mirror of
https://git.code.sf.net/p/quake/quakeforge
synced 2024-11-14 17:01:22 +00:00
8385046486
Forgetting to invoke [super dealloc] in a derived class's -dealloc method has caused me to waste far too much time chasing down the resulting memory leaks and crashes. This is actually the main focus of issue #24, but I want to take care of multiple paths before I consider the issue to be done. However, as a bonus, four cases were found :)
763 lines
25 KiB
C
763 lines
25 KiB
C
/*
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expr.h
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expression construction and manipulations
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Copyright (C) 2001 Bill Currie <bill@taniwha.org>
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Author: Bill Currie <bill@taniwha.org>
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Date: 2001/06/15
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License
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as published by the Free Software Foundation; either version 2
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of the License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
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See the GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to:
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Free Software Foundation, Inc.
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59 Temple Place - Suite 330
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Boston, MA 02111-1307, USA
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*/
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#ifndef __expr_h
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#define __expr_h
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#include "QF/pr_comp.h"
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/** \defgroup qfcc_expr Expressions
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\ingroup qfcc
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*/
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///@{
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/** Type of the exression node in an expression tree.
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*/
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typedef enum {
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ex_error, ///< error expression. used to signal an error
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ex_state, ///< state expression (::ex_state_t)
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ex_bool, ///< short circuit boolean logic expression (::ex_bool_t)
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ex_label, ///< goto/branch label (::ex_label_t)
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ex_labelref, ///< label reference (::ex_labelref_t)
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ex_block, ///< statement block expression (::ex_block_t)
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ex_expr, ///< binary expression (::ex_expr_t)
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ex_uexpr, ///< unary expression (::ex_expr_t)
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ex_def, ///< non-temporary variable (::def_t)
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ex_symbol, ///< non-temporary variable (::symbol_t)
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ex_temp, ///< temporary variable (::ex_temp_t)
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ex_vector, ///< "vector" expression (::ex_vector_t)
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ex_selector, ///< selector expression (::ex_selector_t)
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ex_nil, ///< umm, nil, null. nuff said (0 of any type)
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ex_value, ///< constant value (::ex_value_t)
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ex_compound, ///< compound initializer
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ex_memset, ///< memset needs three params...
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ex_count, ///< number of valid expression types
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} expr_type;
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/** Binary and unary expressions.
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This is used for both binary and unary expressions. Unary expressions do
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not use e2. The opcode is generally the parser token for the expression,
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though special codes are used for non-math expressions.
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*/
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typedef struct ex_expr_s {
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int op; ///< op-code of this expression
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struct type_s *type; ///< the type of the result of this expression
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struct expr_s *e1; ///< left side of binary, sole of unary
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struct expr_s *e2; ///< right side of binary, null for unary
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} ex_expr_t;
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typedef struct ex_label_s {
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struct ex_label_s *next;
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struct reloc_s *refs; ///< relocations associated with this label
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struct sblock_s *dest; ///< the location of this label if known
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const char *name; ///< the name of this label
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struct symbol_s *symbol; ///< symbol used to define this label (maybe 0)
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int used; ///< label is used as a target
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struct daglabel_s *daglabel;
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} ex_label_t;
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typedef struct {
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ex_label_t *label;
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} ex_labelref_t;
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typedef struct element_s {
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struct element_s *next; ///< next in chain
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int offset;
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struct type_s *type;
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struct expr_s *expr; ///< initializer expression
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struct symbol_s *symbol; ///< for labeled initializers
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} element_t;
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typedef struct element_chain_s {
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element_t *head;
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element_t **tail;
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} element_chain_t;
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typedef struct {
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struct expr_s *head; ///< the first expression in the block
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struct expr_s **tail; ///< last expression in the block, for appending
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struct expr_s *result; ///< the result of this block if non-void
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int is_call; ///< this block exprssion forms a function call
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void *return_addr;///< who allocated this
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} ex_block_t;
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typedef struct {
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struct operand_s *op; ///< The operand for the temporary variable, if
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///< allocated
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struct type_s *type; ///< The type of the temporary variable.
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} ex_temp_t;
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typedef struct {
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struct type_s *type; ///< Type of vector (vector/quaternion)
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struct expr_s *list; ///< Linked list of element expressions.
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} ex_vector_t;
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typedef struct {
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struct expr_s *sel_ref; ///< Reference to selector in selector table
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struct selector_s *sel; ///< selector
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} ex_selector_t;
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/** Pointer constant expression.
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Represent a pointer to an absolute address in data space.
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*/
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typedef struct ex_pointer_s {
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int val;
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struct type_s *type;
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struct def_s *def;
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struct operand_s *tempop;
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} ex_pointer_t;
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typedef struct ex_func_s {
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int val;
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struct type_s *type;
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} ex_func_t;
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typedef struct {
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int size;
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struct expr_s *e[1];
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} ex_list_t;
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typedef struct {
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ex_list_t *true_list;
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ex_list_t *false_list;
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struct expr_s *e;
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} ex_bool_t;
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typedef struct ex_memset_s {
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struct expr_s *dst;
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struct expr_s *val;
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struct expr_s *count;
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struct type_s *type;
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} ex_memset_t;
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/** State expression used for think function state-machines.
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State expressions are of the form <code>[framenum, nextthink]</code>
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(standard) or <code>[framenum, nextthink, timestep]</code> (QF extension)
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and come before the opening brace of the function. If the state
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expression is of the former form, then \c step will be null. Normally,
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\c framenum and \c nextthink must be constant (though \c nextthink may
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be a forward reference), but qfcc allows both \c framenum and
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\c nextthink, and also \c timestep, to be variable.
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\par From qcc:
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States are special functions made for convenience. They
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automatically set frame, nextthink (implicitly), and think (allowing
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forward definitions).
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\verbatim
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void() name = [framenum, nextthink] {code};
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\endverbatim
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expands to:
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\verbatim
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void name ()
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{
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self.frame=framenum;
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self.nextthink = time + 0.1;
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self.think = nextthink
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[code]
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};
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\endverbatim
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Although the above expansion shows three expressions, a state expression
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using constant values is just one instruction: either
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<code>state framenum, nextthink</code> (standard) or
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<code>state.f framenum, nextthink, timestep</code> (QF, optional).
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*/
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typedef struct {
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struct expr_s *frame; ///< the frame to which to change in this state
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struct expr_s *think; ///< think function for the next state
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struct expr_s *step; ///< time step until the next state
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} ex_state_t;
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typedef struct ex_value_s {
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struct ex_value_s *next;
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struct daglabel_s *daglabel;///< dag label for this value
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struct type_s *type;
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etype_t lltype;
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union {
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const char *string_val; ///< string constant
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double double_val; ///< double constant
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float float_val; ///< float constant
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float vector_val[3]; ///< vector constant
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int entity_val; ///< entity constant
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ex_func_t func_val; ///< function constant
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ex_pointer_t pointer; ///< pointer constant
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float quaternion_val[4]; ///< quaternion constant
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int integer_val; ///< integer constant
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unsigned uinteger_val; ///< unsigned integer constant
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short short_val; ///< short constant
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} v;
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} ex_value_t;
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#define POINTER_VAL(p) (((p).def ? (p).def->offset : 0) + (p).val)
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typedef struct expr_s {
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struct expr_s *next; ///< the next expression in a block expression
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expr_type type; ///< the type of the result of this expression
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int line; ///< source line that generated this expression
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string_t file; ///< source file that generated this expression
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int printid; ///< avoid duplicate output when printing
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unsigned paren:1; ///< the expression is enclosed in ()
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unsigned rvalue:1; ///< the expression is on the right side of =
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unsigned implicit:1; ///< don't warn for implicit casts
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union {
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ex_label_t label; ///< label expression
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ex_labelref_t labelref; ///< label reference expression (&)
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ex_state_t state; ///< state expression
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ex_bool_t bool; ///< boolean logic expression
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ex_block_t block; ///< statement block expression
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ex_expr_t expr; ///< binary or unary expression
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struct def_s *def; ///< def reference expression
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struct symbol_s *symbol; ///< symbol reference expression
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ex_temp_t temp; ///< temporary variable expression
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ex_vector_t vector; ///< vector expression list
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ex_selector_t selector; ///< selector ref and name
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ex_value_t *value; ///< constant value
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element_chain_t compound; ///< compound initializer
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ex_memset_t memset; ///< memset expr params
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struct type_s *nil; ///< type for nil if known
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} e;
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} expr_t;
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extern const char *expr_names[];
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/** Report a type mismatch error.
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\a e1 is used for reporting the file and line number of the error.
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\param e1 Left side expression. Used for reporting the type.
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\param e2 Right side expression. Used for reporting the type.
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\param op The opcode of the expression.
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\return \a e1 with its type set to ex_error.
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*/
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expr_t *type_mismatch (expr_t *e1, expr_t *e2, int op);
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expr_t *param_mismatch (expr_t *e, int param, const char *fn,
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struct type_s *t1, struct type_s *t2);
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expr_t *cast_error (expr_t *e, struct type_s *t1, struct type_s *t2);
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expr_t *test_error (expr_t *e, struct type_s *t);
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extern expr_t *local_expr;
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/** Get the type descriptor of the expression result.
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\param e The expression from which to get the result type.
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\return Pointer to the type description, or null if the expression
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type (expr_t::type) is inappropriate.
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*/
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struct type_s *get_type (expr_t *e);
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/** Get the basic type code of the expression result.
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\param e The expression from which to get the result type.
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\return Pointer to the type description, or ev_type_count if
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get_type() returns null.
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*/
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etype_t extract_type (expr_t *e);
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/** Create a new expression node.
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Sets the source file and line number information. The expression node is
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otherwise raw. This function is generally not used directly.
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\return The new expression node.
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*/
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expr_t *new_expr (void);
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/** Create a deep copy of an expression tree.
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\param e The root of the expression tree to copy.
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\return A new expression tree giving the same expression.
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*/
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expr_t *copy_expr (expr_t *e);
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/** Copy source expression's file and line to the destination expression
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\param dst The expression to receive the file and line
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\param src The expression from which the file and line will be taken
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\return \a dst
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*/
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expr_t *expr_file_line (expr_t *dst, const expr_t *src);
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/** Create a new label name.
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The label name is guaranteed to be unique to the compilation. It is made
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up of the name of the current function plus an incrementing number. The
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number is not reset between functions.
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\return The string representing the label name.
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*/
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const char *new_label_name (void);
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/** Create a new label expression node.
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The label name is set using new_label_name().
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\return The new label expression (::ex_label_t) node.
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*/
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expr_t *new_label_expr (void);
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/** Create a named label expression node.
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The label name is set using new_label_name(), but the symbol is used to add
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the label to the function's label scope symbol table. If the label already
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exists in the function's label scope, then the existing label is returned,
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allowing for forward label declarations.
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\param label The name symbol to use for adding the label to the function
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label scope.
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\return The new label expression (::ex_label_t) node.
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*/
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expr_t *named_label_expr (struct symbol_s *label);
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/** Create a new label reference expression node.
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Used for taking the address of a label (eg. jump tables).
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The label's \a used field is incremented.
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\return The new label reference expression (::ex_labelref_t) node.
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*/
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expr_t *new_label_ref (ex_label_t *label);
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/** Create a new state expression node.
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The label name is set using new_label_name(), and the label is linked
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into the global list of labels for later resolution.
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\param frame The expression giving the frame number.
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\param think The expression giving the think function.
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\param step The expression giving the time step value, or null if
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no time-step is specified (standard form).
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\return The new state expression (::ex_state_t) node.
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*/
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expr_t *new_state_expr (expr_t *frame, expr_t *think, expr_t *step);
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expr_t *new_bool_expr (ex_list_t *true_list, ex_list_t *false_list, expr_t *e);
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/** Create a new statement block expression node.
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The returned block expression is empty. Use append_expr() to add
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expressions to the block expression.
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\return The new block expression (::ex_block_t) node.
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*/
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expr_t *new_block_expr (void);
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/** Create a new statement block expression node from an expression list
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The returned block holds the expression list in reverse order. This makes
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it easy to build the list in a parser.
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\param expr_list The expression list to convert to an expression block.
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Note that the evaluation order will be reversed.
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\return The new block expression (::ex_block_t) node.
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*/
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expr_t *build_block_expr (expr_t *expr_list);
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element_t *new_element (expr_t *expr, struct symbol_s *symbol);
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expr_t *new_compound_init (void);
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expr_t *append_element (expr_t *compound, element_t *element);
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expr_t *initialized_temp_expr (const struct type_s *type, expr_t *compound);
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void assign_elements (expr_t *local_expr, expr_t *ptr,
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element_chain_t *element_chain);
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void build_element_chain (element_chain_t *element_chain,
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const struct type_s *type,
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expr_t *eles, int base_offset);
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void free_element_chain (element_chain_t *element_chain);
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/** Create a new binary expression node node.
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If either \a e1 or \a e2 are error expressions, then that expression will
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be returned instead of a new binary expression.
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\param op The op-ccode of the binary expression.
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\param e1 The left side of the binary expression.
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\param e2 The right side of the binary expression.
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\return The new binary expression node (::ex_expr_t) if neither
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\a e1 nor \a e2 are error expressions, otherwise the
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expression that is an error expression.
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*/
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expr_t *new_binary_expr (int op, expr_t *e1, expr_t *e2);
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/** Create a new unary expression node node.
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If \a e1 is an error expression, then it will be returned instead of a
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new unary expression.
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\param op The op-code of the unary expression.
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\param e1 The "right" side of the expression.
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\return The new unary expression node (::ex_expr_t) if \a e1
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is not an error expression, otherwise \a e1.
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*/
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expr_t *new_unary_expr (int op, expr_t *e1);
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/** Create a new def reference (non-temporary variable) expression node.
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\return The new def reference expression node (::def_t).
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*/
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expr_t *new_def_expr (struct def_s *def);
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/** Create a new symbol reference (non-temporary variable) expression node.
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\return The new symbol reference expression node (::symbol_t).
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*/
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expr_t *new_symbol_expr (struct symbol_s *symbol);
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/** Create a new temporary variable expression node.
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Does not allocate a new temporary variable.
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The ex_temp_t::users field will be 0.
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\param type The type of the temporary variable.
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\return The new temporary variable expression node (ex_temp_t).
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*/
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expr_t *new_temp_def_expr (const struct type_s *type);
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/** Create a new nil expression node.
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nil represents 0 of any type.
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\return The new nil expression node.
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*/
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expr_t *new_nil_expr (void);
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/** Create a new value expression node.
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\param value The value to put in the expression node.
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\return The new value expression.
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*/
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expr_t *new_value_expr (ex_value_t *value);
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/** Create a new symbol expression node from a name.
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\param name The name for the symbol.
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\return The new symbol expression.
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*/
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expr_t *new_name_expr (const char *name);
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/** Create a new string constant expression node.
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\param string_val The string constant being represented.
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\return The new string constant expression node
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(expr_t::e::string_val).
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*/
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expr_t *new_string_expr (const char *string_val);
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const char *expr_string (expr_t *e) __attribute__((pure));
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/** Create a new double constant expression node.
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\param double_val The double constant being represented.
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\return The new double constant expression node
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(expr_t::e::double_val).
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*/
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expr_t *new_double_expr (double double_val);
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double expr_double (expr_t *e) __attribute__((pure));
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/** Create a new float constant expression node.
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\param float_val The float constant being represented.
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\return The new float constant expression node
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(expr_t::e::float_val).
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*/
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expr_t *new_float_expr (float float_val);
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float expr_float (expr_t *e) __attribute__((pure));
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/** Create a new vector constant expression node.
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\param vector_val The vector constant being represented.
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\return The new vector constant expression node
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(expr_t::e::vector_val).
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*/
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expr_t *new_vector_expr (const float *vector_val);
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const float *expr_vector (expr_t *e) __attribute__((pure));
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expr_t *new_vector_list (expr_t *e);
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/** Create a new entity constant expression node.
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\param entity_val The entity constant being represented.
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\return The new entity constant expression node
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(expr_t::e::entity_val).
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*/
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expr_t *new_entity_expr (int entity_val);
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|
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/** Create a new field constant expression node.
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|
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\param field_val offset? XXX
|
|
\param type The type of the field.
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\param def
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\return The new field constant expression node
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|
(expr_t::e::field_val).
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|
*/
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expr_t *new_field_expr (int field_val, struct type_s *type, struct def_s *def);
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/** Create a new function constant expression node.
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\param func_val The function constant being represented.
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\param type The type of the function
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|
\return The new function constant expression node
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|
(expr_t::e::func_val).
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|
*/
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|
expr_t *new_func_expr (int func_val, struct type_s *type);
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/** Create a new pointer constant expression node.
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\param val The pointer constant (address) being represented. XXX
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|
\param type The type of the referenced value.
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|
\param def
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|
\return The new pointer constant expression node
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|
(expr_t::e::pointer_val).
|
|
*/
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|
expr_t *new_pointer_expr (int val, struct type_s *type, struct def_s *def);
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|
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|
/** Create a new quaternion constant expression node.
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|
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|
\param quaternion_val The quaternion constant being represented.
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|
\return The new quaternion constant expression node
|
|
(expr_t::e::quaternion_val).
|
|
*/
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|
expr_t *new_quaternion_expr (const float *quaternion_val);
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const float *expr_quaternion (expr_t *e) __attribute__((pure));
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|
|
|
/** Create a new integer constant expression node.
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|
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|
\param integer_val The integer constant being represented.
|
|
\return The new integer constant expression node
|
|
(expr_t::e::integer_val).
|
|
*/
|
|
expr_t *new_integer_expr (int integer_val);
|
|
int expr_integer (expr_t *e) __attribute__((pure));
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|
|
|
/** Create a new integer constant expression node.
|
|
|
|
\param uinteger_val The integer constant being represented.
|
|
\return The new integer constant expression node
|
|
(expr_t::e::integer_val).
|
|
*/
|
|
expr_t *new_uinteger_expr (unsigned uinteger_val);
|
|
unsigned expr_uinteger (expr_t *e) __attribute__((pure));
|
|
|
|
/** Create a new short constant expression node.
|
|
|
|
\param short_val The short constant being represented.
|
|
\return The new short constant expression node
|
|
(expr_t::e::short_val).
|
|
*/
|
|
expr_t *new_short_expr (short short_val);
|
|
short expr_short (expr_t *e) __attribute__((pure));
|
|
|
|
int expr_integral (expr_t *e) __attribute__((pure));
|
|
|
|
/** Check if the expression refers to a constant value.
|
|
|
|
\param e The expression to check.
|
|
\return True if the expression is constant.
|
|
*/
|
|
int is_constant (expr_t *e) __attribute__((pure));
|
|
|
|
/** Check if the expression refers to a selector
|
|
|
|
\param e The expression to check.
|
|
\return True if the expression is a selector.
|
|
*/
|
|
int is_selector (expr_t *e) __attribute__((pure));
|
|
|
|
/** Return a value expression representing the constant stored in \a e.
|
|
|
|
If \a e does not represent a constant, or \a e is already a value or
|
|
nil expression, then \a e is returned rather than a new expression.
|
|
|
|
\param e The expression from which to extract the value.
|
|
\return A new expression holding the value of \a e or \e itself.
|
|
*/
|
|
expr_t *constant_expr (expr_t *e);
|
|
|
|
/** Check if the op-code is a comparison.
|
|
|
|
\param op The op-code to check.
|
|
\return True if the op-code is a comparison operator.
|
|
*/
|
|
int is_compare (int op) __attribute__((const));
|
|
|
|
/** Check if the op-code is a math operator.
|
|
|
|
\param op The op-code to check.
|
|
\return True if the op-code is a math operator.
|
|
*/
|
|
int is_math_op (int op) __attribute__((const));
|
|
|
|
/** Check if the op-code is a logic operator.
|
|
|
|
\param op The op-code to check.
|
|
\return True if the op-code is a logic operator.
|
|
*/
|
|
int is_logic (int op) __attribute__((const));
|
|
|
|
int has_function_call (expr_t *e) __attribute__((pure));
|
|
|
|
int is_nil (expr_t *e) __attribute__((pure));
|
|
int is_string_val (expr_t *e) __attribute__((pure));
|
|
int is_float_val (expr_t *e) __attribute__((pure));
|
|
int is_vector_val (expr_t *e) __attribute__((pure));
|
|
int is_quaternion_val (expr_t *e) __attribute__((pure));
|
|
int is_integer_val (expr_t *e) __attribute__((pure));
|
|
int is_uinteger_val (expr_t *e) __attribute__((pure));
|
|
int is_short_val (expr_t *e) __attribute__((pure));
|
|
int is_integral_val (expr_t *e) __attribute__((pure));
|
|
int is_pointer_val (expr_t *e) __attribute__((pure));
|
|
|
|
/** Create a reference to the global <code>.self</code> entity variable.
|
|
|
|
This is used for <code>\@self</code>.
|
|
\return A new expression referencing the <code>.self</code> def.
|
|
*/
|
|
expr_t *new_self_expr (void);
|
|
|
|
/** Create a reference to the <code>.this</code> entity field.
|
|
|
|
This is used for <code>\@this</code>.
|
|
\return A new expression referencing the <code>.this</code> def.
|
|
*/
|
|
expr_t *new_this_expr (void);
|
|
|
|
/** Create an expression of the correct type that references the return slot.
|
|
|
|
\param type The type of the reference to the return slot.
|
|
\return A new expression referencing the return slot.
|
|
*/
|
|
expr_t *new_ret_expr (struct type_s *type);
|
|
|
|
expr_t *new_alias_expr (struct type_s *type, expr_t *expr);
|
|
expr_t *new_offset_alias_expr (struct type_s *type, expr_t *expr, int offset);
|
|
|
|
/** Create an expression of the correct type that references the specified
|
|
parameter slot.
|
|
|
|
\param type The type of the reference to the parameter slot.
|
|
\param num The index of the parameter (0-7).
|
|
\return A new expression referencing the parameter slot.
|
|
*/
|
|
expr_t *new_param_expr (struct type_s *type, int num);
|
|
|
|
/** Create an expression representing a block copy.
|
|
|
|
This is used for structure assignments.
|
|
|
|
\param e1 Destination of move.
|
|
\param e2 Source of move.
|
|
\param type type giving size of move.
|
|
\param indirect Move uses dereferenced pointers.
|
|
\return A new expression representing the move.
|
|
*/
|
|
expr_t *new_move_expr (expr_t *e1, expr_t *e2, struct type_s *type,
|
|
int indirect);
|
|
|
|
expr_t *new_memset_expr (expr_t *dst, expr_t *val, struct type_s *type);
|
|
|
|
|
|
/** Convert a name to an expression of the appropriate type.
|
|
|
|
Converts the expression in-place. If the exprssion is not a name
|
|
expression (ex_name), no converision takes place.
|
|
|
|
\param e The expression to convert.
|
|
*/
|
|
void convert_name (expr_t *e);
|
|
|
|
expr_t *convert_vector (expr_t *e);
|
|
|
|
expr_t *append_expr (expr_t *block, expr_t *e);
|
|
|
|
expr_t *reverse_expr_list (expr_t *e);
|
|
void print_expr (expr_t *e);
|
|
void dump_dot_expr (void *e, const char *filename);
|
|
|
|
void convert_int (expr_t *e);
|
|
void convert_short (expr_t *e);
|
|
void convert_short_int (expr_t *e);
|
|
void convert_double (expr_t *e);
|
|
expr_t *convert_nil (expr_t *e, struct type_s *t);
|
|
|
|
expr_t *test_expr (expr_t *e);
|
|
void backpatch (ex_list_t *list, expr_t *label);
|
|
expr_t *convert_bool (expr_t *e, int block);
|
|
expr_t *convert_from_bool (expr_t *e, struct type_s *type);
|
|
expr_t *bool_expr (int op, expr_t *label, expr_t *e1, expr_t *e2);
|
|
expr_t *binary_expr (int op, expr_t *e1, expr_t *e2);
|
|
expr_t *field_expr (expr_t *e1, expr_t *e2);
|
|
expr_t *asx_expr (int op, expr_t *e1, expr_t *e2);
|
|
expr_t *unary_expr (int op, expr_t *e);
|
|
expr_t *build_function_call (expr_t *fexpr, const struct type_s *ftype,
|
|
expr_t *params);
|
|
expr_t *function_expr (expr_t *e1, expr_t *e2);
|
|
struct function_s;
|
|
expr_t *branch_expr (int op, expr_t *test, expr_t *label);
|
|
expr_t *goto_expr (expr_t *label);
|
|
expr_t *return_expr (struct function_s *f, expr_t *e);
|
|
expr_t *conditional_expr (expr_t *cond, expr_t *e1, expr_t *e2);
|
|
expr_t *incop_expr (int op, expr_t *e, int postop);
|
|
expr_t *array_expr (expr_t *array, expr_t *index);
|
|
expr_t *pointer_expr (expr_t *pointer);
|
|
expr_t *address_expr (expr_t *e1, expr_t *e2, struct type_s *t);
|
|
expr_t *build_if_statement (int not, expr_t *test, expr_t *s1, expr_t *els,
|
|
expr_t *s2);
|
|
expr_t *build_while_statement (int not, expr_t *test, expr_t *statement,
|
|
expr_t *break_label, expr_t *continue_label);
|
|
expr_t *build_do_while_statement (expr_t *statement, int not, expr_t *test,
|
|
expr_t *break_label, expr_t *continue_label);
|
|
expr_t *build_for_statement (expr_t *init, expr_t *test, expr_t *next,
|
|
expr_t *statement,
|
|
expr_t *break_label, expr_t *continue_label);
|
|
expr_t *build_state_expr (expr_t *e);
|
|
expr_t *think_expr (struct symbol_s *think_sym);
|
|
int is_lvalue (const expr_t *expr) __attribute__((pure));
|
|
expr_t *assign_expr (expr_t *dst, expr_t *src);
|
|
expr_t *cast_expr (struct type_s *t, expr_t *e);
|
|
|
|
const char *get_op_string (int op) __attribute__((const));
|
|
|
|
struct keywordarg_s;
|
|
struct class_type_s;
|
|
expr_t *selector_expr (struct keywordarg_s *selector);
|
|
expr_t *protocol_expr (const char *protocol);
|
|
expr_t *encode_expr (struct type_s *type);
|
|
expr_t *super_expr (struct class_type_s *class_type);
|
|
expr_t *message_expr (expr_t *receiver, struct keywordarg_s *message);
|
|
expr_t *sizeof_expr (expr_t *expr, struct type_s *type);
|
|
|
|
expr_t *fold_constants (expr_t *e);
|
|
|
|
///@}
|
|
|
|
#endif//__expr_h
|