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freebsd-nq/contrib/gcc/tree.h
David E. O'Brien 45fc31f8dd Gcc 3.2.1 release virgin vendor import. (19-Nov-2002)
2002-12-04 15:42:16 +00:00

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/* Front-end tree definitions for GNU compiler.
Copyright (C) 1989, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
2001, 2002 Free Software Foundation, Inc.
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free
Software Foundation; either version 2, or (at your option) any later
version.
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING. If not, write to the Free
Software Foundation, 59 Temple Place - Suite 330, Boston, MA
02111-1307, USA. */
#include "machmode.h"
#include "version.h"
/* Codes of tree nodes */
#define DEFTREECODE(SYM, STRING, TYPE, NARGS) SYM,
enum tree_code {
#include "tree.def"
LAST_AND_UNUSED_TREE_CODE /* A convenient way to get a value for
NUM_TREE_CODE. */
};
#undef DEFTREECODE
/* Number of language-independent tree codes. */
#define NUM_TREE_CODES ((int) LAST_AND_UNUSED_TREE_CODE)
/* Indexed by enum tree_code, contains a character which is
`<' for a comparison expression, `1', for a unary arithmetic
expression, `2' for a binary arithmetic expression, `e' for
other types of expressions, `r' for a reference, `c' for a
constant, `d' for a decl, `t' for a type, `s' for a statement,
and `x' for anything else (TREE_LIST, IDENTIFIER, etc). */
#define MAX_TREE_CODES 256
extern char tree_code_type[MAX_TREE_CODES];
#define TREE_CODE_CLASS(CODE) tree_code_type[(int) (CODE)]
/* Returns non-zero iff CLASS is the tree-code class of an
expression. */
#define IS_EXPR_CODE_CLASS(CLASS) \
((CLASS) == '<' || (CLASS) == '1' || (CLASS) == '2' || (CLASS) == 'e')
/* Number of argument-words in each kind of tree-node. */
extern int tree_code_length[MAX_TREE_CODES];
#define TREE_CODE_LENGTH(CODE) tree_code_length[(int) (CODE)]
/* Names of tree components. */
extern const char *tree_code_name[MAX_TREE_CODES];
/* Classify which part of the compiler has defined a given builtin function.
Note that we assume below that this is no more than two bits. */
enum built_in_class
{
NOT_BUILT_IN = 0,
BUILT_IN_FRONTEND,
BUILT_IN_MD,
BUILT_IN_NORMAL
};
/* Names for the above. */
extern const char *const built_in_class_names[4];
/* Codes that identify the various built in functions
so that expand_call can identify them quickly. */
#define DEF_BUILTIN(ENUM, N, C, T, LT, B, F, NA) ENUM,
enum built_in_function
{
#include "builtins.def"
/* Upper bound on non-language-specific builtins. */
END_BUILTINS
};
#undef DEF_BUILTIN
/* Names for the above. */
extern const char *const built_in_names[(int) END_BUILTINS];
/* An array of _DECL trees for the above. */
extern tree built_in_decls[(int) END_BUILTINS];
/* The definition of tree nodes fills the next several pages. */
/* A tree node can represent a data type, a variable, an expression
or a statement. Each node has a TREE_CODE which says what kind of
thing it represents. Some common codes are:
INTEGER_TYPE -- represents a type of integers.
ARRAY_TYPE -- represents a type of pointer.
VAR_DECL -- represents a declared variable.
INTEGER_CST -- represents a constant integer value.
PLUS_EXPR -- represents a sum (an expression).
As for the contents of a tree node: there are some fields
that all nodes share. Each TREE_CODE has various special-purpose
fields as well. The fields of a node are never accessed directly,
always through accessor macros. */
/* Every kind of tree node starts with this structure,
so all nodes have these fields.
See the accessor macros, defined below, for documentation of the
fields. */
struct tree_common
{
tree chain;
tree type;
ENUM_BITFIELD(tree_code) code : 8;
unsigned side_effects_flag : 1;
unsigned constant_flag : 1;
unsigned addressable_flag : 1;
unsigned volatile_flag : 1;
unsigned readonly_flag : 1;
unsigned unsigned_flag : 1;
unsigned asm_written_flag: 1;
unsigned unused_0 : 1;
unsigned used_flag : 1;
unsigned nothrow_flag : 1;
unsigned static_flag : 1;
unsigned public_flag : 1;
unsigned private_flag : 1;
unsigned protected_flag : 1;
unsigned bounded_flag : 1;
unsigned deprecated_flag : 1;
unsigned lang_flag_0 : 1;
unsigned lang_flag_1 : 1;
unsigned lang_flag_2 : 1;
unsigned lang_flag_3 : 1;
unsigned lang_flag_4 : 1;
unsigned lang_flag_5 : 1;
unsigned lang_flag_6 : 1;
unsigned unused_1 : 1;
};
/* The following table lists the uses of each of the above flags and
for which types of nodes they are defined. Note that expressions
include decls.
addressable_flag:
TREE_ADDRESSABLE in
VAR_DECL, FUNCTION_DECL, FIELD_DECL, CONSTRUCTOR, LABEL_DECL,
..._TYPE, IDENTIFIER_NODE.
In a STMT_EXPR, it means we want the result of the enclosed
expression.
static_flag:
TREE_STATIC in
VAR_DECL, FUNCTION_DECL, CONSTRUCTOR, ADDR_EXPR
TREE_NO_UNUSED_WARNING in
CONVERT_EXPR, NOP_EXPR, COMPOUND_EXPR
TREE_VIA_VIRTUAL in
TREE_LIST or TREE_VEC
TREE_CONSTANT_OVERFLOW in
INTEGER_CST, REAL_CST, COMPLEX_CST, VECTOR_CST
TREE_SYMBOL_REFERENCED in
IDENTIFIER_NODE
CLEANUP_EH_ONLY in
TARGET_EXPR, WITH_CLEANUP_EXPR, CLEANUP_STMT,
TREE_LIST elements of a block's cleanup list.
public_flag:
TREE_OVERFLOW in
INTEGER_CST, REAL_CST, COMPLEX_CST, VECTOR_CST
TREE_PUBLIC in
VAR_DECL or FUNCTION_DECL or IDENTIFIER_NODE
TREE_VIA_PUBLIC in
TREE_LIST or TREE_VEC
EXPR_WFL_EMIT_LINE_NOTE in
EXPR_WITH_FILE_LOCATION
private_flag:
TREE_VIA_PRIVATE in
TREE_LIST or TREE_VEC
TREE_PRIVATE in
..._DECL
protected_flag:
TREE_VIA_PROTECTED in
TREE_LIST
TREE_VEC
TREE_PROTECTED in
BLOCK
..._DECL
side_effects_flag:
TREE_SIDE_EFFECTS in
all expressions
volatile_flag:
TREE_THIS_VOLATILE in
all expressions
TYPE_VOLATILE in
..._TYPE
readonly_flag:
TREE_READONLY in
all expressions
TYPE_READONLY in
..._TYPE
constant_flag:
TREE_CONSTANT in
all expressions
unsigned_flag:
TREE_UNSIGNED in
INTEGER_TYPE, ENUMERAL_TYPE, FIELD_DECL
DECL_BUILT_IN_NONANSI in
FUNCTION_DECL
SAVE_EXPR_NOPLACEHOLDER in
SAVE_EXPR
asm_written_flag:
TREE_ASM_WRITTEN in
VAR_DECL, FUNCTION_DECL, RECORD_TYPE, UNION_TYPE, QUAL_UNION_TYPE
BLOCK
used_flag:
TREE_USED in
expressions, IDENTIFIER_NODE
nothrow_flag:
TREE_NOTHROW in
CALL_EXPR, FUNCTION_DECL
bounded_flag:
TREE_BOUNDED in
expressions, VAR_DECL, PARM_DECL, FIELD_DECL, FUNCTION_DECL,
IDENTIFIER_NODE
TYPE_BOUNDED in
..._TYPE
deprecated_flag:
TREE_DEPRECATED in
..._DECL
*/
/* Define accessors for the fields that all tree nodes have
(though some fields are not used for all kinds of nodes). */
/* The tree-code says what kind of node it is.
Codes are defined in tree.def. */
#define TREE_CODE(NODE) ((enum tree_code) (NODE)->common.code)
#define TREE_SET_CODE(NODE, VALUE) \
((NODE)->common.code = (ENUM_BITFIELD (tree_code)) (VALUE))
/* When checking is enabled, errors will be generated if a tree node
is accessed incorrectly. The macros abort with a fatal error. */
#if defined ENABLE_TREE_CHECKING && (GCC_VERSION >= 2007)
#define TREE_CHECK(t, code) __extension__ \
({ const tree __t = (t); \
if (TREE_CODE(__t) != (code)) \
tree_check_failed (__t, code, __FILE__, __LINE__, __FUNCTION__); \
__t; })
#define TREE_CLASS_CHECK(t, class) __extension__ \
({ const tree __t = (t); \
if (TREE_CODE_CLASS(TREE_CODE(__t)) != (class)) \
tree_class_check_failed (__t, class, __FILE__, __LINE__, \
__FUNCTION__); \
__t; })
/* These checks have to be special cased. */
#define CST_OR_CONSTRUCTOR_CHECK(t) __extension__ \
({ const tree __t = (t); \
enum tree_code const __c = TREE_CODE(__t); \
if (__c != CONSTRUCTOR && TREE_CODE_CLASS(__c) != 'c') \
tree_check_failed (__t, CONSTRUCTOR, __FILE__, __LINE__, \
__FUNCTION__); \
__t; })
#define EXPR_CHECK(t) __extension__ \
({ const tree __t = (t); \
char const __c = TREE_CODE_CLASS(TREE_CODE(__t)); \
if (__c != 'r' && __c != 's' && __c != '<' \
&& __c != '1' && __c != '2' && __c != 'e') \
tree_class_check_failed (__t, 'e', __FILE__, __LINE__, \
__FUNCTION__); \
__t; })
extern void tree_check_failed PARAMS ((const tree, enum tree_code,
const char *, int, const char *))
ATTRIBUTE_NORETURN;
extern void tree_class_check_failed PARAMS ((const tree, int,
const char *, int, const char *))
ATTRIBUTE_NORETURN;
#else /* not ENABLE_TREE_CHECKING, or not gcc */
#define TREE_CHECK(t, code) (t)
#define TREE_CLASS_CHECK(t, code) (t)
#define CST_OR_CONSTRUCTOR_CHECK(t) (t)
#define EXPR_CHECK(t) (t)
#endif
#include "tree-check.h"
#define TYPE_CHECK(tree) TREE_CLASS_CHECK (tree, 't')
#define DECL_CHECK(tree) TREE_CLASS_CHECK (tree, 'd')
#define CST_CHECK(tree) TREE_CLASS_CHECK (tree, 'c')
/* In all nodes that are expressions, this is the data type of the expression.
In POINTER_TYPE nodes, this is the type that the pointer points to.
In ARRAY_TYPE nodes, this is the type of the elements.
In VECTOR_TYPE nodes, this is the type of the elements. */
#define TREE_TYPE(NODE) ((NODE)->common.type)
/* Here is how primitive or already-canonicalized types' hash codes
are made. */
#define TYPE_HASH(TYPE) ((size_t) (TYPE) & 0777777)
/* Nodes are chained together for many purposes.
Types are chained together to record them for being output to the debugger
(see the function `chain_type').
Decls in the same scope are chained together to record the contents
of the scope.
Statement nodes for successive statements used to be chained together.
Often lists of things are represented by TREE_LIST nodes that
are chained together. */
#define TREE_CHAIN(NODE) ((NODE)->common.chain)
/* Given an expression as a tree, strip any NON_LVALUE_EXPRs and NOP_EXPRs
that don't change the machine mode. */
#define STRIP_NOPS(EXP) \
while ((TREE_CODE (EXP) == NOP_EXPR \
|| TREE_CODE (EXP) == CONVERT_EXPR \
|| TREE_CODE (EXP) == NON_LVALUE_EXPR) \
&& TREE_OPERAND (EXP, 0) != error_mark_node \
&& (TYPE_MODE (TREE_TYPE (EXP)) \
== TYPE_MODE (TREE_TYPE (TREE_OPERAND (EXP, 0))))) \
(EXP) = TREE_OPERAND (EXP, 0)
/* Like STRIP_NOPS, but don't let the signedness change either. */
#define STRIP_SIGN_NOPS(EXP) \
while ((TREE_CODE (EXP) == NOP_EXPR \
|| TREE_CODE (EXP) == CONVERT_EXPR \
|| TREE_CODE (EXP) == NON_LVALUE_EXPR) \
&& TREE_OPERAND (EXP, 0) != error_mark_node \
&& (TYPE_MODE (TREE_TYPE (EXP)) \
== TYPE_MODE (TREE_TYPE (TREE_OPERAND (EXP, 0)))) \
&& (TREE_UNSIGNED (TREE_TYPE (EXP)) \
== TREE_UNSIGNED (TREE_TYPE (TREE_OPERAND (EXP, 0))))) \
(EXP) = TREE_OPERAND (EXP, 0)
/* Like STRIP_NOPS, but don't alter the TREE_TYPE either. */
#define STRIP_TYPE_NOPS(EXP) \
while ((TREE_CODE (EXP) == NOP_EXPR \
|| TREE_CODE (EXP) == CONVERT_EXPR \
|| TREE_CODE (EXP) == NON_LVALUE_EXPR) \
&& TREE_OPERAND (EXP, 0) != error_mark_node \
&& (TREE_TYPE (EXP) \
== TREE_TYPE (TREE_OPERAND (EXP, 0)))) \
(EXP) = TREE_OPERAND (EXP, 0)
/* Nonzero if TYPE represents an integral type. Note that we do not
include COMPLEX types here. */
#define INTEGRAL_TYPE_P(TYPE) \
(TREE_CODE (TYPE) == INTEGER_TYPE || TREE_CODE (TYPE) == ENUMERAL_TYPE \
|| TREE_CODE (TYPE) == BOOLEAN_TYPE || TREE_CODE (TYPE) == CHAR_TYPE)
/* Nonzero if TYPE represents a floating-point type, including complex
floating-point types. */
#define FLOAT_TYPE_P(TYPE) \
(TREE_CODE (TYPE) == REAL_TYPE \
|| (TREE_CODE (TYPE) == COMPLEX_TYPE \
&& TREE_CODE (TREE_TYPE (TYPE)) == REAL_TYPE))
/* Nonzero if TYPE represents an aggregate (multi-component) type. */
#define AGGREGATE_TYPE_P(TYPE) \
(TREE_CODE (TYPE) == ARRAY_TYPE || TREE_CODE (TYPE) == RECORD_TYPE \
|| TREE_CODE (TYPE) == UNION_TYPE || TREE_CODE (TYPE) == QUAL_UNION_TYPE \
|| TREE_CODE (TYPE) == SET_TYPE)
/* Nonzero if TYPE represents an unbounded pointer or unbounded
reference type. (It should be renamed to INDIRECT_TYPE_P.) */
#define POINTER_TYPE_P(TYPE) \
(TREE_CODE (TYPE) == POINTER_TYPE || TREE_CODE (TYPE) == REFERENCE_TYPE)
/* Nonzero if TYPE represents a bounded pointer or bounded reference type. */
#define BOUNDED_INDIRECT_TYPE_P(TYPE) \
(TREE_CODE (TYPE) == RECORD_TYPE && TREE_TYPE (TYPE))
/* Nonzero if TYPE represents a bounded pointer type. */
#define BOUNDED_POINTER_TYPE_P(TYPE) \
(BOUNDED_INDIRECT_TYPE_P (TYPE) \
&& TREE_CODE (TYPE_BOUNDED_SUBTYPE (TYPE)) == POINTER_TYPE)
/* Nonzero if TYPE represents a bounded reference type. Bounded
reference types have two specific uses: (1) When a reference is
seated to a variable-length RECORD_TYPE that has an array of
indeterminate length as its final field. For all other objects, it
is sufficient to check bounds at the time the reference is seated,
and assume that all future uses of the reference are safe, since
the address of references cannot change. (2) When a reference
supertype is seated to an subtype object. The bounds "remember"
the true size of the complete object, so that subsequent upcasts of
the address of the reference will be checked properly (is such a
thing valid C++?). */
#define BOUNDED_REFERENCE_TYPE_P(TYPE) \
(BOUNDED_INDIRECT_TYPE_P (TYPE) \
&& TREE_CODE (TYPE_BOUNDED_SUBTYPE (TYPE)) == REFERENCE_TYPE)
/* Nonzero if TYPE represents a pointer or reference type, either
bounded or unbounded. */
#define MAYBE_BOUNDED_INDIRECT_TYPE_P(TYPE) \
(POINTER_TYPE_P (TYPE) || BOUNDED_INDIRECT_TYPE_P (TYPE))
/* Nonzero if TYPE represents a pointer type, either bounded or unbounded. */
#define MAYBE_BOUNDED_POINTER_TYPE_P(TYPE) \
(TREE_CODE (TYPE) == POINTER_TYPE || BOUNDED_POINTER_TYPE_P (TYPE))
/* Nonzero if TYPE represents a reference type, either bounded or
unbounded. */
#define MAYBE_BOUNDED_REFERENCE_TYPE_P(TYPE) \
(TREE_CODE (TYPE) == REFERENCE_TYPE || BOUNDED_REFERENCE_TYPE_P (TYPE))
/* Nonzero if this type is a complete type. */
#define COMPLETE_TYPE_P(NODE) (TYPE_SIZE (NODE) != NULL_TREE)
/* Nonzero if this type is the (possibly qualified) void type. */
#define VOID_TYPE_P(NODE) (TREE_CODE (NODE) == VOID_TYPE)
/* Nonzero if this type is complete or is cv void. */
#define COMPLETE_OR_VOID_TYPE_P(NODE) \
(COMPLETE_TYPE_P (NODE) || VOID_TYPE_P (NODE))
/* Nonzero if this type is complete or is an array with unspecified bound. */
#define COMPLETE_OR_UNBOUND_ARRAY_TYPE_P(NODE) \
(COMPLETE_TYPE_P (TREE_CODE (NODE) == ARRAY_TYPE ? TREE_TYPE (NODE) : (NODE)))
/* Nonzero if TYPE represents a type. */
#define TYPE_P(TYPE) (TREE_CODE_CLASS (TREE_CODE (TYPE)) == 't')
/* Define many boolean fields that all tree nodes have. */
/* In VAR_DECL nodes, nonzero means address of this is needed.
So it cannot be in a register.
In a FUNCTION_DECL, nonzero means its address is needed.
So it must be compiled even if it is an inline function.
In a FIELD_DECL node, it means that the programmer is permitted to
construct the address of this field. This is used for aliasing
purposes: see record_component_aliases.
In CONSTRUCTOR nodes, it means object constructed must be in memory.
In LABEL_DECL nodes, it means a goto for this label has been seen
from a place outside all binding contours that restore stack levels.
In ..._TYPE nodes, it means that objects of this type must
be fully addressable. This means that pieces of this
object cannot go into register parameters, for example.
In IDENTIFIER_NODEs, this means that some extern decl for this name
had its address taken. That matters for inline functions. */
#define TREE_ADDRESSABLE(NODE) ((NODE)->common.addressable_flag)
/* In a VAR_DECL, nonzero means allocate static storage.
In a FUNCTION_DECL, nonzero if function has been defined.
In a CONSTRUCTOR, nonzero means allocate static storage. */
#define TREE_STATIC(NODE) ((NODE)->common.static_flag)
/* In a TARGET_EXPR, WITH_CLEANUP_EXPR, CLEANUP_STMT, or element of a
block's cleanup list, means that the pertinent cleanup should only be
executed if an exception is thrown, not on normal exit of its scope. */
#define CLEANUP_EH_ONLY(NODE) ((NODE)->common.static_flag)
/* In a CONVERT_EXPR, NOP_EXPR or COMPOUND_EXPR, this means the node was
made implicitly and should not lead to an "unused value" warning. */
#define TREE_NO_UNUSED_WARNING(NODE) ((NODE)->common.static_flag)
/* Nonzero for a TREE_LIST or TREE_VEC node means that the derivation
chain is via a `virtual' declaration. */
#define TREE_VIA_VIRTUAL(NODE) ((NODE)->common.static_flag)
/* In an INTEGER_CST, REAL_CST, COMPLEX_CST, or VECTOR_CST this means
there was an overflow in folding. This is distinct from
TREE_OVERFLOW because ANSI C requires a diagnostic when overflows
occur in constant expressions. */
#define TREE_CONSTANT_OVERFLOW(NODE) ((NODE)->common.static_flag)
/* In an IDENTIFIER_NODE, this means that assemble_name was called with
this string as an argument. */
#define TREE_SYMBOL_REFERENCED(NODE) \
(IDENTIFIER_NODE_CHECK (NODE)->common.static_flag)
/* In an INTEGER_CST, REAL_CST, COMPLEX_CST, or VECTOR_CST, this means
there was an overflow in folding, and no warning has been issued
for this subexpression. TREE_OVERFLOW implies
TREE_CONSTANT_OVERFLOW, but not vice versa. */
#define TREE_OVERFLOW(NODE) ((NODE)->common.public_flag)
/* In a VAR_DECL or FUNCTION_DECL,
nonzero means name is to be accessible from outside this module.
In an IDENTIFIER_NODE, nonzero means an external declaration
accessible from outside this module was previously seen
for this name in an inner scope. */
#define TREE_PUBLIC(NODE) ((NODE)->common.public_flag)
/* Nonzero for TREE_LIST or TREE_VEC node means that the path to the
base class is via a `public' declaration, which preserves public
fields from the base class as public. */
#define TREE_VIA_PUBLIC(NODE) ((NODE)->common.public_flag)
/* Ditto, for `private' declarations. */
#define TREE_VIA_PRIVATE(NODE) ((NODE)->common.private_flag)
/* Nonzero for TREE_LIST or TREE_VEC node means that the path to the
base class is via a `protected' declaration, which preserves
protected fields from the base class as protected.
OVERLOADED. */
#define TREE_VIA_PROTECTED(NODE) ((NODE)->common.protected_flag)
/* In any expression, nonzero means it has side effects or reevaluation
of the whole expression could produce a different value.
This is set if any subexpression is a function call, a side effect
or a reference to a volatile variable.
In a ..._DECL, this is set only if the declaration said `volatile'. */
#define TREE_SIDE_EFFECTS(NODE) ((NODE)->common.side_effects_flag)
/* Nonzero means this expression is volatile in the C sense:
its address should be of type `volatile WHATEVER *'.
In other words, the declared item is volatile qualified.
This is used in _DECL nodes and _REF nodes.
In a ..._TYPE node, means this type is volatile-qualified.
But use TYPE_VOLATILE instead of this macro when the node is a type,
because eventually we may make that a different bit.
If this bit is set in an expression, so is TREE_SIDE_EFFECTS. */
#define TREE_THIS_VOLATILE(NODE) ((NODE)->common.volatile_flag)
/* In a VAR_DECL, PARM_DECL or FIELD_DECL, or any kind of ..._REF node,
nonzero means it may not be the lhs of an assignment.
In a ..._TYPE node, means this type is const-qualified
(but the macro TYPE_READONLY should be used instead of this macro
when the node is a type). */
#define TREE_READONLY(NODE) ((NODE)->common.readonly_flag)
/* Non-zero if NODE is a _DECL with TREE_READONLY set. */
#define TREE_READONLY_DECL_P(NODE) (TREE_READONLY (NODE) && DECL_P (NODE))
/* Value of expression is constant.
Always appears in all ..._CST nodes.
May also appear in an arithmetic expression, an ADDR_EXPR or a CONSTRUCTOR
if the value is constant. */
#define TREE_CONSTANT(NODE) ((NODE)->common.constant_flag)
/* In INTEGER_TYPE or ENUMERAL_TYPE nodes, means an unsigned type.
In FIELD_DECL nodes, means an unsigned bit field.
The same bit is used in functions as DECL_BUILT_IN_NONANSI. */
#define TREE_UNSIGNED(NODE) ((NODE)->common.unsigned_flag)
#define TYPE_TRAP_SIGNED(NODE) \
(flag_trapv && ! TREE_UNSIGNED (TYPE_CHECK (NODE)))
/* Nonzero in a VAR_DECL means assembler code has been written.
Nonzero in a FUNCTION_DECL means that the function has been compiled.
This is interesting in an inline function, since it might not need
to be compiled separately.
Nonzero in a RECORD_TYPE, UNION_TYPE, QUAL_UNION_TYPE or ENUMERAL_TYPE
if the sdb debugging info for the type has been written.
In a BLOCK node, nonzero if reorder_blocks has already seen this block. */
#define TREE_ASM_WRITTEN(NODE) ((NODE)->common.asm_written_flag)
/* Nonzero in a _DECL if the name is used in its scope.
Nonzero in an expr node means inhibit warning if value is unused.
In IDENTIFIER_NODEs, this means that some extern decl for this name
was used. */
#define TREE_USED(NODE) ((NODE)->common.used_flag)
/* In a FUNCTION_DECL, nonzero means a call to the function cannot throw
an exception. In a CALL_EXPR, nonzero means the call cannot throw. */
#define TREE_NOTHROW(NODE) ((NODE)->common.nothrow_flag)
/* In a type, nonzero means that all objects of the type are guaranteed by the
language or front-end to be properly aligned, so we can indicate that a MEM
of this type is aligned at least to the alignment of the type, even if it
doesn't appear that it is. We see this, for example, in object-oriented
languages where a tag field may show this is an object of a more-aligned
variant of the more generic type. */
#define TYPE_ALIGN_OK(NODE) (TYPE_CHECK (NODE)->common.nothrow_flag)
/* Used in classes in C++. */
#define TREE_PRIVATE(NODE) ((NODE)->common.private_flag)
/* Used in classes in C++.
In a BLOCK node, this is BLOCK_HANDLER_BLOCK. */
#define TREE_PROTECTED(NODE) ((NODE)->common.protected_flag)
/* In a ..._TYPE node, nonzero means that the type's size and layout,
(or the size and layout of its arguments and/or return value in the
case of a FUNCTION_TYPE or METHOD_TYPE) was changed by the presence
of pointer bounds. Use TYPE_BOUNDED instead of this macro when the
node is a type, because eventually we may make that a different
bit. TYPE_BOUNDED doesn't mean that this type is a bounded indirect
type--use BOUNDED_POINTER_TYPE_P, BOUNDED_REFERENCE_TYPE_P,
BOUNDED_INDIRECT_TYPE_P to test for that.
In a FUNCTION_DECL, nonzero means that the size and layout of one
of its arguments and/or return value was changed by the presence of
pointer bounds. This value can differ from the value of
TYPE_BOUNDED (TREE_TYPE (fundecl)) if the function was implicitly
declared, then later called with pointer args, or was declared with
a variable argument list and is later called with pointer values in
the variable argument list.
In a VAR_DECL, PARM_DECL or FIELD_DECL, TREE_BOUNDED matches the value
of the decl's type's BOUNDED_POINTER_TYPE_P.
In a CONSTRUCTOR or other expression, nonzero means the value is a
bounded pointer. It is insufficient to determine the boundedness
of an expression EXP with BOUNDED_POINTER_TYPE_P (TREE_TYPE (EXP)),
since we allow pointer to be temporarily cast to integer for
rounding up to an alignment boudary in a way that preserves the
pointer's bounds.
In an IDENTIFIER_NODE, nonzero means that the name is prefixed with
BP_PREFIX (see varasm.c). This occurs for the DECL_ASSEMBLER_NAME
of a function that has bounded pointer(s) for its return type and/or
argument type(s). */
#define TREE_BOUNDED(NODE) ((NODE)->common.bounded_flag)
/* Nonzero in a IDENTIFIER_NODE if the use of the name is defined as a
deprecated feature by __attribute__((deprecated)). */
#define TREE_DEPRECATED(NODE) ((NODE)->common.deprecated_flag)
/* These flags are available for each language front end to use internally. */
#define TREE_LANG_FLAG_0(NODE) ((NODE)->common.lang_flag_0)
#define TREE_LANG_FLAG_1(NODE) ((NODE)->common.lang_flag_1)
#define TREE_LANG_FLAG_2(NODE) ((NODE)->common.lang_flag_2)
#define TREE_LANG_FLAG_3(NODE) ((NODE)->common.lang_flag_3)
#define TREE_LANG_FLAG_4(NODE) ((NODE)->common.lang_flag_4)
#define TREE_LANG_FLAG_5(NODE) ((NODE)->common.lang_flag_5)
#define TREE_LANG_FLAG_6(NODE) ((NODE)->common.lang_flag_6)
/* Define additional fields and accessors for nodes representing constants. */
/* In an INTEGER_CST node. These two together make a 2-word integer.
If the data type is signed, the value is sign-extended to 2 words
even though not all of them may really be in use.
In an unsigned constant shorter than 2 words, the extra bits are 0. */
#define TREE_INT_CST(NODE) (INTEGER_CST_CHECK (NODE)->int_cst.int_cst)
#define TREE_INT_CST_LOW(NODE) (TREE_INT_CST (NODE).low)
#define TREE_INT_CST_HIGH(NODE) (TREE_INT_CST (NODE).high)
#define INT_CST_LT(A, B) \
(TREE_INT_CST_HIGH (A) < TREE_INT_CST_HIGH (B) \
|| (TREE_INT_CST_HIGH (A) == TREE_INT_CST_HIGH (B) \
&& TREE_INT_CST_LOW (A) < TREE_INT_CST_LOW (B)))
#define INT_CST_LT_UNSIGNED(A, B) \
(((unsigned HOST_WIDE_INT) TREE_INT_CST_HIGH (A) \
< (unsigned HOST_WIDE_INT) TREE_INT_CST_HIGH (B)) \
|| (((unsigned HOST_WIDE_INT) TREE_INT_CST_HIGH (A) \
== (unsigned HOST_WIDE_INT) TREE_INT_CST_HIGH (B)) \
&& TREE_INT_CST_LOW (A) < TREE_INT_CST_LOW (B)))
struct tree_int_cst
{
struct tree_common common;
rtx rtl; /* acts as link to register transfer language
(rtl) info */
/* A sub-struct is necessary here because the function `const_hash'
wants to scan both words as a unit and taking the address of the
sub-struct yields the properly inclusive bounded pointer. */
struct {
unsigned HOST_WIDE_INT low;
HOST_WIDE_INT high;
} int_cst;
};
/* In REAL_CST, STRING_CST, COMPLEX_CST, VECTOR_CST nodes, and
CONSTRUCTOR nodes, and generally in all kinds of constants that
could be given labels (rather than being immediate). */
#define TREE_CST_RTL(NODE) (CST_OR_CONSTRUCTOR_CHECK (NODE)->real_cst.rtl)
/* In a REAL_CST node.
We can represent a real value as either a `double' or an array of
longs. */
#define TREE_REAL_CST(NODE) (REAL_CST_CHECK (NODE)->real_cst.real_cst)
#include "real.h"
struct tree_real_cst
{
struct tree_common common;
rtx rtl; /* acts as link to register transfer language (rtl) info */
REAL_VALUE_TYPE real_cst;
};
/* In a STRING_CST */
#define TREE_STRING_LENGTH(NODE) (STRING_CST_CHECK (NODE)->string.length)
#define TREE_STRING_POINTER(NODE) (STRING_CST_CHECK (NODE)->string.pointer)
struct tree_string
{
struct tree_common common;
rtx rtl; /* acts as link to register transfer language (rtl) info */
int length;
const char *pointer;
};
/* In a COMPLEX_CST node. */
#define TREE_REALPART(NODE) (COMPLEX_CST_CHECK (NODE)->complex.real)
#define TREE_IMAGPART(NODE) (COMPLEX_CST_CHECK (NODE)->complex.imag)
struct tree_complex
{
struct tree_common common;
rtx rtl; /* acts as link to register transfer language (rtl) info */
tree real;
tree imag;
};
/* In a VECTOR_CST node. */
#define TREE_VECTOR_CST_ELTS(NODE) (VECTOR_CST_CHECK (NODE)->vector.elements)
struct tree_vector
{
struct tree_common common;
rtx rtl;
tree elements;
};
#include "hashtable.h"
/* Define fields and accessors for some special-purpose tree nodes. */
#define IDENTIFIER_LENGTH(NODE) \
(IDENTIFIER_NODE_CHECK (NODE)->identifier.id.len)
#define IDENTIFIER_POINTER(NODE) \
((const char *) IDENTIFIER_NODE_CHECK (NODE)->identifier.id.str)
/* Translate a hash table identifier pointer to a tree_identifier
pointer, and vice versa. */
#define HT_IDENT_TO_GCC_IDENT(NODE) \
((tree) ((char *) (NODE) - sizeof (struct tree_common)))
#define GCC_IDENT_TO_HT_IDENT(NODE) (&((struct tree_identifier *) (NODE))->id)
struct tree_identifier
{
struct tree_common common;
struct ht_identifier id;
};
/* In a TREE_LIST node. */
#define TREE_PURPOSE(NODE) (TREE_LIST_CHECK (NODE)->list.purpose)
#define TREE_VALUE(NODE) (TREE_LIST_CHECK (NODE)->list.value)
struct tree_list
{
struct tree_common common;
tree purpose;
tree value;
};
/* In a TREE_VEC node. */
#define TREE_VEC_LENGTH(NODE) (TREE_VEC_CHECK (NODE)->vec.length)
#define TREE_VEC_ELT(NODE,I) (TREE_VEC_CHECK (NODE)->vec.a[I])
#define TREE_VEC_END(NODE) \
((void) TREE_VEC_CHECK (NODE), &((NODE)->vec.a[(NODE)->vec.length]))
struct tree_vec
{
struct tree_common common;
int length;
tree a[1];
};
/* Define fields and accessors for some nodes that represent expressions. */
/* In a SAVE_EXPR node. */
#define SAVE_EXPR_CONTEXT(NODE) TREE_OPERAND (SAVE_EXPR_CHECK (NODE), 1)
#define SAVE_EXPR_RTL(NODE) (*(rtx *) &SAVE_EXPR_CHECK (NODE)->exp.operands[2])
#define SAVE_EXPR_NOPLACEHOLDER(NODE) TREE_UNSIGNED (SAVE_EXPR_CHECK (NODE))
/* Nonzero if the SAVE_EXPRs value should be kept, even if it occurs
both in normal code and in a handler. (Normally, in a handler, all
SAVE_EXPRs are unsaved, meaning that there values are
recalculated.) */
#define SAVE_EXPR_PERSISTENT_P(NODE) TREE_ASM_WRITTEN (SAVE_EXPR_CHECK (NODE))
/* In a RTL_EXPR node. */
#define RTL_EXPR_SEQUENCE(NODE) \
(*(rtx *) &RTL_EXPR_CHECK (NODE)->exp.operands[0])
#define RTL_EXPR_RTL(NODE) (*(rtx *) &RTL_EXPR_CHECK (NODE)->exp.operands[1])
/* In a WITH_CLEANUP_EXPR node. */
#define WITH_CLEANUP_EXPR_RTL(NODE) \
(*(rtx *) &WITH_CLEANUP_EXPR_CHECK (NODE)->exp.operands[2])
/* In a CONSTRUCTOR node. */
#define CONSTRUCTOR_ELTS(NODE) TREE_OPERAND (CONSTRUCTOR_CHECK (NODE), 1)
/* In ordinary expression nodes. */
#define TREE_OPERAND(NODE, I) (EXPR_CHECK (NODE)->exp.operands[I])
#define TREE_COMPLEXITY(NODE) (EXPR_CHECK (NODE)->exp.complexity)
/* In a LABELED_BLOCK_EXPR node. */
#define LABELED_BLOCK_LABEL(NODE) \
TREE_OPERAND (LABELED_BLOCK_EXPR_CHECK (NODE), 0)
#define LABELED_BLOCK_BODY(NODE) \
TREE_OPERAND (LABELED_BLOCK_EXPR_CHECK (NODE), 1)
/* In a EXIT_BLOCK_EXPR node. */
#define EXIT_BLOCK_LABELED_BLOCK(NODE) \
TREE_OPERAND (EXIT_BLOCK_EXPR_CHECK (NODE), 0)
#define EXIT_BLOCK_RETURN(NODE) TREE_OPERAND (EXIT_BLOCK_EXPR_CHECK (NODE), 1)
/* In a LOOP_EXPR node. */
#define LOOP_EXPR_BODY(NODE) TREE_OPERAND (LOOP_EXPR_CHECK (NODE), 0)
/* In a EXPR_WITH_FILE_LOCATION node. */
#define EXPR_WFL_EMIT_LINE_NOTE(NODE) \
(EXPR_WITH_FILE_LOCATION_CHECK (NODE)->common.public_flag)
#define EXPR_WFL_NODE(NODE) \
TREE_OPERAND (EXPR_WITH_FILE_LOCATION_CHECK (NODE), 0)
#define EXPR_WFL_FILENAME_NODE(NODE) \
TREE_OPERAND (EXPR_WITH_FILE_LOCATION_CHECK (NODE), 1)
#define EXPR_WFL_FILENAME(NODE) \
IDENTIFIER_POINTER (EXPR_WFL_FILENAME_NODE (NODE))
/* ??? Java uses this in all expressions. */
#define EXPR_WFL_LINECOL(NODE) (EXPR_CHECK (NODE)->exp.complexity)
#define EXPR_WFL_LINENO(NODE) (EXPR_WFL_LINECOL (NODE) >> 12)
#define EXPR_WFL_COLNO(NODE) (EXPR_WFL_LINECOL (NODE) & 0xfff)
#define EXPR_WFL_SET_LINECOL(NODE, LINE, COL) \
(EXPR_WFL_LINECOL(NODE) = ((LINE) << 12) | ((COL) & 0xfff))
struct tree_exp
{
struct tree_common common;
int complexity;
tree operands[1];
};
/* In a BLOCK node. */
#define BLOCK_VARS(NODE) (BLOCK_CHECK (NODE)->block.vars)
#define BLOCK_SUBBLOCKS(NODE) (BLOCK_CHECK (NODE)->block.subblocks)
#define BLOCK_SUPERCONTEXT(NODE) (BLOCK_CHECK (NODE)->block.supercontext)
/* Note: when changing this, make sure to find the places
that use chainon or nreverse. */
#define BLOCK_CHAIN(NODE) TREE_CHAIN (BLOCK_CHECK (NODE))
#define BLOCK_ABSTRACT_ORIGIN(NODE) (BLOCK_CHECK (NODE)->block.abstract_origin)
#define BLOCK_ABSTRACT(NODE) (BLOCK_CHECK (NODE)->block.abstract_flag)
/* Nonzero means that this block is prepared to handle exceptions
listed in the BLOCK_VARS slot. */
#define BLOCK_HANDLER_BLOCK(NODE) \
(BLOCK_CHECK (NODE)->block.handler_block_flag)
/* An index number for this block. These values are not guaranteed to
be unique across functions -- whether or not they are depends on
the debugging output format in use. */
#define BLOCK_NUMBER(NODE) (BLOCK_CHECK (NODE)->block.block_num)
/* If block reordering splits a lexical block into discontiguous
address ranges, we'll make a copy of the original block.
Note that this is logically distinct from BLOCK_ABSTRACT_ORIGIN.
In that case, we have one source block that has been replicated
(through inlining or unrolling) into many logical blocks, and that
these logical blocks have different physical variables in them.
In this case, we have one logical block split into several
non-contiguous address ranges. Most debug formats can't actually
represent this idea directly, so we fake it by creating multiple
logical blocks with the same variables in them. However, for those
that do support non-contiguous regions, these allow the original
logical block to be reconstructed, along with the set of address
ranges.
One of the logical block fragments is arbitrarily chosen to be
the ORIGIN. The other fragments will point to the origin via
BLOCK_FRAGMENT_ORIGIN; the origin itself will have this pointer
be null. The list of fragments will be chained through
BLOCK_FRAGMENT_CHAIN from the origin. */
#define BLOCK_FRAGMENT_ORIGIN(NODE) (BLOCK_CHECK (NODE)->block.fragment_origin)
#define BLOCK_FRAGMENT_CHAIN(NODE) (BLOCK_CHECK (NODE)->block.fragment_chain)
struct tree_block
{
struct tree_common common;
unsigned handler_block_flag : 1;
unsigned abstract_flag : 1;
unsigned block_num : 30;
tree vars;
tree subblocks;
tree supercontext;
tree abstract_origin;
tree fragment_origin;
tree fragment_chain;
};
/* Define fields and accessors for nodes representing data types. */
/* See tree.def for documentation of the use of these fields.
Look at the documentation of the various ..._TYPE tree codes. */
#define TYPE_UID(NODE) (TYPE_CHECK (NODE)->type.uid)
#define TYPE_SIZE(NODE) (TYPE_CHECK (NODE)->type.size)
#define TYPE_SIZE_UNIT(NODE) (TYPE_CHECK (NODE)->type.size_unit)
#define TYPE_MODE(NODE) (TYPE_CHECK (NODE)->type.mode)
#define TYPE_VALUES(NODE) (TYPE_CHECK (NODE)->type.values)
#define TYPE_DOMAIN(NODE) (TYPE_CHECK (NODE)->type.values)
#define TYPE_FIELDS(NODE) (TYPE_CHECK (NODE)->type.values)
#define TYPE_METHODS(NODE) (TYPE_CHECK (NODE)->type.maxval)
#define TYPE_VFIELD(NODE) (TYPE_CHECK (NODE)->type.minval)
#define TYPE_ARG_TYPES(NODE) (TYPE_CHECK (NODE)->type.values)
#define TYPE_METHOD_BASETYPE(NODE) (TYPE_CHECK (NODE)->type.maxval)
#define TYPE_OFFSET_BASETYPE(NODE) (TYPE_CHECK (NODE)->type.maxval)
#define TYPE_POINTER_TO(NODE) (TYPE_CHECK (NODE)->type.pointer_to)
#define TYPE_REFERENCE_TO(NODE) (TYPE_CHECK (NODE)->type.reference_to)
#define TYPE_MIN_VALUE(NODE) (TYPE_CHECK (NODE)->type.minval)
#define TYPE_MAX_VALUE(NODE) (TYPE_CHECK (NODE)->type.maxval)
#define TYPE_PRECISION(NODE) (TYPE_CHECK (NODE)->type.precision)
#define TYPE_SYMTAB_ADDRESS(NODE) (TYPE_CHECK (NODE)->type.symtab.address)
#define TYPE_SYMTAB_POINTER(NODE) (TYPE_CHECK (NODE)->type.symtab.pointer)
#define TYPE_NAME(NODE) (TYPE_CHECK (NODE)->type.name)
#define TYPE_NEXT_VARIANT(NODE) (TYPE_CHECK (NODE)->type.next_variant)
#define TYPE_MAIN_VARIANT(NODE) (TYPE_CHECK (NODE)->type.main_variant)
#define TYPE_CONTEXT(NODE) (TYPE_CHECK (NODE)->type.context)
#define TYPE_LANG_SPECIFIC(NODE) (TYPE_CHECK (NODE)->type.lang_specific)
/* For a VECTOR_TYPE node, this describes a different type which is emitted
in the debugging output. We use this to describe a vector as a
structure containing an array. */
#define TYPE_DEBUG_REPRESENTATION_TYPE(NODE) (TYPE_CHECK (NODE)->type.values)
/* Indirect types present difficulties because they may be represented
as either POINTER_TYPE/REFERENCE_TYPE nodes (unbounded) or as
RECORD_TYPE nodes (bounded). Bounded and unbounded pointers might
be logically equivalent, but physically different. Simple
comparison of the main variant only tells if the types are
logically equivalent. Use this predicate to compare for physical
equivalency. */
/* Types have the same main variant, and have the same boundedness. */
#define TYPE_MAIN_VARIANTS_PHYSICALLY_EQUAL_P(TYPE1, TYPE2) \
(TYPE_MAIN_VARIANT (TYPE1) == TYPE_MAIN_VARIANT (TYPE2) \
&& TREE_CODE (TYPE1) == TREE_CODE (TYPE2))
/* Return the type variant that has no qualifiers (i.e., the main variant),
except that the boundedness qualifier is preserved. */
#define TYPE_MAIN_PHYSICAL_VARIANT(TYPE) \
(BOUNDED_POINTER_TYPE_P (TYPE) \
? build_qualified_type (TYPE, TYPE_QUAL_BOUNDED) \
: TYPE_MAIN_VARIANT (TYPE))
/* For aggregate types, information about this type, as a base type
for itself. Used in a language-dependent way for types that are
neither a RECORD_TYPE, QUAL_UNION_TYPE, nor a UNION_TYPE. */
#define TYPE_BINFO(NODE) (TYPE_CHECK (NODE)->type.binfo)
/* The (language-specific) typed-based alias set for this type.
Objects whose TYPE_ALIAS_SETs are different cannot alias each
other. If the TYPE_ALIAS_SET is -1, no alias set has yet been
assigned to this type. If the TYPE_ALIAS_SET is 0, objects of this
type can alias objects of any type. */
#define TYPE_ALIAS_SET(NODE) (TYPE_CHECK (NODE)->type.alias_set)
/* Nonzero iff the typed-based alias set for this type has been
calculated. */
#define TYPE_ALIAS_SET_KNOWN_P(NODE) (TYPE_CHECK (NODE)->type.alias_set != -1)
/* A TREE_LIST of IDENTIFIER nodes of the attributes that apply
to this type. */
#define TYPE_ATTRIBUTES(NODE) (TYPE_CHECK (NODE)->type.attributes)
/* The alignment necessary for objects of this type.
The value is an int, measured in bits. */
#define TYPE_ALIGN(NODE) (TYPE_CHECK (NODE)->type.align)
/* 1 if the alignment for this type was requested by "aligned" attribute,
0 if it is the default for this type. */
#define TYPE_USER_ALIGN(NODE) (TYPE_CHECK (NODE)->type.user_align)
/* The alignment for NODE, in bytes. */
#define TYPE_ALIGN_UNIT(NODE) (TYPE_ALIGN (NODE) / BITS_PER_UNIT)
/* If your language allows you to declare types, and you want debug info
for them, then you need to generate corresponding TYPE_DECL nodes.
These "stub" TYPE_DECL nodes have no name, and simply point at the
type node. You then set the TYPE_STUB_DECL field of the type node
to point back at the TYPE_DECL node. This allows the debug routines
to know that the two nodes represent the same type, so that we only
get one debug info record for them. */
#define TYPE_STUB_DECL(NODE) TREE_CHAIN (NODE)
/* In a RECORD_TYPE, UNION_TYPE or QUAL_UNION_TYPE, it means the type
has BLKmode only because it lacks the alignment requirement for
its size. */
#define TYPE_NO_FORCE_BLK(NODE) (TYPE_CHECK (NODE)->type.no_force_blk_flag)
/* In an INTEGER_TYPE, it means the type represents a size. We use
this both for validity checking and to permit optimizations that
are unsafe for other types. Note that the C `size_t' type should
*not* have this flag set. The `size_t' type is simply a typedef
for an ordinary integer type that happens to be the type of an
expression returned by `sizeof'; `size_t' has no special
properties. Expressions whose type have TYPE_IS_SIZETYPE set are
always actual sizes. */
#define TYPE_IS_SIZETYPE(NODE) \
(INTEGER_TYPE_CHECK (NODE)->type.no_force_blk_flag)
/* In a FUNCTION_TYPE, indicates that the function returns with the stack
pointer depressed. */
#define TYPE_RETURNS_STACK_DEPRESSED(NODE) \
(FUNCTION_TYPE_CHECK (NODE)->type.no_force_blk_flag)
/* Nonzero in a type considered volatile as a whole. */
#define TYPE_VOLATILE(NODE) (TYPE_CHECK (NODE)->common.volatile_flag)
/* Means this type is const-qualified. */
#define TYPE_READONLY(NODE) (TYPE_CHECK (NODE)->common.readonly_flag)
/* If nonzero, this type is `restrict'-qualified, in the C sense of
the term. */
#define TYPE_RESTRICT(NODE) (TYPE_CHECK (NODE)->type.restrict_flag)
/* If nonzero, this type's size and layout, (or the size and layout of
its arguments and/or return value in the case of a FUNCTION_TYPE or
METHOD_TYPE) was changed by the presence of pointer bounds. */
#define TYPE_BOUNDED(NODE) (TYPE_CHECK (NODE)->common.bounded_flag)
/* There is a TYPE_QUAL value for each type qualifier. They can be
combined by bitwise-or to form the complete set of qualifiers for a
type. */
#define TYPE_UNQUALIFIED 0x0
#define TYPE_QUAL_CONST 0x1
#define TYPE_QUAL_VOLATILE 0x2
#define TYPE_QUAL_RESTRICT 0x4
#define TYPE_QUAL_BOUNDED 0x8
/* The set of type qualifiers for this type. */
#define TYPE_QUALS(NODE) \
((TYPE_READONLY (NODE) * TYPE_QUAL_CONST) \
| (TYPE_VOLATILE (NODE) * TYPE_QUAL_VOLATILE) \
| (TYPE_RESTRICT (NODE) * TYPE_QUAL_RESTRICT) \
| (BOUNDED_INDIRECT_TYPE_P (NODE) * TYPE_QUAL_BOUNDED))
/* The set of qualifiers pertinent to an expression node. */
#define TREE_EXPR_QUALS(NODE) \
((TREE_READONLY (NODE) * TYPE_QUAL_CONST) \
| (TREE_THIS_VOLATILE (NODE) * TYPE_QUAL_VOLATILE) \
| (TREE_BOUNDED (NODE) * TYPE_QUAL_BOUNDED))
/* The set of qualifiers pertinent to a FUNCTION_DECL node. */
#define TREE_FUNC_QUALS(NODE) \
((TREE_READONLY (NODE) * TYPE_QUAL_CONST) \
| (TREE_THIS_VOLATILE (NODE) * TYPE_QUAL_VOLATILE))
/* These flags are available for each language front end to use internally. */
#define TYPE_LANG_FLAG_0(NODE) (TYPE_CHECK (NODE)->type.lang_flag_0)
#define TYPE_LANG_FLAG_1(NODE) (TYPE_CHECK (NODE)->type.lang_flag_1)
#define TYPE_LANG_FLAG_2(NODE) (TYPE_CHECK (NODE)->type.lang_flag_2)
#define TYPE_LANG_FLAG_3(NODE) (TYPE_CHECK (NODE)->type.lang_flag_3)
#define TYPE_LANG_FLAG_4(NODE) (TYPE_CHECK (NODE)->type.lang_flag_4)
#define TYPE_LANG_FLAG_5(NODE) (TYPE_CHECK (NODE)->type.lang_flag_5)
#define TYPE_LANG_FLAG_6(NODE) (TYPE_CHECK (NODE)->type.lang_flag_6)
/* If set in an ARRAY_TYPE, indicates a string type (for languages
that distinguish string from array of char).
If set in a SET_TYPE, indicates a bitstring type. */
#define TYPE_STRING_FLAG(NODE) (TYPE_CHECK (NODE)->type.string_flag)
/* If non-NULL, this is an upper bound of the size (in bytes) of an
object of the given ARRAY_TYPE. This allows temporaries to be
allocated. */
#define TYPE_ARRAY_MAX_SIZE(ARRAY_TYPE) \
TYPE_MAX_VALUE (ARRAY_TYPE_CHECK (ARRAY_TYPE))
/* For a VECTOR_TYPE, this is the number of sub-parts of the vector. */
#define TYPE_VECTOR_SUBPARTS(VECTOR_TYPE) \
GET_MODE_NUNITS (VECTOR_TYPE_CHECK (VECTOR_TYPE)->type.mode)
/* Indicates that objects of this type must be initialized by calling a
function when they are created. */
#define TYPE_NEEDS_CONSTRUCTING(NODE) \
(TYPE_CHECK (NODE)->type.needs_constructing_flag)
/* Indicates that objects of this type (a UNION_TYPE), should be passed
the same way that the first union alternative would be passed. */
#define TYPE_TRANSPARENT_UNION(NODE) \
(UNION_TYPE_CHECK (NODE)->type.transparent_union_flag)
/* For an ARRAY_TYPE, indicates that it is not permitted to
take the address of a component of the type. */
#define TYPE_NONALIASED_COMPONENT(NODE) \
(ARRAY_TYPE_CHECK (NODE)->type.transparent_union_flag)
/* Indicated that objects of this type should be laid out in as
compact a way as possible. */
#define TYPE_PACKED(NODE) (TYPE_CHECK (NODE)->type.packed_flag)
/* A bounded pointer or bounded reference type (collectively called
indirect types) is represented as a RECORD_TYPE node containing
three pointer fields whose type is the corresponding unbounded
POINTER_TYPE or REFERENCE_TYPE. A RECORD_TYPE node that represents
a bounded indirect type differs from a normal RECORD_TYPE node in
that its TREE_TYPE is non-NULL and has the pointed-to type just as
a POINTER_TYPE or REFERENCE_TYPE node has. The bounded RECORD_TYPE
nodes are stored on the same type variant chain alongside the
variants of the underlaying indirect types nodes. The main variant
of such chains is always the unbounded type. */
/* Access the field decls of a bounded-pointer type. */
#define TYPE_BOUNDED_VALUE(TYPE) TYPE_FIELDS (TYPE)
#define TYPE_BOUNDED_BASE(TYPE) TREE_CHAIN (TYPE_BOUNDED_VALUE (TYPE))
#define TYPE_BOUNDED_EXTENT(TYPE) TREE_CHAIN (TYPE_BOUNDED_BASE (TYPE))
/* Access the simple-pointer subtype of a bounded-pointer type. */
#define TYPE_BOUNDED_SUBTYPE(TYPE) TREE_TYPE (TYPE_BOUNDED_VALUE (TYPE))
/* Find the unbounded counterpart to a type, or return TYPE if it is
already unbounded. */
#define TYPE_UNBOUNDED_VARIANT(TYPE) \
(BOUNDED_POINTER_TYPE_P (TYPE) ? TYPE_BOUNDED_SUBTYPE (TYPE) : (TYPE))
/* This field comprises two bits, for values in the range 0..3:
depth=0 means that type is a scalar, or an aggregate that contains
only depth=0 types, or a function that has only depth=0 types for
its return value and argument types.
depth=1 means that type is a pointer to a depth=0 type, or an
aggregate that contains only depth=0 and depth=1 types, or a
function that has only depth=0 and depth=1 types for its return
value and argument types.
The meanings of depth=2 and depth=3 are obvious by induction.
Varargs functions are depth=3. The type `va_list' is depth=3.
The purpose of measuring pointer depth of a type is to determine
the eligibility of a function for an automatically-generated
bounded-pointer thunk. A depth=0 functions needs no thunk. A
depth=1 function is eligible for an automatic thunk. Functions
with depth 2 or more are too complex to get automatic thunks.
Function decls also have a pointer_depth field, since we also
consider the actual argument types for functions. */
#define TYPE_POINTER_DEPTH(TYPE) (TYPE_CHECK (TYPE)->type.pointer_depth)
/* In a FUNCTION_TYPE node, this bit stores the value of
default_pointer_boundedness at the time TYPE was created. It is
useful for choosing default boundedness of function arguments for
non-prototype function decls and for varargs/stdarg lists. */
#define TYPE_AMBIENT_BOUNDEDNESS(TYPE) \
(FUNCTION_TYPE_CHECK (TYPE)->type.transparent_union_flag)
#define MAX_POINTER_DEPTH 2
#define VA_LIST_POINTER_DEPTH 3
struct tree_type
{
struct tree_common common;
tree values;
tree size;
tree size_unit;
tree attributes;
unsigned int uid;
unsigned int precision : 9;
ENUM_BITFIELD(machine_mode) mode : 7;
unsigned string_flag : 1;
unsigned no_force_blk_flag : 1;
unsigned needs_constructing_flag : 1;
unsigned transparent_union_flag : 1;
unsigned packed_flag : 1;
unsigned restrict_flag : 1;
unsigned pointer_depth : 2;
unsigned lang_flag_0 : 1;
unsigned lang_flag_1 : 1;
unsigned lang_flag_2 : 1;
unsigned lang_flag_3 : 1;
unsigned lang_flag_4 : 1;
unsigned lang_flag_5 : 1;
unsigned lang_flag_6 : 1;
unsigned user_align : 1;
unsigned int align;
tree pointer_to;
tree reference_to;
union {int address; char *pointer; } symtab;
tree name;
tree minval;
tree maxval;
tree next_variant;
tree main_variant;
tree binfo;
tree context;
HOST_WIDE_INT alias_set;
/* Points to a structure whose details depend on the language in use. */
struct lang_type *lang_specific;
};
/* Define accessor macros for information about type inheritance
and basetypes.
A "basetype" means a particular usage of a data type for inheritance
in another type. Each such basetype usage has its own "binfo"
object to describe it. The binfo object is a TREE_VEC node.
Inheritance is represented by the binfo nodes allocated for a
given type. For example, given types C and D, such that D is
inherited by C, 3 binfo nodes will be allocated: one for describing
the binfo properties of C, similarly one for D, and one for
describing the binfo properties of D as a base type for C.
Thus, given a pointer to class C, one can get a pointer to the binfo
of D acting as a basetype for C by looking at C's binfo's basetypes. */
/* The actual data type node being inherited in this basetype. */
#define BINFO_TYPE(NODE) TREE_TYPE (NODE)
/* The offset where this basetype appears in its containing type.
BINFO_OFFSET slot holds the offset (in bytes)
from the base of the complete object to the base of the part of the
object that is allocated on behalf of this `type'.
This is always 0 except when there is multiple inheritance. */
#define BINFO_OFFSET(NODE) TREE_VEC_ELT ((NODE), 1)
#define TYPE_BINFO_OFFSET(NODE) BINFO_OFFSET (TYPE_BINFO (NODE))
#define BINFO_OFFSET_ZEROP(NODE) (integer_zerop (BINFO_OFFSET (NODE)))
/* The virtual function table belonging to this basetype. Virtual
function tables provide a mechanism for run-time method dispatching.
The entries of a virtual function table are language-dependent. */
#define BINFO_VTABLE(NODE) TREE_VEC_ELT ((NODE), 2)
#define TYPE_BINFO_VTABLE(NODE) BINFO_VTABLE (TYPE_BINFO (NODE))
/* The virtual functions in the virtual function table. This is
a TREE_LIST that is used as an initial approximation for building
a virtual function table for this basetype. */
#define BINFO_VIRTUALS(NODE) TREE_VEC_ELT ((NODE), 3)
#define TYPE_BINFO_VIRTUALS(NODE) BINFO_VIRTUALS (TYPE_BINFO (NODE))
/* A vector of binfos for the direct basetypes inherited by this
basetype.
If this basetype describes type D as inherited in C, and if the
basetypes of D are E and F, then this vector contains binfos for
inheritance of E and F by C.
??? This could probably be done by just allocating the
base types at the end of this TREE_VEC (instead of using
another TREE_VEC). This would simplify the calculation
of how many basetypes a given type had. */
#define BINFO_BASETYPES(NODE) TREE_VEC_ELT ((NODE), 4)
#define TYPE_BINFO_BASETYPES(NODE) TREE_VEC_ELT (TYPE_BINFO (NODE), 4)
/* The number of basetypes for NODE. */
#define BINFO_N_BASETYPES(NODE) \
(BINFO_BASETYPES (NODE) ? TREE_VEC_LENGTH (BINFO_BASETYPES (NODE)) : 0)
/* Accessor macro to get to the Nth basetype of this basetype. */
#define BINFO_BASETYPE(NODE,N) TREE_VEC_ELT (BINFO_BASETYPES (NODE), (N))
#define TYPE_BINFO_BASETYPE(NODE,N) \
BINFO_TYPE (TREE_VEC_ELT (BINFO_BASETYPES (TYPE_BINFO (NODE)), (N)))
/* For a BINFO record describing a virtual base class, i.e., one where
TREE_VIA_VIRTUAL is set, this field assists in locating the virtual
base. The actual contents are language-dependent. Under the old
ABI, the C++ front-end uses a FIELD_DECL whose contents are a
pointer to the virtual base; under the new ABI this field is
instead a INTEGER_CST giving an offset into the vtable where the
offset to the virtual base can be found. */
#define BINFO_VPTR_FIELD(NODE) TREE_VEC_ELT (NODE, 5)
/* The size of a base class subobject of this type. Not all frontends
currently allocate the space for these fields. */
#define BINFO_SIZE(NODE) TREE_VEC_ELT (NODE, 6)
#define BINFO_SIZE_UNIT(NODE) TREE_VEC_ELT (NODE, 7)
#define TYPE_BINFO_SIZE(NODE) BINFO_SIZE (TYPE_BINFO (NODE))
#define TYPE_BINFO_SIZE_UNIT(NODE) BINFO_SIZE_UNIT (TYPE_BINFO (NODE))
/* Slot used to build a chain that represents a use of inheritance.
For example, if X is derived from Y, and Y is derived from Z,
then this field can be used to link the binfo node for X to
the binfo node for X's Y to represent the use of inheritance
from X to Y. Similarly, this slot of the binfo node for X's Y
can point to the Z from which Y is inherited (in X's inheritance
hierarchy). In this fashion, one can represent and traverse specific
uses of inheritance using the binfo nodes themselves (instead of
consing new space pointing to binfo nodes).
It is up to the language-dependent front-ends to maintain
this information as necessary. */
#define BINFO_INHERITANCE_CHAIN(NODE) TREE_VEC_ELT ((NODE), 0)
/* Define fields and accessors for nodes representing declared names. */
/* Nonzero if DECL represents a decl. */
#define DECL_P(DECL) (TREE_CODE_CLASS (TREE_CODE (DECL)) == 'd')
/* This is the name of the object as written by the user.
It is an IDENTIFIER_NODE. */
#define DECL_NAME(NODE) (DECL_CHECK (NODE)->decl.name)
/* The name of the object as the assembler will see it (but before any
translations made by ASM_OUTPUT_LABELREF). Often this is the same
as DECL_NAME. It is an IDENTIFIER_NODE. */
#define DECL_ASSEMBLER_NAME(NODE) \
((DECL_ASSEMBLER_NAME_SET_P (NODE) \
? (void) 0 \
: (*lang_set_decl_assembler_name) (NODE)), \
DECL_CHECK (NODE)->decl.assembler_name)
/* Returns non-zero if the DECL_ASSEMBLER_NAME for NODE has been set. If zero,
the NODE might still have a DECL_ASSEMBLER_NAME -- it just hasn't been set
yet. */
#define DECL_ASSEMBLER_NAME_SET_P(NODE) \
(DECL_CHECK (NODE)->decl.assembler_name != NULL_TREE)
/* Set the DECL_ASSEMBLER_NAME for NODE to NAME. */
#define SET_DECL_ASSEMBLER_NAME(NODE, NAME) \
(DECL_CHECK (NODE)->decl.assembler_name = (NAME))
/* Copy the DECL_ASSEMBLER_NAME from DECL1 to DECL2. Note that if DECL1's
DECL_ASSEMBLER_NAME has not yet been set, using this macro will not cause
the DECL_ASSEMBLER_NAME of either DECL to be set. In other words, the
semantics of using this macro, are different than saying:
SET_DECL_ASSEMBLER_NAME(DECL2, DECL_ASSEMBLER_NAME (DECL1))
which will try to set the DECL_ASSEMBLER_NAME for DECL1. */
#define COPY_DECL_ASSEMBLER_NAME(DECL1, DECL2) \
(DECL_ASSEMBLER_NAME_SET_P (DECL1) \
? (void) SET_DECL_ASSEMBLER_NAME (DECL2, \
DECL_ASSEMBLER_NAME (DECL1)) \
: (void) 0)
/* Records the section name in a section attribute. Used to pass
the name from decl_attributes to make_function_rtl and make_decl_rtl. */
#define DECL_SECTION_NAME(NODE) (DECL_CHECK (NODE)->decl.section_name)
/* For FIELD_DECLs, this is the
RECORD_TYPE, UNION_TYPE, or QUAL_UNION_TYPE node that the field is
a member of. For VAR_DECL, PARM_DECL, FUNCTION_DECL, LABEL_DECL,
and CONST_DECL nodes, this points to either the FUNCTION_DECL for the
containing function, the RECORD_TYPE or UNION_TYPE for the containing
type, or NULL_TREE if the given decl has "file scope". */
#define DECL_CONTEXT(NODE) (DECL_CHECK (NODE)->decl.context)
#define DECL_FIELD_CONTEXT(NODE) (FIELD_DECL_CHECK (NODE)->decl.context)
/* In a DECL this is the field where attributes are stored. */
#define DECL_ATTRIBUTES(NODE) (DECL_CHECK (NODE)->decl.attributes)
/* In a FIELD_DECL, this is the field position, counting in bytes, of the
byte containing the bit closest to the beginning of the structure. */
#define DECL_FIELD_OFFSET(NODE) (FIELD_DECL_CHECK (NODE)->decl.arguments)
/* In a FIELD_DECL, this is the offset, in bits, of the first bit of the
field from DECL_FIELD_OFFSET. */
#define DECL_FIELD_BIT_OFFSET(NODE) (FIELD_DECL_CHECK (NODE)->decl.u2.t)
/* In a FIELD_DECL, this indicates whether the field was a bit-field and
if so, the type that was originally specified for it.
TREE_TYPE may have been modified (in finish_struct). */
#define DECL_BIT_FIELD_TYPE(NODE) (FIELD_DECL_CHECK (NODE)->decl.result)
/* In FUNCTION_DECL, a chain of ..._DECL nodes.
VAR_DECL and PARM_DECL reserve the arguments slot for language-specific
uses. */
#define DECL_ARGUMENTS(NODE) (DECL_CHECK (NODE)->decl.arguments)
/* This field is used to reference anything in decl.result and is meant only
for use by the garbage collector. */
#define DECL_RESULT_FLD(NODE) (DECL_CHECK (NODE)->decl.result)
/* In FUNCTION_DECL, holds the decl for the return value. */
#define DECL_RESULT(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.result)
/* For a TYPE_DECL, holds the "original" type. (TREE_TYPE has the copy.) */
#define DECL_ORIGINAL_TYPE(NODE) (TYPE_DECL_CHECK (NODE)->decl.result)
/* In PARM_DECL, holds the type as written (perhaps a function or array). */
#define DECL_ARG_TYPE_AS_WRITTEN(NODE) (PARM_DECL_CHECK (NODE)->decl.result)
/* For a FUNCTION_DECL, holds the tree of BINDINGs.
For a VAR_DECL, holds the initial value.
For a PARM_DECL, not used--default
values for parameters are encoded in the type of the function,
not in the PARM_DECL slot. */
#define DECL_INITIAL(NODE) (DECL_CHECK (NODE)->decl.initial)
/* For a PARM_DECL, records the data type used to pass the argument,
which may be different from the type seen in the program. */
#define DECL_ARG_TYPE(NODE) (PARM_DECL_CHECK (NODE)->decl.initial)
/* For a FIELD_DECL in a QUAL_UNION_TYPE, records the expression, which
if nonzero, indicates that the field occupies the type. */
#define DECL_QUALIFIER(NODE) (FIELD_DECL_CHECK (NODE)->decl.initial)
/* These two fields describe where in the source code the declaration
was. If the declaration appears in several places (as for a C
function that is declared first and then defined later), this
information should refer to the definition. */
#define DECL_SOURCE_FILE(NODE) (DECL_CHECK (NODE)->decl.filename)
#define DECL_SOURCE_LINE(NODE) (DECL_CHECK (NODE)->decl.linenum)
/* Holds the size of the datum, in bits, as a tree expression.
Need not be constant. */
#define DECL_SIZE(NODE) (DECL_CHECK (NODE)->decl.size)
/* Likewise for the size in bytes. */
#define DECL_SIZE_UNIT(NODE) (DECL_CHECK (NODE)->decl.size_unit)
/* Holds the alignment required for the datum, in bits. */
#define DECL_ALIGN(NODE) (DECL_CHECK (NODE)->decl.u1.a.align)
/* The alignment of NODE, in bytes. */
#define DECL_ALIGN_UNIT(NODE) (DECL_ALIGN (NODE) / BITS_PER_UNIT)
/* For FIELD_DECLs, off_align holds the number of low-order bits of
DECL_FIELD_OFFSET which are known to be always zero.
DECL_OFFSET_ALIGN thus returns the alignment that DECL_FIELD_OFFSET
has. */
#define DECL_OFFSET_ALIGN(NODE) \
(((unsigned HOST_WIDE_INT)1) << FIELD_DECL_CHECK (NODE)->decl.u1.a.off_align)
/* Specify that DECL_ALIGN(NODE) is a multiple of X. */
#define SET_DECL_OFFSET_ALIGN(NODE, X) \
(FIELD_DECL_CHECK (NODE)->decl.u1.a.off_align = exact_log2 ((X) & -(X)))
/* 1 if the alignment for this type was requested by "aligned" attribute,
0 if it is the default for this type. */
#define DECL_USER_ALIGN(NODE) (DECL_CHECK (NODE)->decl.user_align)
/* Holds the machine mode corresponding to the declaration of a variable or
field. Always equal to TYPE_MODE (TREE_TYPE (decl)) except for a
FIELD_DECL. */
#define DECL_MODE(NODE) (DECL_CHECK (NODE)->decl.mode)
/* Holds the RTL expression for the value of a variable or function. If
PROMOTED_MODE is defined, the mode of this expression may not be same
as DECL_MODE. In that case, DECL_MODE contains the mode corresponding
to the variable's data type, while the mode
of DECL_RTL is the mode actually used to contain the data.
This value can be evaluated lazily for functions, variables with
static storage duration, and labels. */
#define DECL_RTL(NODE) \
(DECL_CHECK (NODE)->decl.rtl \
? (NODE)->decl.rtl \
: (make_decl_rtl (NODE, NULL), (NODE)->decl.rtl))
/* Set the DECL_RTL for NODE to RTL. */
#define SET_DECL_RTL(NODE, RTL) (DECL_CHECK (NODE)->decl.rtl = (RTL))
/* Returns non-zero if the DECL_RTL for NODE has already been set. */
#define DECL_RTL_SET_P(NODE) (DECL_CHECK (NODE)->decl.rtl != NULL)
/* Copy the RTL from NODE1 to NODE2. If the RTL was not set for
NODE1, it will not be set for NODE2; this is a lazy copy. */
#define COPY_DECL_RTL(NODE1, NODE2) \
(DECL_CHECK (NODE2)->decl.rtl = DECL_CHECK (NODE1)->decl.rtl)
/* The DECL_RTL for NODE, if it is set, or NULL, if it is not set. */
#define DECL_RTL_IF_SET(NODE) (DECL_RTL_SET_P (NODE) ? DECL_RTL (NODE) : NULL)
/* Holds an INSN_LIST of all of the live ranges in which the variable
has been moved to a possibly different register. */
#define DECL_LIVE_RANGE_RTL(NODE) (DECL_CHECK (NODE)->decl.live_range_rtl)
/* For PARM_DECL, holds an RTL for the stack slot or register
where the data was actually passed. */
#define DECL_INCOMING_RTL(NODE) (PARM_DECL_CHECK (NODE)->decl.u2.r)
/* For FUNCTION_DECL, if it is inline, holds the saved insn chain. */
#define DECL_SAVED_INSNS(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.u2.f)
/* For FUNCTION_DECL, if it is built-in,
this identifies which built-in operation it is. */
#define DECL_FUNCTION_CODE(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.u1.f)
/* The DECL_VINDEX is used for FUNCTION_DECLS in two different ways.
Before the struct containing the FUNCTION_DECL is laid out,
DECL_VINDEX may point to a FUNCTION_DECL in a base class which
is the FUNCTION_DECL which this FUNCTION_DECL will replace as a virtual
function. When the class is laid out, this pointer is changed
to an INTEGER_CST node which is suitable for use as an index
into the virtual function table. */
#define DECL_VINDEX(NODE) (DECL_CHECK (NODE)->decl.vindex)
/* For FIELD_DECLS, DECL_FCONTEXT is the *first* baseclass in
which this FIELD_DECL is defined. This information is needed when
writing debugging information about vfield and vbase decls for C++. */
#define DECL_FCONTEXT(NODE) (FIELD_DECL_CHECK (NODE)->decl.vindex)
/* Every ..._DECL node gets a unique number. */
#define DECL_UID(NODE) (DECL_CHECK (NODE)->decl.uid)
/* For any sort of a ..._DECL node, this points to the original (abstract)
decl node which this decl is an instance of, or else it is NULL indicating
that this decl is not an instance of some other decl. For example,
in a nested declaration of an inline function, this points back to the
definition. */
#define DECL_ABSTRACT_ORIGIN(NODE) (DECL_CHECK (NODE)->decl.abstract_origin)
/* Like DECL_ABSTRACT_ORIGIN, but returns NODE if there's no abstract
origin. This is useful when setting the DECL_ABSTRACT_ORIGIN. */
#define DECL_ORIGIN(NODE) \
(DECL_ABSTRACT_ORIGIN (NODE) ? DECL_ABSTRACT_ORIGIN (NODE) : (NODE))
/* Nonzero for any sort of ..._DECL node means this decl node represents an
inline instance of some original (abstract) decl from an inline function;
suppress any warnings about shadowing some other variable. FUNCTION_DECL
nodes can also have their abstract origin set to themselves. */
#define DECL_FROM_INLINE(NODE) (DECL_ABSTRACT_ORIGIN (NODE) != NULL_TREE \
&& DECL_ABSTRACT_ORIGIN (NODE) != (NODE))
/* Nonzero if a _DECL means that the name of this decl should be ignored
for symbolic debug purposes. */
#define DECL_IGNORED_P(NODE) (DECL_CHECK (NODE)->decl.ignored_flag)
/* Nonzero for a given ..._DECL node means that this node represents an
"abstract instance" of the given declaration (e.g. in the original
declaration of an inline function). When generating symbolic debugging
information, we mustn't try to generate any address information for nodes
marked as "abstract instances" because we don't actually generate
any code or allocate any data space for such instances. */
#define DECL_ABSTRACT(NODE) (DECL_CHECK (NODE)->decl.abstract_flag)
/* Nonzero if a _DECL means that no warnings should be generated just
because this decl is unused. */
#define DECL_IN_SYSTEM_HEADER(NODE) \
(DECL_CHECK (NODE)->decl.in_system_header_flag)
/* Nonzero for a given ..._DECL node means that this node should be
put in .common, if possible. If a DECL_INITIAL is given, and it
is not error_mark_node, then the decl cannot be put in .common. */
#define DECL_COMMON(NODE) (DECL_CHECK (NODE)->decl.common_flag)
/* Language-specific decl information. */
#define DECL_LANG_SPECIFIC(NODE) (DECL_CHECK (NODE)->decl.lang_specific)
/* In a VAR_DECL or FUNCTION_DECL,
nonzero means external reference:
do not allocate storage, and refer to a definition elsewhere. */
#define DECL_EXTERNAL(NODE) (DECL_CHECK (NODE)->decl.external_flag)
/* In a VAR_DECL for a RECORD_TYPE, sets number for non-init_priority
initializatons. */
#define DEFAULT_INIT_PRIORITY 65535
#define MAX_INIT_PRIORITY 65535
#define MAX_RESERVED_INIT_PRIORITY 100
/* In a TYPE_DECL
nonzero means the detail info about this type is not dumped into stabs.
Instead it will generate cross reference ('x') of names.
This uses the same flag as DECL_EXTERNAL. */
#define TYPE_DECL_SUPPRESS_DEBUG(NODE) \
(TYPE_DECL_CHECK (NODE)->decl.external_flag)
/* In VAR_DECL and PARM_DECL nodes, nonzero means declared `register'. */
#define DECL_REGISTER(NODE) (DECL_CHECK (NODE)->decl.regdecl_flag)
/* In LABEL_DECL nodes, nonzero means that an error message about
jumping into such a binding contour has been printed for this label. */
#define DECL_ERROR_ISSUED(NODE) (LABEL_DECL_CHECK (NODE)->decl.regdecl_flag)
/* In a FIELD_DECL, indicates this field should be bit-packed. */
#define DECL_PACKED(NODE) (FIELD_DECL_CHECK (NODE)->decl.regdecl_flag)
/* In a FUNCTION_DECL with a non-zero DECL_CONTEXT, indicates that a
static chain is not needed. */
#define DECL_NO_STATIC_CHAIN(NODE) \
(FUNCTION_DECL_CHECK (NODE)->decl.regdecl_flag)
/* Nonzero in a ..._DECL means this variable is ref'd from a nested function.
For VAR_DECL nodes, PARM_DECL nodes, and FUNCTION_DECL nodes.
For LABEL_DECL nodes, nonzero if nonlocal gotos to the label are permitted.
Also set in some languages for variables, etc., outside the normal
lexical scope, such as class instance variables. */
#define DECL_NONLOCAL(NODE) (DECL_CHECK (NODE)->decl.nonlocal_flag)
/* Nonzero in a FUNCTION_DECL means this function can be substituted
where it is called. */
#define DECL_INLINE(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.inline_flag)
/* In a FUNCTION_DECL, nonzero if the function cannot be inlined. */
#define DECL_UNINLINABLE(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.uninlinable)
/* In a FUNCTION_DECL, the saved representation of the body of the
entire function. Usually a COMPOUND_STMT, but in C++ this may also
be a RETURN_INIT, CTOR_INITIALIZER, or TRY_BLOCK. */
#define DECL_SAVED_TREE(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.saved_tree)
/* List of FUNCTION_DECLs inlined into this function's body. */
#define DECL_INLINED_FNS(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.inlined_fns)
/* Nonzero in a FUNCTION_DECL means this is a built-in function
that is not specified by ansi C and that users are supposed to be allowed
to redefine for any purpose whatever. */
#define DECL_BUILT_IN_NONANSI(NODE) \
(FUNCTION_DECL_CHECK (NODE)->common.unsigned_flag)
/* Nonzero in a FUNCTION_DECL means this function should be treated
as if it were a malloc, meaning it returns a pointer that is
not an alias. */
#define DECL_IS_MALLOC(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.malloc_flag)
/* Nonzero in a FUNCTION_DECL means this function should be treated
as "pure" function (like const function, but may read global memory). */
#define DECL_IS_PURE(NODE) (FUNCTION_DECL_CHECK (NODE)->decl.pure_flag)
/* Nonzero in a FIELD_DECL means it is a bit field, and must be accessed
specially. */
#define DECL_BIT_FIELD(NODE) (FIELD_DECL_CHECK (NODE)->decl.bit_field_flag)
/* In a LABEL_DECL, nonzero means label was defined inside a binding
contour that restored a stack level and which is now exited. */
#define DECL_TOO_LATE(NODE) (LABEL_DECL_CHECK (NODE)->decl.bit_field_flag)
/* Unused in FUNCTION_DECL. */
/* In a VAR_DECL that's static,
nonzero if the space is in the text section. */
#define DECL_IN_TEXT_SECTION(NODE) (VAR_DECL_CHECK (NODE)->decl.bit_field_flag)
/* In a FUNCTION_DECL, nonzero means a built in function. */
#define DECL_BUILT_IN(NODE) (DECL_BUILT_IN_CLASS (NODE) != NOT_BUILT_IN)
/* For a builtin function, identify which part of the compiler defined it. */
#define DECL_BUILT_IN_CLASS(NODE) \
(FUNCTION_DECL_CHECK (NODE)->decl.built_in_class)
/* Used in VAR_DECLs to indicate that the variable is a vtable.
Used in FIELD_DECLs for vtable pointers.
Used in FUNCTION_DECLs to indicate that the function is virtual. */
#define DECL_VIRTUAL_P(NODE) (DECL_CHECK (NODE)->decl.virtual_flag)
/* Used to indicate that the linkage status of this DECL is not yet known,
so it should not be output now. */
#define DECL_DEFER_OUTPUT(NODE) (DECL_CHECK (NODE)->decl.defer_output)
/* Used in PARM_DECLs whose type are unions to indicate that the
argument should be passed in the same way that the first union
alternative would be passed. */
#define DECL_TRANSPARENT_UNION(NODE) \
(PARM_DECL_CHECK (NODE)->decl.transparent_union)
/* Used in FUNCTION_DECLs to indicate that they should be run automatically
at the beginning or end of execution. */
#define DECL_STATIC_CONSTRUCTOR(NODE) \
(FUNCTION_DECL_CHECK (NODE)->decl.static_ctor_flag)
#define DECL_STATIC_DESTRUCTOR(NODE) \
(FUNCTION_DECL_CHECK (NODE)->decl.static_dtor_flag)
/* Used to indicate that this DECL represents a compiler-generated entity. */
#define DECL_ARTIFICIAL(NODE) (DECL_CHECK (NODE)->decl.artificial_flag)
/* Used to indicate that this DECL has weak linkage. */
#define DECL_WEAK(NODE) (DECL_CHECK (NODE)->decl.weak_flag)
/* Used in TREE_PUBLIC decls to indicate that copies of this DECL in
multiple translation units should be merged. */
#define DECL_ONE_ONLY(NODE) (DECL_CHECK (NODE)->decl.transparent_union)
/* Used in a DECL to indicate that, even if it TREE_PUBLIC, it need
not be put out unless it is needed in this translation unit.
Entities like this are shared across translation units (like weak
entities), but are guaranteed to be generated by any translation
unit that needs them, and therefore need not be put out anywhere
where they are not needed. DECL_COMDAT is just a hint to the
back-end; it is up to front-ends which set this flag to ensure
that there will never be any harm, other than bloat, in putting out
something which is DECL_COMDAT. */
#define DECL_COMDAT(NODE) (DECL_CHECK (NODE)->decl.comdat_flag)
/* Used in FUNCTION_DECLs to indicate that function entry and exit should
be instrumented with calls to support routines. */
#define DECL_NO_INSTRUMENT_FUNCTION_ENTRY_EXIT(NODE) \
(FUNCTION_DECL_CHECK (NODE)->decl.no_instrument_function_entry_exit)
/* Used in FUNCTION_DECLs to indicate that limit-stack-* should be
disabled in this function. */
#define DECL_NO_LIMIT_STACK(NODE) \
(FUNCTION_DECL_CHECK (NODE)->decl.no_limit_stack)
/* Additional flags for language-specific uses. */
#define DECL_LANG_FLAG_0(NODE) (DECL_CHECK (NODE)->decl.lang_flag_0)
#define DECL_LANG_FLAG_1(NODE) (DECL_CHECK (NODE)->decl.lang_flag_1)
#define DECL_LANG_FLAG_2(NODE) (DECL_CHECK (NODE)->decl.lang_flag_2)
#define DECL_LANG_FLAG_3(NODE) (DECL_CHECK (NODE)->decl.lang_flag_3)
#define DECL_LANG_FLAG_4(NODE) (DECL_CHECK (NODE)->decl.lang_flag_4)
#define DECL_LANG_FLAG_5(NODE) (DECL_CHECK (NODE)->decl.lang_flag_5)
#define DECL_LANG_FLAG_6(NODE) (DECL_CHECK (NODE)->decl.lang_flag_6)
#define DECL_LANG_FLAG_7(NODE) (DECL_CHECK (NODE)->decl.lang_flag_7)
/* Used to indicate that the pointer to this DECL cannot be treated as
an address constant. */
#define DECL_NON_ADDR_CONST_P(NODE) (DECL_CHECK (NODE)->decl.non_addr_const_p)
/* Used in a FIELD_DECL to indicate that we cannot form the address of
this component. */
#define DECL_NONADDRESSABLE_P(NODE) \
(FIELD_DECL_CHECK (NODE)->decl.non_addressable)
/* Used to indicate an alias set for the memory pointed to by this
particular FIELD_DECL, PARM_DECL, or VAR_DECL, which must have
pointer (or reference) type. */
#define DECL_POINTER_ALIAS_SET(NODE) \
(DECL_CHECK (NODE)->decl.pointer_alias_set)
/* Nonzero if an alias set has been assigned to this declaration. */
#define DECL_POINTER_ALIAS_SET_KNOWN_P(NODE) \
(DECL_POINTER_ALIAS_SET (NODE) != - 1)
/* The pointer_depth field comprises two bits for values in the range
0..3. The value is normally equal to TYPE_POINTER_DEPTH of decl's
type node, but for functions it migth be greater. For example,
this can happen when the function is declared to accept a parameter
of type void* (depth=1), but is actually called with an argument of
type foo** (depth=2). The function type will get the formal
parameter's depth, but the function decl will get the actual
argument's depth. */
#define DECL_POINTER_DEPTH(DECL) (DECL_CHECK (DECL)->decl.pointer_depth)
struct function;
struct tree_decl
{
struct tree_common common;
const char *filename;
int linenum;
unsigned int uid;
tree size;
ENUM_BITFIELD(machine_mode) mode : 8;
unsigned external_flag : 1;
unsigned nonlocal_flag : 1;
unsigned regdecl_flag : 1;
unsigned inline_flag : 1;
unsigned bit_field_flag : 1;
unsigned virtual_flag : 1;
unsigned ignored_flag : 1;
unsigned abstract_flag : 1;
unsigned in_system_header_flag : 1;
unsigned common_flag : 1;
unsigned defer_output : 1;
unsigned transparent_union : 1;
unsigned static_ctor_flag : 1;
unsigned static_dtor_flag : 1;
unsigned artificial_flag : 1;
unsigned weak_flag : 1;
unsigned non_addr_const_p : 1;
unsigned no_instrument_function_entry_exit : 1;
unsigned comdat_flag : 1;
unsigned malloc_flag : 1;
unsigned no_limit_stack : 1;
ENUM_BITFIELD(built_in_class) built_in_class : 2;
unsigned pure_flag : 1;
unsigned pointer_depth : 2;
unsigned non_addressable : 1;
unsigned user_align : 1;
unsigned uninlinable : 1;
/* Three unused bits. */
unsigned lang_flag_0 : 1;
unsigned lang_flag_1 : 1;
unsigned lang_flag_2 : 1;
unsigned lang_flag_3 : 1;
unsigned lang_flag_4 : 1;
unsigned lang_flag_5 : 1;
unsigned lang_flag_6 : 1;
unsigned lang_flag_7 : 1;
union {
/* In a FUNCTION_DECL for which DECL_BUILT_IN holds, this is
DECL_FUNCTION_CODE. */
enum built_in_function f;
/* In a FUNCITON_DECL for which DECL_BUILT_IN does not hold, this
is used by language-dependent code. */
HOST_WIDE_INT i;
/* DECL_ALIGN and DECL_OFFSET_ALIGN. (These are not used for
FUNCTION_DECLs). */
struct {unsigned int align : 24; unsigned int off_align : 8;} a;
} u1;
tree size_unit;
tree name;
tree context;
tree arguments; /* Also used for DECL_FIELD_OFFSET */
tree result; /* Also used for DECL_BIT_FIELD_TYPE */
tree initial; /* Also used for DECL_QUALIFIER */
tree abstract_origin;
tree assembler_name;
tree section_name;
tree attributes;
rtx rtl; /* RTL representation for object. */
rtx live_range_rtl;
/* In FUNCTION_DECL, if it is inline, holds the saved insn chain.
In FIELD_DECL, is DECL_FIELD_BIT_OFFSET.
In PARM_DECL, holds an RTL for the stack slot
of register where the data was actually passed.
Used by Chill and Java in LABEL_DECL and by C++ and Java in VAR_DECL. */
union {
struct function *f;
rtx r;
tree t;
int i;
} u2;
/* In a FUNCTION_DECL, this is DECL_SAVED_TREE. */
tree saved_tree;
/* In a FUNCTION_DECL, these are function data which is to be kept
as long as FUNCTION_DECL is kept. */
tree inlined_fns;
tree vindex;
HOST_WIDE_INT pointer_alias_set;
/* Points to a structure whose details depend on the language in use. */
struct lang_decl *lang_specific;
};
/* Define the overall contents of a tree node.
It may be any of the structures declared above
for various types of node. */
union tree_node
{
struct tree_common common;
struct tree_int_cst int_cst;
struct tree_real_cst real_cst;
struct tree_vector vector;
struct tree_string string;
struct tree_complex complex;
struct tree_identifier identifier;
struct tree_decl decl;
struct tree_type type;
struct tree_list list;
struct tree_vec vec;
struct tree_exp exp;
struct tree_block block;
};
/* Standard named or nameless data types of the C compiler. */
enum tree_index
{
TI_ERROR_MARK,
TI_INTQI_TYPE,
TI_INTHI_TYPE,
TI_INTSI_TYPE,
TI_INTDI_TYPE,
TI_INTTI_TYPE,
TI_UINTQI_TYPE,
TI_UINTHI_TYPE,
TI_UINTSI_TYPE,
TI_UINTDI_TYPE,
TI_UINTTI_TYPE,
TI_INTEGER_ZERO,
TI_INTEGER_ONE,
TI_INTEGER_MINUS_ONE,
TI_NULL_POINTER,
TI_SIZE_ZERO,
TI_SIZE_ONE,
TI_BITSIZE_ZERO,
TI_BITSIZE_ONE,
TI_BITSIZE_UNIT,
TI_COMPLEX_INTEGER_TYPE,
TI_COMPLEX_FLOAT_TYPE,
TI_COMPLEX_DOUBLE_TYPE,
TI_COMPLEX_LONG_DOUBLE_TYPE,
TI_FLOAT_TYPE,
TI_DOUBLE_TYPE,
TI_LONG_DOUBLE_TYPE,
TI_VOID_TYPE,
TI_PTR_TYPE,
TI_CONST_PTR_TYPE,
TI_PTRDIFF_TYPE,
TI_VA_LIST_TYPE,
TI_VOID_LIST_NODE,
TI_UV4SF_TYPE,
TI_UV4SI_TYPE,
TI_UV8HI_TYPE,
TI_UV8QI_TYPE,
TI_UV4HI_TYPE,
TI_UV2SI_TYPE,
TI_UV2SF_TYPE,
TI_UV16QI_TYPE,
TI_V4SF_TYPE,
TI_V16SF_TYPE,
TI_V4SI_TYPE,
TI_V8HI_TYPE,
TI_V8QI_TYPE,
TI_V4HI_TYPE,
TI_V2SI_TYPE,
TI_V2SF_TYPE,
TI_V16QI_TYPE,
TI_MAIN_IDENTIFIER,
TI_MAX
};
extern tree global_trees[TI_MAX];
#define error_mark_node global_trees[TI_ERROR_MARK]
#define intQI_type_node global_trees[TI_INTQI_TYPE]
#define intHI_type_node global_trees[TI_INTHI_TYPE]
#define intSI_type_node global_trees[TI_INTSI_TYPE]
#define intDI_type_node global_trees[TI_INTDI_TYPE]
#define intTI_type_node global_trees[TI_INTTI_TYPE]
#define unsigned_intQI_type_node global_trees[TI_UINTQI_TYPE]
#define unsigned_intHI_type_node global_trees[TI_UINTHI_TYPE]
#define unsigned_intSI_type_node global_trees[TI_UINTSI_TYPE]
#define unsigned_intDI_type_node global_trees[TI_UINTDI_TYPE]
#define unsigned_intTI_type_node global_trees[TI_UINTTI_TYPE]
#define integer_zero_node global_trees[TI_INTEGER_ZERO]
#define integer_one_node global_trees[TI_INTEGER_ONE]
#define integer_minus_one_node global_trees[TI_INTEGER_MINUS_ONE]
#define size_zero_node global_trees[TI_SIZE_ZERO]
#define size_one_node global_trees[TI_SIZE_ONE]
#define bitsize_zero_node global_trees[TI_BITSIZE_ZERO]
#define bitsize_one_node global_trees[TI_BITSIZE_ONE]
#define bitsize_unit_node global_trees[TI_BITSIZE_UNIT]
#define null_pointer_node global_trees[TI_NULL_POINTER]
#define float_type_node global_trees[TI_FLOAT_TYPE]
#define double_type_node global_trees[TI_DOUBLE_TYPE]
#define long_double_type_node global_trees[TI_LONG_DOUBLE_TYPE]
#define complex_integer_type_node global_trees[TI_COMPLEX_INTEGER_TYPE]
#define complex_float_type_node global_trees[TI_COMPLEX_FLOAT_TYPE]
#define complex_double_type_node global_trees[TI_COMPLEX_DOUBLE_TYPE]
#define complex_long_double_type_node global_trees[TI_COMPLEX_LONG_DOUBLE_TYPE]
#define void_type_node global_trees[TI_VOID_TYPE]
/* The C type `void *'. */
#define ptr_type_node global_trees[TI_PTR_TYPE]
/* The C type `const void *'. */
#define const_ptr_type_node global_trees[TI_CONST_PTR_TYPE]
#define ptrdiff_type_node global_trees[TI_PTRDIFF_TYPE]
#define va_list_type_node global_trees[TI_VA_LIST_TYPE]
/* The node that should be placed at the end of a parameter list to
indicate that the function does not take a variable number of
arguments. The TREE_VALUE will be void_type_node and there will be
no TREE_CHAIN. Language-independent code should not assume
anything else about this node. */
#define void_list_node global_trees[TI_VOID_LIST_NODE]
#define main_identifier_node global_trees[TI_MAIN_IDENTIFIER]
#define MAIN_NAME_P(NODE) (IDENTIFIER_NODE_CHECK (NODE) == main_identifier_node)
#define unsigned_V16QI_type_node global_trees[TI_UV16QI_TYPE]
#define unsigned_V4SI_type_node global_trees[TI_UV4SI_TYPE]
#define unsigned_V8QI_type_node global_trees[TI_UV8QI_TYPE]
#define unsigned_V8HI_type_node global_trees[TI_UV8HI_TYPE]
#define unsigned_V4HI_type_node global_trees[TI_UV4HI_TYPE]
#define unsigned_V2SI_type_node global_trees[TI_UV2SI_TYPE]
#define V16QI_type_node global_trees[TI_V16QI_TYPE]
#define V4SF_type_node global_trees[TI_V4SF_TYPE]
#define V4SI_type_node global_trees[TI_V4SI_TYPE]
#define V8QI_type_node global_trees[TI_V8QI_TYPE]
#define V8HI_type_node global_trees[TI_V8HI_TYPE]
#define V4HI_type_node global_trees[TI_V4HI_TYPE]
#define V2SI_type_node global_trees[TI_V2SI_TYPE]
#define V2SF_type_node global_trees[TI_V2SF_TYPE]
#define V16SF_type_node global_trees[TI_V16SF_TYPE]
/* An enumeration of the standard C integer types. These must be
ordered so that shorter types appear before longer ones. */
enum integer_type_kind
{
itk_char,
itk_signed_char,
itk_unsigned_char,
itk_short,
itk_unsigned_short,
itk_int,
itk_unsigned_int,
itk_long,
itk_unsigned_long,
itk_long_long,
itk_unsigned_long_long,
itk_none
};
typedef enum integer_type_kind integer_type_kind;
/* The standard C integer types. Use integer_type_kind to index into
this array. */
extern tree integer_types[itk_none];
#define char_type_node integer_types[itk_char]
#define signed_char_type_node integer_types[itk_signed_char]
#define unsigned_char_type_node integer_types[itk_unsigned_char]
#define short_integer_type_node integer_types[itk_short]
#define short_unsigned_type_node integer_types[itk_unsigned_short]
#define integer_type_node integer_types[itk_int]
#define unsigned_type_node integer_types[itk_unsigned_int]
#define long_integer_type_node integer_types[itk_long]
#define long_unsigned_type_node integer_types[itk_unsigned_long]
#define long_long_integer_type_node integer_types[itk_long_long]
#define long_long_unsigned_type_node integer_types[itk_unsigned_long_long]
/* A pointer-to-function member type looks like:
struct {
__P __pfn;
ptrdiff_t __delta;
};
If __pfn is NULL, it is a NULL pointer-to-member-function.
(Because the vtable is always the first thing in the object, we
don't need its offset.) If the function is virtual, then PFN is
one plus twice the index into the vtable; otherwise, it is just a
pointer to the function.
Unfortunately, using the lowest bit of PFN doesn't work in
architectures that don't impose alignment requirements on function
addresses, or that use the lowest bit to tell one ISA from another,
for example. For such architectures, we use the lowest bit of
DELTA instead of the lowest bit of the PFN, and DELTA will be
multiplied by 2. */
enum ptrmemfunc_vbit_where_t
{
ptrmemfunc_vbit_in_pfn,
ptrmemfunc_vbit_in_delta
};
#define NULL_TREE (tree) NULL
/* Approximate positive square root of a host double. This is for
statistical reports, not code generation. */
extern double approx_sqrt PARAMS ((double));
extern char *permalloc PARAMS ((int));
extern char *expralloc PARAMS ((int));
/* Compute the number of bytes occupied by 'node'. This routine only
looks at TREE_CODE and, if the code is TREE_VEC, TREE_VEC_LENGTH. */
extern size_t tree_size PARAMS ((tree));
/* Lowest level primitive for allocating a node.
The TREE_CODE is the only argument. Contents are initialized
to zero except for a few of the common fields. */
extern tree make_node PARAMS ((enum tree_code));
extern tree make_lang_type PARAMS ((enum tree_code));
extern tree (*make_lang_type_fn) PARAMS ((enum tree_code));
/* Make a copy of a node, with all the same contents except
for TREE_PERMANENT. (The copy is permanent
iff nodes being made now are permanent.) */
extern tree copy_node PARAMS ((tree));
/* Make a copy of a chain of TREE_LIST nodes. */
extern tree copy_list PARAMS ((tree));
/* Make a TREE_VEC. */
extern tree make_tree_vec PARAMS ((int));
/* Return the (unique) IDENTIFIER_NODE node for a given name.
The name is supplied as a char *. */
extern tree get_identifier PARAMS ((const char *));
/* Identical to get_identifier, except that the length is assumed
known. */
extern tree get_identifier_with_length PARAMS ((const char *, unsigned int));
/* If an identifier with the name TEXT (a null-terminated string) has
previously been referred to, return that node; otherwise return
NULL_TREE. */
extern tree maybe_get_identifier PARAMS ((const char *));
/* Construct various types of nodes. */
#define build_int_2(LO, HI) \
build_int_2_wide ((unsigned HOST_WIDE_INT) (LO), (HOST_WIDE_INT) (HI))
extern tree build PARAMS ((enum tree_code, tree, ...));
extern tree build_nt PARAMS ((enum tree_code, ...));
extern tree build_int_2_wide PARAMS ((unsigned HOST_WIDE_INT, HOST_WIDE_INT));
extern tree build_vector PARAMS ((tree, tree));
extern tree build_real PARAMS ((tree, REAL_VALUE_TYPE));
extern tree build_real_from_int_cst PARAMS ((tree, tree));
extern tree build_complex PARAMS ((tree, tree, tree));
extern tree build_string PARAMS ((int, const char *));
extern tree build1 PARAMS ((enum tree_code, tree, tree));
extern tree build_tree_list PARAMS ((tree, tree));
extern tree build_decl PARAMS ((enum tree_code, tree, tree));
extern tree build_block PARAMS ((tree, tree, tree, tree, tree));
extern tree build_expr_wfl PARAMS ((tree, const char *, int, int));
/* Construct various nodes representing data types. */
extern tree make_signed_type PARAMS ((int));
extern tree make_unsigned_type PARAMS ((int));
extern void initialize_sizetypes PARAMS ((void));
extern void set_sizetype PARAMS ((tree));
extern tree signed_or_unsigned_type PARAMS ((int, tree));
extern void fixup_unsigned_type PARAMS ((tree));
extern tree build_pointer_type PARAMS ((tree));
extern tree build_reference_type PARAMS ((tree));
extern tree build_type_no_quals PARAMS ((tree));
extern tree build_index_type PARAMS ((tree));
extern tree build_index_2_type PARAMS ((tree, tree));
extern tree build_array_type PARAMS ((tree, tree));
extern tree build_function_type PARAMS ((tree, tree));
extern tree build_method_type PARAMS ((tree, tree));
extern tree build_offset_type PARAMS ((tree, tree));
extern tree build_complex_type PARAMS ((tree));
extern tree array_type_nelts PARAMS ((tree));
extern tree value_member PARAMS ((tree, tree));
extern tree purpose_member PARAMS ((tree, tree));
extern tree binfo_member PARAMS ((tree, tree));
extern unsigned int attribute_hash_list PARAMS ((tree));
extern int attribute_list_equal PARAMS ((tree, tree));
extern int attribute_list_contained PARAMS ((tree, tree));
extern int tree_int_cst_equal PARAMS ((tree, tree));
extern int tree_int_cst_lt PARAMS ((tree, tree));
extern int tree_int_cst_compare PARAMS ((tree, tree));
extern int host_integerp PARAMS ((tree, int));
extern HOST_WIDE_INT tree_low_cst PARAMS ((tree, int));
extern int tree_int_cst_msb PARAMS ((tree));
extern int tree_int_cst_sgn PARAMS ((tree));
extern int tree_expr_nonnegative_p PARAMS ((tree));
extern int rtl_expr_nonnegative_p PARAMS ((rtx));
extern int index_type_equal PARAMS ((tree, tree));
extern tree get_inner_array_type PARAMS ((tree));
/* From expmed.c. Since rtl.h is included after tree.h, we can't
put the prototype here. Rtl.h does declare the prototype if
tree.h had been included. */
extern tree make_tree PARAMS ((tree, rtx));
/* Return a type like TTYPE except that its TYPE_ATTRIBUTES
is ATTRIBUTE.
Such modified types already made are recorded so that duplicates
are not made. */
extern tree build_type_attribute_variant PARAMS ((tree, tree));
extern tree build_decl_attribute_variant PARAMS ((tree, tree));
/* Structure describing an attribute and a function to handle it. */
struct attribute_spec
{
/* The name of the attribute (without any leading or trailing __),
or NULL to mark the end of a table of attributes. */
const char *const name;
/* The minimum length of the list of arguments of the attribute. */
const int min_length;
/* The maximum length of the list of arguments of the attribute
(-1 for no maximum). */
const int max_length;
/* Whether this attribute requires a DECL. If it does, it will be passed
from types of DECLs, function return types and array element types to
the DECLs, function types and array types respectively; but when
applied to a type in any other circumstances, it will be ignored with
a warning. (If greater control is desired for a given attribute,
this should be false, and the flags argument to the handler may be
used to gain greater control in that case.) */
const bool decl_required;
/* Whether this attribute requires a type. If it does, it will be passed
from a DECL to the type of that DECL. */
const bool type_required;
/* Whether this attribute requires a function (or method) type. If it does,
it will be passed from a function pointer type to the target type,
and from a function return type (which is not itself a function
pointer type) to the function type. */
const bool function_type_required;
/* Function to handle this attribute. NODE points to the node to which
the attribute is to be applied. If a DECL, it should be modified in
place; if a TYPE, a copy should be created. NAME is the name of the
attribute (possibly with leading or trailing __). ARGS is the TREE_LIST
of the arguments (which may be NULL). FLAGS gives further information
about the context of the attribute. Afterwards, the attributes will
be added to the DECL_ATTRIBUTES or TYPE_ATTRIBUTES, as appropriate,
unless *NO_ADD_ATTRS is set to true (which should be done on error,
as well as in any other cases when the attributes should not be added
to the DECL or TYPE). Depending on FLAGS, any attributes to be
applied to another type or DECL later may be returned;
otherwise the return value should be NULL_TREE. This pointer may be
NULL if no special handling is required beyond the checks implied
by the rest of this structure. */
tree (*const handler) PARAMS ((tree *node, tree name, tree args,
int flags, bool *no_add_attrs));
};
extern const struct attribute_spec default_target_attribute_table[];
/* Flags that may be passed in the third argument of decl_attributes, and
to handler functions for attributes. */
enum attribute_flags
{
/* The type passed in is the type of a DECL, and any attributes that
should be passed in again to be applied to the DECL rather than the
type should be returned. */
ATTR_FLAG_DECL_NEXT = 1,
/* The type passed in is a function return type, and any attributes that
should be passed in again to be applied to the function type rather
than the return type should be returned. */
ATTR_FLAG_FUNCTION_NEXT = 2,
/* The type passed in is an array element type, and any attributes that
should be passed in again to be applied to the array type rather
than the element type should be returned. */
ATTR_FLAG_ARRAY_NEXT = 4,
/* The type passed in is a structure, union or enumeration type being
created, and should be modified in place. */
ATTR_FLAG_TYPE_IN_PLACE = 8,
/* The attributes are being applied by default to a library function whose
name indicates known behavior, and should be silently ignored if they
are not in fact compatible with the function type. */
ATTR_FLAG_BUILT_IN = 16
};
/* Default versions of target-overridable functions. */
extern tree merge_decl_attributes PARAMS ((tree, tree));
extern tree merge_type_attributes PARAMS ((tree, tree));
extern int default_comp_type_attributes PARAMS ((tree, tree));
extern void default_set_default_type_attributes PARAMS ((tree));
extern void default_insert_attributes PARAMS ((tree, tree *));
extern bool default_function_attribute_inlinable_p PARAMS ((tree));
extern bool default_ms_bitfield_layout_p PARAMS ((tree));
/* Split a list of declspecs and attributes into two. */
extern void split_specs_attrs PARAMS ((tree, tree *, tree *));
/* Strip attributes from a list of combined specs and attrs. */
extern tree strip_attrs PARAMS ((tree));
/* Return 1 if an attribute and its arguments are valid for a decl or type. */
extern int valid_machine_attribute PARAMS ((tree, tree, tree, tree));
/* Given a tree node and a string, return non-zero if the tree node is
a valid attribute name for the string. */
extern int is_attribute_p PARAMS ((const char *, tree));
/* Given an attribute name and a list of attributes, return the list element
of the attribute or NULL_TREE if not found. */
extern tree lookup_attribute PARAMS ((const char *, tree));
/* Given two attributes lists, return a list of their union. */
extern tree merge_attributes PARAMS ((tree, tree));
#ifdef TARGET_DLLIMPORT_DECL_ATTRIBUTES
/* Given two Windows decl attributes lists, possibly including
dllimport, return a list of their union . */
extern tree merge_dllimport_decl_attributes PARAMS ((tree, tree));
#endif
/* Return a version of the TYPE, qualified as indicated by the
TYPE_QUALS, if one exists. If no qualified version exists yet,
return NULL_TREE. */
extern tree get_qualified_type PARAMS ((tree, int));
/* Like get_qualified_type, but creates the type if it does not
exist. This function never returns NULL_TREE. */
extern tree build_qualified_type PARAMS ((tree, int));
/* Like build_qualified_type, but only deals with the `const' and
`volatile' qualifiers. This interface is retained for backwards
compatiblity with the various front-ends; new code should use
build_qualified_type instead. */
#define build_type_variant(TYPE, CONST_P, VOLATILE_P) \
build_qualified_type ((TYPE), \
((CONST_P) ? TYPE_QUAL_CONST : 0) \
| ((VOLATILE_P) ? TYPE_QUAL_VOLATILE : 0))
/* Make a copy of a type node. */
extern tree build_type_copy PARAMS ((tree));
/* Given a ..._TYPE node, calculate the TYPE_SIZE, TYPE_SIZE_UNIT,
TYPE_ALIGN and TYPE_MODE fields. If called more than once on one
node, does nothing except for the first time. */
extern void layout_type PARAMS ((tree));
/* These functions allow a front-end to perform a manual layout of a
RECORD_TYPE. (For instance, if the placement of subsequent fields
depends on the placement of fields so far.) Begin by calling
start_record_layout. Then, call place_field for each of the
fields. Then, call finish_record_layout. See layout_type for the
default way in which these functions are used. */
typedef struct record_layout_info_s
{
/* The RECORD_TYPE that we are laying out. */
tree t;
/* The offset into the record so far, in bytes, not including bits in
BITPOS. */
tree offset;
/* The last known alignment of SIZE. */
unsigned int offset_align;
/* The bit position within the last OFFSET_ALIGN bits, in bits. */
tree bitpos;
/* The alignment of the record so far, in bits. */
unsigned int record_align;
/* The alignment of the record so far, not including padding, in bits. */
unsigned int unpacked_align;
/* The alignment of the record so far, allowing for the record to be
padded only at the end, in bits. */
unsigned int unpadded_align;
/* The previous field layed out. */
tree prev_field;
/* The static variables (i.e., class variables, as opposed to
instance variables) encountered in T. */
tree pending_statics;
int packed_maybe_necessary;
} *record_layout_info;
extern void set_lang_adjust_rli PARAMS ((void (*) PARAMS
((record_layout_info))));
extern record_layout_info start_record_layout PARAMS ((tree));
extern tree bit_from_pos PARAMS ((tree, tree));
extern tree byte_from_pos PARAMS ((tree, tree));
extern void pos_from_byte PARAMS ((tree *, tree *, unsigned int,
tree));
extern void pos_from_bit PARAMS ((tree *, tree *, unsigned int,
tree));
extern void normalize_offset PARAMS ((tree *, tree *,
unsigned int));
extern tree rli_size_unit_so_far PARAMS ((record_layout_info));
extern tree rli_size_so_far PARAMS ((record_layout_info));
extern void normalize_rli PARAMS ((record_layout_info));
extern void place_field PARAMS ((record_layout_info, tree));
extern void compute_record_mode PARAMS ((tree));
extern void finish_record_layout PARAMS ((record_layout_info));
/* Given a hashcode and a ..._TYPE node (for which the hashcode was made),
return a canonicalized ..._TYPE node, so that duplicates are not made.
How the hash code is computed is up to the caller, as long as any two
callers that could hash identical-looking type nodes agree. */
extern tree type_hash_canon PARAMS ((unsigned int, tree));
/* Given a VAR_DECL, PARM_DECL, RESULT_DECL or FIELD_DECL node,
calculates the DECL_SIZE, DECL_SIZE_UNIT, DECL_ALIGN and DECL_MODE
fields. Call this only once for any given decl node.
Second argument is the boundary that this field can be assumed to
be starting at (in bits). Zero means it can be assumed aligned
on any boundary that may be needed. */
extern void layout_decl PARAMS ((tree, unsigned));
/* Return the mode for data of a given size SIZE and mode class CLASS.
If LIMIT is nonzero, then don't use modes bigger than MAX_FIXED_MODE_SIZE.
The value is BLKmode if no other mode is found. This is like
mode_for_size, but is passed a tree. */
extern enum machine_mode mode_for_size_tree PARAMS ((tree, enum mode_class,
int));
/* Return an expr equal to X but certainly not valid as an lvalue. */
extern tree non_lvalue PARAMS ((tree));
extern tree pedantic_non_lvalue PARAMS ((tree));
extern tree convert PARAMS ((tree, tree));
extern unsigned int expr_align PARAMS ((tree));
extern tree size_in_bytes PARAMS ((tree));
extern HOST_WIDE_INT int_size_in_bytes PARAMS ((tree));
extern tree bit_position PARAMS ((tree));
extern HOST_WIDE_INT int_bit_position PARAMS ((tree));
extern tree byte_position PARAMS ((tree));
extern HOST_WIDE_INT int_byte_position PARAMS ((tree));
/* Define data structures, macros, and functions for handling sizes
and the various types used to represent sizes. */
enum size_type_kind
{
SIZETYPE, /* Normal representation of sizes in bytes. */
SSIZETYPE, /* Signed representation of sizes in bytes. */
USIZETYPE, /* Unsigned representation of sizes in bytes. */
BITSIZETYPE, /* Normal representation of sizes in bits. */
SBITSIZETYPE, /* Signed representation of sizes in bits. */
UBITSIZETYPE, /* Unsifgned representation of sizes in bits. */
TYPE_KIND_LAST};
extern tree sizetype_tab[(int) TYPE_KIND_LAST];
#define sizetype sizetype_tab[(int) SIZETYPE]
#define bitsizetype sizetype_tab[(int) BITSIZETYPE]
#define ssizetype sizetype_tab[(int) SSIZETYPE]
#define usizetype sizetype_tab[(int) USIZETYPE]
#define sbitsizetype sizetype_tab[(int) SBITSIZETYPE]
#define ubitsizetype sizetype_tab[(int) UBITSIZETYPE]
extern tree size_binop PARAMS ((enum tree_code, tree, tree));
extern tree size_diffop PARAMS ((tree, tree));
extern tree size_int_wide PARAMS ((HOST_WIDE_INT,
enum size_type_kind));
extern tree size_int_type_wide PARAMS ((HOST_WIDE_INT, tree));
#define size_int_type(L, T) size_int_type_wide ((HOST_WIDE_INT) (L), T)
#define size_int(L) size_int_wide ((HOST_WIDE_INT) (L), SIZETYPE)
#define ssize_int(L) size_int_wide ((HOST_WIDE_INT) (L), SSIZETYPE)
#define bitsize_int(L) size_int_wide ((HOST_WIDE_INT) (L), BITSIZETYPE)
#define sbitsize_int(L) size_int_wide ((HOST_WIDE_INT) (L), SBITSIZETYPE)
extern tree round_up PARAMS ((tree, int));
extern tree round_down PARAMS ((tree, int));
extern tree get_pending_sizes PARAMS ((void));
extern int is_pending_size PARAMS ((tree));
extern void put_pending_size PARAMS ((tree));
extern void put_pending_sizes PARAMS ((tree));
/* Type for sizes of data-type. */
#define BITS_PER_UNIT_LOG \
((BITS_PER_UNIT > 1) + (BITS_PER_UNIT > 2) + (BITS_PER_UNIT > 4) \
+ (BITS_PER_UNIT > 8) + (BITS_PER_UNIT > 16) + (BITS_PER_UNIT > 32) \
+ (BITS_PER_UNIT > 64) + (BITS_PER_UNIT > 128) + (BITS_PER_UNIT > 256))
/* If nonzero, an upper limit on alignment of structure fields, in bits. */
extern unsigned int maximum_field_alignment;
/* If non-zero, the alignment of a bitstring or (power-)set value, in bits. */
extern unsigned int set_alignment;
/* Concatenate two lists (chains of TREE_LIST nodes) X and Y
by making the last node in X point to Y.
Returns X, except if X is 0 returns Y. */
extern tree chainon PARAMS ((tree, tree));
/* Make a new TREE_LIST node from specified PURPOSE, VALUE and CHAIN. */
extern tree tree_cons PARAMS ((tree, tree, tree));
/* Return the last tree node in a chain. */
extern tree tree_last PARAMS ((tree));
/* Reverse the order of elements in a chain, and return the new head. */
extern tree nreverse PARAMS ((tree));
/* Returns the length of a chain of nodes
(number of chain pointers to follow before reaching a null pointer). */
extern int list_length PARAMS ((tree));
/* Returns the number of FIELD_DECLs in a type. */
extern int fields_length PARAMS ((tree));
/* integer_zerop (tree x) is nonzero if X is an integer constant of value 0 */
extern int integer_zerop PARAMS ((tree));
/* integer_onep (tree x) is nonzero if X is an integer constant of value 1 */
extern int integer_onep PARAMS ((tree));
/* integer_all_onesp (tree x) is nonzero if X is an integer constant
all of whose significant bits are 1. */
extern int integer_all_onesp PARAMS ((tree));
/* integer_pow2p (tree x) is nonzero is X is an integer constant with
exactly one bit 1. */
extern int integer_pow2p PARAMS ((tree));
/* staticp (tree x) is nonzero if X is a reference to data allocated
at a fixed address in memory. */
extern int staticp PARAMS ((tree));
/* Gets an error if argument X is not an lvalue.
Also returns 1 if X is an lvalue, 0 if not. */
extern int lvalue_or_else PARAMS ((tree, const char *));
/* save_expr (EXP) returns an expression equivalent to EXP
but it can be used multiple times within context CTX
and only evaluate EXP once. */
extern tree save_expr PARAMS ((tree));
/* Returns the index of the first non-tree operand for CODE, or the number
of operands if all are trees. */
extern int first_rtl_op PARAMS ((enum tree_code));
/* unsave_expr (EXP) returns an expression equivalent to EXP but it
can be used multiple times and will evaluate EXP in its entirety
each time. */
extern tree unsave_expr PARAMS ((tree));
/* Reset EXP in place so that it can be expaned again. Does not
recurse into subtrees. */
extern void unsave_expr_1 PARAMS ((tree));
/* Like unsave_expr_1, but recurses into all subtrees. */
extern tree unsave_expr_now PARAMS ((tree));
/* If non-null, these are language-specific helper functions for
unsave_expr_now. If present, LANG_UNSAVE is called before its
argument (an UNSAVE_EXPR) is to be unsaved, and all other
processing in unsave_expr_now is aborted. LANG_UNSAVE_EXPR_NOW is
called from unsave_expr_1 for language-specific tree codes. */
extern void (*lang_unsave) PARAMS ((tree *));
extern void (*lang_unsave_expr_now) PARAMS ((tree));
/* Return 0 if it is safe to evaluate EXPR multiple times,
return 1 if it is safe if EXPR is unsaved afterward, or
return 2 if it is completely unsafe. */
extern int unsafe_for_reeval PARAMS ((tree));
/* If non-null, these are language-specific helper functions for
unsafe_for_reeval. Return negative to not handle some tree. */
extern int (*lang_unsafe_for_reeval) PARAMS ((tree));
/* Return 1 if EXP contains a PLACEHOLDER_EXPR; i.e., if it represents a size
or offset that depends on a field within a record.
Note that we only allow such expressions within simple arithmetic
or a COND_EXPR. */
extern int contains_placeholder_p PARAMS ((tree));
/* Return 1 if EXP contains any expressions that produce cleanups for an
outer scope to deal with. Used by fold. */
extern int has_cleanups PARAMS ((tree));
/* Given a tree EXP, a FIELD_DECL F, and a replacement value R,
return a tree with all occurrences of references to F in a
PLACEHOLDER_EXPR replaced by R. Note that we assume here that EXP
contains only arithmetic expressions. */
extern tree substitute_in_expr PARAMS ((tree, tree, tree));
/* variable_size (EXP) is like save_expr (EXP) except that it
is for the special case of something that is part of a
variable size for a data type. It makes special arrangements
to compute the value at the right time when the data type
belongs to a function parameter. */
extern tree variable_size PARAMS ((tree));
/* stabilize_reference (EXP) returns an reference equivalent to EXP
but it can be used multiple times
and only evaluate the subexpressions once. */
extern tree stabilize_reference PARAMS ((tree));
/* Subroutine of stabilize_reference; this is called for subtrees of
references. Any expression with side-effects must be put in a SAVE_EXPR
to ensure that it is only evaluated once. */
extern tree stabilize_reference_1 PARAMS ((tree));
/* Return EXP, stripped of any conversions to wider types
in such a way that the result of converting to type FOR_TYPE
is the same as if EXP were converted to FOR_TYPE.
If FOR_TYPE is 0, it signifies EXP's type. */
extern tree get_unwidened PARAMS ((tree, tree));
/* Return OP or a simpler expression for a narrower value
which can be sign-extended or zero-extended to give back OP.
Store in *UNSIGNEDP_PTR either 1 if the value should be zero-extended
or 0 if the value should be sign-extended. */
extern tree get_narrower PARAMS ((tree, int *));
/* Given MODE and UNSIGNEDP, return a suitable type-tree
with that mode.
The definition of this resides in language-specific code
as the repertoire of available types may vary. */
extern tree type_for_mode PARAMS ((enum machine_mode, int));
/* Given PRECISION and UNSIGNEDP, return a suitable type-tree
for an integer type with at least that precision.
The definition of this resides in language-specific code
as the repertoire of available types may vary. */
extern tree type_for_size PARAMS ((unsigned, int));
/* Given an integer type T, return a type like T but unsigned.
If T is unsigned, the value is T.
The definition of this resides in language-specific code
as the repertoire of available types may vary. */
extern tree unsigned_type PARAMS ((tree));
/* Given an integer type T, return a type like T but signed.
If T is signed, the value is T.
The definition of this resides in language-specific code
as the repertoire of available types may vary. */
extern tree signed_type PARAMS ((tree));
/* This function must be defined in the language-specific files.
expand_expr calls it to build the cleanup-expression for a TARGET_EXPR.
This is defined in a language-specific file. */
extern tree maybe_build_cleanup PARAMS ((tree));
/* Given an expression EXP that may be a COMPONENT_REF or an ARRAY_REF,
look for nested component-refs or array-refs at constant positions
and find the ultimate containing object, which is returned. */
extern tree get_inner_reference PARAMS ((tree, HOST_WIDE_INT *,
HOST_WIDE_INT *, tree *,
enum machine_mode *, int *,
int *));
/* Return 1 if T is an expression that get_inner_reference handles. */
extern int handled_component_p PARAMS ((tree));
/* Given a DECL or TYPE, return the scope in which it was declared, or
NUL_TREE if there is no containing scope. */
extern tree get_containing_scope PARAMS ((tree));
/* Return the FUNCTION_DECL which provides this _DECL with its context,
or zero if none. */
extern tree decl_function_context PARAMS ((tree));
/* Return the RECORD_TYPE, UNION_TYPE, or QUAL_UNION_TYPE which provides
this _DECL with its context, or zero if none. */
extern tree decl_type_context PARAMS ((tree));
/* Given the FUNCTION_DECL for the current function,
return zero if it is ok for this function to be inline.
Otherwise return a warning message with a single %s
for the function's name. */
extern const char *function_cannot_inline_p PARAMS ((tree));
/* Return 1 if EXPR is the real constant zero. */
extern int real_zerop PARAMS ((tree));
/* Declare commonly used variables for tree structure. */
/* Points to the name of the input file from which the current input
being parsed originally came (before it went into cpp). */
extern const char *input_filename;
/* Current line number in input file. */
extern int lineno;
/* Nonzero means lvalues are limited to those valid in pedantic ANSI C.
Zero means allow extended lvalues. */
extern int pedantic_lvalues;
/* Nonzero means can safely call expand_expr now;
otherwise layout_type puts variable sizes onto `pending_sizes' instead. */
extern int immediate_size_expand;
/* Points to the FUNCTION_DECL of the function whose body we are reading. */
extern tree current_function_decl;
/* Nonzero means a FUNC_BEGIN label was emitted. */
extern tree current_function_func_begin_label;
/* Nonzero means all ..._TYPE nodes should be allocated permanently. */
extern int all_types_permanent;
/* Pointer to function to compute the name to use to print a declaration.
DECL is the declaration in question.
VERBOSITY determines what information will be printed:
0: DECL_NAME, demangled as necessary.
1: and scope information.
2: and any other information that might be interesting, such as function
parameter types in C++. */
extern const char *(*decl_printable_name) PARAMS ((tree, int));
/* Pointer to function to finish handling an incomplete decl at the
end of compilation. */
extern void (*incomplete_decl_finalize_hook) PARAMS ((tree));
/* Declare a predefined function. Return the declaration. This function is
provided by each language frontend. */
extern tree builtin_function PARAMS ((const char *, tree, int,
enum built_in_class,
const char *));
/* In tree.c */
extern char *perm_calloc PARAMS ((int, long));
extern void clean_symbol_name PARAMS ((char *));
extern tree get_file_function_name_long PARAMS ((const char *));
extern tree get_set_constructor_bits PARAMS ((tree, char *, int));
extern tree get_set_constructor_bytes PARAMS ((tree,
unsigned char *, int));
extern tree get_callee_fndecl PARAMS ((tree));
extern void set_decl_assembler_name PARAMS ((tree));
extern int type_num_arguments PARAMS ((tree));
/* In stmt.c */
extern int in_control_zone_p PARAMS ((void));
extern void expand_fixups PARAMS ((rtx));
extern tree expand_start_stmt_expr PARAMS ((int));
extern tree expand_end_stmt_expr PARAMS ((tree));
extern void expand_expr_stmt PARAMS ((tree));
extern void expand_expr_stmt_value PARAMS ((tree, int, int));
extern int warn_if_unused_value PARAMS ((tree));
extern void expand_decl_init PARAMS ((tree));
extern void clear_last_expr PARAMS ((void));
extern void expand_label PARAMS ((tree));
extern void expand_goto PARAMS ((tree));
extern void expand_asm PARAMS ((tree));
extern void expand_start_cond PARAMS ((tree, int));
extern void expand_end_cond PARAMS ((void));
extern void expand_start_else PARAMS ((void));
extern void expand_start_elseif PARAMS ((tree));
extern struct nesting *expand_start_loop PARAMS ((int));
extern struct nesting *expand_start_loop_continue_elsewhere PARAMS ((int));
extern struct nesting *expand_start_null_loop PARAMS ((void));
extern void expand_loop_continue_here PARAMS ((void));
extern void expand_end_loop PARAMS ((void));
extern void expand_end_null_loop PARAMS ((void));
extern int expand_continue_loop PARAMS ((struct nesting *));
extern int expand_exit_loop PARAMS ((struct nesting *));
extern int expand_exit_loop_if_false PARAMS ((struct nesting *,
tree));
extern int expand_exit_loop_top_cond PARAMS ((struct nesting *,
tree));
extern int expand_exit_something PARAMS ((void));
extern void expand_return PARAMS ((tree));
extern int optimize_tail_recursion PARAMS ((tree, rtx));
extern void expand_start_bindings_and_block PARAMS ((int, tree));
#define expand_start_bindings(flags) \
expand_start_bindings_and_block(flags, NULL_TREE)
extern void expand_end_bindings PARAMS ((tree, int, int));
extern void warn_about_unused_variables PARAMS ((tree));
extern void start_cleanup_deferral PARAMS ((void));
extern void end_cleanup_deferral PARAMS ((void));
extern int is_body_block PARAMS ((tree));
extern int conditional_context PARAMS ((void));
extern struct nesting * current_nesting_level PARAMS ((void));
extern tree last_cleanup_this_contour PARAMS ((void));
extern void expand_start_case PARAMS ((int, tree, tree,
const char *));
extern void expand_end_case_type PARAMS ((tree, tree));
#define expand_end_case(cond) expand_end_case_type (cond, NULL)
extern int add_case_node PARAMS ((tree, tree,
tree, tree *));
extern int pushcase PARAMS ((tree,
tree (*) (tree, tree),
tree, tree *));
extern int pushcase_range PARAMS ((tree, tree,
tree (*) (tree, tree),
tree, tree *));
extern void using_eh_for_cleanups PARAMS ((void));
extern int stmt_loop_nest_empty PARAMS ((void));
/* In fold-const.c */
/* Fold constants as much as possible in an expression.
Returns the simplified expression.
Acts only on the top level of the expression;
if the argument itself cannot be simplified, its
subexpressions are not changed. */
extern tree fold PARAMS ((tree));
extern int force_fit_type PARAMS ((tree, int));
extern int add_double PARAMS ((unsigned HOST_WIDE_INT, HOST_WIDE_INT,
unsigned HOST_WIDE_INT, HOST_WIDE_INT,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *));
extern int neg_double PARAMS ((unsigned HOST_WIDE_INT, HOST_WIDE_INT,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *));
extern int mul_double PARAMS ((unsigned HOST_WIDE_INT,
HOST_WIDE_INT,
unsigned HOST_WIDE_INT, HOST_WIDE_INT,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *));
extern void lshift_double PARAMS ((unsigned HOST_WIDE_INT, HOST_WIDE_INT,
HOST_WIDE_INT, unsigned int,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *, int));
extern void rshift_double PARAMS ((unsigned HOST_WIDE_INT, HOST_WIDE_INT,
HOST_WIDE_INT, unsigned int,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *, int));
extern void lrotate_double PARAMS ((unsigned HOST_WIDE_INT, HOST_WIDE_INT,
HOST_WIDE_INT, unsigned int,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *));
extern void rrotate_double PARAMS ((unsigned HOST_WIDE_INT, HOST_WIDE_INT,
HOST_WIDE_INT, unsigned int,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *));
extern int operand_equal_p PARAMS ((tree, tree, int));
extern tree invert_truthvalue PARAMS ((tree));
/* In builtins.c. Given a type, apply default promotions wrt unnamed
function arguments and return the new type. Return NULL_TREE if no
change. Required by any language that supports variadic arguments. */
extern tree (*lang_type_promotes_to) PARAMS ((tree));
extern tree fold_builtin PARAMS ((tree));
/* The language front-end must define these functions. */
/* Function to replace the DECL_LANG_SPECIFIC field of a DECL with a copy. */
extern void copy_lang_decl PARAMS ((tree));
/* Function called with no arguments to parse and compile the input. */
extern int yyparse PARAMS ((void));
/* Functions for processing symbol declarations. */
/* Function to enter a new lexical scope.
Takes one argument: always zero when called from outside the front end. */
extern void pushlevel PARAMS ((int));
/* Function to exit a lexical scope. It returns a BINDING for that scope.
Takes three arguments:
KEEP -- nonzero if there were declarations in this scope.
REVERSE -- reverse the order of decls before returning them.
FUNCTIONBODY -- nonzero if this level is the body of a function. */
extern tree poplevel PARAMS ((int, int, int));
/* Set the BLOCK node for the current scope level. */
extern void set_block PARAMS ((tree));
/* Function to add a decl to the current scope level.
Takes one argument, a decl to add.
Returns that decl, or, if the same symbol is already declared, may
return a different decl for that name. */
extern tree pushdecl PARAMS ((tree));
/* Function to return the chain of decls so far in the current scope level. */
extern tree getdecls PARAMS ((void));
/* Function to return the chain of structure tags in the current scope level. */
extern tree gettags PARAMS ((void));
extern tree build_range_type PARAMS ((tree, tree, tree));
/* In alias.c */
extern void record_component_aliases PARAMS ((tree));
extern HOST_WIDE_INT get_alias_set PARAMS ((tree));
extern int alias_sets_conflict_p PARAMS ((HOST_WIDE_INT,
HOST_WIDE_INT));
extern int readonly_fields_p PARAMS ((tree));
extern int objects_must_conflict_p PARAMS ((tree, tree));
/* Set the DECL_ASSEMBLER_NAME for a node. If it is the sort of thing
that the assembler should talk about, set DECL_ASSEMBLER_NAME to an
appropriate IDENTIFIER_NODE. Otherwise, set it to the
ERROR_MARK_NODE to ensure that the assembler does not talk about
it. */
extern void (*lang_set_decl_assembler_name) PARAMS ((tree));
struct obstack;
/* In tree.c */
extern int really_constant_p PARAMS ((tree));
extern int int_fits_type_p PARAMS ((tree, tree));
extern bool variably_modified_type_p PARAMS ((tree));
extern int tree_log2 PARAMS ((tree));
extern int tree_floor_log2 PARAMS ((tree));
extern void preserve_data PARAMS ((void));
extern int object_permanent_p PARAMS ((tree));
extern int type_precision PARAMS ((tree));
extern int simple_cst_equal PARAMS ((tree, tree));
extern int compare_tree_int PARAMS ((tree,
unsigned HOST_WIDE_INT));
extern int type_list_equal PARAMS ((tree, tree));
extern int chain_member PARAMS ((tree, tree));
extern int chain_member_purpose PARAMS ((tree, tree));
extern int chain_member_value PARAMS ((tree, tree));
extern tree listify PARAMS ((tree));
extern tree type_hash_lookup PARAMS ((unsigned int, tree));
extern void type_hash_add PARAMS ((unsigned int, tree));
extern unsigned int type_hash_list PARAMS ((tree));
extern int simple_cst_list_equal PARAMS ((tree, tree));
extern void dump_tree_statistics PARAMS ((void));
extern void print_obstack_statistics PARAMS ((const char *,
struct obstack *));
#ifdef BUFSIZ
extern void print_obstack_name PARAMS ((char *, FILE *,
const char *));
#endif
extern void expand_function_end PARAMS ((const char *, int, int));
extern void expand_function_start PARAMS ((tree, int));
extern void expand_pending_sizes PARAMS ((tree));
extern int real_onep PARAMS ((tree));
extern int real_twop PARAMS ((tree));
extern void gcc_obstack_init PARAMS ((struct obstack *));
extern void init_obstacks PARAMS ((void));
extern void build_common_tree_nodes PARAMS ((int));
extern void build_common_tree_nodes_2 PARAMS ((int));
extern void mark_tree_hashtable PARAMS ((void *));
/* In function.c */
extern void setjmp_protect_args PARAMS ((void));
extern void setjmp_protect PARAMS ((tree));
extern void expand_main_function PARAMS ((void));
extern void mark_varargs PARAMS ((void));
extern void init_dummy_function_start PARAMS ((void));
extern void expand_dummy_function_end PARAMS ((void));
extern void init_function_for_compilation PARAMS ((void));
extern void init_function_start PARAMS ((tree, const char *, int));
extern void assign_parms PARAMS ((tree));
extern void put_var_into_stack PARAMS ((tree));
extern void flush_addressof PARAMS ((tree));
extern void uninitialized_vars_warning PARAMS ((tree));
extern void setjmp_args_warning PARAMS ((void));
extern void mark_all_temps_used PARAMS ((void));
extern void init_temp_slots PARAMS ((void));
extern void combine_temp_slots PARAMS ((void));
extern void free_temp_slots PARAMS ((void));
extern void pop_temp_slots PARAMS ((void));
extern void push_temp_slots PARAMS ((void));
extern void preserve_temp_slots PARAMS ((rtx));
extern void preserve_rtl_expr_temps PARAMS ((tree));
extern int aggregate_value_p PARAMS ((tree));
extern void free_temps_for_rtl_expr PARAMS ((tree));
extern void instantiate_virtual_regs PARAMS ((tree, rtx));
extern void unshare_all_rtl PARAMS ((tree, rtx));
extern int max_parm_reg_num PARAMS ((void));
extern void push_function_context PARAMS ((void));
extern void pop_function_context PARAMS ((void));
extern void push_function_context_to PARAMS ((tree));
extern void pop_function_context_from PARAMS ((tree));
extern void ggc_mark_struct_function PARAMS ((struct function *));
/* In print-rtl.c */
#ifdef BUFSIZ
extern void print_rtl PARAMS ((FILE *, rtx));
#endif
/* In print-tree.c */
extern void debug_tree PARAMS ((tree));
#ifdef BUFSIZ
extern void print_node PARAMS ((FILE *, const char *, tree,
int));
extern void print_node_brief PARAMS ((FILE *, const char *, tree,
int));
extern void indent_to PARAMS ((FILE *, int));
#endif
/* In expr.c */
extern int apply_args_register_offset PARAMS ((int));
extern rtx expand_builtin_return_addr
PARAMS ((enum built_in_function, int, rtx));
extern void check_max_integer_computation_mode PARAMS ((tree));
/* In emit-rtl.c */
extern void start_sequence_for_rtl_expr PARAMS ((tree));
extern rtx emit_line_note PARAMS ((const char *, int));
/* In calls.c */
extern int setjmp_call_p PARAMS ((tree));
/* In attribs.c. */
/* Process the attributes listed in ATTRIBUTES and install them in *NODE,
which is either a DECL (including a TYPE_DECL) or a TYPE. If a DECL,
it should be modified in place; if a TYPE, a copy should be created
unless ATTR_FLAG_TYPE_IN_PLACE is set in FLAGS. FLAGS gives further
information, in the form of a bitwise OR of flags in enum attribute_flags
from tree.h. Depending on these flags, some attributes may be
returned to be applied at a later stage (for example, to apply
a decl attribute to the declaration rather than to its type). */
extern tree decl_attributes PARAMS ((tree *, tree, int));
/* The following function must be provided by front ends
using attribs.c. */
/* Possibly apply default attributes to a function (represented by
a FUNCTION_DECL). */
extern void insert_default_attributes PARAMS ((tree));
/* Table of machine-independent attributes for checking formats, if used. */
extern const struct attribute_spec *format_attribute_table;
/* Table of machine-independent attributes for a particular language. */
extern const struct attribute_spec *lang_attribute_table;
/* Flag saying whether common language attributes are to be supported. */
extern int lang_attribute_common;
/* In front end. */
extern int mark_addressable PARAMS ((tree));
extern void incomplete_type_error PARAMS ((tree, tree));
extern tree truthvalue_conversion PARAMS ((tree));
extern int global_bindings_p PARAMS ((void));
extern void insert_block PARAMS ((tree));
/* In integrate.c */
extern void save_for_inline PARAMS ((tree));
extern void set_decl_abstract_flags PARAMS ((tree, int));
extern void output_inline_function PARAMS ((tree));
extern void set_decl_origin_self PARAMS ((tree));
/* In stor-layout.c */
extern void fixup_signed_type PARAMS ((tree));
extern void internal_reference_types PARAMS ((void));
/* varasm.c */
extern void make_decl_rtl PARAMS ((tree, const char *));
extern void make_decl_one_only PARAMS ((tree));
extern int supports_one_only PARAMS ((void));
extern void variable_section PARAMS ((tree, int));
/* In fold-const.c */
extern int div_and_round_double PARAMS ((enum tree_code, int,
unsigned HOST_WIDE_INT,
HOST_WIDE_INT,
unsigned HOST_WIDE_INT,
HOST_WIDE_INT,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *,
unsigned HOST_WIDE_INT *,
HOST_WIDE_INT *));
/* In stmt.c */
extern void emit_nop PARAMS ((void));
extern void expand_computed_goto PARAMS ((tree));
extern bool parse_output_constraint PARAMS ((const char **,
int, int, int,
bool *, bool *, bool *));
extern void expand_asm_operands PARAMS ((tree, tree, tree, tree, int,
const char *, int));
extern int any_pending_cleanups PARAMS ((int));
extern void init_stmt PARAMS ((void));
extern void init_stmt_for_function PARAMS ((void));
extern int drop_through_at_end_p PARAMS ((void));
extern void expand_start_target_temps PARAMS ((void));
extern void expand_end_target_temps PARAMS ((void));
extern void expand_elseif PARAMS ((tree));
extern void save_stack_pointer PARAMS ((void));
extern void expand_decl PARAMS ((tree));
extern int expand_decl_cleanup PARAMS ((tree, tree));
extern int expand_decl_cleanup_eh PARAMS ((tree, tree, int));
extern void expand_anon_union_decl PARAMS ((tree, tree, tree));
extern void move_cleanups_up PARAMS ((void));
extern void expand_start_case_dummy PARAMS ((void));
extern void expand_end_case_dummy PARAMS ((void));
extern tree case_index_expr_type PARAMS ((void));
extern HOST_WIDE_INT all_cases_count PARAMS ((tree, int *));
extern void check_for_full_enumeration_handling PARAMS ((tree));
extern void declare_nonlocal_label PARAMS ((tree));
/* If KIND=='I', return a suitable global initializer (constructor) name.
If KIND=='D', return a suitable global clean-up (destructor) name. */
extern tree get_file_function_name PARAMS ((int));
/* Interface of the DWARF2 unwind info support. */
/* Generate a new label for the CFI info to refer to. */
extern char *dwarf2out_cfi_label PARAMS ((void));
/* Entry point to update the canonical frame address (CFA). */
extern void dwarf2out_def_cfa PARAMS ((const char *, unsigned, long));
/* Add the CFI for saving a register window. */
extern void dwarf2out_window_save PARAMS ((const char *));
/* Add a CFI to update the running total of the size of arguments pushed
onto the stack. */
extern void dwarf2out_args_size PARAMS ((const char *, long));
/* Entry point for saving a register to the stack. */
extern void dwarf2out_reg_save PARAMS ((const char *, unsigned, long));
/* Entry point for saving the return address in the stack. */
extern void dwarf2out_return_save PARAMS ((const char *, long));
/* Entry point for saving the return address in a register. */
extern void dwarf2out_return_reg PARAMS ((const char *, unsigned));
/* The type of a function that walks over tree structure. */
typedef tree (*walk_tree_fn) PARAMS ((tree *, int *, void *));
/* In tree-dump.c */
/* Different tree dump places. When you add new tree dump places,
extend the DUMP_FILES array in tree-dump.c */
enum tree_dump_index
{
TDI_all, /* dump the whole translation unit */
TDI_class, /* dump class hierarchy */
TDI_original, /* dump each function before optimizing it */
TDI_optimized, /* dump each function after optimizing it */
TDI_inlined, /* dump each function after inlining
within it. */
TDI_end
};
/* Bit masks to control tree dumping. Not all values are applicable to
all tree dumps. Add new ones at the end. When you define new
values, extend the DUMP_OPTIONS array in tree-dump.c */
#define TDF_ADDRESS (1 << 0) /* dump node addresses */
#define TDF_SLIM (1 << 1) /* don't go wild following links */
typedef struct dump_info *dump_info_p;
extern int dump_flag PARAMS ((dump_info_p, int, tree));
extern int dump_enabled_p PARAMS ((enum tree_dump_index));
extern FILE *dump_begin PARAMS ((enum tree_dump_index, int *));
extern void dump_end PARAMS ((enum tree_dump_index, FILE *));
extern void dump_node PARAMS ((tree, int, FILE *));
extern int dump_switch_p PARAMS ((const char *));
extern const char *dump_flag_name PARAMS ((enum tree_dump_index));
/* Redefine abort to report an internal error w/o coredump, and
reporting the location of the error in the source file. This logic
is duplicated in rtl.h and tree.h because every file that needs the
special abort includes one or both. toplev.h gets too few files,
system.h gets too many. */
extern void fancy_abort PARAMS ((const char *, int, const char *))
ATTRIBUTE_NORETURN;
#define abort() fancy_abort (__FILE__, __LINE__, __FUNCTION__)
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