is true if the function returns by direct
reference. RETURN_BY_INVISI_REF_P is true if the function returns by
invisible reference. */
tree
create_subprog_type (tree return_type, tree param_decl_list, tree cico_list,
bool return_unconstrained_p, bool return_by_direct_ref_p,
bool return_by_invisi_ref_p)
{
/* A list of the data type nodes of the subprogram formal parameters.
This list is generated by traversing the input list of PARM_DECL
nodes. */
VEC(tree,gc) *param_type_list = NULL;
tree t, type;
for (t = param_decl_list; t; t = DECL_CHAIN (t))
VEC_safe_push (tree, gc, param_type_list, TREE_TYPE (t));
type = build_function_type_vec (return_type, param_type_list);
/* TYPE may have been shared since GCC hashes types. If it has a different
CICO_LIST, make a copy. Likewise for the various flags. */
if (!fntype_same_flags_p (type, cico_list, return_unconstrained_p,
return_by_direct_ref_p, return_by_invisi_ref_p))
{
type = copy_type (type);
TYPE_CI_CO_LIST (type) = cico_list;
TYPE_RETURN_UNCONSTRAINED_P (type) = return_unconstrained_p;
TYPE_RETURN_BY_DIRECT_REF_P (type) = return_by_direct_ref_p;
TREE_ADDRESSABLE (type) = return_by_invisi_ref_p;
}
return type;
}
/* Return a copy of TYPE but safe to modify in any way. */
tree
copy_type (tree type)
{
tree new_type = copy_node (type);
/* Unshare the language-specific data. */
if (TYPE_LANG_SPECIFIC (type))
{
TYPE_LANG_SPECIFIC (new_type) = NULL;
SET_TYPE_LANG_SPECIFIC (new_type, GET_TYPE_LANG_SPECIFIC (type));
}
/* And the contents of the language-specific slot if needed. */
if ((INTEGRAL_TYPE_P (type) || TREE_CODE (type) == REAL_TYPE)
&& TYPE_RM_VALUES (type))
{
TYPE_RM_VALUES (new_type) = NULL_TREE;
SET_TYPE_RM_SIZE (new_type, TYPE_RM_SIZE (type));
SET_TYPE_RM_MIN_VALUE (new_type, TYPE_RM_MIN_VALUE (type));
SET_TYPE_RM_MAX_VALUE (new_type, TYPE_RM_MAX_VALUE (type));
}
/* copy_node clears this field instead of copying it, because it is
aliased with TREE_CHAIN. */
TYPE_STUB_DECL (new_type) = TYPE_STUB_DECL (type);
TYPE_POINTER_TO (new_type) = 0;
TYPE_REFERENCE_TO (new_type) = 0;
TYPE_MAIN_VARIANT (new_type) = new_type;
TYPE_NEXT_VARIANT (new_type) = 0;
return new_type;
}
/* Return a subtype of sizetype with range MIN to MAX and whose
TYPE_INDEX_TYPE is INDEX. GNAT_NODE is used for the position
of the associated TYPE_DECL. */
tree
create_index_type (tree min, tree max, tree index, Node_Id gnat_node)
{
/* First build a type for the desired range. */
tree type = build_nonshared_range_type (sizetype, min, max);
/* Then set the index type. */
SET_TYPE_INDEX_TYPE (type, index);
create_type_decl (NULL_TREE, type, NULL, true, false, gnat_node);
return type;
}
/* Return a subtype of TYPE with range MIN to MAX. If TYPE is NULL,
sizetype is used. */
tree
create_range_type (tree type, tree min, tree max)
{
tree range_type;
if (type == NULL_TREE)
type = sizetype;
/* First build a type with the base range. */
range_type = build_nonshared_range_type (type, TYPE_MIN_VALUE (type),
TYPE_MAX_VALUE (type));
/* Then set the actual range. */
SET_TYPE_RM_MIN_VALUE (range_type, convert (type, min));
SET_TYPE_RM_MAX_VALUE (range_type, convert (type, max));
return range_type;
}
/* Return a TYPE_DECL node suitable for the TYPE_STUB_DECL field of a type.
TYPE_NAME gives the name of the type and TYPE is a ..._TYPE node giving
its data type. */
tree
create_type_stub_decl (tree type_name, tree type)
{
/* Using a named TYPE_DECL ensures that a type name marker is emitted in
STABS while setting DECL_ARTIFICIAL ensures that no DW_TAG_typedef is
emitted in DWARF. */
tree type_decl = build_decl (input_location,
TYPE_DECL, type_name, type);
DECL_ARTIFICIAL (type_decl) = 1;
TYPE_ARTIFICIAL (type) = 1;
return type_decl;
}
/* Return a TYPE_DECL node. TYPE_NAME gives the name of the type and TYPE
is a ..._TYPE node giving its data type. ARTIFICIAL_P is true if this
is a declaration that was generated by the compiler. DEBUG_INFO_P is
true if we need to write debug information about this type. GNAT_NODE
is used for the position of the decl. */
tree
create_type_decl (tree type_name, tree type, struct attrib *attr_list,
bool artificial_p, bool debug_info_p, Node_Id gnat_node)
{
enum tree_code code = TREE_CODE (type);
bool named = TYPE_NAME (type) && TREE_CODE (TYPE_NAME (type)) == TYPE_DECL;
tree type_decl;
/* Only the builtin TYPE_STUB_DECL should be used for dummy types. */
gcc_assert (!TYPE_IS_DUMMY_P (type));
/* If the type hasn't been named yet, we're naming it; preserve an existing
TYPE_STUB_DECL that has been attached to it for some purpose. */
if (!named && TYPE_STUB_DECL (type))
{
type_decl = TYPE_STUB_DECL (type);
DECL_NAME (type_decl) = type_name;
}
else
type_decl = build_decl (input_location,
TYPE_DECL, type_name, type);
DECL_ARTIFICIAL (type_decl) = artificial_p;
TYPE_ARTIFICIAL (type) = artificial_p;
/* Add this decl to the current binding level. */
gnat_pushdecl (type_decl, gnat_node);
process_attributes (type_decl, attr_list);
/* If we're naming the type, equate the TYPE_STUB_DECL to the name.
This causes the name to be also viewed as a "tag" by the debug
back-end, with the advantage that no DW_TAG_typedef is emitted
for artificial "tagged" types in DWARF. */
if (!named)
TYPE_STUB_DECL (type) = type_decl;
/* Do not generate debug info for UNCONSTRAINED_ARRAY_TYPE that the
back-end doesn't support, and for others if we don't need to. */
if (code == UNCONSTRAINED_ARRAY_TYPE || !debug_info_p)
DECL_IGNORED_P (type_decl) = 1;
return type_decl;
}
/* Return a VAR_DECL or CONST_DECL node.
VAR_NAME gives the name of the variable. ASM_NAME is its assembler name
(if provided). TYPE is its data type (a GCC ..._TYPE node). VAR_INIT is
the GCC tree for an optional initial expression; NULL_TREE if none.
CONST_FLAG is true if this variable is constant, in which case we might
return a CONST_DECL node unless CONST_DECL_ALLOWED_P is false.
PUBLIC_FLAG is true if this is for a reference to a public entity or for a
definition to be made visible outside of the current compilation unit, for
instance variable definitions in a package specification.
EXTERN_FLAG is true when processing an external variable declaration (as
opposed to a definition: no storage is to be allocated for the variable).
STATIC_FLAG is only relevant when not at top level. In that case
it indicates whether to always allocate storage to the variable.
GNAT_NODE is used for the position of the decl. */
tree
create_var_decl_1 (tree var_name, tree asm_name, tree type, tree var_init,
bool const_flag, bool public_flag, bool extern_flag,
bool static_flag, bool const_decl_allowed_p,
struct attrib *attr_list, Node_Id gnat_node)
{
/* Whether the initializer is a constant initializer. At the global level
or for an external object or an object to be allocated in static memory,
we check that it is a valid constant expression for use in initializing
a static variable; otherwise, we only check that it is constant. */
bool init_const
= (var_init != 0
&& gnat_types_compatible_p (type, TREE_TYPE (var_init))
&& (global_bindings_p () || extern_flag || static_flag
? initializer_constant_valid_p (var_init, TREE_TYPE (var_init)) != 0
: TREE_CONSTANT (var_init)));
/* Whether we will make TREE_CONSTANT the DECL we produce here, in which
case the initializer may be used in-lieu of the DECL node (as done in
Identifier_to_gnu). This is useful to prevent the need of elaboration
code when an identifier for which such a decl is made is in turn used as
an initializer. We used to rely on CONST vs VAR_DECL for this purpose,
but extra constraints apply to this choice (see below) and are not
relevant to the distinction we wish to make. */
bool constant_p = const_flag && init_const;
/* The actual DECL node. CONST_DECL was initially intended for enumerals
and may be used for scalars in general but not for aggregates. */
tree var_decl
= build_decl (input_location,
(constant_p && const_decl_allowed_p
&& !AGGREGATE_TYPE_P (type)) ? CONST_DECL : VAR_DECL,
var_name, type);
/* If this is external, throw away any initializations (they will be done
elsewhere) unless this is a constant for which we would like to remain
able to get the initializer. If we are defining a global here, leave a
constant initialization and save any variable elaborations for the
elaboration routine. If we are just annotating types, throw away the
initialization if it isn't a constant. */
if ((extern_flag && !constant_p)
|| (type_annotate_only && var_init && !TREE_CONSTANT (var_init)))
var_init = NULL_TREE;
/* At the global level, an initializer requiring code to be generated
produces elaboration statements. Check that such statements are allowed,
that is, not violating a No_Elaboration_Code restriction. */
if (global_bindings_p () && var_init != 0 && !init_const)
Check_Elaboration_Code_Allowed (gnat_node);
DECL_INITIAL (var_decl) = var_init;
TREE_READONLY (var_decl) = const_flag;
DECL_EXTERNAL (var_decl) = extern_flag;
TREE_PUBLIC (var_decl) = public_flag || extern_flag;
TREE_CONSTANT (var_decl) = constant_p;
TREE_THIS_VOLATILE (var_decl) = TREE_SIDE_EFFECTS (var_decl)
= TYPE_VOLATILE (type);
/* Ada doesn't feature Fortran-like COMMON variables so we shouldn't
try to fiddle with DECL_COMMON. However, on platforms that don't
support global BSS sections, uninitialized global variables would
go in DATA instead, thus increasing the size of the executable. */
if (!flag_no_common
&& TREE_CODE (var_decl) == VAR_DECL
&& TREE_PUBLIC (var_decl)
&& !have_global_bss_p ())
DECL_COMMON (var_decl) = 1;
/* At the global binding level, we need to allocate static storage for the
variable if it isn't external. Otherwise, we allocate automatic storage
unless requested not to. */
TREE_STATIC (var_decl)
= !extern_flag && (static_flag || global_bindings_p ());
/* For an external constant whose initializer is not absolute, do not emit
debug info. In DWARF this would mean a global relocation in a read-only
section which runs afoul of the PE-COFF run-time relocation mechanism. */
if (extern_flag
&& constant_p
&& var_init
&& initializer_constant_valid_p (var_init, TREE_TYPE (var_init))
!= null_pointer_node)
DECL_IGNORED_P (var_decl) = 1;
/* Add this decl to the current binding level. */
gnat_pushdecl (var_decl, gnat_node);
if (TREE_SIDE_EFFECTS (var_decl))
TREE_ADDRESSABLE (var_decl) = 1;
if (TREE_CODE (var_decl) == VAR_DECL)
{
if (asm_name)
SET_DECL_ASSEMBLER_NAME (var_decl, asm_name);
process_attributes (var_decl, attr_list);
if (global_bindings_p ())
rest_of_decl_compilation (var_decl, true, 0);
}
return var_decl;
}
/* Return true if TYPE, an aggregate type, contains (or is) an array. */
static bool
aggregate_type_contains_array_p (tree type)
{
switch (TREE_CODE (type))
{
case RECORD_TYPE:
case UNION_TYPE:
case QUAL_UNION_TYPE:
{
tree field;
for (field = TYPE_FIELDS (type); field; field = DECL_CHAIN (field))
if (AGGREGATE_TYPE_P (TREE_TYPE (field))
&& aggregate_type_contains_array_p (TREE_TYPE (field)))
return true;
return false;
}
case ARRAY_TYPE:
return true;
default:
gcc_unreachable ();
}
}
/* Return a FIELD_DECL node. FIELD_NAME is the field's name, FIELD_TYPE is
its type and RECORD_TYPE is the type of the enclosing record. If SIZE is
nonzero, it is the specified size of the field. If POS is nonzero, it is
the bit position. PACKED is 1 if the enclosing record is packed, -1 if it
has Component_Alignment of Storage_Unit. If ADDRESSABLE is nonzero, it
means we are allowed to take the address of the field; if it is negative,
we should not make a bitfield, which is used by make_aligning_type. */
tree
create_field_decl (tree field_name, tree field_type, tree record_type,
tree size, tree pos, int packed, int addressable)
{
tree field_decl = build_decl (input_location,
FIELD_DECL, field_name, field_type);
DECL_CONTEXT (field_decl) = record_type;
TREE_READONLY (field_decl) = TYPE_READONLY (field_type);
/* If FIELD_TYPE is BLKmode, we must ensure this is aligned to at least a
byte boundary since GCC cannot handle less-aligned BLKmode bitfields.
Likewise for an aggregate without specified position that contains an
array, because in this case slices of variable length of this array
must be handled by GCC and variable-sized objects need to be aligned
to at least a byte boundary. */
if (packed && (TYPE_MODE (field_type) == BLKmode
|| (!pos
&& AGGREGATE_TYPE_P (field_type)
&& aggregate_type_contains_array_p (field_type))))
DECL_ALIGN (field_decl) = BITS_PER_UNIT;
/* If a size is specified, use it. Otherwise, if the record type is packed
compute a size to use, which may differ from the object's natural size.
We always set a size in this case to trigger the checks for bitfield
creation below, which is typically required when no position has been
specified. */
if (size)
size = convert (bitsizetype, size);
else if (packed == 1)
{
size = rm_size (field_type);
if (TYPE_MODE (field_type) == BLKmode)
size = round_up (size, BITS_PER_UNIT);
}
/* If we may, according to ADDRESSABLE, make a bitfield if a size is
specified for two reasons: first if the size differs from the natural
size. Second, if the alignment is insufficient. There are a number of
ways the latter can be true.
We never make a bitfield if the type of the field has a nonconstant size,
because no such entity requiring bitfield operations should reach here.
We do *preventively* make a bitfield when there might be the need for it
but we don't have all the necessary information to decide, as is the case
of a field with no specified position in a packed record.
We also don't look at STRICT_ALIGNMENT here, and rely on later processing
in layout_decl or finish_record_type to clear the bit_field indication if
it is in fact not needed. */
if (addressable >= 0
&& size
&& TREE_CODE (size) == INTEGER_CST
&& TREE_CODE (TYPE_SIZE (field_type)) == INTEGER_CST
&& (!tree_int_cst_equal (size, TYPE_SIZE (field_type))
|| (pos && !value_factor_p (pos, TYPE_ALIGN (field_type)))
|| packed
|| (TYPE_ALIGN (record_type) != 0
&& TYPE_ALIGN (record_type) < TYPE_ALIGN (field_type))))
{
DECL_BIT_FIELD (field_decl) = 1;
DECL_SIZE (field_decl) = size;
if (!packed && !pos)
{
if (TYPE_ALIGN (record_type) != 0
&& TYPE_ALIGN (record_type) < TYPE_ALIGN (field_type))
DECL_ALIGN (field_decl) = TYPE_ALIGN (record_type);
else
DECL_ALIGN (field_decl) = TYPE_ALIGN (field_type);
}
}
DECL_PACKED (field_decl) = pos ? DECL_BIT_FIELD (field_decl) : packed;
/* Bump the alignment if need be, either for bitfield/packing purposes or
to satisfy the type requirements if no such consideration applies. When
we get the alignment from the type, indicate if this is from an explicit
user request, which prevents stor-layout from lowering it later on. */
{
unsigned int bit_align
= (DECL_BIT_FIELD (field_decl) ? 1
: packed && TYPE_MODE (field_type) != BLKmode ? BITS_PER_UNIT : 0);
if (bit_align > DECL_ALIGN (field_decl))
DECL_ALIGN (field_decl) = bit_align;
else if (!bit_align && TYPE_ALIGN (field_type) > DECL_ALIGN (field_decl))
{
DECL_ALIGN (field_decl) = TYPE_ALIGN (field_type);
DECL_USER_ALIGN (field_decl) = TYPE_USER_ALIGN (field_type);
}
}
if (pos)
{
/* We need to pass in the alignment the DECL is known to have.
This is the lowest-order bit set in POS, but no more than
the alignment of the record, if one is specified. Note
that an alignment of 0 is taken as infinite. */
unsigned int known_align;
if (host_integerp (pos, 1))
known_align = tree_low_cst (pos, 1) & - tree_low_cst (pos, 1);
else
known_align = BITS_PER_UNIT;
if (TYPE_ALIGN (record_type)
&& (known_align == 0 || known_align > TYPE_ALIGN (record_type)))
known_align = TYPE_ALIGN (record_type);
layout_decl (field_decl, known_align);
SET_DECL_OFFSET_ALIGN (field_decl,
host_integerp (pos, 1) ? BIGGEST_ALIGNMENT
: BITS_PER_UNIT);
pos_from_bit (&DECL_FIELD_OFFSET (field_decl),
&DECL_FIELD_BIT_OFFSET (field_decl),
DECL_OFFSET_ALIGN (field_decl), pos);
}
/* In addition to what our caller says, claim the field is addressable if we
know that its type is not suitable.
The field may also be "technically" nonaddressable, meaning that even if
we attempt to take the field's address we will actually get the address
of a copy. This is the case for true bitfields, but the DECL_BIT_FIELD
value we have at this point is not accurate enough, so we don't account
for this here and let finish_record_type decide. */
if (!addressable && !type_for_nonaliased_component_p (field_type))
addressable = 1;
DECL_NONADDRESSABLE_P (field_decl) = !addressable;
return field_decl;
}
/* Return a PARM_DECL node. PARAM_NAME is the name of the parameter and
PARAM_TYPE is its type. READONLY is true if the parameter is readonly
(either an In parameter or an address of a pass-by-ref parameter). */
tree
create_param_decl (tree param_name, tree param_type, bool readonly)
{
tree param_decl = build_decl (input_location,
PARM_DECL, param_name, param_type);
/* Honor TARGET_PROMOTE_PROTOTYPES like the C compiler, as not doing so
can lead to various ABI violations. */
if (targetm.calls.promote_prototypes (NULL_TREE)
&& INTEGRAL_TYPE_P (param_type)
&& TYPE_PRECISION (param_type) < TYPE_PRECISION (integer_type_node))
{
/* We have to be careful about biased types here. Make a subtype
of integer_type_node with the proper biasing. */
if (TREE_CODE (param_type) == INTEGER_TYPE
&& TYPE_BIASED_REPRESENTATION_P (param_type))
{
tree subtype
= make_unsigned_type (TYPE_PRECISION (integer_type_node));
TREE_TYPE (subtype) = integer_type_node;
TYPE_BIASED_REPRESENTATION_P (subtype) = 1;
SET_TYPE_RM_MIN_VALUE (subtype, TYPE_MIN_VALUE (param_type));
SET_TYPE_RM_MAX_VALUE (subtype, TYPE_MAX_VALUE (param_type));
param_type = subtype;
}
else
param_type = integer_type_node;
}
DECL_ARG_TYPE (param_decl) = param_type;
TREE_READONLY (param_decl) = readonly;
return param_decl;
}
/* Given a DECL and ATTR_LIST, process the listed attributes. */
static void
process_attributes (tree decl, struct attrib *attr_list)
{
for (; attr_list; attr_list = attr_list->next)
switch (attr_list->type)
{
case ATTR_MACHINE_ATTRIBUTE:
input_location = DECL_SOURCE_LOCATION (decl);
decl_attributes (&decl, tree_cons (attr_list->name, attr_list->args,
NULL_TREE),
ATTR_FLAG_TYPE_IN_PLACE);
break;
case ATTR_LINK_ALIAS:
if (! DECL_EXTERNAL (decl))
{
TREE_STATIC (decl) = 1;
assemble_alias (decl, attr_list->name);
}
break;
case ATTR_WEAK_EXTERNAL:
if (SUPPORTS_WEAK)
declare_weak (decl);
else
post_error ("?weak declarations not supported on this target",
attr_list->error_point);
break;
case ATTR_LINK_SECTION:
if (targetm_common.have_named_sections)
{
DECL_SECTION_NAME (decl)
= build_string (IDENTIFIER_LENGTH (attr_list->name),
IDENTIFIER_POINTER (attr_list->name));
DECL_COMMON (decl) = 0;
}
else
post_error ("?section attributes are not supported for this target",
attr_list->error_point);
break;
case ATTR_LINK_CONSTRUCTOR:
DECL_STATIC_CONSTRUCTOR (decl) = 1;
TREE_USED (decl) = 1;
break;
case ATTR_LINK_DESTRUCTOR:
DECL_STATIC_DESTRUCTOR (decl) = 1;
TREE_USED (decl) = 1;
break;
case ATTR_THREAD_LOCAL_STORAGE:
DECL_TLS_MODEL (decl) = decl_default_tls_model (decl);
DECL_COMMON (decl) = 0;
break;
}
}
/* Record DECL as a global renaming pointer. */
void
record_global_renaming_pointer (tree decl)
{
gcc_assert (!DECL_LOOP_PARM_P (decl) && DECL_RENAMED_OBJECT (decl));
VEC_safe_push (tree, gc, global_renaming_pointers, decl);
}
/* Invalidate the global renaming pointers. */
void
invalidate_global_renaming_pointers (void)
{
unsigned int i;
tree iter;
FOR_EACH_VEC_ELT (tree, global_renaming_pointers, i, iter)
SET_DECL_RENAMED_OBJECT (iter, NULL_TREE);
VEC_free (tree, gc, global_renaming_pointers);
}
/* Return true if VALUE is a known to be a multiple of FACTOR, which must be
a power of 2. */
bool
value_factor_p (tree value, HOST_WIDE_INT factor)
{
if (host_integerp (value, 1))
return tree_low_cst (value, 1) % factor == 0;
if (TREE_CODE (value) == MULT_EXPR)
return (value_factor_p (TREE_OPERAND (value, 0), factor)
|| value_factor_p (TREE_OPERAND (value, 1), factor));
return false;
}
/* Given two consecutive field decls PREV_FIELD and CURR_FIELD, return true
unless we can prove these 2 fields are laid out in such a way that no gap
exist between the end of PREV_FIELD and the beginning of CURR_FIELD. OFFSET
is the distance in bits between the end of PREV_FIELD and the starting
position of CURR_FIELD. It is ignored if null. */
static bool
potential_alignment_gap (tree prev_field, tree curr_field, tree offset)
{
/* If this is the first field of the record, there cannot be any gap */
if (!prev_field)
return false;
/* If the previous field is a union type, then return False: The only
time when such a field is not the last field of the record is when
there are other components at fixed positions after it (meaning there
was a rep clause for every field), in which case we don't want the
alignment constraint to override them. */
if (TREE_CODE (TREE_TYPE (prev_field)) == QUAL_UNION_TYPE)
return false;
/* If the distance between the end of prev_field and the beginning of
curr_field is constant, then there is a gap if the value of this
constant is not null. */
if (offset && host_integerp (offset, 1))
return !integer_zerop (offset);
/* If the size and position of the previous field are constant,
then check the sum of this size and position. There will be a gap
iff it is not multiple of the current field alignment. */
if (host_integerp (DECL_SIZE (prev_field), 1)
&& host_integerp (bit_position (prev_field), 1))
return ((tree_low_cst (bit_position (prev_field), 1)
+ tree_low_cst (DECL_SIZE (prev_field), 1))
% DECL_ALIGN (curr_field) != 0);
/* If both the position and size of the previous field are multiples
of the current field alignment, there cannot be any gap. */
if (value_factor_p (bit_position (prev_field), DECL_ALIGN (curr_field))
&& value_factor_p (DECL_SIZE (prev_field), DECL_ALIGN (curr_field)))
return false;
/* Fallback, return that there may be a potential gap */
return true;
}
/* Return a LABEL_DECL with LABEL_NAME. GNAT_NODE is used for the position
of the decl. */
tree
create_label_decl (tree label_name, Node_Id gnat_node)
{
tree label_decl
= build_decl (input_location, LABEL_DECL, label_name, void_type_node);
DECL_MODE (label_decl) = VOIDmode;
/* Add this decl to the current binding level. */
gnat_pushdecl (label_decl, gnat_node);
return label_decl;
}
/* Return a FUNCTION_DECL node. SUBPROG_NAME is the name of the subprogram,
ASM_NAME is its assembler name, SUBPROG_TYPE is its type (a FUNCTION_TYPE
node), PARAM_DECL_LIST is the list of the subprogram arguments (a list of
PARM_DECL nodes chained through the DECL_CHAIN field).
INLINE_FLAG, PUBLIC_FLAG, EXTERN_FLAG, ARTIFICIAL_FLAG and ATTR_LIST are
used to set the appropriate fields in the FUNCTION_DECL. GNAT_NODE is
used for the position of the decl. */
tree
create_subprog_decl (tree subprog_name, tree asm_name, tree subprog_type,
tree param_decl_list, bool inline_flag, bool public_flag,
bool extern_flag, bool artificial_flag,
struct attrib *attr_list, Node_Id gnat_node)
{
tree subprog_decl = build_decl (input_location, FUNCTION_DECL, subprog_name,
subprog_type);
tree result_decl = build_decl (input_location, RESULT_DECL, NULL_TREE,
TREE_TYPE (subprog_type));
DECL_ARGUMENTS (subprog_decl) = param_decl_list;
/* If this is a non-inline function nested inside an inlined external
function, we cannot honor both requests without cloning the nested
function in the current unit since it is private to the other unit.
We could inline the nested function as well but it's probably better
to err on the side of too little inlining. */
if (!inline_flag
&& !public_flag
&& current_function_decl
&& DECL_DECLARED_INLINE_P (current_function_decl)
&& DECL_EXTERNAL (current_function_decl))
DECL_DECLARED_INLINE_P (current_function_decl) = 0;
DECL_ARTIFICIAL (subprog_decl) = artificial_flag;
DECL_EXTERNAL (subprog_decl) = extern_flag;
DECL_DECLARED_INLINE_P (subprog_decl) = inline_flag;
DECL_NO_INLINE_WARNING_P (subprog_decl) = inline_flag && artificial_flag;
TREE_PUBLIC (subprog_decl) = public_flag;
TREE_READONLY (subprog_decl) = TYPE_READONLY (subprog_type);
TREE_THIS_VOLATILE (subprog_decl) = TYPE_VOLATILE (subprog_type);
TREE_SIDE_EFFECTS (subprog_decl) = TYPE_VOLATILE (subprog_type);
DECL_ARTIFICIAL (result_decl) = 1;
DECL_IGNORED_P (result_decl) = 1;
DECL_BY_REFERENCE (result_decl) = TREE_ADDRESSABLE (subprog_type);
DECL_RESULT (subprog_decl) = result_decl;
if (asm_name)
{
SET_DECL_ASSEMBLER_NAME (subprog_decl, asm_name);
/* The expand_main_function circuitry expects "main_identifier_node" to
designate the DECL_NAME of the 'main' entry point, in turn expected
to be declared as the "main" function literally by default. Ada
program entry points are typically declared with a different name
within the binder generated file, exported as 'main' to satisfy the
system expectations. Force main_identifier_node in this case. */
if (asm_name == main_identifier_node)
DECL_NAME (subprog_decl) = main_identifier_node;
}
/* Add this decl to the current binding level. */
gnat_pushdecl (subprog_decl, gnat_node);
process_attributes (subprog_decl, attr_list);
/* Output the assembler code and/or RTL for the declaration. */
rest_of_decl_compilation (subprog_decl, global_bindings_p (), 0);
return subprog_decl;
}
/* Set up the framework for generating code for SUBPROG_DECL, a subprogram
body. This routine needs to be invoked before processing the declarations
appearing in the subprogram. */
void
begin_subprog_body (tree subprog_decl)
{
tree param_decl;
announce_function (subprog_decl);
/* This function is being defined. */
TREE_STATIC (subprog_decl) = 1;
current_function_decl = subprog_decl;
/* Enter a new binding level and show that all the parameters belong to
this function. */
gnat_pushlevel ();
for (param_decl = DECL_ARGUMENTS (subprog_decl); param_decl;
param_decl = DECL_CHAIN (param_decl))
DECL_CONTEXT (param_decl) = subprog_decl;
make_decl_rtl (subprog_decl);
}
/* Finish translating the current subprogram and set its BODY. */
void
end_subprog_body (tree body)
{
tree fndecl = current_function_decl;
/* Attach the BLOCK for this level to the function and pop the level. */
BLOCK_SUPERCONTEXT (current_binding_level->block) = fndecl;
DECL_INITIAL (fndecl) = current_binding_level->block;
gnat_poplevel ();
/* Mark the RESULT_DECL as being in this subprogram. */
DECL_CONTEXT (DECL_RESULT (fndecl)) = fndecl;
/* The body should be a BIND_EXPR whose BLOCK is the top-level one. */
if (TREE_CODE (body) == BIND_EXPR)
{
BLOCK_SUPERCONTEXT (BIND_EXPR_BLOCK (body)) = fndecl;
DECL_INITIAL (fndecl) = BIND_EXPR_BLOCK (body);
}
DECL_SAVED_TREE (fndecl) = body;
current_function_decl = decl_function_context (fndecl);
}
/* Wrap up compilation of SUBPROG_DECL, a subprogram body. */
void
rest_of_subprog_body_compilation (tree subprog_decl)
{
/* We cannot track the location of errors past this point. */
error_gnat_node = Empty;
/* If we're only annotating types, don't actually compile this function. */
if (type_annotate_only)
return;
/* Dump functions before gimplification. */
dump_function (TDI_original, subprog_decl);
if (!decl_function_context (subprog_decl))
cgraph_finalize_function (subprog_decl, false);
else
/* Register this function with cgraph just far enough to get it
added to our parent's nested function list. */
(void) cgraph_get_create_node (subprog_decl);
}
tree
gnat_builtin_function (tree decl)
{
gnat_pushdecl (decl, Empty);
return decl;
}
/* Return an integer type with the number of bits of precision given by
PRECISION. UNSIGNEDP is nonzero if the type is unsigned; otherwise
it is a signed type. */
tree
gnat_type_for_size (unsigned precision, int unsignedp)
{
tree t;
char type_name[20];
if (precision <= 2 * MAX_BITS_PER_WORD
&& signed_and_unsigned_types[precision][unsignedp])
return signed_and_unsigned_types[precision][unsignedp];
if (unsignedp)
t = make_unsigned_type (precision);
else
t = make_signed_type (precision);
if (precision <= 2 * MAX_BITS_PER_WORD)
signed_and_unsigned_types[precision][unsignedp] = t;
if (!TYPE_NAME (t))
{
sprintf (type_name, "%sSIGNED_%d", unsignedp ? "UN" : "", precision);
TYPE_NAME (t) = get_identifier (type_name);
}
return t;
}
/* Likewise for floating-point types. */
static tree
float_type_for_precision (int precision, enum machine_mode mode)
{
tree t;
char type_name[20];
if (float_types[(int) mode])
return float_types[(int) mode];
float_types[(int) mode] = t = make_node (REAL_TYPE);
TYPE_PRECISION (t) = precision;
layout_type (t);
gcc_assert (TYPE_MODE (t) == mode);
if (!TYPE_NAME (t))
{
sprintf (type_name, "FLOAT_%d", precision);
TYPE_NAME (t) = get_identifier (type_name);
}
return t;
}
/* Return a data type that has machine mode MODE. UNSIGNEDP selects
an unsigned type; otherwise a signed type is returned. */
tree
gnat_type_for_mode (enum machine_mode mode, int unsignedp)
{
if (mode == BLKmode)
return NULL_TREE;
if (mode == VOIDmode)
return void_type_node;
if (COMPLEX_MODE_P (mode))
return NULL_TREE;
if (SCALAR_FLOAT_MODE_P (mode))
return float_type_for_precision (GET_MODE_PRECISION (mode), mode);
if (SCALAR_INT_MODE_P (mode))
return gnat_type_for_size (GET_MODE_BITSIZE (mode), unsignedp);
if (VECTOR_MODE_P (mode))
{
enum machine_mode inner_mode = GET_MODE_INNER (mode);
tree inner_type = gnat_type_for_mode (inner_mode, unsignedp);
if (inner_type)
return build_vector_type_for_mode (inner_type, mode);
}
return NULL_TREE;
}
/* Return the unsigned version of a TYPE_NODE, a scalar type. */
tree
gnat_unsigned_type (tree type_node)
{
tree type = gnat_type_for_size (TYPE_PRECISION (type_node), 1);
if (TREE_CODE (type_node) == INTEGER_TYPE && TYPE_MODULAR_P (type_node))
{
type = copy_node (type);
TREE_TYPE (type) = type_node;
}
else if (TREE_TYPE (type_node)
&& TREE_CODE (TREE_TYPE (type_node)) == INTEGER_TYPE
&& TYPE_MODULAR_P (TREE_TYPE (type_node)))
{
type = copy_node (type);
TREE_TYPE (type) = TREE_TYPE (type_node);
}
return type;
}
/* Return the signed version of a TYPE_NODE, a scalar type. */
tree
gnat_signed_type (tree type_node)
{
tree type = gnat_type_for_size (TYPE_PRECISION (type_node), 0);
if (TREE_CODE (type_node) == INTEGER_TYPE && TYPE_MODULAR_P (type_node))
{
type = copy_node (type);
TREE_TYPE (type) = type_node;
}
else if (TREE_TYPE (type_node)
&& TREE_CODE (TREE_TYPE (type_node)) == INTEGER_TYPE
&& TYPE_MODULAR_P (TREE_TYPE (type_node)))
{
type = copy_node (type);
TREE_TYPE (type) = TREE_TYPE (type_node);
}
return type;
}
/* Return 1 if the types T1 and T2 are compatible, i.e. if they can be
transparently converted to each other. */
int
gnat_types_compatible_p (tree t1, tree t2)
{
enum tree_code code;
/* This is the default criterion. */
if (TYPE_MAIN_VARIANT (t1) == TYPE_MAIN_VARIANT (t2))
return 1;
/* We only check structural equivalence here. */
if ((code = TREE_CODE (t1)) != TREE_CODE (t2))
return 0;
/* Vector types are also compatible if they have the same number of subparts
and the same form of (scalar) element type. */
if (code == VECTOR_TYPE
&& TYPE_VECTOR_SUBPARTS (t1) == TYPE_VECTOR_SUBPARTS (t2)
&& TREE_CODE (TREE_TYPE (t1)) == TREE_CODE (TREE_TYPE (t2))
&& TYPE_PRECISION (TREE_TYPE (t1)) == TYPE_PRECISION (TREE_TYPE (t2)))
return 1;
/* Array types are also compatible if they are constrained and have the same
domain(s) and the same component type. */
if (code == ARRAY_TYPE
&& (TYPE_DOMAIN (t1) == TYPE_DOMAIN (t2)
|| (TYPE_DOMAIN (t1)
&& TYPE_DOMAIN (t2)
&& tree_int_cst_equal (TYPE_MIN_VALUE (TYPE_DOMAIN (t1)),
TYPE_MIN_VALUE (TYPE_DOMAIN (t2)))
&& tree_int_cst_equal (TYPE_MAX_VALUE (TYPE_DOMAIN (t1)),
TYPE_MAX_VALUE (TYPE_DOMAIN (t2)))))
&& (TREE_TYPE (t1) == TREE_TYPE (t2)
|| (TREE_CODE (TREE_TYPE (t1)) == ARRAY_TYPE
&& gnat_types_compatible_p (TREE_TYPE (t1), TREE_TYPE (t2)))))
return 1;
return 0;
}
/* Return true if EXPR is a useless type conversion. */
bool
gnat_useless_type_conversion (tree expr)
{
if (CONVERT_EXPR_P (expr)
|| TREE_CODE (expr) == VIEW_CONVERT_EXPR
|| TREE_CODE (expr) == NON_LVALUE_EXPR)
return gnat_types_compatible_p (TREE_TYPE (expr),
TREE_TYPE (TREE_OPERAND (expr, 0)));
return false;
}
/* Return true if T, a FUNCTION_TYPE, has the specified list of flags. */
bool
fntype_same_flags_p (const_tree t, tree cico_list, bool return_unconstrained_p,
bool return_by_direct_ref_p, bool return_by_invisi_ref_p)
{
return TYPE_CI_CO_LIST (t) == cico_list
&& TYPE_RETURN_UNCONSTRAINED_P (t) == return_unconstrained_p
&& TYPE_RETURN_BY_DIRECT_REF_P (t) == return_by_direct_ref_p
&& TREE_ADDRESSABLE (t) == return_by_invisi_ref_p;
}
/* EXP is an expression for the size of an object. If this size contains
discriminant references, replace them with the maximum (if MAX_P) or
minimum (if !MAX_P) possible value of the discriminant. */
tree
max_size (tree exp, bool max_p)
{
enum tree_code code = TREE_CODE (exp);
tree type = TREE_TYPE (exp);
switch (TREE_CODE_CLASS (code))
{
case tcc_declaration:
case tcc_constant:
return exp;
case tcc_vl_exp:
if (code == CALL_EXPR)
{
tree t, *argarray;
int n, i;
t = maybe_inline_call_in_expr (exp);
if (t)
return max_size (t, max_p);
n = call_expr_nargs (exp);
gcc_assert (n > 0);
argarray = XALLOCAVEC (tree, n);
for (i = 0; i < n; i++)
argarray[i] = max_size (CALL_EXPR_ARG (exp, i), max_p);
return build_call_array (type, CALL_EXPR_FN (exp), n, argarray);
}
break;
case tcc_reference:
/* If this contains a PLACEHOLDER_EXPR, it is the thing we want to
modify. Otherwise, we treat it like a variable. */
if (!CONTAINS_PLACEHOLDER_P (exp))
return exp;
type = TREE_TYPE (TREE_OPERAND (exp, 1));
return
max_size (max_p ? TYPE_MAX_VALUE (type) : TYPE_MIN_VALUE (type), true);
case tcc_comparison:
return max_p ? size_one_node : size_zero_node;
case tcc_unary:
case tcc_binary:
case tcc_expression:
switch (TREE_CODE_LENGTH (code))
{
case 1:
if (code == SAVE_EXPR)
return exp;
else if (code == NON_LVALUE_EXPR)
return max_size (TREE_OPERAND (exp, 0), max_p);
else
return
fold_build1 (code, type,
max_size (TREE_OPERAND (exp, 0),
code == NEGATE_EXPR ? !max_p : max_p));
case 2:
if (code == COMPOUND_EXPR)
return max_size (TREE_OPERAND (exp, 1), max_p);
{
tree lhs = max_size (TREE_OPERAND (exp, 0), max_p);
tree rhs = max_size (TREE_OPERAND (exp, 1),
code == MINUS_EXPR ? !max_p : max_p);
/* Special-case wanting the maximum value of a MIN_EXPR.
In that case, if one side overflows, return the other.
sizetype is signed, but we know sizes are non-negative.
Likewise, handle a MINUS_EXPR or PLUS_EXPR with the LHS
overflowing and the RHS a variable. */
if (max_p
&& code == MIN_EXPR
&& TREE_CODE (rhs) == INTEGER_CST
&& TREE_OVERFLOW (rhs))
return lhs;
else if (max_p
&& code == MIN_EXPR
&& TREE_CODE (lhs) == INTEGER_CST
&& TREE_OVERFLOW (lhs))
return rhs;
else if ((code == MINUS_EXPR || code == PLUS_EXPR)
&& TREE_CODE (lhs) == INTEGER_CST
&& TREE_OVERFLOW (lhs)
&& !TREE_CONSTANT (rhs))
return lhs;
else
return fold_build2 (code, type, lhs, rhs);
}
case 3:
if (code == COND_EXPR)
return fold_build2 (max_p ? MAX_EXPR : MIN_EXPR, type,
max_size (TREE_OPERAND (exp, 1), max_p),
max_size (TREE_OPERAND (exp, 2), max_p));
}
/* Other tree classes cannot happen. */
default:
break;
}
gcc_unreachable ();
}
/* Build a template of type TEMPLATE_TYPE from the array bounds of ARRAY_TYPE.
EXPR is an expression that we can use to locate any PLACEHOLDER_EXPRs.
Return a constructor for the template. */
tree
build_template (tree template_type, tree array_type, tree expr)
{
VEC(constructor_elt,gc) *template_elts = NULL;
tree bound_list = NULL_TREE;
tree field;
while (TREE_CODE (array_type) == RECORD_TYPE
&& (TYPE_PADDING_P (array_type)
|| TYPE_JUSTIFIED_MODULAR_P (array_type)))
array_type = TREE_TYPE (TYPE_FIELDS (array_type));
if (TREE_CODE (array_type) == ARRAY_TYPE
|| (TREE_CODE (array_type) == INTEGER_TYPE
&& TYPE_HAS_ACTUAL_BOUNDS_P (array_type)))
bound_list = TYPE_ACTUAL_BOUNDS (array_type);
/* First make the list for a CONSTRUCTOR for the template. Go down the
field list of the template instead of the type chain because this
array might be an Ada array of arrays and we can't tell where the
nested arrays stop being the underlying object. */
for (field = TYPE_FIELDS (template_type); field;
(bound_list
? (bound_list = TREE_CHAIN (bound_list))
: (array_type = TREE_TYPE (array_type))),
field = DECL_CHAIN (DECL_CHAIN (field)))
{
tree bounds, min, max;
/* If we have a bound list, get the bounds from there. Likewise
for an ARRAY_TYPE. Otherwise, if expr is a PARM_DECL with
DECL_BY_COMPONENT_PTR_P, use the bounds of the field in the template.
This will give us a maximum range. */
if (bound_list)
bounds = TREE_VALUE (bound_list);
else if (TREE_CODE (array_type) == ARRAY_TYPE)
bounds = TYPE_INDEX_TYPE (TYPE_DOMAIN (array_type));
else if (expr && TREE_CODE (expr) == PARM_DECL
&& DECL_BY_COMPONENT_PTR_P (expr))
bounds = TREE_TYPE (field);
else
gcc_unreachable ();
min = convert (TREE_TYPE (field), TYPE_MIN_VALUE (bounds));
max = convert (TREE_TYPE (DECL_CHAIN (field)), TYPE_MAX_VALUE (bounds));
/* If either MIN or MAX involve a PLACEHOLDER_EXPR, we must
substitute it from OBJECT. */
min = SUBSTITUTE_PLACEHOLDER_IN_EXPR (min, expr);
max = SUBSTITUTE_PLACEHOLDER_IN_EXPR (max, expr);
CONSTRUCTOR_APPEND_ELT (template_elts, field, min);
CONSTRUCTOR_APPEND_ELT (template_elts, DECL_CHAIN (field), max);
}
return gnat_build_constructor (template_type, template_elts);
}
/* Helper routine to make a descriptor field. FIELD_LIST is the list of decls
being built; the new decl is chained on to the front of the list. */
static tree
make_descriptor_field (const char *name, tree type, tree rec_type,
tree initial, tree field_list)
{
tree field
= create_field_decl (get_identifier (name), type, rec_type, NULL_TREE,
NULL_TREE, 0, 0);
DECL_INITIAL (field) = initial;
DECL_CHAIN (field) = field_list;
return field;
}
/* Build a 32-bit VMS descriptor from a Mechanism_Type, which must specify a
descriptor type, and the GCC type of an object. Each FIELD_DECL in the
type contains in its DECL_INITIAL the expression to use when a constructor
is made for the type. GNAT_ENTITY is an entity used to print out an error
message if the mechanism cannot be applied to an object of that type and
also for the name. */
tree
build_vms_descriptor32 (tree type, Mechanism_Type mech, Entity_Id gnat_entity)
{
tree record_type = make_node (RECORD_TYPE);
tree pointer32_type, pointer64_type;
tree field_list = NULL_TREE;
int klass, ndim, i, dtype = 0;
tree inner_type, tem;
tree *idx_arr;
/* If TYPE is an unconstrained array, use the underlying array type. */
if (TREE_CODE (type) == UNCONSTRAINED_ARRAY_TYPE)
type = TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (type))));
/* If this is an array, compute the number of dimensions in the array,
get the index types, and point to the inner type. */
if (TREE_CODE (type) != ARRAY_TYPE)
ndim = 0;
else
for (ndim = 1, inner_type = type;
TREE_CODE (TREE_TYPE (inner_type)) == ARRAY_TYPE
&& TYPE_MULTI_ARRAY_P (TREE_TYPE (inner_type));
ndim++, inner_type = TREE_TYPE (inner_type))
;
idx_arr = XALLOCAVEC (tree, ndim);
if (mech != By_Descriptor_NCA && mech != By_Short_Descriptor_NCA
&& TREE_CODE (type) == ARRAY_TYPE && TYPE_CONVENTION_FORTRAN_P (type))
for (i = ndim - 1, inner_type = type;
i >= 0;
i--, inner_type = TREE_TYPE (inner_type))
idx_arr[i] = TYPE_DOMAIN (inner_type);
else
for (i = 0, inner_type = type;
i < ndim;
i++, inner_type = TREE_TYPE (inner_type))
idx_arr[i] = TYPE_DOMAIN (inner_type);
/* Now get the DTYPE value. */
switch (TREE_CODE (type))
{
case INTEGER_TYPE:
case ENUMERAL_TYPE:
case BOOLEAN_TYPE:
if (TYPE_VAX_FLOATING_POINT_P (type))
switch (tree_low_cst (TYPE_DIGITS_VALUE (type), 1))
{
case 6:
dtype = 10;
break;
case 9:
dtype = 11;
break;
case 15:
dtype = 27;
break;
}
else
switch (GET_MODE_BITSIZE (TYPE_MODE (type)))
{
case 8:
dtype = TYPE_UNSIGNED (type) ? 2 : 6;
break;
case 16:
dtype = TYPE_UNSIGNED (type) ? 3 : 7;
break;
case 32:
dtype = TYPE_UNSIGNED (type) ? 4 : 8;
break;
case 64:
dtype = TYPE_UNSIGNED (type) ? 5 : 9;
break;
case 128:
dtype = TYPE_UNSIGNED (type) ? 25 : 26;
break;
}
break;
case REAL_TYPE:
dtype = GET_MODE_BITSIZE (TYPE_MODE (type)) == 32 ? 52 : 53;
break;
case COMPLEX_TYPE:
if (TREE_CODE (TREE_TYPE (type)) == INTEGER_TYPE
&& TYPE_VAX_FLOATING_POINT_P (type))
switch (tree_low_cst (TYPE_DIGITS_VALUE (type), 1))
{
case 6:
dtype = 12;
break;
case 9:
dtype = 13;
break;
case 15:
dtype = 29;
}
else
dtype = GET_MODE_BITSIZE (TYPE_MODE (TREE_TYPE (type))) == 32 ? 54: 55;
break;
case ARRAY_TYPE:
dtype = 14;
break;
default:
break;
}
/* Get the CLASS value. */
switch (mech)
{
case By_Descriptor_A:
case By_Short_Descriptor_A:
klass = 4;
break;
case By_Descriptor_NCA:
case By_Short_Descriptor_NCA:
klass = 10;
break;
case By_Descriptor_SB:
case By_Short_Descriptor_SB:
klass = 15;
break;
case By_Descriptor:
case By_Short_Descriptor:
case By_Descriptor_S:
case By_Short_Descriptor_S:
default:
klass = 1;
break;
}
/* Make the type for a descriptor for VMS. The first four fields are the
same for all types. */
field_list
= make_descriptor_field ("LENGTH", gnat_type_for_size (16, 1), record_type,
size_in_bytes ((mech == By_Descriptor_A
|| mech == By_Short_Descriptor_A)
? inner_type : type),
field_list);
field_list
= make_descriptor_field ("DTYPE", gnat_type_for_size (8, 1), record_type,
size_int (dtype), field_list);
field_list
= make_descriptor_field ("CLASS", gnat_type_for_size (8, 1), record_type,
size_int (klass), field_list);
pointer32_type = build_pointer_type_for_mode (type, SImode, false);
pointer64_type = build_pointer_type_for_mode (type, DImode, false);
/* Ensure that only 32-bit pointers are passed in 32-bit descriptors. Note
that we cannot build a template call to the CE routine as it would get a
wrong source location; instead we use a second placeholder for it. */
tem = build_unary_op (ADDR_EXPR, pointer64_type,
build0 (PLACEHOLDER_EXPR, type));
tem = build3 (COND_EXPR, pointer32_type,
Pmode != SImode
? build_binary_op (GE_EXPR, boolean_type_node, tem,
build_int_cstu (pointer64_type, 0x80000000))
: boolean_false_node,
build0 (PLACEHOLDER_EXPR, void_type_node),
convert (pointer32_type, tem));
field_list
= make_descriptor_field ("POINTER", pointer32_type, record_type, tem,
field_list);
switch (mech)
{
case By_Descriptor:
case By_Short_Descriptor:
case By_Descriptor_S:
case By_Short_Descriptor_S:
break;
case By_Descriptor_SB:
case By_Short_Descriptor_SB:
field_list
= make_descriptor_field ("SB_L1", gnat_type_for_size (32, 1),
record_type,
(TREE_CODE (type) == ARRAY_TYPE
? TYPE_MIN_VALUE (TYPE_DOMAIN (type))
: size_zero_node),
field_list);
field_list
= make_descriptor_field ("SB_U1", gnat_type_for_size (32, 1),
record_type,
(TREE_CODE (type) == ARRAY_TYPE
? TYPE_MAX_VALUE (TYPE_DOMAIN (type))
: size_zero_node),
field_list);
break;
case By_Descriptor_A:
case By_Short_Descriptor_A:
case By_Descriptor_NCA:
case By_Short_Descriptor_NCA:
field_list
= make_descriptor_field ("SCALE", gnat_type_for_size (8, 1),
record_type, size_zero_node, field_list);
field_list
= make_descriptor_field ("DIGITS", gnat_type_for_size (8, 1),
record_type, size_zero_node, field_list);
field_list
= make_descriptor_field ("AFLAGS", gnat_type_for_size (8, 1),
record_type,
size_int ((mech == By_Descriptor_NCA
|| mech == By_Short_Descriptor_NCA)
? 0
/* Set FL_COLUMN, FL_COEFF, and
FL_BOUNDS. */
: (TREE_CODE (type) == ARRAY_TYPE
&& TYPE_CONVENTION_FORTRAN_P
(type)
? 224 : 192)),
field_list);
field_list
= make_descriptor_field ("DIMCT", gnat_type_for_size (8, 1),
record_type, size_int (ndim), field_list);
field_list
= make_descriptor_field ("ARSIZE", gnat_type_for_size (32, 1),
record_type, size_in_bytes (type),
field_list);
/* Now build a pointer to the 0,0,0... element. */
tem = build0 (PLACEHOLDER_EXPR, type);
for (i = 0, inner_type = type; i < ndim;
i++, inner_type = TREE_TYPE (inner_type))
tem = build4 (ARRAY_REF, TREE_TYPE (inner_type), tem,
convert (TYPE_DOMAIN (inner_type), size_zero_node),
NULL_TREE, NULL_TREE);
field_list
= make_descriptor_field ("A0", pointer32_type, record_type,
build1 (ADDR_EXPR, pointer32_type, tem),
field_list);
/* Next come the addressing coefficients. */
tem = size_one_node;
for (i = 0; i < ndim; i++)
{
char fname[3];
tree idx_length
= size_binop (MULT_EXPR, tem,
size_binop (PLUS_EXPR,
size_binop (MINUS_EXPR,
TYPE_MAX_VALUE (idx_arr[i]),
TYPE_MIN_VALUE (idx_arr[i])),
size_int (1)));
fname[0] = ((mech == By_Descriptor_NCA ||
mech == By_Short_Descriptor_NCA) ? 'S' : 'M');
fname[1] = '0' + i, fname[2] = 0;
field_list
= make_descriptor_field (fname, gnat_type_for_size (32, 1),
record_type, idx_length, field_list);
if (mech == By_Descriptor_NCA || mech == By_Short_Descriptor_NCA)
tem = idx_length;
}
/* Finally here are the bounds. */
for (i = 0; i < ndim; i++)
{
char fname[3];
fname[0] = 'L', fname[1] = '0' + i, fname[2] = 0;
field_list
= make_descriptor_field (fname, gnat_type_for_size (32, 1),
record_type, TYPE_MIN_VALUE (idx_arr[i]),
field_list);
fname[0] = 'U';
field_list
= make_descriptor_field (fname, gnat_type_for_size (32, 1),
record_type, TYPE_MAX_VALUE (idx_arr[i]),
field_list);
}
break;
default:
post_error ("unsupported descriptor type for &", gnat_entity);
}
TYPE_NAME (record_type) = create_concat_name (gnat_entity, "DESC");
finish_record_type (record_type, nreverse (field_list), 0, false);
return record_type;
}
/* Build a 64-bit VMS descriptor from a Mechanism_Type, which must specify a
descriptor type, and the GCC type of an object. Each FIELD_DECL in the
type contains in its DECL_INITIAL the expression to use when a constructor
is made for the type. GNAT_ENTITY is an entity used to print out an error
message if the mechanism cannot be applied to an object of that type and
also for the name. */
tree
build_vms_descriptor (tree type, Mechanism_Type mech, Entity_Id gnat_entity)
{
tree record_type = make_node (RECORD_TYPE);
tree pointer64_type;
tree field_list = NULL_TREE;
int klass, ndim, i, dtype = 0;
tree inner_type, tem;
tree *idx_arr;
/* If TYPE is an unconstrained array, use the underlying array type. */
if (TREE_CODE (type) == UNCONSTRAINED_ARRAY_TYPE)
type = TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (type))));
/* If this is an array, compute the number of dimensions in the array,
get the index types, and point to the inner type. */
if (TREE_CODE (type) != ARRAY_TYPE)
ndim = 0;
else
for (ndim = 1, inner_type = type;
TREE_CODE (TREE_TYPE (inner_type)) == ARRAY_TYPE
&& TYPE_MULTI_ARRAY_P (TREE_TYPE (inner_type));
ndim++, inner_type = TREE_TYPE (inner_type))
;
idx_arr = XALLOCAVEC (tree, ndim);
if (mech != By_Descriptor_NCA
&& TREE_CODE (type) == ARRAY_TYPE && TYPE_CONVENTION_FORTRAN_P (type))
for (i = ndim - 1, inner_type = type;
i >= 0;
i--, inner_type = TREE_TYPE (inner_type))
idx_arr[i] = TYPE_DOMAIN (inner_type);
else
for (i = 0, inner_type = type;
i < ndim;
i++, inner_type = TREE_TYPE (inner_type))
idx_arr[i] = TYPE_DOMAIN (inner_type);
/* Now get the DTYPE value. */
switch (TREE_CODE (type))
{
case INTEGER_TYPE:
case ENUMERAL_TYPE:
case BOOLEAN_TYPE:
if (TYPE_VAX_FLOATING_POINT_P (type))
switch (tree_low_cst (TYPE_DIGITS_VALUE (type), 1))
{
case 6:
dtype = 10;
break;
case 9:
dtype = 11;
break;
case 15:
dtype = 27;
break;
}
else
switch (GET_MODE_BITSIZE (TYPE_MODE (type)))
{
case 8:
dtype = TYPE_UNSIGNED (type) ? 2 : 6;
break;
case 16:
dtype = TYPE_UNSIGNED (type) ? 3 : 7;
break;
case 32:
dtype = TYPE_UNSIGNED (type) ? 4 : 8;
break;
case 64:
dtype = TYPE_UNSIGNED (type) ? 5 : 9;
break;
case 128:
dtype = TYPE_UNSIGNED (type) ? 25 : 26;
break;
}
break;
case REAL_TYPE:
dtype = GET_MODE_BITSIZE (TYPE_MODE (type)) == 32 ? 52 : 53;
break;
case COMPLEX_TYPE:
if (TREE_CODE (TREE_TYPE (type)) == INTEGER_TYPE
&& TYPE_VAX_FLOATING_POINT_P (type))
switch (tree_low_cst (TYPE_DIGITS_VALUE (type), 1))
{
case 6:
dtype = 12;
break;
case 9:
dtype = 13;
break;
case 15:
dtype = 29;
}
else
dtype = GET_MODE_BITSIZE (TYPE_MODE (TREE_TYPE (type))) == 32 ? 54: 55;
break;
case ARRAY_TYPE:
dtype = 14;
break;
default:
break;
}
/* Get the CLASS value. */
switch (mech)
{
case By_Descriptor_A:
klass = 4;
break;
case By_Descriptor_NCA:
klass = 10;
break;
case By_Descriptor_SB:
klass = 15;
break;
case By_Descriptor:
case By_Descriptor_S:
default:
klass = 1;
break;
}
/* Make the type for a 64-bit descriptor for VMS. The first six fields
are the same for all types. */
field_list
= make_descriptor_field ("MBO", gnat_type_for_size (16, 1),
record_type, size_int (1), field_list);
field_list
= make_descriptor_field ("DTYPE", gnat_type_for_size (8, 1),
record_type, size_int (dtype), field_list);
field_list
= make_descriptor_field ("CLASS", gnat_type_for_size (8, 1),
record_type, size_int (klass), field_list);
field_list
= make_descriptor_field ("MBMO", gnat_type_for_size (32, 1),
record_type, size_int (-1), field_list);
field_list
= make_descriptor_field ("LENGTH", gnat_type_for_size (64, 1),
record_type,
size_in_bytes (mech == By_Descriptor_A
? inner_type : type),
field_list);
pointer64_type = build_pointer_type_for_mode (type, DImode, false);
field_list
= make_descriptor_field ("POINTER", pointer64_type, record_type,
build_unary_op (ADDR_EXPR, pointer64_type,
build0 (PLACEHOLDER_EXPR, type)),
field_list);
switch (mech)
{
case By_Descriptor:
case By_Descriptor_S:
break;
case By_Descriptor_SB:
field_list
= make_descriptor_field ("SB_L1", gnat_type_for_size (64, 1),
record_type,
(TREE_CODE (type) == ARRAY_TYPE
? TYPE_MIN_VALUE (TYPE_DOMAIN (type))
: size_zero_node),
field_list);
field_list
= make_descriptor_field ("SB_U1", gnat_type_for_size (64, 1),
record_type,
(TREE_CODE (type) == ARRAY_TYPE
? TYPE_MAX_VALUE (TYPE_DOMAIN (type))
: size_zero_node),
field_list);
break;
case By_Descriptor_A:
case By_Descriptor_NCA:
field_list
= make_descriptor_field ("SCALE", gnat_type_for_size (8, 1),
record_type, size_zero_node, field_list);
field_list
= make_descriptor_field ("DIGITS", gnat_type_for_size (8, 1),
record_type, size_zero_node, field_list);
dtype = (mech == By_Descriptor_NCA
? 0
/* Set FL_COLUMN, FL_COEFF, and
FL_BOUNDS. */
: (TREE_CODE (type) == ARRAY_TYPE
&& TYPE_CONVENTION_FORTRAN_P (type)
? 224 : 192));
field_list
= make_descriptor_field ("AFLAGS", gnat_type_for_size (8, 1),
record_type, size_int (dtype),
field_list);
field_list
= make_descriptor_field ("DIMCT", gnat_type_for_size (8, 1),
record_type, size_int (ndim), field_list);
field_list
= make_descriptor_field ("MBZ", gnat_type_for_size (32, 1),
record_type, size_int (0), field_list);
field_list
= make_descriptor_field ("ARSIZE", gnat_type_for_size (64, 1),
record_type, size_in_bytes (type),
field_list);
/* Now build a pointer to the 0,0,0... element. */
tem = build0 (PLACEHOLDER_EXPR, type);
for (i = 0, inner_type = type; i < ndim;
i++, inner_type = TREE_TYPE (inner_type))
tem = build4 (ARRAY_REF, TREE_TYPE (inner_type), tem,
convert (TYPE_DOMAIN (inner_type), size_zero_node),
NULL_TREE, NULL_TREE);
field_list
= make_descriptor_field ("A0", pointer64_type, record_type,
build1 (ADDR_EXPR, pointer64_type, tem),
field_list);
/* Next come the addressing coefficients. */
tem = size_one_node;
for (i = 0; i < ndim; i++)
{
char fname[3];
tree idx_length
= size_binop (MULT_EXPR, tem,
size_binop (PLUS_EXPR,
size_binop (MINUS_EXPR,
TYPE_MAX_VALUE (idx_arr[i]),
TYPE_MIN_VALUE (idx_arr[i])),
size_int (1)));
fname[0] = (mech == By_Descriptor_NCA ? 'S' : 'M');
fname[1] = '0' + i, fname[2] = 0;
field_list
= make_descriptor_field (fname, gnat_type_for_size (64, 1),
record_type, idx_length, field_list);
if (mech == By_Descriptor_NCA)
tem = idx_length;
}
/* Finally here are the bounds. */
for (i = 0; i < ndim; i++)
{
char fname[3];
fname[0] = 'L', fname[1] = '0' + i, fname[2] = 0;
field_list
= make_descriptor_field (fname, gnat_type_for_size (64, 1),
record_type,
TYPE_MIN_VALUE (idx_arr[i]), field_list);
fname[0] = 'U';
field_list
= make_descriptor_field (fname, gnat_type_for_size (64, 1),
record_type,
TYPE_MAX_VALUE (idx_arr[i]), field_list);
}
break;
default:
post_error ("unsupported descriptor type for &", gnat_entity);
}
TYPE_NAME (record_type) = create_concat_name (gnat_entity, "DESC64");
finish_record_type (record_type, nreverse (field_list), 0, false);
return record_type;
}
/* Fill in a VMS descriptor of GNU_TYPE for GNU_EXPR and return the result.
GNAT_ACTUAL is the actual parameter for which the descriptor is built. */
tree
fill_vms_descriptor (tree gnu_type, tree gnu_expr, Node_Id gnat_actual)
{
VEC(constructor_elt,gc) *v = NULL;
tree field;
gnu_expr = maybe_unconstrained_array (gnu_expr);
gnu_expr = gnat_protect_expr (gnu_expr);
gnat_mark_addressable (gnu_expr);
/* We may need to substitute both GNU_EXPR and a CALL_EXPR to the raise CE
routine in case we have a 32-bit descriptor. */
gnu_expr = build2 (COMPOUND_EXPR, void_type_node,
build_call_raise (CE_Range_Check_Failed, gnat_actual,
N_Raise_Constraint_Error),
gnu_expr);
for (field = TYPE_FIELDS (gnu_type); field; field = DECL_CHAIN (field))
{
tree value
= convert (TREE_TYPE (field),
SUBSTITUTE_PLACEHOLDER_IN_EXPR (DECL_INITIAL (field),
gnu_expr));
CONSTRUCTOR_APPEND_ELT (v, field, value);
}
return gnat_build_constructor (gnu_type, v);
}
/* Convert GNU_EXPR, a pointer to a 64bit VMS descriptor, to GNU_TYPE, a
regular pointer or fat pointer type. GNAT_SUBPROG is the subprogram to
which the VMS descriptor is passed. */
static tree
convert_vms_descriptor64 (tree gnu_type, tree gnu_expr, Entity_Id gnat_subprog)
{
tree desc_type = TREE_TYPE (TREE_TYPE (gnu_expr));
tree desc = build1 (INDIRECT_REF, desc_type, gnu_expr);
/* The CLASS field is the 3rd field in the descriptor. */
tree klass = DECL_CHAIN (DECL_CHAIN (TYPE_FIELDS (desc_type)));
/* The POINTER field is the 6th field in the descriptor. */
tree pointer = DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (klass)));
/* Retrieve the value of the POINTER field. */
tree gnu_expr64
= build3 (COMPONENT_REF, TREE_TYPE (pointer), desc, pointer, NULL_TREE);
if (POINTER_TYPE_P (gnu_type))
return convert (gnu_type, gnu_expr64);
else if (TYPE_IS_FAT_POINTER_P (gnu_type))
{
tree p_array_type = TREE_TYPE (TYPE_FIELDS (gnu_type));
tree p_bounds_type = TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (gnu_type)));
tree template_type = TREE_TYPE (p_bounds_type);
tree min_field = TYPE_FIELDS (template_type);
tree max_field = DECL_CHAIN (TYPE_FIELDS (template_type));
tree template_tree, template_addr, aflags, dimct, t, u;
/* See the head comment of build_vms_descriptor. */
int iklass = TREE_INT_CST_LOW (DECL_INITIAL (klass));
tree lfield, ufield;
VEC(constructor_elt,gc) *v;
/* Convert POINTER to the pointer-to-array type. */
gnu_expr64 = convert (p_array_type, gnu_expr64);
switch (iklass)
{
case 1: /* Class S */
case 15: /* Class SB */
/* Build {1, LENGTH} template; LENGTH64 is the 5th field. */
v = VEC_alloc (constructor_elt, gc, 2);
t = DECL_CHAIN (DECL_CHAIN (klass));
t = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
CONSTRUCTOR_APPEND_ELT (v, min_field,
convert (TREE_TYPE (min_field),
integer_one_node));
CONSTRUCTOR_APPEND_ELT (v, max_field,
convert (TREE_TYPE (max_field), t));
template_tree = gnat_build_constructor (template_type, v);
template_addr = build_unary_op (ADDR_EXPR, NULL_TREE, template_tree);
/* For class S, we are done. */
if (iklass == 1)
break;
/* Test that we really have a SB descriptor, like DEC Ada. */
t = build3 (COMPONENT_REF, TREE_TYPE (klass), desc, klass, NULL);
u = convert (TREE_TYPE (klass), DECL_INITIAL (klass));
u = build_binary_op (EQ_EXPR, boolean_type_node, t, u);
/* If so, there is already a template in the descriptor and
it is located right after the POINTER field. The fields are
64bits so they must be repacked. */
t = DECL_CHAIN (pointer);
lfield = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
lfield = convert (TREE_TYPE (TYPE_FIELDS (template_type)), lfield);
t = DECL_CHAIN (t);
ufield = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
ufield = convert
(TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (template_type))), ufield);
/* Build the template in the form of a constructor. */
v = VEC_alloc (constructor_elt, gc, 2);
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (template_type), lfield);
CONSTRUCTOR_APPEND_ELT (v, DECL_CHAIN (TYPE_FIELDS (template_type)),
ufield);
template_tree = gnat_build_constructor (template_type, v);
/* Otherwise use the {1, LENGTH} template we build above. */
template_addr = build3 (COND_EXPR, p_bounds_type, u,
build_unary_op (ADDR_EXPR, p_bounds_type,
template_tree),
template_addr);
break;
case 4: /* Class A */
/* The AFLAGS field is the 3rd field after the pointer in the
descriptor. */
t = DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (pointer)));
aflags = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
/* The DIMCT field is the next field in the descriptor after
aflags. */
t = DECL_CHAIN (t);
dimct = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
/* Raise CONSTRAINT_ERROR if either more than 1 dimension
or FL_COEFF or FL_BOUNDS not set. */
u = build_int_cst (TREE_TYPE (aflags), 192);
u = build_binary_op (TRUTH_OR_EXPR, boolean_type_node,
build_binary_op (NE_EXPR, boolean_type_node,
dimct,
convert (TREE_TYPE (dimct),
size_one_node)),
build_binary_op (NE_EXPR, boolean_type_node,
build2 (BIT_AND_EXPR,
TREE_TYPE (aflags),
aflags, u),
u));
/* There is already a template in the descriptor and it is located
in block 3. The fields are 64bits so they must be repacked. */
t = DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (DECL_CHAIN
(t)))));
lfield = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
lfield = convert (TREE_TYPE (TYPE_FIELDS (template_type)), lfield);
t = DECL_CHAIN (t);
ufield = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
ufield = convert
(TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (template_type))), ufield);
/* Build the template in the form of a constructor. */
v = VEC_alloc (constructor_elt, gc, 2);
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (template_type), lfield);
CONSTRUCTOR_APPEND_ELT (v, DECL_CHAIN (TYPE_FIELDS (template_type)),
ufield);
template_tree = gnat_build_constructor (template_type, v);
template_tree = build3 (COND_EXPR, template_type, u,
build_call_raise (CE_Length_Check_Failed, Empty,
N_Raise_Constraint_Error),
template_tree);
template_addr
= build_unary_op (ADDR_EXPR, p_bounds_type, template_tree);
break;
case 10: /* Class NCA */
default:
post_error ("unsupported descriptor type for &", gnat_subprog);
template_addr = integer_zero_node;
break;
}
/* Build the fat pointer in the form of a constructor. */
v = VEC_alloc (constructor_elt, gc, 2);
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (gnu_type), gnu_expr64);
CONSTRUCTOR_APPEND_ELT (v, DECL_CHAIN (TYPE_FIELDS (gnu_type)),
template_addr);
return gnat_build_constructor (gnu_type, v);
}
else
gcc_unreachable ();
}
/* Convert GNU_EXPR, a pointer to a 32bit VMS descriptor, to GNU_TYPE, a
regular pointer or fat pointer type. GNAT_SUBPROG is the subprogram to
which the VMS descriptor is passed. */
static tree
convert_vms_descriptor32 (tree gnu_type, tree gnu_expr, Entity_Id gnat_subprog)
{
tree desc_type = TREE_TYPE (TREE_TYPE (gnu_expr));
tree desc = build1 (INDIRECT_REF, desc_type, gnu_expr);
/* The CLASS field is the 3rd field in the descriptor. */
tree klass = DECL_CHAIN (DECL_CHAIN (TYPE_FIELDS (desc_type)));
/* The POINTER field is the 4th field in the descriptor. */
tree pointer = DECL_CHAIN (klass);
/* Retrieve the value of the POINTER field. */
tree gnu_expr32
= build3 (COMPONENT_REF, TREE_TYPE (pointer), desc, pointer, NULL_TREE);
if (POINTER_TYPE_P (gnu_type))
return convert (gnu_type, gnu_expr32);
else if (TYPE_IS_FAT_POINTER_P (gnu_type))
{
tree p_array_type = TREE_TYPE (TYPE_FIELDS (gnu_type));
tree p_bounds_type = TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (gnu_type)));
tree template_type = TREE_TYPE (p_bounds_type);
tree min_field = TYPE_FIELDS (template_type);
tree max_field = DECL_CHAIN (TYPE_FIELDS (template_type));
tree template_tree, template_addr, aflags, dimct, t, u;
/* See the head comment of build_vms_descriptor. */
int iklass = TREE_INT_CST_LOW (DECL_INITIAL (klass));
VEC(constructor_elt,gc) *v;
/* Convert POINTER to the pointer-to-array type. */
gnu_expr32 = convert (p_array_type, gnu_expr32);
switch (iklass)
{
case 1: /* Class S */
case 15: /* Class SB */
/* Build {1, LENGTH} template; LENGTH is the 1st field. */
v = VEC_alloc (constructor_elt, gc, 2);
t = TYPE_FIELDS (desc_type);
t = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
CONSTRUCTOR_APPEND_ELT (v, min_field,
convert (TREE_TYPE (min_field),
integer_one_node));
CONSTRUCTOR_APPEND_ELT (v, max_field,
convert (TREE_TYPE (max_field), t));
template_tree = gnat_build_constructor (template_type, v);
template_addr = build_unary_op (ADDR_EXPR, NULL_TREE, template_tree);
/* For class S, we are done. */
if (iklass == 1)
break;
/* Test that we really have a SB descriptor, like DEC Ada. */
t = build3 (COMPONENT_REF, TREE_TYPE (klass), desc, klass, NULL);
u = convert (TREE_TYPE (klass), DECL_INITIAL (klass));
u = build_binary_op (EQ_EXPR, boolean_type_node, t, u);
/* If so, there is already a template in the descriptor and
it is located right after the POINTER field. */
t = DECL_CHAIN (pointer);
template_tree
= build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
/* Otherwise use the {1, LENGTH} template we build above. */
template_addr = build3 (COND_EXPR, p_bounds_type, u,
build_unary_op (ADDR_EXPR, p_bounds_type,
template_tree),
template_addr);
break;
case 4: /* Class A */
/* The AFLAGS field is the 7th field in the descriptor. */
t = DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (pointer)));
aflags = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
/* The DIMCT field is the 8th field in the descriptor. */
t = DECL_CHAIN (t);
dimct = build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
/* Raise CONSTRAINT_ERROR if either more than 1 dimension
or FL_COEFF or FL_BOUNDS not set. */
u = build_int_cst (TREE_TYPE (aflags), 192);
u = build_binary_op (TRUTH_OR_EXPR, boolean_type_node,
build_binary_op (NE_EXPR, boolean_type_node,
dimct,
convert (TREE_TYPE (dimct),
size_one_node)),
build_binary_op (NE_EXPR, boolean_type_node,
build2 (BIT_AND_EXPR,
TREE_TYPE (aflags),
aflags, u),
u));
/* There is already a template in the descriptor and it is
located at the start of block 3 (12th field). */
t = DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (t))));
template_tree
= build3 (COMPONENT_REF, TREE_TYPE (t), desc, t, NULL_TREE);
template_tree = build3 (COND_EXPR, TREE_TYPE (t), u,
build_call_raise (CE_Length_Check_Failed, Empty,
N_Raise_Constraint_Error),
template_tree);
template_addr
= build_unary_op (ADDR_EXPR, p_bounds_type, template_tree);
break;
case 10: /* Class NCA */
default:
post_error ("unsupported descriptor type for &", gnat_subprog);
template_addr = integer_zero_node;
break;
}
/* Build the fat pointer in the form of a constructor. */
v = VEC_alloc (constructor_elt, gc, 2);
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (gnu_type), gnu_expr32);
CONSTRUCTOR_APPEND_ELT (v, DECL_CHAIN (TYPE_FIELDS (gnu_type)),
template_addr);
return gnat_build_constructor (gnu_type, v);
}
else
gcc_unreachable ();
}
/* Convert GNU_EXPR, a pointer to a VMS descriptor, to GNU_TYPE, a regular
pointer or fat pointer type. GNU_EXPR_ALT_TYPE is the alternate (32-bit)
pointer type of GNU_EXPR. BY_REF is true if the result is to be used by
reference. GNAT_SUBPROG is the subprogram to which the VMS descriptor is
passed. */
tree
convert_vms_descriptor (tree gnu_type, tree gnu_expr, tree gnu_expr_alt_type,
bool by_ref, Entity_Id gnat_subprog)
{
tree desc_type = TREE_TYPE (TREE_TYPE (gnu_expr));
tree desc = build1 (INDIRECT_REF, desc_type, gnu_expr);
tree mbo = TYPE_FIELDS (desc_type);
const char *mbostr = IDENTIFIER_POINTER (DECL_NAME (mbo));
tree mbmo = DECL_CHAIN (DECL_CHAIN (DECL_CHAIN (mbo)));
tree real_type, is64bit, gnu_expr32, gnu_expr64;
if (by_ref)
real_type = TREE_TYPE (gnu_type);
else
real_type = gnu_type;
/* If the field name is not MBO, it must be 32-bit and no alternate.
Otherwise primary must be 64-bit and alternate 32-bit. */
if (strcmp (mbostr, "MBO") != 0)
{
tree ret = convert_vms_descriptor32 (real_type, gnu_expr, gnat_subprog);
if (by_ref)
ret = build_unary_op (ADDR_EXPR, gnu_type, ret);
return ret;
}
/* Build the test for 64-bit descriptor. */
mbo = build3 (COMPONENT_REF, TREE_TYPE (mbo), desc, mbo, NULL_TREE);
mbmo = build3 (COMPONENT_REF, TREE_TYPE (mbmo), desc, mbmo, NULL_TREE);
is64bit
= build_binary_op (TRUTH_ANDIF_EXPR, boolean_type_node,
build_binary_op (EQ_EXPR, boolean_type_node,
convert (integer_type_node, mbo),
integer_one_node),
build_binary_op (EQ_EXPR, boolean_type_node,
convert (integer_type_node, mbmo),
integer_minus_one_node));
/* Build the 2 possible end results. */
gnu_expr64 = convert_vms_descriptor64 (real_type, gnu_expr, gnat_subprog);
if (by_ref)
gnu_expr64 = build_unary_op (ADDR_EXPR, gnu_type, gnu_expr64);
gnu_expr = fold_convert (gnu_expr_alt_type, gnu_expr);
gnu_expr32 = convert_vms_descriptor32 (real_type, gnu_expr, gnat_subprog);
if (by_ref)
gnu_expr32 = build_unary_op (ADDR_EXPR, gnu_type, gnu_expr32);
return build3 (COND_EXPR, gnu_type, is64bit, gnu_expr64, gnu_expr32);
}
/* Build a type to be used to represent an aliased object whose nominal type
is an unconstrained array. This consists of a RECORD_TYPE containing a
field of TEMPLATE_TYPE and a field of OBJECT_TYPE, which is an ARRAY_TYPE.
If ARRAY_TYPE is that of an unconstrained array, this is used to represent
an arbitrary unconstrained object. Use NAME as the name of the record.
DEBUG_INFO_P is true if we need to write debug information for the type. */
tree
build_unc_object_type (tree template_type, tree object_type, tree name,
bool debug_info_p)
{
tree type = make_node (RECORD_TYPE);
tree template_field
= create_field_decl (get_identifier ("BOUNDS"), template_type, type,
NULL_TREE, NULL_TREE, 0, 1);
tree array_field
= create_field_decl (get_identifier ("ARRAY"), object_type, type,
NULL_TREE, NULL_TREE, 0, 1);
TYPE_NAME (type) = name;
TYPE_CONTAINS_TEMPLATE_P (type) = 1;
DECL_CHAIN (template_field) = array_field;
finish_record_type (type, template_field, 0, true);
/* Declare it now since it will never be declared otherwise. This is
necessary to ensure that its subtrees are properly marked. */
create_type_decl (name, type, NULL, true, debug_info_p, Empty);
return type;
}
/* Same, taking a thin or fat pointer type instead of a template type. */
tree
build_unc_object_type_from_ptr (tree thin_fat_ptr_type, tree object_type,
tree name, bool debug_info_p)
{
tree template_type;
gcc_assert (TYPE_IS_FAT_OR_THIN_POINTER_P (thin_fat_ptr_type));
template_type
= (TYPE_IS_FAT_POINTER_P (thin_fat_ptr_type)
? TREE_TYPE (TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (thin_fat_ptr_type))))
: TREE_TYPE (TYPE_FIELDS (TREE_TYPE (thin_fat_ptr_type))));
return
build_unc_object_type (template_type, object_type, name, debug_info_p);
}
/* Update anything previously pointing to OLD_TYPE to point to NEW_TYPE.
In the normal case this is just two adjustments, but we have more to
do if NEW_TYPE is an UNCONSTRAINED_ARRAY_TYPE. */
void
update_pointer_to (tree old_type, tree new_type)
{
tree ptr = TYPE_POINTER_TO (old_type);
tree ref = TYPE_REFERENCE_TO (old_type);
tree t;
/* If this is the main variant, process all the other variants first. */
if (TYPE_MAIN_VARIANT (old_type) == old_type)
for (t = TYPE_NEXT_VARIANT (old_type); t; t = TYPE_NEXT_VARIANT (t))
update_pointer_to (t, new_type);
/* If no pointers and no references, we are done. */
if (!ptr && !ref)
return;
/* Merge the old type qualifiers in the new type.
Each old variant has qualifiers for specific reasons, and the new
designated type as well. Each set of qualifiers represents useful
information grabbed at some point, and merging the two simply unifies
these inputs into the final type description.
Consider for instance a volatile type frozen after an access to constant
type designating it; after the designated type's freeze, we get here with
a volatile NEW_TYPE and a dummy OLD_TYPE with a readonly variant, created
when the access type was processed. We will make a volatile and readonly
designated type, because that's what it really is.
We might also get here for a non-dummy OLD_TYPE variant with different
qualifiers than those of NEW_TYPE, for instance in some cases of pointers
to private record type elaboration (see the comments around the call to
this routine in gnat_to_gnu_entity <E_Access_Type>). We have to merge
the qualifiers in those cases too, to avoid accidentally discarding the
initial set, and will often end up with OLD_TYPE == NEW_TYPE then. */
new_type
= build_qualified_type (new_type,
TYPE_QUALS (old_type) | TYPE_QUALS (new_type));
/* If old type and new type are identical, there is nothing to do. */
if (old_type == new_type)
return;
/* Otherwise, first handle the simple case. */
if (TREE_CODE (new_type) != UNCONSTRAINED_ARRAY_TYPE)
{
tree new_ptr, new_ref;
/* If pointer or reference already points to new type, nothing to do.
This can happen as update_pointer_to can be invoked multiple times
on the same couple of types because of the type variants. */
if ((ptr && TREE_TYPE (ptr) == new_type)
|| (ref && TREE_TYPE (ref) == new_type))
return;
/* Chain PTR and its variants at the end. */
new_ptr = TYPE_POINTER_TO (new_type);
if (new_ptr)
{
while (TYPE_NEXT_PTR_TO (new_ptr))
new_ptr = TYPE_NEXT_PTR_TO (new_ptr);
TYPE_NEXT_PTR_TO (new_ptr) = ptr;
}
else
TYPE_POINTER_TO (new_type) = ptr;
/* Now adjust them. */
for (; ptr; ptr = TYPE_NEXT_PTR_TO (ptr))
for (t = TYPE_MAIN_VARIANT (ptr); t; t = TYPE_NEXT_VARIANT (t))
{
TREE_TYPE (t) = new_type;
if (TYPE_NULL_BOUNDS (t))
TREE_TYPE (TREE_OPERAND (TYPE_NULL_BOUNDS (t), 0)) = new_type;
}
/* Chain REF and its variants at the end. */
new_ref = TYPE_REFERENCE_TO (new_type);
if (new_ref)
{
while (TYPE_NEXT_REF_TO (new_ref))
new_ref = TYPE_NEXT_REF_TO (new_ref);
TYPE_NEXT_REF_TO (new_ref) = ref;
}
else
TYPE_REFERENCE_TO (new_type) = ref;
/* Now adjust them. */
for (; ref; ref = TYPE_NEXT_REF_TO (ref))
for (t = TYPE_MAIN_VARIANT (ref); t; t = TYPE_NEXT_VARIANT (t))
TREE_TYPE (t) = new_type;
TYPE_POINTER_TO (old_type) = NULL_TREE;
TYPE_REFERENCE_TO (old_type) = NULL_TREE;
}
/* Now deal with the unconstrained array case. In this case the pointer
is actually a record where both fields are pointers to dummy nodes.
Turn them into pointers to the correct types using update_pointer_to.
Likewise for the pointer to the object record (thin pointer). */
else
{
tree new_ptr = TYPE_POINTER_TO (new_type);
gcc_assert (TYPE_IS_FAT_POINTER_P (ptr));
/* If PTR already points to NEW_TYPE, nothing to do. This can happen
since update_pointer_to can be invoked multiple times on the same
couple of types because of the type variants. */
if (TYPE_UNCONSTRAINED_ARRAY (ptr) == new_type)
return;
update_pointer_to
(TREE_TYPE (TREE_TYPE (TYPE_FIELDS (ptr))),
TREE_TYPE (TREE_TYPE (TYPE_FIELDS (new_ptr))));
update_pointer_to
(TREE_TYPE (TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (ptr)))),
TREE_TYPE (TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (new_ptr)))));
update_pointer_to (TYPE_OBJECT_RECORD_TYPE (old_type),
TYPE_OBJECT_RECORD_TYPE (new_type));
TYPE_POINTER_TO (old_type) = NULL_TREE;
}
}
/* Convert EXPR, a pointer to a constrained array, into a pointer to an
unconstrained one. This involves making or finding a template. */
static tree
convert_to_fat_pointer (tree type, tree expr)
{
tree template_type = TREE_TYPE (TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (type))));
tree p_array_type = TREE_TYPE (TYPE_FIELDS (type));
tree etype = TREE_TYPE (expr);
tree template_tree;
VEC(constructor_elt,gc) *v = VEC_alloc (constructor_elt, gc, 2);
/* If EXPR is null, make a fat pointer that contains a null pointer to the
array (compare_fat_pointers ensures that this is the full discriminant)
and a valid pointer to the bounds. This latter property is necessary
since the compiler can hoist the load of the bounds done through it. */
if (integer_zerop (expr))
{
tree ptr_template_type = TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (type)));
tree null_bounds, t;
if (TYPE_NULL_BOUNDS (ptr_template_type))
null_bounds = TYPE_NULL_BOUNDS (ptr_template_type);
else
{
/* The template type can still be dummy at this point so we build an
empty constructor. The middle-end will fill it in with zeros. */
t = build_constructor (template_type, NULL);
TREE_CONSTANT (t) = TREE_STATIC (t) = 1;
null_bounds = build_unary_op (ADDR_EXPR, NULL_TREE, t);
SET_TYPE_NULL_BOUNDS (ptr_template_type, null_bounds);
}
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (type),
fold_convert (p_array_type, null_pointer_node));
CONSTRUCTOR_APPEND_ELT (v, DECL_CHAIN (TYPE_FIELDS (type)), null_bounds);
t = build_constructor (type, v);
/* Do not set TREE_CONSTANT so as to force T to static memory. */
TREE_CONSTANT (t) = 0;
TREE_STATIC (t) = 1;
return t;
}
/* If EXPR is a thin pointer, make template and data from the record. */
if (TYPE_IS_THIN_POINTER_P (etype))
{
tree field = TYPE_FIELDS (TREE_TYPE (etype));
expr = gnat_protect_expr (expr);
if (TREE_CODE (expr) == ADDR_EXPR)
expr = TREE_OPERAND (expr, 0);
else
{
/* If we have a TYPE_UNCONSTRAINED_ARRAY attached to the RECORD_TYPE,
the thin pointer value has been shifted so we first need to shift
it back to get the template address. */
if (TYPE_UNCONSTRAINED_ARRAY (TREE_TYPE (etype)))
expr
= build_binary_op (POINTER_PLUS_EXPR, etype, expr,
fold_build1 (NEGATE_EXPR, sizetype,
byte_position
(DECL_CHAIN (field))));
expr = build1 (INDIRECT_REF, TREE_TYPE (etype), expr);
}
template_tree = build_component_ref (expr, NULL_TREE, field, false);
expr = build_unary_op (ADDR_EXPR, NULL_TREE,
build_component_ref (expr, NULL_TREE,
DECL_CHAIN (field), false));
}
/* Otherwise, build the constructor for the template. */
else
template_tree = build_template (template_type, TREE_TYPE (etype), expr);
/* The final result is a constructor for the fat pointer.
If EXPR is an argument of a foreign convention subprogram, the type it
points to is directly the component type. In this case, the expression
type may not match the corresponding FIELD_DECL type at this point, so we
call "convert" here to fix that up if necessary. This type consistency is
required, for instance because it ensures that possible later folding of
COMPONENT_REFs against this constructor always yields something of the
same type as the initial reference.
Note that the call to "build_template" above is still fine because it
will only refer to the provided TEMPLATE_TYPE in this case. */
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (type),
convert (p_array_type, expr));
CONSTRUCTOR_APPEND_ELT (v, DECL_CHAIN (TYPE_FIELDS (type)),
build_unary_op (ADDR_EXPR, NULL_TREE,
template_tree));
return gnat_build_constructor (type, v);
}
/* Create an expression whose value is that of EXPR,
converted to type TYPE. The TREE_TYPE of the value
is always TYPE. This function implements all reasonable
conversions; callers should filter out those that are
not permitted by the language being compiled. */
tree
convert (tree type, tree expr)
{
tree etype = TREE_TYPE (expr);
enum tree_code ecode = TREE_CODE (etype);
enum tree_code code = TREE_CODE (type);
/* If the expression is already of the right type, we are done. */
if (etype == type)
return expr;
/* If both input and output have padding and are of variable size, do this
as an unchecked conversion. Likewise if one is a mere variant of the
other, so we avoid a pointless unpad/repad sequence. */
else if (code == RECORD_TYPE && ecode == RECORD_TYPE
&& TYPE_PADDING_P (type) && TYPE_PADDING_P (etype)
&& (!TREE_CONSTANT (TYPE_SIZE (type))
|| !TREE_CONSTANT (TYPE_SIZE (etype))
|| TYPE_MAIN_VARIANT (type) == TYPE_MAIN_VARIANT (etype)
|| TYPE_NAME (TREE_TYPE (TYPE_FIELDS (type)))
== TYPE_NAME (TREE_TYPE (TYPE_FIELDS (etype)))))
;
/* If the output type has padding, convert to the inner type and make a
constructor to build the record, unless a variable size is involved. */
else if (code == RECORD_TYPE && TYPE_PADDING_P (type))
{
VEC(constructor_elt,gc) *v;
/* If we previously converted from another type and our type is
of variable size, remove the conversion to avoid the need for
variable-sized temporaries. Likewise for a conversion between
original and packable version. */
if (TREE_CODE (expr) == VIEW_CONVERT_EXPR
&& (!TREE_CONSTANT (TYPE_SIZE (type))
|| (ecode == RECORD_TYPE
&& TYPE_NAME (etype)
== TYPE_NAME (TREE_TYPE (TREE_OPERAND (expr, 0))))))
expr = TREE_OPERAND (expr, 0);
/* If we are just removing the padding from expr, convert the original
object if we have variable size in order to avoid the need for some
variable-sized temporaries. Likewise if the padding is a variant
of the other, so we avoid a pointless unpad/repad sequence. */
if (TREE_CODE (expr) == COMPONENT_REF
&& TYPE_IS_PADDING_P (TREE_TYPE (TREE_OPERAND (expr, 0)))
&& (!TREE_CONSTANT (TYPE_SIZE (type))
|| TYPE_MAIN_VARIANT (type)
== TYPE_MAIN_VARIANT (TREE_TYPE (TREE_OPERAND (expr, 0)))
|| (ecode == RECORD_TYPE
&& TYPE_NAME (etype)
== TYPE_NAME (TREE_TYPE (TYPE_FIELDS (type))))))
return convert (type, TREE_OPERAND (expr, 0));
/* If the inner type is of self-referential size and the expression type
is a record, do this as an unchecked conversion. But first pad the
expression if possible to have the same size on both sides. */
if (ecode == RECORD_TYPE
&& CONTAINS_PLACEHOLDER_P (DECL_SIZE (TYPE_FIELDS (type))))
{
if (TREE_CODE (TYPE_SIZE (etype)) == INTEGER_CST)
expr = convert (maybe_pad_type (etype, TYPE_SIZE (type), 0, Empty,
false, false, false, true),
expr);
return unchecked_convert (type, expr, false);
}
/* If we are converting between array types with variable size, do the
final conversion as an unchecked conversion, again to avoid the need
for some variable-sized temporaries. If valid, this conversion is
very likely purely technical and without real effects. */
if (ecode == ARRAY_TYPE
&& TREE_CODE (TREE_TYPE (TYPE_FIELDS (type))) == ARRAY_TYPE
&& !TREE_CONSTANT (TYPE_SIZE (etype))
&& !TREE_CONSTANT (TYPE_SIZE (type)))
return unchecked_convert (type,
convert (TREE_TYPE (TYPE_FIELDS (type)),
expr),
false);
v = VEC_alloc (constructor_elt, gc, 1);
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (type),
convert (TREE_TYPE (TYPE_FIELDS (type)), expr));
return gnat_build_constructor (type, v);
}
/* If the input type has padding, remove it and convert to the output type.
The conditions ordering is arranged to ensure that the output type is not
a padding type here, as it is not clear whether the conversion would
always be correct if this was to happen. */
else if (ecode == RECORD_TYPE && TYPE_PADDING_P (etype))
{
tree unpadded;
/* If we have just converted to this padded type, just get the
inner expression. */
if (TREE_CODE (expr) == CONSTRUCTOR
&& !VEC_empty (constructor_elt, CONSTRUCTOR_ELTS (expr))
&& VEC_index (constructor_elt, CONSTRUCTOR_ELTS (expr), 0)->index
== TYPE_FIELDS (etype))
unpadded
= VEC_index (constructor_elt, CONSTRUCTOR_ELTS (expr), 0)->value;
/* Otherwise, build an explicit component reference. */
else
unpadded
= build_component_ref (expr, NULL_TREE, TYPE_FIELDS (etype), false);
return convert (type, unpadded);
}
/* If the input is a biased type, adjust first. */
if (ecode == INTEGER_TYPE && TYPE_BIASED_REPRESENTATION_P (etype))
return convert (type, fold_build2 (PLUS_EXPR, TREE_TYPE (etype),
fold_convert (TREE_TYPE (etype),
expr),
TYPE_MIN_VALUE (etype)));
/* If the input is a justified modular type, we need to extract the actual
object before converting it to any other type with the exceptions of an
unconstrained array or of a mere type variant. It is useful to avoid the
extraction and conversion in the type variant case because it could end
up replacing a VAR_DECL expr by a constructor and we might be about the
take the address of the result. */
if (ecode == RECORD_TYPE && TYPE_JUSTIFIED_MODULAR_P (etype)
&& code != UNCONSTRAINED_ARRAY_TYPE
&& TYPE_MAIN_VARIANT (type) != TYPE_MAIN_VARIANT (etype))
return convert (type, build_component_ref (expr, NULL_TREE,
TYPE_FIELDS (etype), false));
/* If converting to a type that contains a template, convert to the data
type and then build the template. */
if (code == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (type))
{
tree obj_type = TREE_TYPE (DECL_CHAIN (TYPE_FIELDS (type)));
VEC(constructor_elt,gc) *v = VEC_alloc (constructor_elt, gc, 2);
/* If the source already has a template, get a reference to the
associated array only, as we are going to rebuild a template
for the target type anyway. */
expr = maybe_unconstrained_array (expr);
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (type),
build_template (TREE_TYPE (TYPE_FIELDS (type)),
obj_type, NULL_TREE));
CONSTRUCTOR_APPEND_ELT (v, DECL_CHAIN (TYPE_FIELDS (type)),
convert (obj_type, expr));
return gnat_build_constructor (type, v);
}
/* There are some cases of expressions that we process specially. */
switch (TREE_CODE (expr))
{
case ERROR_MARK:
return expr;
case NULL_EXPR:
/* Just set its type here. For TRANSFORM_EXPR, we will do the actual
conversion in gnat_expand_expr. NULL_EXPR does not represent
and actual value, so no conversion is needed. */
expr = copy_node (expr);
TREE_TYPE (expr) = type;
return expr;
case STRING_CST:
/* If we are converting a STRING_CST to another constrained array type,
just make a new one in the proper type. */
if (code == ecode && AGGREGATE_TYPE_P (etype)
&& !(TREE_CODE (TYPE_SIZE (etype)) == INTEGER_CST
&& TREE_CODE (TYPE_SIZE (type)) != INTEGER_CST))
{
expr = copy_node (expr);
TREE_TYPE (expr) = type;
return expr;
}
break;
case VECTOR_CST:
/* If we are converting a VECTOR_CST to a mere variant type, just make
a new one in the proper type. */
if (code == ecode && gnat_types_compatible_p (type, etype))
{
expr = copy_node (expr);
TREE_TYPE (expr) = type;
return expr;
}
case CONSTRUCTOR:
/* If we are converting a CONSTRUCTOR to a mere variant type, just make
a new one in the proper type. */
if (code == ecode && gnat_types_compatible_p (type, etype))
{
expr = copy_node (expr);
TREE_TYPE (expr) = type;
CONSTRUCTOR_ELTS (expr)
= VEC_copy (constructor_elt, gc, CONSTRUCTOR_ELTS (expr));
return expr;
}
/* Likewise for a conversion between original and packable version, or
conversion between types of the same size and with the same list of
fields, but we have to work harder to preserve type consistency. */
if (code == ecode
&& code == RECORD_TYPE
&& (TYPE_NAME (type) == TYPE_NAME (etype)
|| tree_int_cst_equal (TYPE_SIZE (type), TYPE_SIZE (etype))))
{
VEC(constructor_elt,gc) *e = CONSTRUCTOR_ELTS (expr);
unsigned HOST_WIDE_INT len = VEC_length (constructor_elt, e);
VEC(constructor_elt,gc) *v = VEC_alloc (constructor_elt, gc, len);
tree efield = TYPE_FIELDS (etype), field = TYPE_FIELDS (type);
unsigned HOST_WIDE_INT idx;
tree index, value;
/* Whether we need to clear TREE_CONSTANT et al. on the output
constructor when we convert in place. */
bool clear_constant = false;
FOR_EACH_CONSTRUCTOR_ELT(e, idx, index, value)
{
constructor_elt *elt;
/* We expect only simple constructors. */
if (!SAME_FIELD_P (index, efield))
break;
/* The field must be the same. */
if (!SAME_FIELD_P (efield, field))
break;
elt = VEC_quick_push (constructor_elt, v, NULL);
elt->index = field;
elt->value = convert (TREE_TYPE (field), value);
/* If packing has made this field a bitfield and the input
value couldn't be emitted statically any more, we need to
clear TREE_CONSTANT on our output. */
if (!clear_constant
&& TREE_CONSTANT (expr)
&& !CONSTRUCTOR_BITFIELD_P (efield)
&& CONSTRUCTOR_BITFIELD_P (field)
&& !initializer_constant_valid_for_bitfield_p (value))
clear_constant = true;
efield = DECL_CHAIN (efield);
field = DECL_CHAIN (field);
}
/* If we have been able to match and convert all the input fields
to their output type, convert in place now. We'll fallback to a
view conversion downstream otherwise. */
if (idx == len)
{
expr = copy_node (expr);
TREE_TYPE (expr) = type;
CONSTRUCTOR_ELTS (expr) = v;
if (clear_constant)
TREE_CONSTANT (expr) = TREE_STATIC (expr) = 0;
return expr;
}
}
/* Likewise for a conversion between array type and vector type with a
compatible representative array. */
else if (code == VECTOR_TYPE
&& ecode == ARRAY_TYPE
&& gnat_types_compatible_p (TYPE_REPRESENTATIVE_ARRAY (type),
etype))
{
VEC(constructor_elt,gc) *e = CONSTRUCTOR_ELTS (expr);
unsigned HOST_WIDE_INT len = VEC_length (constructor_elt, e);
VEC(constructor_elt,gc) *v;
unsigned HOST_WIDE_INT ix;
tree value;
/* Build a VECTOR_CST from a *constant* array constructor. */
if (TREE_CONSTANT (expr))
{
bool constant_p = true;
/* Iterate through elements and check if all constructor
elements are *_CSTs. */
FOR_EACH_CONSTRUCTOR_VALUE (e, ix, value)
if (!CONSTANT_CLASS_P (value))
{
constant_p = false;
break;
}
if (constant_p)
return build_vector_from_ctor (type,
CONSTRUCTOR_ELTS (expr));
}
/* Otherwise, build a regular vector constructor. */
v = VEC_alloc (constructor_elt, gc, len);
FOR_EACH_CONSTRUCTOR_VALUE (e, ix, value)
{
constructor_elt *elt = VEC_quick_push (constructor_elt, v, NULL);
elt->index = NULL_TREE;
elt->value = value;
}
expr = copy_node (expr);
TREE_TYPE (expr) = type;
CONSTRUCTOR_ELTS (expr) = v;
return expr;
}
break;
case UNCONSTRAINED_ARRAY_REF:
/* First retrieve the underlying array. */
expr = maybe_unconstrained_array (expr);
etype = TREE_TYPE (expr);
ecode = TREE_CODE (etype);
break;
case VIEW_CONVERT_EXPR:
{
/* GCC 4.x is very sensitive to type consistency overall, and view
conversions thus are very frequent. Even though just "convert"ing
the inner operand to the output type is fine in most cases, it
might expose unexpected input/output type mismatches in special
circumstances so we avoid such recursive calls when we can. */
tree op0 = TREE_OPERAND (expr, 0);
/* If we are converting back to the original type, we can just
lift the input conversion. This is a common occurrence with
switches back-and-forth amongst type variants. */
if (type == TREE_TYPE (op0))
return op0;
/* Otherwise, if we're converting between two aggregate or vector
types, we might be allowed to substitute the VIEW_CONVERT_EXPR
target type in place or to just convert the inner expression. */
if ((AGGREGATE_TYPE_P (type) && AGGREGATE_TYPE_P (etype))
|| (VECTOR_TYPE_P (type) && VECTOR_TYPE_P (etype)))
{
/* If we are converting between mere variants, we can just
substitute the VIEW_CONVERT_EXPR in place. */
if (gnat_types_compatible_p (type, etype))
return build1 (VIEW_CONVERT_EXPR, type, op0);
/* Otherwise, we may just bypass the input view conversion unless
one of the types is a fat pointer, which is handled by
specialized code below which relies on exact type matching. */
else if (!TYPE_IS_FAT_POINTER_P (type)
&& !TYPE_IS_FAT_POINTER_P (etype))
return convert (type, op0);
}
break;
}
default:
break;
}
/* Check for converting to a pointer to an unconstrained array. */
if (TYPE_IS_FAT_POINTER_P (type) && !TYPE_IS_FAT_POINTER_P (etype))
return convert_to_fat_pointer (type, expr);
/* If we are converting between two aggregate or vector types that are mere
variants, just make a VIEW_CONVERT_EXPR. Likewise when we are converting
to a vector type from its representative array type. */
else if ((code == ecode
&& (AGGREGATE_TYPE_P (type) || VECTOR_TYPE_P (type))
&& gnat_types_compatible_p (type, etype))
|| (code == VECTOR_TYPE
&& ecode == ARRAY_TYPE
&& gnat_types_compatible_p (TYPE_REPRESENTATIVE_ARRAY (type),
etype)))
return build1 (VIEW_CONVERT_EXPR, type, expr);
/* If we are converting between tagged types, try to upcast properly. */
else if (ecode == RECORD_TYPE && code == RECORD_TYPE
&& TYPE_ALIGN_OK (etype) && TYPE_ALIGN_OK (type))
{
tree child_etype = etype;
do {
tree field = TYPE_FIELDS (child_etype);
if (DECL_NAME (field) == parent_name_id && TREE_TYPE (field) == type)
return build_component_ref (expr, NULL_TREE, field, false);
child_etype = TREE_TYPE (field);
} while (TREE_CODE (child_etype) == RECORD_TYPE);
}
/* If we are converting from a smaller form of record type back to it, just
make a VIEW_CONVERT_EXPR. But first pad the expression to have the same
size on both sides. */
else if (ecode == RECORD_TYPE && code == RECORD_TYPE
&& smaller_form_type_p (etype, type))
{
expr = convert (maybe_pad_type (etype, TYPE_SIZE (type), 0, Empty,
false, false, false, true),
expr);
return build1 (VIEW_CONVERT_EXPR, type, expr);
}
/* In all other cases of related types, make a NOP_EXPR. */
else if (TYPE_MAIN_VARIANT (type) == TYPE_MAIN_VARIANT (etype))
return fold_convert (type, expr);
switch (code)
{
case VOID_TYPE:
return fold_build1 (CONVERT_EXPR, type, expr);
case INTEGER_TYPE:
if (TYPE_HAS_ACTUAL_BOUNDS_P (type)
&& (ecode == ARRAY_TYPE || ecode == UNCONSTRAINED_ARRAY_TYPE
|| (ecode == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (etype))))
return unchecked_convert (type, expr, false);
else if (TYPE_BIASED_REPRESENTATION_P (type))
return fold_convert (type,
fold_build2 (MINUS_EXPR, TREE_TYPE (type),
convert (TREE_TYPE (type), expr),
TYPE_MIN_VALUE (type)));
/* ... fall through ... */
case ENUMERAL_TYPE:
case BOOLEAN_TYPE:
/* If we are converting an additive expression to an integer type
with lower precision, be wary of the optimization that can be
applied by convert_to_integer. There are 2 problematic cases:
- if the first operand was originally of a biased type,
because we could be recursively called to convert it
to an intermediate type and thus rematerialize the
additive operator endlessly,
- if the expression contains a placeholder, because an
intermediate conversion that changes the sign could
be inserted and thus introduce an artificial overflow
at compile time when the placeholder is substituted. */
if (code == INTEGER_TYPE
&& ecode == INTEGER_TYPE
&& TYPE_PRECISION (type) < TYPE_PRECISION (etype)
&& (TREE_CODE (expr) == PLUS_EXPR || TREE_CODE (expr) == MINUS_EXPR))
{
tree op0 = get_unwidened (TREE_OPERAND (expr, 0), type);
if ((TREE_CODE (TREE_TYPE (op0)) == INTEGER_TYPE
&& TYPE_BIASED_REPRESENTATION_P (TREE_TYPE (op0)))
|| CONTAINS_PLACEHOLDER_P (expr))
return build1 (NOP_EXPR, type, expr);
}
return fold (convert_to_integer (type, expr));
case POINTER_TYPE:
case REFERENCE_TYPE:
/* If converting between two thin pointers, adjust if needed to account
for differing offsets from the base pointer, depending on whether
there is a TYPE_UNCONSTRAINED_ARRAY attached to the record type. */
if (TYPE_IS_THIN_POINTER_P (etype) && TYPE_IS_THIN_POINTER_P (type))
{
tree etype_pos
= TYPE_UNCONSTRAINED_ARRAY (TREE_TYPE (etype)) != NULL_TREE
? byte_position (DECL_CHAIN (TYPE_FIELDS (TREE_TYPE (etype))))
: size_zero_node;
tree type_pos
= TYPE_UNCONSTRAINED_ARRAY (TREE_TYPE (type)) != NULL_TREE
? byte_position (DECL_CHAIN (TYPE_FIELDS (TREE_TYPE (type))))
: size_zero_node;
tree byte_diff = size_diffop (type_pos, etype_pos);
expr = build1 (NOP_EXPR, type, expr);
if (integer_zerop (byte_diff))
return expr;
return build_binary_op (POINTER_PLUS_EXPR, type, expr,
fold_convert (sizetype, byte_diff));
}
/* If converting fat pointer to normal or thin pointer, get the pointer
to the array and then convert it. */
if (TYPE_IS_FAT_POINTER_P (etype))
expr
= build_component_ref (expr, NULL_TREE, TYPE_FIELDS (etype), false);
return fold (convert_to_pointer (type, expr));
case REAL_TYPE:
return fold (convert_to_real (type, expr));
case RECORD_TYPE:
if (TYPE_JUSTIFIED_MODULAR_P (type) && !AGGREGATE_TYPE_P (etype))
{
VEC(constructor_elt,gc) *v = VEC_alloc (constructor_elt, gc, 1);
CONSTRUCTOR_APPEND_ELT (v, TYPE_FIELDS (type),
convert (TREE_TYPE (TYPE_FIELDS (type)),
expr));
return gnat_build_constructor (type, v);
}
/* ... fall through ... */
case ARRAY_TYPE:
/* In these cases, assume the front-end has validated the conversion.
If the conversion is valid, it will be a bit-wise conversion, so
it can be viewed as an unchecked conversion. */
return unchecked_convert (type, expr, false);
case UNION_TYPE:
/* This is a either a conversion between a tagged type and some
subtype, which we have to mark as a UNION_TYPE because of
overlapping fields or a conversion of an Unchecked_Union. */
return unchecked_convert (type, expr, false);
case UNCONSTRAINED_ARRAY_TYPE:
/* If the input is a VECTOR_TYPE, convert to the representative
array type first. */
if (ecode == VECTOR_TYPE)
{
expr = convert (TYPE_REPRESENTATIVE_ARRAY (etype), expr);
etype = TREE_TYPE (expr);
ecode = TREE_CODE (etype);
}
/* If EXPR is a constrained array, take its address, convert it to a
fat pointer, and then dereference it. Likewise if EXPR is a
record containing both a template and a constrained array.
Note that a record representing a justified modular type
always represents a packed constrained array. */
if (ecode == ARRAY_TYPE
|| (ecode == INTEGER_TYPE && TYPE_HAS_ACTUAL_BOUNDS_P (etype))
|| (ecode == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (etype))
|| (ecode == RECORD_TYPE && TYPE_JUSTIFIED_MODULAR_P (etype)))
return
build_unary_op
(INDIRECT_REF, NULL_TREE,
convert_to_fat_pointer (TREE_TYPE (type),
build_unary_op (ADDR_EXPR,
NULL_TREE, expr)));
/* Do something very similar for converting one unconstrained
array to another. */
else if (ecode == UNCONSTRAINED_ARRAY_TYPE)
return
build_unary_op (INDIRECT_REF, NULL_TREE,
convert (TREE_TYPE (type),
build_unary_op (ADDR_EXPR,
NULL_TREE, expr)));
else
gcc_unreachable ();
case COMPLEX_TYPE:
return fold (convert_to_complex (type, expr));
default:
gcc_unreachable ();
}
}
/* Create an expression whose value is that of EXPR converted to the common
index type, which is sizetype. EXPR is supposed to be in the base type
of the GNAT index type. Calling it is equivalent to doing
convert (sizetype, expr)
but we try to distribute the type conversion with the knowledge that EXPR
cannot overflow in its type. This is a best-effort approach and we fall
back to the above expression as soon as difficulties are encountered.
This is necessary to overcome issues that arise when the GNAT base index
type and the GCC common index type (sizetype) don't have the same size,
which is quite frequent on 64-bit architectures. In this case, and if
the GNAT base index type is signed but the iteration type of the loop has
been forced to unsigned, the loop scalar evolution engine cannot compute
a simple evolution for the general induction variables associated with the
array indices, because it will preserve the wrap-around semantics in the
unsigned type of their "inner" part. As a result, many loop optimizations
are blocked.
The solution is to use a special (basic) induction variable that is at
least as large as sizetype, and to express the aforementioned general
induction variables in terms of this induction variable, eliminating
the problematic intermediate truncation to the GNAT base index type.
This is possible as long as the original expression doesn't overflow
and if the middle-end hasn't introduced artificial overflows in the
course of the various simplification it can make to the expression. */
tree
convert_to_index_type (tree expr)
{
enum tree_code code = TREE_CODE (expr);
tree type = TREE_TYPE (expr);
/* If the type is unsigned, overflow is allowed so we cannot be sure that
EXPR doesn't overflow. Keep it simple if optimization is disabled. */
if (TYPE_UNSIGNED (type) || !optimize)
return convert (sizetype, expr);
switch (code)
{
case VAR_DECL:
/* The main effect of the function: replace a loop parameter with its
associated special induction variable. */
if (DECL_LOOP_PARM_P (expr) && DECL_INDUCTION_VAR (expr))
expr = DECL_INDUCTION_VAR (expr);
break;
CASE_CONVERT:
{
tree otype = TREE_TYPE (TREE_OPERAND (expr, 0));
/* Bail out as soon as we suspect some sort of type frobbing. */
if (TYPE_PRECISION (type) != TYPE_PRECISION (otype)
|| TYPE_UNSIGNED (type) != TYPE_UNSIGNED (otype))
break;
}
/* ... fall through ... */
case NON_LVALUE_EXPR:
return fold_build1 (code, sizetype,
convert_to_index_type (TREE_OPERAND (expr, 0)));
case PLUS_EXPR:
case MINUS_EXPR:
case MULT_EXPR:
return fold_build2 (code, sizetype,
convert_to_index_type (TREE_OPERAND (expr, 0)),
convert_to_index_type (TREE_OPERAND (expr, 1)));
case COMPOUND_EXPR:
return fold_build2 (code, sizetype, TREE_OPERAND (expr, 0),
convert_to_index_type (TREE_OPERAND (expr, 1)));
case COND_EXPR:
return fold_build3 (code, sizetype, TREE_OPERAND (expr, 0),
convert_to_index_type (TREE_OPERAND (expr, 1)),
convert_to_index_type (TREE_OPERAND (expr, 2)));
default:
break;
}
return convert (sizetype, expr);
}
/* Remove all conversions that are done in EXP. This includes converting
from a padded type or to a justified modular type. If TRUE_ADDRESS
is true, always return the address of the containing object even if
the address is not bit-aligned. */
tree
remove_conversions (tree exp, bool true_address)
{
switch (TREE_CODE (exp))
{
case CONSTRUCTOR:
if (true_address
&& TREE_CODE (TREE_TYPE (exp)) == RECORD_TYPE
&& TYPE_JUSTIFIED_MODULAR_P (TREE_TYPE (exp)))
return
remove_conversions (VEC_index (constructor_elt,
CONSTRUCTOR_ELTS (exp), 0)->value,
true);
break;
case COMPONENT_REF:
if (TYPE_IS_PADDING_P (TREE_TYPE (TREE_OPERAND (exp, 0))))
return remove_conversions (TREE_OPERAND (exp, 0), true_address);
break;
CASE_CONVERT:
case VIEW_CONVERT_EXPR:
case NON_LVALUE_EXPR:
return remove_conversions (TREE_OPERAND (exp, 0), true_address);
default:
break;
}
return exp;
}
/* If EXP's type is an UNCONSTRAINED_ARRAY_TYPE, return an expression that
refers to the underlying array. If it has TYPE_CONTAINS_TEMPLATE_P,
likewise return an expression pointing to the underlying array. */
tree
maybe_unconstrained_array (tree exp)
{
enum tree_code code = TREE_CODE (exp);
tree type = TREE_TYPE (exp);
switch (TREE_CODE (type))
{
case UNCONSTRAINED_ARRAY_TYPE:
if (code == UNCONSTRAINED_ARRAY_REF)
{
const bool read_only = TREE_READONLY (exp);
const bool no_trap = TREE_THIS_NOTRAP (exp);
exp = TREE_OPERAND (exp, 0);
type = TREE_TYPE (exp);
if (TREE_CODE (exp) == COND_EXPR)
{
tree op1
= build_unary_op (INDIRECT_REF, NULL_TREE,
build_component_ref (TREE_OPERAND (exp, 1),
NULL_TREE,
TYPE_FIELDS (type),
false));
tree op2
= build_unary_op (INDIRECT_REF, NULL_TREE,
build_component_ref (TREE_OPERAND (exp, 2),
NULL_TREE,
TYPE_FIELDS (type),
false));
exp = build3 (COND_EXPR,
TREE_TYPE (TREE_TYPE (TYPE_FIELDS (type))),
TREE_OPERAND (exp, 0), op1, op2);
}
else
{
exp = build_unary_op (INDIRECT_REF, NULL_TREE,
build_component_ref (exp, NULL_TREE,
TYPE_FIELDS (type),
false));
TREE_READONLY (exp) = read_only;
TREE_THIS_NOTRAP (exp) = no_trap;
}
}
else if (code == NULL_EXPR)
exp = build1 (NULL_EXPR,
TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (type)))),
TREE_OPERAND (exp, 0));
break;
case RECORD_TYPE:
/* If this is a padded type and it contains a template, convert to the
unpadded type first. */
if (TYPE_PADDING_P (type)
&& TREE_CODE (TREE_TYPE (TYPE_FIELDS (type))) == RECORD_TYPE
&& TYPE_CONTAINS_TEMPLATE_P (TREE_TYPE (TYPE_FIELDS (type))))
{
exp = convert (TREE_TYPE (TYPE_FIELDS (type)), exp);
type = TREE_TYPE (exp);
}
if (TYPE_CONTAINS_TEMPLATE_P (type))
{
exp = build_component_ref (exp, NULL_TREE,
DECL_CHAIN (TYPE_FIELDS (type)),
false);
type = TREE_TYPE (exp);
/* If the array type is padded, convert to the unpadded type. */
if (TYPE_IS_PADDING_P (type))
exp = convert (TREE_TYPE (TYPE_FIELDS (type)), exp);
}
break;
default:
break;
}
return exp;
}
/* Return true if EXPR is an expression that can be folded as an operand
of a VIEW_CONVERT_EXPR. See ada-tree.h for a complete rationale. */
static bool
can_fold_for_view_convert_p (tree expr)
{
tree t1, t2;
/* The folder will fold NOP_EXPRs between integral types with the same
precision (in the middle-end's sense). We cannot allow it if the
types don't have the same precision in the Ada sense as well. */
if (TREE_CODE (expr) != NOP_EXPR)
return true;
t1 = TREE_TYPE (expr);
t2 = TREE_TYPE (TREE_OPERAND (expr, 0));
/* Defer to the folder for non-integral conversions. */
if (!(INTEGRAL_TYPE_P (t1) && INTEGRAL_TYPE_P (t2)))
return true;
/* Only fold conversions that preserve both precisions. */
if (TYPE_PRECISION (t1) == TYPE_PRECISION (t2)
&& operand_equal_p (rm_size (t1), rm_size (t2), 0))
return true;
return false;
}
/* Return an expression that does an unchecked conversion of EXPR to TYPE.
If NOTRUNC_P is true, truncation operations should be suppressed.
Special care is required with (source or target) integral types whose
precision is not equal to their size, to make sure we fetch or assign
the value bits whose location might depend on the endianness, e.g.
Rmsize : constant := 8;
subtype Int is Integer range 0 .. 2 ** Rmsize - 1;
type Bit_Array is array (1 .. Rmsize) of Boolean;
pragma Pack (Bit_Array);
function To_Bit_Array is new Unchecked_Conversion (Int, Bit_Array);
Value : Int := 2#1000_0001#;
Vbits : Bit_Array := To_Bit_Array (Value);
we expect the 8 bits at Vbits'Address to always contain Value, while
their original location depends on the endianness, at Value'Address
on a little-endian architecture but not on a big-endian one. */
tree
unchecked_convert (tree type, tree expr, bool notrunc_p)
{
tree etype = TREE_TYPE (expr);
enum tree_code ecode = TREE_CODE (etype);
enum tree_code code = TREE_CODE (type);
int c;
/* If the expression is already of the right type, we are done. */
if (etype == type)
return expr;
/* If both types types are integral just do a normal conversion.
Likewise for a conversion to an unconstrained array. */
if ((((INTEGRAL_TYPE_P (type)
&& !(code == INTEGER_TYPE && TYPE_VAX_FLOATING_POINT_P (type)))
|| (POINTER_TYPE_P (type) && !TYPE_IS_THIN_POINTER_P (type))
|| (code == RECORD_TYPE && TYPE_JUSTIFIED_MODULAR_P (type)))
&& ((INTEGRAL_TYPE_P (etype)
&& !(ecode == INTEGER_TYPE && TYPE_VAX_FLOATING_POINT_P (etype)))
|| (POINTER_TYPE_P (etype) && !TYPE_IS_THIN_POINTER_P (etype))
|| (ecode == RECORD_TYPE && TYPE_JUSTIFIED_MODULAR_P (etype))))
|| code == UNCONSTRAINED_ARRAY_TYPE)
{
if (ecode == INTEGER_TYPE && TYPE_BIASED_REPRESENTATION_P (etype))
{
tree ntype = copy_type (etype);
TYPE_BIASED_REPRESENTATION_P (ntype) = 0;
TYPE_MAIN_VARIANT (ntype) = ntype;
expr = build1 (NOP_EXPR, ntype, expr);
}
if (code == INTEGER_TYPE && TYPE_BIASED_REPRESENTATION_P (type))
{
tree rtype = copy_type (type);
TYPE_BIASED_REPRESENTATION_P (rtype) = 0;
TYPE_MAIN_VARIANT (rtype) = rtype;
expr = convert (rtype, expr);
expr = build1 (NOP_EXPR, type, expr);
}
else
expr = convert (type, expr);
}
/* If we are converting to an integral type whose precision is not equal
to its size, first unchecked convert to a record type that contains an
field of the given precision. Then extract the field. */
else if (INTEGRAL_TYPE_P (type)
&& TYPE_RM_SIZE (type)
&& 0 != compare_tree_int (TYPE_RM_SIZE (type),
GET_MODE_BITSIZE (TYPE_MODE (type))))
{
tree rec_type = make_node (RECORD_TYPE);
unsigned HOST_WIDE_INT prec = TREE_INT_CST_LOW (TYPE_RM_SIZE (type));
tree field_type, field;
if (TYPE_UNSIGNED (type))
field_type = make_unsigned_type (prec);
else
field_type = make_signed_type (prec);
SET_TYPE_RM_SIZE (field_type, TYPE_RM_SIZE (type));
field = create_field_decl (get_identifier ("OBJ"), field_type, rec_type,
NULL_TREE, NULL_TREE, 1, 0);
TYPE_FIELDS (rec_type) = field;
layout_type (rec_type);
expr = unchecked_convert (rec_type, expr, notrunc_p);
expr = build_component_ref (expr, NULL_TREE, field, false);
expr = fold_build1 (NOP_EXPR, type, expr);
}
/* Similarly if we are converting from an integral type whose precision is
not equal to its size, first copy into a field of the given precision
and unchecked convert the record type. */
else if (INTEGRAL_TYPE_P (etype)
&& TYPE_RM_SIZE (etype)
&& 0 != compare_tree_int (TYPE_RM_SIZE (etype),
GET_MODE_BITSIZE (TYPE_MODE (etype))))
{
tree rec_type = make_node (RECORD_TYPE);
unsigned HOST_WIDE_INT prec = TREE_INT_CST_LOW (TYPE_RM_SIZE (etype));
VEC(constructor_elt,gc) *v = VEC_alloc (constructor_elt, gc, 1);
tree field_type, field;
if (TYPE_UNSIGNED (etype))
field_type = make_unsigned_type (prec);
else
field_type = make_signed_type (prec);
SET_TYPE_RM_SIZE (field_type, TYPE_RM_SIZE (etype));
field = create_field_decl (get_identifier ("OBJ"), field_type, rec_type,
NULL_TREE, NULL_TREE, 1, 0);
TYPE_FIELDS (rec_type) = field;
layout_type (rec_type);
expr = fold_build1 (NOP_EXPR, field_type, expr);
CONSTRUCTOR_APPEND_ELT (v, field, expr);
expr = gnat_build_constructor (rec_type, v);
expr = unchecked_convert (type, expr, notrunc_p);
}
/* If we are converting from a scalar type to a type with a different size,
we need to pad to have the same size on both sides.
??? We cannot do it unconditionally because unchecked conversions are
used liberally by the front-end to implement polymorphism, e.g. in:
S191s : constant ada__tags__addr_ptr := ada__tags__addr_ptr!(S190s);
return p___size__4 (p__object!(S191s.all));
so we skip all expressions that are references. */
else if (!REFERENCE_CLASS_P (expr)
&& !AGGREGATE_TYPE_P (etype)
&& TREE_CODE (TYPE_SIZE (type)) == INTEGER_CST
&& (c = tree_int_cst_compare (TYPE_SIZE (etype), TYPE_SIZE (type))))
{
if (c < 0)
{
expr = convert (maybe_pad_type (etype, TYPE_SIZE (type), 0, Empty,
false, false, false, true),
expr);
expr = unchecked_convert (type, expr, notrunc_p);
}
else
{
tree rec_type = maybe_pad_type (type, TYPE_SIZE (etype), 0, Empty,
false, false, false, true);
expr = unchecked_convert (rec_type, expr, notrunc_p);
expr = build_component_ref (expr, NULL_TREE, TYPE_FIELDS (rec_type),
false);
}
}
/* We have a special case when we are converting between two unconstrained
array types. In that case, take the address, convert the fat pointer
types, and dereference. */
else if (ecode == code && code == UNCONSTRAINED_ARRAY_TYPE)
expr = build_unary_op (INDIRECT_REF, NULL_TREE,
build1 (VIEW_CONVERT_EXPR, TREE_TYPE (type),
build_unary_op (ADDR_EXPR, NULL_TREE,
expr)));
/* Another special case is when we are converting to a vector type from its
representative array type; this a regular conversion. */
else if (code == VECTOR_TYPE
&& ecode == ARRAY_TYPE
&& gnat_types_compatible_p (TYPE_REPRESENTATIVE_ARRAY (type),
etype))
expr = convert (type, expr);
else
{
expr = maybe_unconstrained_array (expr);
etype = TREE_TYPE (expr);
ecode = TREE_CODE (etype);
if (can_fold_for_view_convert_p (expr))
expr = fold_build1 (VIEW_CONVERT_EXPR, type, expr);
else
expr = build1 (VIEW_CONVERT_EXPR, type, expr);
}
/* If the result is an integral type whose precision is not equal to its
size, sign- or zero-extend the result. We need not do this if the input
is an integral type of the same precision and signedness or if the output
is a biased type or if both the input and output are unsigned. */
if (!notrunc_p
&& INTEGRAL_TYPE_P (type) && TYPE_RM_SIZE (type)
&& !(code == INTEGER_TYPE && TYPE_BIASED_REPRESENTATION_P (type))
&& 0 != compare_tree_int (TYPE_RM_SIZE (type),
GET_MODE_BITSIZE (TYPE_MODE (type)))
&& !(INTEGRAL_TYPE_P (etype)
&& TYPE_UNSIGNED (type) == TYPE_UNSIGNED (etype)
&& operand_equal_p (TYPE_RM_SIZE (type),
(TYPE_RM_SIZE (etype) != 0
? TYPE_RM_SIZE (etype) : TYPE_SIZE (etype)),
0))
&& !(TYPE_UNSIGNED (type) && TYPE_UNSIGNED (etype)))
{
tree base_type
= gnat_type_for_mode (TYPE_MODE (type), TYPE_UNSIGNED (type));
tree shift_expr
= convert (base_type,
size_binop (MINUS_EXPR,
bitsize_int
(GET_MODE_BITSIZE (TYPE_MODE (type))),
TYPE_RM_SIZE (type)));
expr
= convert (type,
build_binary_op (RSHIFT_EXPR, base_type,
build_binary_op (LSHIFT_EXPR, base_type,
convert (base_type, expr),
shift_expr),
shift_expr));
}
/* An unchecked conversion should never raise Constraint_Error. The code
below assumes that GCC's conversion routines overflow the same way that
the underlying hardware does. This is probably true. In the rare case
when it is false, we can rely on the fact that such conversions are
erroneous anyway. */
if (TREE_CODE (expr) == INTEGER_CST)
TREE_OVERFLOW (expr) = 0;
/* If the sizes of the types differ and this is an VIEW_CONVERT_EXPR,
show no longer constant. */
if (TREE_CODE (expr) == VIEW_CONVERT_EXPR
&& !operand_equal_p (TYPE_SIZE_UNIT (type), TYPE_SIZE_UNIT (etype),
OEP_ONLY_CONST))
TREE_CONSTANT (expr) = 0;
return expr;
}
/* Return the appropriate GCC tree code for the specified GNAT_TYPE,
the latter being a record type as predicated by Is_Record_Type. */
enum tree_code
tree_code_for_record_type (Entity_Id gnat_type)
{
Node_Id component_list, component;
/* Return UNION_TYPE if it's an Unchecked_Union whose non-discriminant
fields are all in the variant part. Otherwise, return RECORD_TYPE. */
if (!Is_Unchecked_Union (gnat_type))
return RECORD_TYPE;
gnat_type = Implementation_Base_Type (gnat_type);
component_list
= Component_List (Type_Definition (Declaration_Node (gnat_type)));
for (component = First_Non_Pragma (Component_Items (component_list));
Present (component);
component = Next_Non_Pragma (component))
if (Ekind (Defining_Entity (component)) == E_Component)
return RECORD_TYPE;
return UNION_TYPE;
}
/* Return true if GNAT_TYPE is a "double" floating-point type, i.e. whose
size is equal to 64 bits, or an array of such a type. Set ALIGN_CLAUSE
according to the presence of an alignment clause on the type or, if it
is an array, on the component type. */
bool
is_double_float_or_array (Entity_Id gnat_type, bool *align_clause)
{
gnat_type = Underlying_Type (gnat_type);
*align_clause = Present (Alignment_Clause (gnat_type));
if (Is_Array_Type (gnat_type))
{
gnat_type = Underlying_Type (Component_Type (gnat_type));
if (Present (Alignment_Clause (gnat_type)))
*align_clause = true;
}
if (!Is_Floating_Point_Type (gnat_type))
return false;
if (UI_To_Int (Esize (gnat_type)) != 64)
return false;
return true;
}
/* Return true if GNAT_TYPE is a "double" or larger scalar type, i.e. whose
size is greater or equal to 64 bits, or an array of such a type. Set
ALIGN_CLAUSE according to the presence of an alignment clause on the
type or, if it is an array, on the component type. */
bool
is_double_scalar_or_array (Entity_Id gnat_type, bool *align_clause)
{
gnat_type = Underlying_Type (gnat_type);
*align_clause = Present (Alignment_Clause (gnat_type));
if (Is_Array_Type (gnat_type))
{
gnat_type = Underlying_Type (Component_Type (gnat_type));
if (Present (Alignment_Clause (gnat_type)))
*align_clause = true;
}
if (!Is_Scalar_Type (gnat_type))
return false;
if (UI_To_Int (Esize (gnat_type)) < 64)
return false;
return true;
}
/* Return true if GNU_TYPE is suitable as the type of a non-aliased
component of an aggregate type. */
bool
type_for_nonaliased_component_p (tree gnu_type)
{
/* If the type is passed by reference, we may have pointers to the
component so it cannot be made non-aliased. */
if (must_pass_by_ref (gnu_type) || default_pass_by_ref (gnu_type))
return false;
/* We used to say that any component of aggregate type is aliased
because the front-end may take 'Reference of it. The front-end
has been enhanced in the meantime so as to use a renaming instead
in most cases, but the back-end can probably take the address of
such a component too so we go for the conservative stance.
For instance, we might need the address of any array type, even
if normally passed by copy, to construct a fat pointer if the
component is used as an actual for an unconstrained formal.
Likewise for record types: even if a specific record subtype is
passed by copy, the parent type might be passed by ref (e.g. if
it's of variable size) and we might take the address of a child
component to pass to a parent formal. We have no way to check
for such conditions here. */
if (AGGREGATE_TYPE_P (gnu_type))
return false;
return true;
}
/* Return true if TYPE is a smaller form of ORIG_TYPE. */
bool
smaller_form_type_p (tree type, tree orig_type)
{
tree size, osize;
/* We're not interested in variants here. */
if (TYPE_MAIN_VARIANT (type) == TYPE_MAIN_VARIANT (orig_type))
return false;
/* Like a variant, a packable version keeps the original TYPE_NAME. */
if (TYPE_NAME (type) != TYPE_NAME (orig_type))
return false;
size = TYPE_SIZE (type);
osize = TYPE_SIZE (orig_type);
if (!(TREE_CODE (size) == INTEGER_CST && TREE_CODE (osize) == INTEGER_CST))
return false;
return tree_int_cst_lt (size, osize) != 0;
}
/* Perform final processing on global variables. */
static GTY (()) tree dummy_global;
void
gnat_write_global_declarations (void)
{
unsigned int i;
tree iter;
/* If we have declared types as used at the global level, insert them in
the global hash table. We use a dummy variable for this purpose. */
if (!VEC_empty (tree, types_used_by_cur_var_decl))
{
struct varpool_node *node;
char *label;
ASM_FORMAT_PRIVATE_NAME (label, first_global_object_name, 0);
dummy_global
= build_decl (BUILTINS_LOCATION, VAR_DECL, get_identifier (label),
void_type_node);
TREE_STATIC (dummy_global) = 1;
TREE_ASM_WRITTEN (dummy_global) = 1;
node = varpool_node (dummy_global);
node->symbol.force_output = 1;
while (!VEC_empty (tree, types_used_by_cur_var_decl))
{
tree t = VEC_pop (tree, types_used_by_cur_var_decl);
types_used_by_var_decl_insert (t, dummy_global);
}
}
/* Output debug information for all global type declarations first. This
ensures that global types whose compilation hasn't been finalized yet,
for example pointers to Taft amendment types, have their compilation
finalized in the right context. */
FOR_EACH_VEC_ELT (tree, global_decls, i, iter)
if (TREE_CODE (iter) == TYPE_DECL)
debug_hooks->global_decl (iter);
/* Proceed to optimize and emit assembly. */
finalize_compilation_unit ();
/* After cgraph has had a chance to emit everything that's going to
be emitted, output debug information for the rest of globals. */
if (!seen_error ())
{
timevar_push (TV_SYMOUT);
FOR_EACH_VEC_ELT (tree, global_decls, i, iter)
if (TREE_CODE (iter) != TYPE_DECL)
debug_hooks->global_decl (iter);
timevar_pop (TV_SYMOUT);
}
}
/* ************************************************************************
* * GCC builtins support *
* ************************************************************************ */
/* The general scheme is fairly simple:
For each builtin function/type to be declared, gnat_install_builtins calls
internal facilities which eventually get to gnat_push_decl, which in turn
tracks the so declared builtin function decls in the 'builtin_decls' global
datastructure. When an Intrinsic subprogram declaration is processed, we
search this global datastructure to retrieve the associated BUILT_IN DECL
node. */
/* Search the chain of currently available builtin declarations for a node
corresponding to function NAME (an IDENTIFIER_NODE). Return the first node
found, if any, or NULL_TREE otherwise. */
tree
builtin_decl_for (tree name)
{
unsigned i;
tree decl;
FOR_EACH_VEC_ELT (tree, builtin_decls, i, decl)
if (DECL_NAME (decl) == name)
return decl;
return NULL_TREE;
}
/* The code below eventually exposes gnat_install_builtins, which declares
the builtin types and functions we might need, either internally or as
user accessible facilities.
??? This is a first implementation shot, still in rough shape. It is
heavily inspired from the "C" family implementation, with chunks copied
verbatim from there.
Two obvious TODO candidates are
o Use a more efficient name/decl mapping scheme
o Devise a middle-end infrastructure to avoid having to copy
pieces between front-ends. */
/* ----------------------------------------------------------------------- *
* BUILTIN ELEMENTARY TYPES *
* ----------------------------------------------------------------------- */
/* Standard data types to be used in builtin argument declarations. */
enum c_tree_index
{
CTI_SIGNED_SIZE_TYPE, /* For format checking only. */
CTI_STRING_TYPE,
CTI_CONST_STRING_TYPE,
CTI_MAX
};
static tree c_global_trees[CTI_MAX];
#define signed_size_type_node c_global_trees[CTI_SIGNED_SIZE_TYPE]
#define string_type_node c_global_trees[CTI_STRING_TYPE]
#define const_string_type_node c_global_trees[CTI_CONST_STRING_TYPE]
/* ??? In addition some attribute handlers, we currently don't support a
(small) number of builtin-types, which in turns inhibits support for a
number of builtin functions. */
#define wint_type_node void_type_node
#define intmax_type_node void_type_node
#define uintmax_type_node void_type_node
/* Build the void_list_node (void_type_node having been created). */
static tree
build_void_list_node (void)
{
tree t = build_tree_list (NULL_TREE, void_type_node);
return t;
}
/* Used to help initialize the builtin-types.def table. When a type of
the correct size doesn't exist, use error_mark_node instead of NULL.
The later results in segfaults even when a decl using the type doesn't
get invoked. */
static tree
builtin_type_for_size (int size, bool unsignedp)
{
tree type = gnat_type_for_size (size, unsignedp);
return type ? type : error_mark_node;
}
/* Build/push the elementary type decls that builtin functions/types
will need. */
static void
install_builtin_elementary_types (void)
{
signed_size_type_node = gnat_signed_type (size_type_node);
pid_type_node = integer_type_node;
void_list_node = build_void_list_node ();
string_type_node = build_pointer_type (char_type_node);
const_string_type_node
= build_pointer_type (build_qualified_type
(char_type_node, TYPE_QUAL_CONST));
}
/* ----------------------------------------------------------------------- *
* BUILTIN FUNCTION TYPES *
* ----------------------------------------------------------------------- */
/* Now, builtin function types per se. */
enum c_builtin_type
{
#define DEF_PRIMITIVE_TYPE(NAME, VALUE) NAME,
#define DEF_FUNCTION_TYPE_0(NAME, RETURN) NAME,
#define DEF_FUNCTION_TYPE_1(NAME, RETURN, ARG1) NAME,
#define DEF_FUNCTION_TYPE_2(NAME, RETURN, ARG1, ARG2) NAME,
#define DEF_FUNCTION_TYPE_3(NAME, RETURN, ARG1, ARG2, ARG3) NAME,
#define DEF_FUNCTION_TYPE_4(NAME, RETURN, ARG1, ARG2, ARG3, ARG4) NAME,
#define DEF_FUNCTION_TYPE_5(NAME, RETURN, ARG1, ARG2, ARG3, ARG4, ARG5) NAME,
#define DEF_FUNCTION_TYPE_6(NAME, RETURN, ARG1, ARG2, ARG3, ARG4, ARG5, ARG6) NAME,
#define DEF_FUNCTION_TYPE_7(NAME, RETURN, ARG1, ARG2, ARG3, ARG4, ARG5, ARG6, ARG7) NAME,
#define DEF_FUNCTION_TYPE_VAR_0(NAME, RETURN) NAME,
#define DEF_FUNCTION_TYPE_VAR_1(NAME, RETURN, ARG1) NAME,
#define DEF_FUNCTION_TYPE_VAR_2(NAME, RETURN, ARG1, ARG2) NAME,
#define DEF_FUNCTION_TYPE_VAR_3(NAME, RETURN, ARG1, ARG2, ARG3) NAME,
#define DEF_FUNCTION_TYPE_VAR_4(NAME, RETURN, ARG1, ARG2, ARG3, ARG4) NAME,
#define DEF_FUNCTION_TYPE_VAR_5(NAME, RETURN, ARG1, ARG2, ARG3, ARG4, ARG6) \
NAME,
#define DEF_POINTER_TYPE(NAME, TYPE) NAME,
#include "builtin-types.def"
#undef DEF_PRIMITIVE_TYPE
#undef DEF_FUNCTION_TYPE_0
#undef DEF_FUNCTION_TYPE_1
#undef DEF_FUNCTION_TYPE_2
#undef DEF_FUNCTION_TYPE_3
#undef DEF_FUNCTION_TYPE_4
#undef DEF_FUNCTION_TYPE_5
#undef DEF_FUNCTION_TYPE_6
#undef DEF_FUNCTION_TYPE_7
#undef DEF_FUNCTION_TYPE_VAR_0
#undef DEF_FUNCTION_TYPE_VAR_1
#undef DEF_FUNCTION_TYPE_VAR_2
#undef DEF_FUNCTION_TYPE_VAR_3
#undef DEF_FUNCTION_TYPE_VAR_4
#undef DEF_FUNCTION_TYPE_VAR_5
#undef DEF_POINTER_TYPE
BT_LAST
};
typedef enum c_builtin_type builtin_type;
/* A temporary array used in communication with def_fn_type. */
static GTY(()) tree builtin_types[(int) BT_LAST + 1];
/* A helper function for install_builtin_types. Build function type
for DEF with return type RET and N arguments. If VAR is true, then the
function should be variadic after those N arguments.
Takes special care not to ICE if any of the types involved are
error_mark_node, which indicates that said type is not in fact available
(see builtin_type_for_size). In which case the function type as a whole
should be error_mark_node. */
static void
def_fn_type (builtin_type def, builtin_type ret, bool var, int n, ...)
{
tree t;
tree *args = XALLOCAVEC (tree, n);
va_list list;
int i;
va_start (list, n);
for (i = 0; i < n; ++i)
{
builtin_type a = (builtin_type) va_arg (list, int);
t = builtin_types[a];
if (t == error_mark_node)
goto egress;
args[i] = t;
}
t = builtin_types[ret];
if (t == error_mark_node)
goto egress;
if (var)
t = build_varargs_function_type_array (t, n, args);
else
t = build_function_type_array (t, n, args);
egress:
builtin_types[def] = t;
va_end (list);
}
/* Build the builtin function types and install them in the builtin_types
array for later use in builtin function decls. */
static void
install_builtin_function_types (void)
{
tree va_list_ref_type_node;
tree va_list_arg_type_node;
if (TREE_CODE (va_list_type_node) == ARRAY_TYPE)
{
va_list_arg_type_node = va_list_ref_type_node =
build_pointer_type (TREE_TYPE (va_list_type_node));
}
else
{
va_list_arg_type_node = va_list_type_node;
va_list_ref_type_node = build_reference_type (va_list_type_node);
}
#define DEF_PRIMITIVE_TYPE(ENUM, VALUE) \
builtin_types[ENUM] = VALUE;
#define DEF_FUNCTION_TYPE_0(ENUM, RETURN) \
def_fn_type (ENUM, RETURN, 0, 0);
#define DEF_FUNCTION_TYPE_1(ENUM, RETURN, ARG1) \
def_fn_type (ENUM, RETURN, 0, 1, ARG1);
#define DEF_FUNCTION_TYPE_2(ENUM, RETURN, ARG1, ARG2) \
def_fn_type (ENUM, RETURN, 0, 2, ARG1, ARG2);
#define DEF_FUNCTION_TYPE_3(ENUM, RETURN, ARG1, ARG2, ARG3) \
def_fn_type (ENUM, RETURN, 0, 3, ARG1, ARG2, ARG3);
#define DEF_FUNCTION_TYPE_4(ENUM, RETURN, ARG1, ARG2, ARG3, ARG4) \
def_fn_type (ENUM, RETURN, 0, 4, ARG1, ARG2, ARG3, ARG4);
#define DEF_FUNCTION_TYPE_5(ENUM, RETURN, ARG1, ARG2, ARG3, ARG4, ARG5) \
def_fn_type (ENUM, RETURN, 0, 5, ARG1, ARG2, ARG3, ARG4, ARG5);
#define DEF_FUNCTION_TYPE_6(ENUM, RETURN, ARG1, ARG2, ARG3, ARG4, ARG5, \
ARG6) \
def_fn_type (ENUM, RETURN, 0, 6, ARG1, ARG2, ARG3, ARG4, ARG5, ARG6);
#define DEF_FUNCTION_TYPE_7(ENUM, RETURN, ARG1, ARG2, ARG3, ARG4, ARG5, \
ARG6, ARG7) \
def_fn_type (ENUM, RETURN, 0, 7, ARG1, ARG2, ARG3, ARG4, ARG5, ARG6, ARG7);
#define DEF_FUNCTION_TYPE_VAR_0(ENUM, RETURN) \
def_fn_type (ENUM, RETURN, 1, 0);
#define DEF_FUNCTION_TYPE_VAR_1(ENUM, RETURN, ARG1) \
def_fn_type (ENUM, RETURN, 1, 1, ARG1);
#define DEF_FUNCTION_TYPE_VAR_2(ENUM, RETURN, ARG1, ARG2) \
def_fn_type (ENUM, RETURN, 1, 2, ARG1, ARG2);
#define DEF_FUNCTION_TYPE_VAR_3(ENUM, RETURN, ARG1, ARG2, ARG3) \
def_fn_type (ENUM, RETURN, 1, 3, ARG1, ARG2, ARG3);
#define DEF_FUNCTION_TYPE_VAR_4(ENUM, RETURN, ARG1, ARG2, ARG3, ARG4) \
def_fn_type (ENUM, RETURN, 1, 4, ARG1, ARG2, ARG3, ARG4);
#define DEF_FUNCTION_TYPE_VAR_5(ENUM, RETURN, ARG1, ARG2, ARG3, ARG4, ARG5) \
def_fn_type (ENUM, RETURN, 1, 5, ARG1, ARG2, ARG3, ARG4, ARG5);
#define DEF_POINTER_TYPE(ENUM, TYPE) \
builtin_types[(int) ENUM] = build_pointer_type (builtin_types[(int) TYPE]);
#include "builtin-types.def"
#undef DEF_PRIMITIVE_TYPE
#undef DEF_FUNCTION_TYPE_1
#undef DEF_FUNCTION_TYPE_2
#undef DEF_FUNCTION_TYPE_3
#undef DEF_FUNCTION_TYPE_4
#undef DEF_FUNCTION_TYPE_5
#undef DEF_FUNCTION_TYPE_6
#undef DEF_FUNCTION_TYPE_VAR_0
#undef DEF_FUNCTION_TYPE_VAR_1
#undef DEF_FUNCTION_TYPE_VAR_2
#undef DEF_FUNCTION_TYPE_VAR_3
#undef DEF_FUNCTION_TYPE_VAR_4
#undef DEF_FUNCTION_TYPE_VAR_5
#undef DEF_POINTER_TYPE
builtin_types[(int) BT_LAST] = NULL_TREE;
}
/* ----------------------------------------------------------------------- *
* BUILTIN ATTRIBUTES *
* ----------------------------------------------------------------------- */
enum built_in_attribute
{
#define DEF_ATTR_NULL_TREE(ENUM) ENUM,
#define DEF_ATTR_INT(ENUM, VALUE) ENUM,
#define DEF_ATTR_STRING(ENUM, VALUE) ENUM,
#define DEF_ATTR_IDENT(ENUM, STRING) ENUM,
#define DEF_ATTR_TREE_LIST(ENUM, PURPOSE, VALUE, CHAIN) ENUM,
#include "builtin-attrs.def"
#undef DEF_ATTR_NULL_TREE
#undef DEF_ATTR_INT
#undef DEF_ATTR_STRING
#undef DEF_ATTR_IDENT
#undef DEF_ATTR_TREE_LIST
ATTR_LAST
};
static GTY(()) tree built_in_attributes[(int) ATTR_LAST];
static void
install_builtin_attributes (void)
{
/* Fill in the built_in_attributes array. */
#define DEF_ATTR_NULL_TREE(ENUM) \
built_in_attributes[(int) ENUM] = NULL_TREE;
#define DEF_ATTR_INT(ENUM, VALUE) \
built_in_attributes[(int) ENUM] = build_int_cst (NULL_TREE, VALUE);
#define DEF_ATTR_STRING(ENUM, VALUE) \
built_in_attributes[(int) ENUM] = build_string (strlen (VALUE), VALUE);
#define DEF_ATTR_IDENT(ENUM, STRING) \
built_in_attributes[(int) ENUM] = get_identifier (STRING);
#define DEF_ATTR_TREE_LIST(ENUM, PURPOSE, VALUE, CHAIN) \
built_in_attributes[(int) ENUM] \
= tree_cons (built_in_attributes[(int) PURPOSE], \
built_in_attributes[(int) VALUE], \
built_in_attributes[(int) CHAIN]);
#include "builtin-attrs.def"
#undef DEF_ATTR_NULL_TREE
#undef DEF_ATTR_INT
#undef DEF_ATTR_STRING
#undef DEF_ATTR_IDENT
#undef DEF_ATTR_TREE_LIST
}
/* Handle a "const" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_const_attribute (tree *node, tree ARG_UNUSED (name),
tree ARG_UNUSED (args), int ARG_UNUSED (flags),
bool *no_add_attrs)
{
if (TREE_CODE (*node) == FUNCTION_DECL)
TREE_READONLY (*node) = 1;
else
*no_add_attrs = true;
return NULL_TREE;
}
/* Handle a "nothrow" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_nothrow_attribute (tree *node, tree ARG_UNUSED (name),
tree ARG_UNUSED (args), int ARG_UNUSED (flags),
bool *no_add_attrs)
{
if (TREE_CODE (*node) == FUNCTION_DECL)
TREE_NOTHROW (*node) = 1;
else
*no_add_attrs = true;
return NULL_TREE;
}
/* Handle a "pure" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_pure_attribute (tree *node, tree name, tree ARG_UNUSED (args),
int ARG_UNUSED (flags), bool *no_add_attrs)
{
if (TREE_CODE (*node) == FUNCTION_DECL)
DECL_PURE_P (*node) = 1;
/* ??? TODO: Support types. */
else
{
warning (OPT_Wattributes, "%qs attribute ignored",
IDENTIFIER_POINTER (name));
*no_add_attrs = true;
}
return NULL_TREE;
}
/* Handle a "no vops" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_novops_attribute (tree *node, tree ARG_UNUSED (name),
tree ARG_UNUSED (args), int ARG_UNUSED (flags),
bool *ARG_UNUSED (no_add_attrs))
{
gcc_assert (TREE_CODE (*node) == FUNCTION_DECL);
DECL_IS_NOVOPS (*node) = 1;
return NULL_TREE;
}
/* Helper for nonnull attribute handling; fetch the operand number
from the attribute argument list. */
static bool
get_nonnull_operand (tree arg_num_expr, unsigned HOST_WIDE_INT *valp)
{
/* Verify the arg number is a constant. */
if (TREE_CODE (arg_num_expr) != INTEGER_CST
|| TREE_INT_CST_HIGH (arg_num_expr) != 0)
return false;
*valp = TREE_INT_CST_LOW (arg_num_expr);
return true;
}
/* Handle the "nonnull" attribute. */
static tree
handle_nonnull_attribute (tree *node, tree ARG_UNUSED (name),
tree args, int ARG_UNUSED (flags),
bool *no_add_attrs)
{
tree type = *node;
unsigned HOST_WIDE_INT attr_arg_num;
/* If no arguments are specified, all pointer arguments should be
non-null. Verify a full prototype is given so that the arguments
will have the correct types when we actually check them later. */
if (!args)
{
if (!prototype_p (type))
{
error ("nonnull attribute without arguments on a non-prototype");
*no_add_attrs = true;
}
return NULL_TREE;
}
/* Argument list specified. Verify that each argument number references
a pointer argument. */
for (attr_arg_num = 1; args; args = TREE_CHAIN (args))
{
unsigned HOST_WIDE_INT arg_num = 0, ck_num;
if (!get_nonnull_operand (TREE_VALUE (args), &arg_num))
{
error ("nonnull argument has invalid operand number (argument %lu)",
(unsigned long) attr_arg_num);
*no_add_attrs = true;
return NULL_TREE;
}
if (prototype_p (type))
{
function_args_iterator iter;
tree argument;
function_args_iter_init (&iter, type);
for (ck_num = 1; ; ck_num++, function_args_iter_next (&iter))
{
argument = function_args_iter_cond (&iter);
if (!argument || ck_num == arg_num)
break;
}
if (!argument
|| TREE_CODE (argument) == VOID_TYPE)
{
error ("nonnull argument with out-of-range operand number "
"(argument %lu, operand %lu)",
(unsigned long) attr_arg_num, (unsigned long) arg_num);
*no_add_attrs = true;
return NULL_TREE;
}
if (TREE_CODE (argument) != POINTER_TYPE)
{
error ("nonnull argument references non-pointer operand "
"(argument %lu, operand %lu)",
(unsigned long) attr_arg_num, (unsigned long) arg_num);
*no_add_attrs = true;
return NULL_TREE;
}
}
}
return NULL_TREE;
}
/* Handle a "sentinel" attribute. */
static tree
handle_sentinel_attribute (tree *node, tree name, tree args,
int ARG_UNUSED (flags), bool *no_add_attrs)
{
if (!prototype_p (*node))
{
warning (OPT_Wattributes,
"%qs attribute requires prototypes with named arguments",
IDENTIFIER_POINTER (name));
*no_add_attrs = true;
}
else
{
if (!stdarg_p (*node))
{
warning (OPT_Wattributes,
"%qs attribute only applies to variadic functions",
IDENTIFIER_POINTER (name));
*no_add_attrs = true;
}
}
if (args)
{
tree position = TREE_VALUE (args);
if (TREE_CODE (position) != INTEGER_CST)
{
warning (0, "requested position is not an integer constant");
*no_add_attrs = true;
}
else
{
if (tree_int_cst_lt (position, integer_zero_node))
{
warning (0, "requested position is less than zero");
*no_add_attrs = true;
}
}
}
return NULL_TREE;
}
/* Handle a "noreturn" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_noreturn_attribute (tree *node, tree name, tree ARG_UNUSED (args),
int ARG_UNUSED (flags), bool *no_add_attrs)
{
tree type = TREE_TYPE (*node);
/* See FIXME comment in c_common_attribute_table. */
if (TREE_CODE (*node) == FUNCTION_DECL)
TREE_THIS_VOLATILE (*node) = 1;
else if (TREE_CODE (type) == POINTER_TYPE
&& TREE_CODE (TREE_TYPE (type)) == FUNCTION_TYPE)
TREE_TYPE (*node)
= build_pointer_type
(build_type_variant (TREE_TYPE (type),
TYPE_READONLY (TREE_TYPE (type)), 1));
else
{
warning (OPT_Wattributes, "%qs attribute ignored",
IDENTIFIER_POINTER (name));
*no_add_attrs = true;
}
return NULL_TREE;
}
/* Handle a "leaf" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_leaf_attribute (tree *node, tree name,
tree ARG_UNUSED (args),
int ARG_UNUSED (flags), bool *no_add_attrs)
{
if (TREE_CODE (*node) != FUNCTION_DECL)
{
warning (OPT_Wattributes, "%qE attribute ignored", name);
*no_add_attrs = true;
}
if (!TREE_PUBLIC (*node))
{
warning (OPT_Wattributes, "%qE attribute has no effect", name);
*no_add_attrs = true;
}
return NULL_TREE;
}
/* Handle a "malloc" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_malloc_attribute (tree *node, tree name, tree ARG_UNUSED (args),
int ARG_UNUSED (flags), bool *no_add_attrs)
{
if (TREE_CODE (*node) == FUNCTION_DECL
&& POINTER_TYPE_P (TREE_TYPE (TREE_TYPE (*node))))
DECL_IS_MALLOC (*node) = 1;
else
{
warning (OPT_Wattributes, "%qs attribute ignored",
IDENTIFIER_POINTER (name));
*no_add_attrs = true;
}
return NULL_TREE;
}
/* Fake handler for attributes we don't properly support. */
tree
fake_attribute_handler (tree * ARG_UNUSED (node),
tree ARG_UNUSED (name),
tree ARG_UNUSED (args),
int ARG_UNUSED (flags),
bool * ARG_UNUSED (no_add_attrs))
{
return NULL_TREE;
}
/* Handle a "type_generic" attribute. */
static tree
handle_type_generic_attribute (tree *node, tree ARG_UNUSED (name),
tree ARG_UNUSED (args), int ARG_UNUSED (flags),
bool * ARG_UNUSED (no_add_attrs))
{
/* Ensure we have a function type. */
gcc_assert (TREE_CODE (*node) == FUNCTION_TYPE);
/* Ensure we have a variadic function. */
gcc_assert (!prototype_p (*node) || stdarg_p (*node));
return NULL_TREE;
}
/* Handle a "vector_size" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_vector_size_attribute (tree *node, tree name, tree args,
int ARG_UNUSED (flags),
bool *no_add_attrs)
{
unsigned HOST_WIDE_INT vecsize, nunits;
enum machine_mode orig_mode;
tree type = *node, new_type, size;
*no_add_attrs = true;
size = TREE_VALUE (args);
if (!host_integerp (size, 1))
{
warning (OPT_Wattributes, "%qs attribute ignored",
IDENTIFIER_POINTER (name));
return NULL_TREE;
}
/* Get the vector size (in bytes). */
vecsize = tree_low_cst (size, 1);
/* We need to provide for vector pointers, vector arrays, and
functions returning vectors. For example:
__attribute__((vector_size(16))) short *foo;
In this case, the mode is SI, but the type being modified is
HI, so we need to look further. */
while (POINTER_TYPE_P (type)
|| TREE_CODE (type) == FUNCTION_TYPE
|| TREE_CODE (type) == ARRAY_TYPE)
type = TREE_TYPE (type);
/* Get the mode of the type being modified. */
orig_mode = TYPE_MODE (type);
if ((!INTEGRAL_TYPE_P (type)
&& !SCALAR_FLOAT_TYPE_P (type)
&& !FIXED_POINT_TYPE_P (type))
|| (!SCALAR_FLOAT_MODE_P (orig_mode)
&& GET_MODE_CLASS (orig_mode) != MODE_INT
&& !ALL_SCALAR_FIXED_POINT_MODE_P (orig_mode))
|| !host_integerp (TYPE_SIZE_UNIT (type), 1)
|| TREE_CODE (type) == BOOLEAN_TYPE)
{
error ("invalid vector type for attribute %qs",
IDENTIFIER_POINTER (name));
return NULL_TREE;
}
if (vecsize % tree_low_cst (TYPE_SIZE_UNIT (type), 1))
{
error ("vector size not an integral multiple of component size");
return NULL;
}
if (vecsize == 0)
{
error ("zero vector size");
return NULL;
}
/* Calculate how many units fit in the vector. */
nunits = vecsize / tree_low_cst (TYPE_SIZE_UNIT (type), 1);
if (nunits & (nunits - 1))
{
error ("number of components of the vector not a power of two");
return NULL_TREE;
}
new_type = build_vector_type (type, nunits);
/* Build back pointers if needed. */
*node = reconstruct_complex_type (*node, new_type);
return NULL_TREE;
}
/* Handle a "vector_type" attribute; arguments as in
struct attribute_spec.handler. */
static tree
handle_vector_type_attribute (tree *node, tree name, tree ARG_UNUSED (args),
int ARG_UNUSED (flags),
bool *no_add_attrs)
{
/* Vector representative type and size. */
tree rep_type = *node;
tree rep_size = TYPE_SIZE_UNIT (rep_type);
tree rep_name;
/* Vector size in bytes and number of units. */
unsigned HOST_WIDE_INT vec_bytes, vec_units;
/* Vector element type and mode. */
tree elem_type;
enum machine_mode elem_mode;
*no_add_attrs = true;
/* Get the representative array type, possibly nested within a
padding record e.g. for alignment purposes. */
if (TYPE_IS_PADDING_P (rep_type))
rep_type = TREE_TYPE (TYPE_FIELDS (rep_type));
if (TREE_CODE (rep_type) != ARRAY_TYPE)
{
error ("attribute %qs applies to array types only",
IDENTIFIER_POINTER (name));
return NULL_TREE;
}
/* Silently punt on variable sizes. We can't make vector types for them,
need to ignore them on front-end generated subtypes of unconstrained
bases, and this attribute is for binding implementors, not end-users, so
we should never get there from legitimate explicit uses. */
if (!host_integerp (rep_size, 1))
return NULL_TREE;
/* Get the element type/mode and check this is something we know
how to make vectors of. */
elem_type = TREE_TYPE (rep_type);
elem_mode = TYPE_MODE (elem_type);
if ((!INTEGRAL_TYPE_P (elem_type)
&& !SCALAR_FLOAT_TYPE_P (elem_type)
&& !FIXED_POINT_TYPE_P (elem_type))
|| (!SCALAR_FLOAT_MODE_P (elem_mode)
&& GET_MODE_CLASS (elem_mode) != MODE_INT
&& !ALL_SCALAR_FIXED_POINT_MODE_P (elem_mode))
|| !host_integerp (TYPE_SIZE_UNIT (elem_type), 1))
{
error ("invalid element type for attribute %qs",
IDENTIFIER_POINTER (name));
return NULL_TREE;
}
/* Sanity check the vector size and element type consistency. */
vec_bytes = tree_low_cst (rep_size, 1);
if (vec_bytes % tree_low_cst (TYPE_SIZE_UNIT (elem_type), 1))
{
error ("vector size not an integral multiple of component size");
return NULL;
}
if (vec_bytes == 0)
{
error ("zero vector size");
return NULL;
}
vec_units = vec_bytes / tree_low_cst (TYPE_SIZE_UNIT (elem_type), 1);
if (vec_units & (vec_units - 1))
{
error ("number of components of the vector not a power of two");
return NULL_TREE;
}
/* Build the vector type and replace. */
*node = build_vector_type (elem_type, vec_units);
rep_name = TYPE_NAME (rep_type);
if (TREE_CODE (rep_name) == TYPE_DECL)
rep_name = DECL_NAME (rep_name);
TYPE_NAME (*node) = rep_name;
TYPE_REPRESENTATIVE_ARRAY (*node) = rep_type;
return NULL_TREE;
}
/* ----------------------------------------------------------------------- *
* BUILTIN FUNCTIONS *
* ----------------------------------------------------------------------- */
/* Worker for DEF_BUILTIN. Possibly define a builtin function with one or two
names. Does not declare a non-__builtin_ function if flag_no_builtin, or
if nonansi_p and flag_no_nonansi_builtin. */
static void
def_builtin_1 (enum built_in_function fncode,
const char *name,
enum built_in_class fnclass,
tree fntype, tree libtype,
bool both_p, bool fallback_p,
bool nonansi_p ATTRIBUTE_UNUSED,
tree fnattrs, bool implicit_p)
{
tree decl;
const char *libname;
/* Preserve an already installed decl. It most likely was setup in advance
(e.g. as part of the internal builtins) for specific reasons. */
if (builtin_decl_explicit (fncode) != NULL_TREE)
return;
gcc_assert ((!both_p && !fallback_p)
|| !strncmp (name, "__builtin_",
strlen ("__builtin_")));
libname = name + strlen ("__builtin_");
decl = add_builtin_function (name, fntype, fncode, fnclass,
(fallback_p ? libname : NULL),
fnattrs);
if (both_p)
/* ??? This is normally further controlled by command-line options
like -fno-builtin, but we don't have them for Ada. */
add_builtin_function (libname, libtype, fncode, fnclass,
NULL, fnattrs);
set_builtin_decl (fncode, decl, implicit_p);
}
static int flag_isoc94 = 0;
static int flag_isoc99 = 0;
/* Install what the common builtins.def offers. */
static void
install_builtin_functions (void)
{
#define DEF_BUILTIN(ENUM, NAME, CLASS, TYPE, LIBTYPE, BOTH_P, FALLBACK_P, \
NONANSI_P, ATTRS, IMPLICIT, COND) \
if (NAME && COND) \
def_builtin_1 (ENUM, NAME, CLASS, \
builtin_types[(int) TYPE], \
builtin_types[(int) LIBTYPE], \
BOTH_P, FALLBACK_P, NONANSI_P, \
built_in_attributes[(int) ATTRS], IMPLICIT);
#include "builtins.def"
#undef DEF_BUILTIN
}
/* ----------------------------------------------------------------------- *
* BUILTIN FUNCTIONS *
* ----------------------------------------------------------------------- */
/* Install the builtin functions we might need. */
void
gnat_install_builtins (void)
{
install_builtin_elementary_types ();
install_builtin_function_types ();
install_builtin_attributes ();
/* Install builtins used by generic middle-end pieces first. Some of these
know about internal specificities and control attributes accordingly, for
instance __builtin_alloca vs no-throw and -fstack-check. We will ignore
the generic definition from builtins.def. */
build_common_builtin_nodes ();
/* Now, install the target specific builtins, such as the AltiVec family on
ppc, and the common set as exposed by builtins.def. */
targetm.init_builtins ();
install_builtin_functions ();
}
#include "gt-ada-utils.h"
#include "gtype-ada.h"
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