2 * Copyright (C) 1995-2010 University of Karlsruhe. All right reserved.
4 * This file is part of libFirm.
6 * This file may be distributed and/or modified under the terms of the
7 * GNU General Public License version 2 as published by the Free Software
8 * Foundation and appearing in the file LICENSE.GPL included in the
9 * packaging of this file.
11 * Licensees holding valid libFirm Professional Edition licenses may use
12 * this file in accordance with the libFirm Commercial License.
13 * Agreement provided with the Software.
15 * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
16 * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
22 * @brief Various irnode constructors. Automatic construction of SSA
24 * @author Martin Trapp, Christian Schaefer, Goetz Lindenmaier, Boris Boesler,
31 * documentation no more supported since 2001
33 * IR node construction.
35 * This file documents all datatypes and constructors needed to
36 * build a FIRM representation of a procedure. The constructors are
37 * also implemented in this file.
39 * The documentation also gives a short manual how to use the library.
41 * For extensive documentation of FIRM see UKA Techreport 1999-14.
44 * Three kinds of nodes
45 * --------------------
47 * There are three kinds of nodes known to the IR: entities,
50 * + ir_nodes are the actual nodes of the FIRM intermediate representation.
51 * They represent operations on the data of the program and control flow
54 * + entity ==> implemented in entity.h
55 * Refers to a single entity of the compiled program, e.g. a field of a
56 * class or a method. If a method or variable can not be assigned to
57 * a method or class or the like, it is a global object.
59 * + types ==> implemented in type.h
60 * With types type information is represented. There are several type
63 * Implementation of the FIRM operations: ir_node
64 * ----------------------------------------------
66 * Ir_nodes represent operations on the data of the program and control flow
67 * operations. Examples of ir_nodes: Add, Jmp, Cmp
69 * FIRM is a dataflow graph. A dataflow graph is a directed graph,
70 * so that every node has incoming and outgoing edges. A node is
71 * executable if every input at its incoming edges is available.
72 * Execution of the dataflow graph is started at the Start node which
73 * has no incoming edges and ends when the End node executes, even if
74 * there are still executable or not executed nodes. (Is this true,
75 * or must all executable nodes be executed?) (There are exceptions
76 * to the dataflow paradigma that all inputs have to be available
77 * before a node can execute: Phi, Block. See UKA Techreport
80 * The implementation of FIRM differs from the view as a dataflow
81 * graph. To allow fast traversion of the graph edges are
82 * implemented as C-pointers. Inputs to nodes are not ambiguous, the
83 * results can be used by several other nodes. Each input can be
84 * implemented as a single pointer to a predecessor node, outputs
85 * need to be lists of pointers to successors. Therefore a node
86 * contains pointers to its predecessors so that the implementation is a
87 * dataflow graph with reversed edges. It has to be traversed bottom
90 * All nodes of the IR have the same basic structure. They are
91 * distinguished by a field containing the opcode.
93 * The fields of an ir_node:
95 * kind A firm_kind tag containing k_ir_node. This is useful for
96 * dynamically checking the type of a node.
98 * *op This ir_op gives the opcode as a tag and a string
99 * and the number of attributes of an ir_node. There is
100 * one statically allocated struct ir_op for each opcode.
102 * *mode The ir_mode of the operation represented by this firm
103 * node. The mode of the operation is the mode of its
104 * result. A Firm mode is a datatype as known to the
105 * target, not a type of the source language.
107 * visit A flag for traversing the IR.
109 * **in An array with pointers to the node's predecessors.
111 * *link A pointer to an ir_node. With this pointer all Phi nodes
112 * are attached to a Block, i.e. a Block points to its
113 * first Phi node, this node points to the second Phi node
114 * in the Block and so forth. Used in mature_immBlock
115 * to find all Phi nodes to be matured. It's also used to
116 * annotate a node with a better, optimized version of it.
118 * attr An attr struct containing the attributes of the nodes. The
119 * attributes depend on the opcode of the node. The number
120 * of these attributes is given in op.
124 * Not yet documented. See irop.h.
128 * Not yet documented. See irmode.h.
130 * GLOBAL VARIABLES -- now also fields of ir_graph.
133 * current_ir_graph Points to the current ir_graph. All constructors for
134 * nodes add nodes to this graph.
136 * ir_visited An int used as flag to traverse the ir_graph.
138 * block_visited An int used as a flag to traverse block nodes in the
141 * Others not yet documented.
145 * CONSTRUCTOR FOR IR_GRAPH --> see irgraph.h
146 * ========================
149 * PROCEDURE TO CONSTRUCT AN IR GRAPH --> see also Firm tutorial
150 * ==================================
152 * This library supplies several interfaces to construct a FIRM graph for
154 * - A "comfortable" interface generating SSA automatically. Automatically
155 * computed predecessors of nodes need not be specified in the constructors.
156 * (new_<Node> constructurs and a set of additional routines.)
157 * - A less comfortable interface where all predecessors except the block
158 * an operation belongs to need to be specified. SSA must be constructed
159 * by hand. (new_<Node> constructors and set_cur_block()). This interface
160 * is called "block oriented". It automatically calles the local optimizations
162 * - An even less comfortable interface where the block needs to be specified
163 * explicitly. This is called the "raw" interface. (new_r_<Node>
164 * constructors). These nodes are not optimized.
166 * To use the functionality of the comfortable interface correctly the Front
167 * End needs to follow certain protocols. This is explained in the following.
168 * To build a correct IR with the other interfaces study the semantics of
169 * the firm node (See tech-reprot UKA 1999-14). For the construction of
170 * types and entities see the documentation in those modules.
172 * First the Frontend needs to decide which variables and values used in
173 * a procedure can be represented by dataflow edges. These are variables
174 * that need not be saved to memory as they cause no side effects visible
175 * out of the procedure. Often these are all compiler generated
176 * variables and simple local variables of the procedure as integers,
177 * reals and pointers. The frontend has to count and number these variables.
179 * First an ir_graph needs to be constructed with new_ir_graph. The
180 * constructor gets the number of local variables. The graph is held in the
181 * global variable irg.
183 * Now the construction of the procedure can start. Several basic blocks can
184 * be constructed in parallel, but the code within each block needs to
185 * be constructed (almost) in program order.
187 * A global variable holds the current basic block. All (non block) nodes
188 * generated are added to this block. The current block can be set with
189 * set_cur_block(block). If several blocks are constructed in parallel block
190 * switches need to be performed constantly.
192 * To generate a Block node (with the comfortable interface), its predecessor
193 * control flow nodes need not be known. In case of cyclic control flow these
194 * can not be known when the block is constructed. With add_immBlock_pred(block,
195 * cfnode) predecessors can be added to the block. If all predecessors are
196 * added to the block mature_immBlock(b) needs to be called. Calling mature_immBlock
197 * early improves the efficiency of the Phi node construction algorithm.
198 * But if several blocks are constructed at once, mature_immBlock must only
199 * be called after performing all set_values and set_stores in the block!
200 * (See documentation of new_immBlock constructor.)
202 * The constructors of arithmetic nodes require that their predecessors
203 * are mentioned. Sometimes these are available in the Frontend as the
204 * predecessors have just been generated by the frontend. If they are local
205 * values, the predecessors can be obtained from the library with a call to
206 * get_value(local_val_nr). (local_val_nr needs to be administered by
207 * the Frontend.) A call to get_value triggers the generation of Phi nodes.
208 * If an arithmetic operation produces a local value, this value needs to be
209 * passed to the library by set_value(node, local_val_nr).
210 * In straight line code these two operations just remember and return the
211 * pointer to nodes producing the value. If the value passes block boundaries
212 * Phi nodes can be inserted.
213 * Similar routines exist to manage the Memory operands: set_store and
216 * Several nodes produce more than one result. An example is the Div node.
217 * Such nodes return tuples of values. From these individual values can be
218 * extracted by proj nodes.
220 * The following example illustrates the construction of a simple basic block
221 * with two predecessors stored in variables cf_pred1 and cf_pred2, containing
224 * and finally jumping to an other block. The variable a got the local_val_nr
225 * 42 by the frontend.
227 * ir_node *this_block, *cf_pred1, *cf_pred2, *a_val, *mem, *div, *res, *cf_op;
229 * this_block = new_immBlock();
230 * add_immBlock_pred(this_block, cf_pred1);
231 * add_immBlock_pred(this_block, cf_pred2);
232 * mature_immBlock(this_block);
233 * a_val = get_value(42, mode_Iu);
235 * div = new_Div(mem, a_val, a_val, mode_Iu);
236 * mem = new_Proj(div, mode_M, pn_Div_M); * for the numbers for Proj see docu *
237 * res = new_Proj(div, mode_Iu, pn_Div_res);
239 * set_value(res, 42);
242 * For further information look at the documentation of the nodes and
243 * constructors and at the paragraph COPING WITH DATA OBJECTS at the
244 * end of this documentation.
246 * The comfortable interface contains the following routines further explained
249 * ir_node *new_immBlock (void);
250 * ir_node *new_Start (void);
251 * ir_node *new_End (void);
252 * ir_node *new_Jmp (void);
253 * ir_node *new_IJmp (ir_node *tgt);
254 * ir_node *new_Cond (ir_node *c);
255 * ir_node *new_Return (ir_node *store, int arity, ir_node **in);
256 * ir_node *new_Const (ir_tarval *con);
257 * ir_node *new_SymConst (ir_mode *mode, symconst_symbol value, symconst_kind kind);
258 * ir_node *new_simpleSel (ir_node *store, ir_node *objptr, ir_entity *ent);
259 * ir_node *new_Sel (ir_node *store, ir_node *objptr, int arity,
260 * ir_node **in, ir_entity *ent);
261 * ir_node *new_Call (ir_node *store, ir_node *callee, int arity,
262 * ir_node **in, type_method *type);
263 * ir_node *new_Builtin(ir_node *store, ir_builtin_kind kind, int arity,
264 * ir_node **in, type_method *type);
265 * ir_node *new_Add (ir_node *op1, ir_node *op2, ir_mode *mode);
266 * ir_node *new_Sub (ir_node *op1, ir_node *op2, ir_mode *mode);
267 * ir_node *new_Minus (ir_node *op, ir_mode *mode);
268 * ir_node *new_Mul (ir_node *op1, ir_node *op2, ir_mode *mode);
269 * ir_node *new_Mulh (ir_node *op1, ir_node *op2, ir_mode *mode);
270 * ir_node *new_Div (ir_node *memop, ir_node *op1, ir_node *op2, ir_mode *mode, op_pin_state state);
271 * ir_node *new_Mod (ir_node *memop, ir_node *op1, ir_node *op2, ir_mode *mode, op_pin_state state;
272 * ir_node *new_And (ir_node *op1, ir_node *op2, ir_mode *mode);
273 * ir_node *new_Or (ir_node *op1, ir_node *op2, ir_mode *mode);
274 * ir_node *new_Eor (ir_node *op1, ir_node *op2, ir_mode *mode);
275 * ir_node *new_Not (ir_node *op, ir_mode *mode);
276 * ir_node *new_Shl (ir_node *op, ir_node *k, ir_mode *mode);
277 * ir_node *new_Shr (ir_node *op, ir_node *k, ir_mode *mode);
278 * ir_node *new_Shrs (ir_node *op, ir_node *k, ir_mode *mode);
279 * ir_node *new_Rotl (ir_node *op, ir_node *k, ir_mode *mode);
280 * ir_node *new_Cmp (ir_node *op1, ir_node *op2);
281 * ir_node *new_Conv (ir_node *op, ir_mode *mode);
282 * ir_node *new_Cast (ir_node *op, ir_type *to_tp);
283 * ir_node *new_Carry (ir_node *op1, ir_node *op2, ir_mode *mode);
284 * ir_node *new_Borrow (ir_node *op1, ir_node *op2, ir_mode *mode);
285 * ir_node *new_Load (ir_node *store, ir_node *addr, ir_mode *mode, ir_cons_flags flags);
286 * ir_node *new_Store (ir_node *store, ir_node *addr, ir_node *val, ir_cons_flags flags);
287 * ir_node *new_Alloc (ir_node *store, ir_node *count, ir_type *alloc_type,
288 * where_alloc where);
289 * ir_node *new_Free (ir_node *store, ir_node *ptr, ir_node *size,
290 * ir_type *free_type, where_alloc where);
291 * ir_node *new_Proj (ir_node *arg, ir_mode *mode, long proj);
292 * ir_node *new_NoMem (void);
293 * ir_node *new_Mux (ir_node *sel, ir_node *ir_false, ir_node *ir_true, ir_mode *mode);
294 * ir_node *new_CopyB (ir_node *store, ir_node *dst, ir_node *src, ir_type *data_type);
295 * ir_node *new_InstOf (ir_node *store, ir_node obj, ir_type *ent);
296 * ir_node *new_Raise (ir_node *store, ir_node *obj);
297 * ir_node *new_Bound (ir_node *store, ir_node *idx, ir_node *lower, ir_node *upper);
298 * ir_node *new_Pin (ir_node *node);
300 * void add_immBlock_pred (ir_node *block, ir_node *jmp);
301 * void mature_immBlock (ir_node *block);
302 * void set_cur_block (ir_node *target);
303 * ir_node *get_value (int pos, ir_mode *mode);
304 * void set_value (int pos, ir_node *value);
305 * ir_node *get_store (void);
306 * void set_store (ir_node *store);
307 * keep_alive (ir_node ka)
309 * IR_NODES AND CONSTRUCTORS FOR IR_NODES
310 * =======================================
312 * All ir_nodes are defined by a common data structure. They are distinguished
313 * by their opcode and differ in the number of their attributes.
315 * Const nodes are always added to the start block.
316 * All other constructors add the created node to the current_block.
317 * swich_block(block) allows to set the current block to block.
319 * Watch for my inconsistent use of input and predecessor (dataflow view)
320 * and `the node points to' (implementation view).
322 * The following description of the nodes lists four properties them if these
324 * - the parameters to the constructor
325 * - the inputs of the Firm node
326 * - the outputs of the Firm node
327 * - attributes to the node
331 * ir_node *new_immBlock (void)
332 * ----------------------------
334 * Creates a new block. When a new block is created it cannot be known how
335 * many predecessors this block will have in the control flow graph.
336 * Therefore the list of inputs can not be fixed at creation. Predecessors
337 * can be added with add_immBlock_pred (block, control flow operation).
338 * With every added predecessor the number of inputs to Phi nodes also
341 * The block can be completed by mature_immBlock(block) if all predecessors are
342 * known. If several blocks are built at once, mature_immBlock can only be called
343 * after set_value has been called for all values that are life at the end
344 * of the block. This is necessary so that Phi nodes created mature_immBlock
345 * get the right predecessors in case of cyclic dependencies. If all set_values
346 * of this block are called after maturing it and before calling get_value
347 * in some block that is control flow dependent on this block, the construction
350 * Example for faulty IR construction: (draw the graph on a paper and you'll
353 * block_before_loop = new_immBlock();
354 * set_cur_block(block_before_loop);
356 * mature_immBlock(block_before_loop);
357 * before2header = new_Jmp;
359 * loop_header = new_immBlock ();
360 * set_cur_block(loop_header);
361 * header2body - new_Jmp();
363 * loop_body = new_immBlock ();
364 * set_cur_block(loop_body);
365 * body2header = new_Jmp();
367 * add_immBlock_pred(loop_header, before2header);
368 * add_immBlock_pred(loop_header, body2header);
369 * add_immBlock_pred(loop_body, header2body);
371 * mature_immBlock(loop_header);
372 * mature_immBlock(loop_body);
374 * get_value(loop_body, x); // gets the Phi in loop_header
375 * set_value(loop_header, x); // sets the value the above get_value should
376 * // have returned!!!
378 * Mature_immBlock also fixes the number of inputs to the Phi nodes. Mature_immBlock
379 * should be called as early as possible, as afterwards the generation of Phi
380 * nodes is more efficient.
383 * There is an input for each control flow predecessor of the block.
384 * The input points to an instruction producing an output of type X.
385 * Possible predecessors: Start, Jmp, Cond, Raise or Return or any node
386 * possibly causing an exception. (Often the real predecessors are Projs.)
388 * Mode BB (R), all nodes belonging to this block should consume this output.
389 * As they are strict (except Block and Phi node) it is a necessary condition
390 * that the block node executed before any other node in this block executes.
392 * block.matured Indicates whether the block is mature.
394 * This attribute contains all local values valid in this
395 * block. This is needed to build the Phi nodes and removed
396 * if the graph is complete. This field is used by the
397 * internal construction algorithm and should not be accessed
401 * ir_node *new_Block (int arity, ir_node **in)
402 * --------------------------------------------
404 * Creates a new Block with the given list of predecessors. This block
405 * is mature. As other constructors calls optimization and verify for the
406 * block. If one of the predecessors is Unknown (as it has to be filled in
407 * later) optimizations are skipped. This is necessary to
408 * construct Blocks in loops.
411 * CONTROL FLOW OPERATIONS
412 * -----------------------
414 * In each block there must be exactly one of the control flow
415 * operations Start, End, Jmp, Cond, Return or Raise. The output of a
416 * control flow operation points to the block to be executed next.
418 * ir_node *new_Start (void)
419 * -------------------------
421 * Creates a start node. Not actually needed public. There is only one such
422 * node in each procedure which is automatically created by new_ir_graph.
425 * No inputs except the block it belongs to.
427 * A tuple of 4 (5, 6) distinct values. These are labeled by the following
428 * projection numbers (pn_Start):
429 * * pn_Start_X_initial_exec mode X, points to the first block to be exe * cuted.
430 * * pn_Start_M mode M, the global store
431 * * pn_Start_P_frame_base mode P, a pointer to the base of the proce * dures stack frame.
432 * * pn_Start_P_globals mode P, a pointer to the part of the memory * containing_all_ global things.
433 * * pn_Start_T_args mode T, a tuple containing all arguments of * the procedure.
436 * ir_node *new_End (void)
437 * -----------------------
439 * Creates an end node. Not actually needed public. There is only one such
440 * node in each procedure which is automatically created by new_ir_graph.
443 * No inputs except the block it belongs to.
447 * ir_node *new_Jmp (void)
448 * -----------------------
450 * Creates a Jmp node.
453 * The block the node belongs to
455 * Control flow to the next block.
457 * ir_node *new_IJmp (ir_node *tgt)
458 * -----------------------
460 * Creates an IJmp node.
463 * The node that represents the target jump address
465 * Control flow to an unknown target, must be pinned by
468 * ir_node *new_Cond (ir_node *c)
469 * ------------------------------
471 * Creates a Cond node. There are two versions of this node.
477 * A tuple of two control flows. The first is taken if the input is
478 * false, the second if it is true.
482 * A value of mode I_u. (i)
484 * A tuple of n control flows. If the Cond's input is i, control
485 * flow will proceed along output i. If the input is >= n control
486 * flow proceeds along output n.
488 * ir_node *new_Return (ir_node *store, int arity, ir_node **in)
489 * -------------------------------------------------------------
491 * The Return node has as inputs the results of the procedure. It
492 * passes the control flow to the end_block.
498 * Control flow to the end block.
501 * ir_node *new_Const (ir_tarval *con)
502 * -----------------------------------------------
504 * Creates a constant in the constant table and adds a Const node
505 * returning this value to the start block. The mode is derived
509 * *con Points to an entry in the constant table.
510 * This pointer is added to the attributes of
511 * the node (self->attr.con)
513 * No inputs except the block it belogns to.
515 * The constant value.
517 * attr.con A tarval* pointer to the proper entry in the constant
520 * ir_node *new_SymConst (ir_mode *mode, union symconst_symbol value, symconst_addr_ent kind)
521 * -----------------------------------------------------------------------------------------
523 * There are several symbolic constants:
524 * symconst_type_tag The symbolic constant represents a type tag.
525 * symconst_type_size The symbolic constant represents the size of a type.
526 * symconst_type_align The symbolic constant represents the alignment of a type.
527 * symconst_addr_ent The symbolic constant represents the address of an entity.
528 * symconst_ofs_ent The symbolic constant represents the offset of an
529 * entity in its owner type.
530 * symconst_enum_const The symbolic constant is a enumeration constant of an
534 * mode P for SymConsts representing addresses, Iu otherwise.
535 * value The type, ident, entity or enum constant, depending on the
537 * kind The kind of the symbolic constant, see the list above.
540 * No inputs except the block it belongs to.
542 * A symbolic constant.
545 * attr.i.num The symconst_addr_ent, i.e. one of
547 * -symconst_type_size
548 * -symconst_type_align
551 * If the attr.i.num is symconst_type_tag, symconst_type_size or symconst_type_align,
552 * the node contains an attribute:
554 * attr.i.*type, a pointer to a type_class.
555 * if it is linkage_ptr_info it contains
556 * attr.i.*ptrinfo, an ident holding information for the linker.
560 * ir_node *new_simpleSel (ir_node *store, ir_node *frame, ir_entity *sel)
561 * -----------------------------------------------------------------------
564 * Selects an entity from a compound type. This entity can be a field or
568 * *store The memory in which the object the entity should be selected
570 * *frame The pointer to the object.
571 * *sel The entity to select.
574 * The memory containing the object.
575 * A pointer to the object.
576 * An unsigned integer.
578 * A pointer to the selected entity.
580 * attr.sel Pointer to the entity
583 * ir_node *new_Sel (ir_node *store, ir_node *frame, int arity, ir_node **in,
584 * --------------------------------------------------------------------------
588 * Selects a field from an array type. The entity has as owner the array, as
589 * type the arrays element type. The indices to access an array element are
593 * *store The memory in which the object the entity should be selected from
595 * *frame The pointer to the object.
596 * *arity number of array indices.
597 * *in array with index inputs to the node.
598 * *sel The entity to select.
601 * The memory containing the object.
602 * A pointer to the object.
603 * As much unsigned integer as there are array expressions.
605 * A pointer to the selected entity.
607 * attr.sel Pointer to the entity
609 * The constructors new_Sel and new_simpleSel generate the same IR nodes.
610 * simpleSel just sets the arity of the index inputs to zero.
613 * ARITHMETIC OPERATIONS
614 * ---------------------
616 * ir_node *new_Call (ir_node *store, ir_node *callee, int arity, ir_node **in,
617 * ----------------------------------------------------------------------------
621 * Creates a procedure call.
624 * *store The actual store.
625 * *callee A pointer to the called procedure.
626 * arity The number of procedure parameters.
627 * **in An array with the pointers to the parameters.
628 * The constructor copies this array.
629 * *type Type information of the procedure called.
632 * The store, the callee and the parameters.
634 * A tuple containing the eventually changed store and the procedure
637 * attr.call Contains the attributes for the procedure.
639 * ir_node *new_Builtin(ir_node *store, ir_builtin_kind kind, int arity, ir_node **in,
640 * -----------------------------------------------------------------------------------
644 * Creates a builtin call.
647 * *store The actual store.
648 * kind Describes the called builtin.
649 * arity The number of procedure parameters.
650 * **in An array with the pointers to the parameters.
651 * The constructor copies this array.
652 * *type Type information of the procedure called.
655 * The store, the kind and the parameters.
657 * A tuple containing the eventually changed store and the procedure
660 * attr.builtin Contains the attributes for the called builtin.
662 * ir_node *new_Add (ir_node *op1, ir_node *op2, ir_mode *mode)
663 * ------------------------------------------------------------
667 * ir_node *new_Sub (ir_node *op1, ir_node *op2, ir_mode *mode)
668 * ------------------------------------------------------------
672 * ir_node *new_Minus (ir_node *op, ir_mode *mode)
673 * -----------------------------------------------
675 * Unary Minus operations on integer and floating point values.
677 * ir_node *new_Mul (ir_node *op1, ir_node *op2, ir_mode *mode)
678 * ------------------------------------------------------------
682 * ir_node *new_Mulh (ir_node *op1, ir_node *op2, ir_mode *mode)
683 * ------------------------------------------------------------
685 * Returns the high order bits of a n*n=2n multiplication.
687 * ir_node *new_Div (ir_node *memop, ir_node *op1, ir_node *op2, ir_mode *mode, op_pin_state state)
688 * ------------------------------------------------------------------------------------------------
692 * ir_node *new_Mod (ir_node *memop, ir_node *op1, ir_node *op2, ir_mode *mode, op_pin_state state)
693 * ------------------------------------------------------------------------------------------------
697 * ir_node *new_And (ir_node *op1, ir_node *op2, ir_mode *mode)
698 * ------------------------------------------------------------
702 * ir_node *new_Or (ir_node *op1, ir_node *op2, ir_mode *mode)
703 * -----------------------------------------------------------
707 * ir_node *new_Eor (ir_node *op1, ir_node *op2, ir_mode *mode)
708 * ------------------------------------------------------------
712 * ir_node *new_Not (ir_node *op, ir_mode *mode)
713 * ---------------------------------------------
715 * This node constructs a constant where all bits are set to one
716 * and a Eor of this constant and the operator. This simulates a
719 * ir_node *new_Shl (ir_node *op, ir_node *k, ir_mode *mode)
720 * ---------------------------------------------------------
724 * ir_node *new_Shr (ir_node *op, ir_node *k, ir_mode *mode)
725 * ---------------------------------------------------------
727 * Logic shift right, i.e., zero extended.
730 * ir_node *new_Shrs (ir_node *op, ir_node *k, ir_mode *mode)
731 * ----------------------------------------------------------
733 * Arithmetic shift right, i.e., sign extended.
735 * ir_node *new_Rotl (ir_node *op, ir_node *k, ir_mode *mode)
736 * ---------------------------------------------------------
738 * Rotates the operand to the left by k bits.
740 * ir_node *new_Carry (ir_node *op1, ir_node *op2, ir_mode *mode)
741 * ------------------------------------------------------------
743 * Calculates the Carry value for integer addition. Used only
746 * ir_node *new_Borrow (ir_node *op1, ir_node *op2, ir_mode *mode)
747 * ------------------------------------------------------------
749 * Calculates the Borrow value for integer substraction. Used only
752 * ir_node *new_Conv (ir_node *op, ir_mode *mode)
753 * ---------------------------------------------
755 * Mode conversion. For allowed conversions see UKA Tech Report
758 * ir_node *new_Cmp (ir_node *op1, ir_node *op2)
759 * ---------------------------------------------
762 * The two values to be compared.
764 * A 16-tuple containing the results of the 16 different comparisons.
765 * The following is a list giving the comparisons and a projection
766 * number (pn_Cmp) to use in Proj nodes to extract the proper result.
770 * pn_Cmp_Le less or equal
772 * pn_Cmp_Ge greater of equal
773 * pn_Cmp_Lg less or greater
774 * pn_Cmp_Leg less, equal or greater = ordered
775 * pn_Cmp_Uo unordered
776 * pn_Cmp_Ue unordered or equal
777 * pn_Cmp_Ul unordered or less
778 * pn_Cmp_Ule unordered, less or equal
779 * pn_Cmp_Ug unordered or greater
780 * pn_Cmp_Uge unordered, greater or equal
781 * pn_Cmp_Ne unordered, less or greater = not equal
788 * In general, Phi nodes are automaitcally inserted. In some cases, if
789 * all predecessors of a block are known, an explicit Phi node constructor
790 * is needed. E.g., to construct a FIRM graph for a statement as
791 * a = (b==c) ? 2 : 5;
793 * ir_node *new_Phi (int arity, ir_node **in, ir_mode *mode)
794 * ---------------------------------------------------------
796 * Creates a Phi node. The in's order has to correspond to the order
797 * of in's of current_block. This is not checked by the library!
798 * If one of the predecessors is Unknown (as it has to be filled in
799 * later) optimizations are skipped. This is necessary to
800 * construct Phi nodes in loops.
803 * arity number of predecessors
804 * **in array with predecessors
805 * *mode The mode of its inputs and output.
807 * A Phi node has as many inputs as the block it belongs to.
808 * Each input points to a definition of the same value on a
809 * different path in the control flow.
811 * The definition valid in this block.
813 * ir_node *new_Mux (ir_node *sel, ir_node *ir_false, ir_node *ir_true, ir_mode *mode)
814 * -----------------------------------------------------------------------------------
816 * Creates a Mux node. This node implements the following semantic:
817 * If the sel node (which must be of mode_b) evaluates to true, its value is
818 * ir_true, else ir_false;
822 * OPERATIONS TO MANAGE MEMORY EXPLICITLY
823 * --------------------------------------
825 * ir_node *new_Load (ir_node *store, ir_node *addr, ir_mode *mode, ir_cons_flags flags)
826 * -------------------------------------------------------------------------------------
828 * The Load operation reads a value from memory.
831 * *store The current memory.
832 * *addr A pointer to the variable to be read in this memory.
833 * *mode The mode of the value to be loaded.
834 * flags Additional flags for alignment, volatility and pin state.
837 * The memory and a pointer to a variable in this memory.
839 * A tuple of the memory, a control flow to be taken in case of
840 * an exception and the loaded value.
842 * ir_node *new_Store (ir_node *store, ir_node *addr, ir_node *val, ir_cons_flags flags)
843 * -------------------------------------------------------------------------------------
845 * The Store operation writes a value to a variable in memory.
848 * The memory, a pointer to a variable in this memory and the value
849 * to write to this variable.
851 * A tuple of the changed memory and a control flow to be taken in
852 * case of an exception.
854 * ir_node *new_Alloc (ir_node *store, ir_node *count, ir_type *alloc_type,
855 * -----------------------------------------------------------------------
859 * The Alloc node allocates a new variable. It can be specified whether the
860 * variable should be allocated to the stack or to the heap.
863 * *store The memory which shall contain the new variable.
864 * *count This field is for allocating arrays, it specifies how
865 * many array elements are to be allocated.
866 * *alloc_type The type of the allocated variable. In case of allocating
867 * arrays this has to be the array type, not the type of the
869 * where Where to allocate the variable, either heap_alloc or stack_alloc.
872 * A memory and an unsigned integer.
874 * A tuple of the changed memory, a control flow to be taken in
875 * case of an exception and the pointer to the new variable.
877 * a.where Indicates where the variable is allocated.
878 * a.*type A pointer to the class the allocated data object
881 * ir_node *new_Free (ir_node *store, ir_node *ptr, ir_node *size, ir_type *free_type,
882 * -----------------------------------------------------------------------------------
886 * The Free node frees memory of the given variable.
889 * *store The memory which shall contain the new variable.
890 * *ptr The pointer to the object to free.
891 * *size The number of objects of type free_type to free in a sequence.
892 * *free_type The type of the freed variable.
893 * where Where the variable was allocated, either heap_alloc or stack_alloc.
896 * A memory, a pointer and an unsigned integer.
898 * The changed memory.
900 * f.*type A pointer to the type information of the freed data object.
904 * ir_node *new_Sync (int arity, ir_node **in)
905 * -------------------------------------------
907 * The Sync operation unifies several partial memory blocks. These blocks
908 * have to be pairwise disjunct or the values in common locations have to
909 * be identical. This operation allows to specify all operations that eventually
910 * need several partial memory blocks as input with a single entrance by
911 * unifying the memories with a preceding Sync operation.
914 * arity The number of memories to synchronize.
915 * **in An array of pointers to nodes that produce an output of
920 * The unified memory.
926 * ir_node *new_NoMem (void)
927 * -----------------------------------------------------------------------------------
929 * Returns the unique NoMem node current_ir_graph->no_mem.
930 * This node is used as input for operations that need a Memory, but do not
931 * change it like Div by const != 0, analyzed calls etc.
933 * ir_node *new_Proj (ir_node *arg, ir_mode *mode, long proj)
934 * ----------------------------------------------------------
936 * Selects one entry of a tuple. This is a hidden edge with attributes.
939 * *arg A node producing a tuple.
940 * *mode The mode of the value to project.
941 * proj The position of the value in the tuple.
947 * ir_node *new_Tuple (int arity, ir_node **in)
948 * --------------------------------------------
950 * Builds a Tuple from single values. This is needed to implement
951 * optimizations that remove a node that produced a tuple. The node can be
952 * replaced by the Tuple operation so that the following Proj nodes have not to
953 * be changed. (They are hard to find due to the implementation with pointers
954 * in only one direction.) The Tuple node is smaller than any other
955 * node, so that a node can be changed into a Tuple by just changing its
956 * opcode and giving it a new in array.
959 * arity The number of tuple elements.
960 * **in An array containing pointers to the nodes producing the
963 * ir_node *new_Id (ir_node *val, ir_mode *mode)
964 * ---------------------------------------------
966 * The single output of the Id operation is its input. Also needed
970 * HIGH LEVEL OPERATIONS
971 * ---------------------
973 * ir_node *new_CopyB (ir_node *store, ir_node *dst, ir_node *src, ir_type *data_type)
974 * -----------------------------------------------------------------------------------
976 * Describes a high level block copy of a compound type from address src to
977 * address dst. Must be lowered to a Call to a runtime memory copy function.
980 * HIGH LEVEL OPERATIONS: Exception Support
981 * ----------------------------------------
982 * See TechReport 1999-14, chapter Exceptions.
984 * ir_node *new_InstOf(ir_node *store, ir_node *ptr, ir_type *type);
985 * -----------------------------------------------------------------------------------
987 * Describes a high level type check. Must be lowered to a Call to a runtime check
990 * ir_node *new_Raise (ir_node *store, ir_node *obj)
991 * -------------------------------------------------
993 * Raises an exception. Unconditional change of control flow. Writes
994 * an explicit Except variable to memory to pass it to the exception
995 * handler. Must be lowered to a Call to a runtime check
1000 * A pointer to the Except variable.
1002 * A tuple of control flow and the changed memory state. The control flow
1003 * points to the exception handler if it is definied in this procedure,
1004 * else it points to the end_block.
1006 * ir_node *new_Bound (ir_node *store, ir_node *idx, ir_node *lower, ir_node *upper);
1007 * -----------------------------------------------------------------------------------
1009 * Describes a high level bounds check. Must be lowered to a Call to a runtime check
1012 * ir_node *new_Pin (ir_node *node);
1013 * -----------------------------------------------------------------------------------
1015 * Pin the value of the node node in the current block No users of the Pin node can
1016 * float above the Block of the Pin. The node cannot float behind this block. Often
1017 * used to Pin the NoMem node.
1020 * COPING WITH DATA OBJECTS
1021 * ========================
1023 * Two kinds of data objects have to be distinguished for generating
1024 * FIRM. First there are local variables other than arrays that are
1025 * known to be alias free. Second there are all other data objects.
1026 * For the first a common SSA representation is built, the second
1027 * are modeled by saving them to memory. The memory is treated as
1028 * a single local variable, the alias problem is hidden in the
1029 * content of this variable.
1031 * All values known in a Block are listed in the block's attribute,
1032 * block.**graph_arr which is used to automatically insert Phi nodes.
1033 * The following two functions can be used to add a newly computed value
1034 * to the array, or to get the producer of a value, i.e., the current
1037 * inline void set_value (int pos, ir_node *value)
1038 * -----------------------------------------------
1040 * Has to be called for every assignment to a local variable. It
1041 * adds the value to the array of used values at position pos. Pos
1042 * has to be a unique identifier for an entry in the procedure's
1043 * definition table. It can be used to access the value again.
1044 * Requires current_block to be set correctly.
1046 * ir_node *get_value (int pos, ir_mode *mode)
1047 * -------------------------------------------
1049 * Returns the node defining the value referred to by pos. If the
1050 * value is not defined in this block a Phi node is generated and
1051 * all definitions reaching this Phi node are collected. It can
1052 * happen that the algorithm allocates an unnecessary Phi node,
1053 * e.g. if there is only one definition of this value, but this
1054 * definition reaches the currend block on several different
1055 * paths. This Phi node will be eliminated if optimizations are
1056 * turned on right after its creation.
1057 * Requires current_block to be set correctly.
1059 * There are two special routines for the global store:
1061 * void set_store (ir_node *store)
1062 * -------------------------------
1064 * Adds the store to the array of known values at a reserved
1066 * Requires current_block to be set correctly.
1068 * ir_node *get_store (void)
1069 * -------------------------
1071 * Returns the node defining the actual store.
1072 * Requires current_block to be set correctly.
1075 * inline void keep_alive (ir_node *ka)
1076 * ------------------------------------
1078 * Keep this node alive because it is (might be) not in the control
1079 * flow from Start to End. Adds the node to the list in the end
1083 #ifndef FIRM_IR_IRCONS_H
1084 #define FIRM_IR_IRCONS_H
1086 #include "firm_types.h"
1090 /*-------------------------------------------------------------------------*/
1091 /* The raw interface */
1092 /*-------------------------------------------------------------------------*/
1095 * Constructor for a Const node.
1097 * Adds the node to the start block.
1099 * Constructor for a Const node. The constant represents a target
1100 * value. Sets the type information to type_unknown. (No more
1101 * supported: If tv is entity derives a somehow useful type.)
1103 * @param *db A pointer for debug information.
1104 * @param *irg The IR graph the node belongs to.
1105 * @param *mode The mode of the operands and results.
1106 * @param value A value from which the tarval is made.
1108 FIRM_API ir_node *new_rd_Const_long(dbg_info *db, ir_graph *irg,
1109 ir_mode *mode, long value);
1111 /** Constructor for a SymConst node.
1113 * This is the constructor for a symbolic constant.
1114 * There are several kinds of symbolic constants:
1115 * - symconst_type_tag The symbolic constant represents a type tag. The
1116 * type the tag stands for is given explicitly.
1117 * - symconst_type_size The symbolic constant represents the size of a type.
1118 * The type of which the constant represents the size
1119 * is given explicitly.
1120 * - symconst_type_align The symbolic constant represents the alignment of a
1121 * type. The type of which the constant represents the
1122 * size is given explicitly.
1123 * - symconst_addr_ent The symbolic constant represents the address of an
1124 * entity (variable or method). The variable is given
1125 * explicitly by a firm entity.
1126 * - symconst_ofs_ent The symbolic constant represents the offset of an
1127 * entity in its owner type.
1128 * - symconst_enum_const The symbolic constant is a enumeration constant of
1129 * an enumeration type.
1131 * Inputs to the node:
1132 * No inputs except the block it belongs to.
1133 * Outputs of the node.
1134 * An unsigned integer (I_u) or a pointer (P).
1136 * Mention union in declaration so that the firmjni generator recognizes that
1137 * it can not cast the argument to an int.
1139 * @param *db A pointer for debug information.
1140 * @param *irg The IR graph the node belongs to.
1141 * @param mode The mode for the SymConst.
1142 * @param value A type, ident, entity or enum constant depending on the
1144 * @param kind The kind of the symbolic constant, see the list above
1146 FIRM_API ir_node *new_rd_SymConst(dbg_info *db, ir_graph *irg, ir_mode *mode,
1147 union symconst_symbol value,
1148 symconst_kind kind);
1150 /** Constructor for a SymConst addr_ent node.
1152 * Same as new_rd_SymConst, except that the constructor is tailored for
1153 * symconst_addr_ent.
1154 * Adds the SymConst to the start block of irg. */
1155 FIRM_API ir_node *new_rd_SymConst_addr_ent(dbg_info *db, ir_graph *irg,
1156 ir_mode *mode, ir_entity *symbol);
1158 /** Constructor for a SymConst ofs_ent node.
1160 * Same as new_rd_SymConst, except that the constructor is tailored for
1162 * Adds the SymConst to the start block of irg.
1164 FIRM_API ir_node *new_rd_SymConst_ofs_ent(dbg_info *db, ir_graph *irg,
1165 ir_mode *mode, ir_entity *symbol);
1167 /** Constructor for a SymConst type_tag node.
1169 * Same as new_rd_SymConst, except that the constructor is tailored for
1170 * symconst_type_tag.
1171 * Adds the SymConst to the start block of irg.
1173 FIRM_API ir_node *new_rd_SymConst_type_tag(dbg_info *db, ir_graph *irg,
1174 ir_mode *mode, ir_type *symbol);
1176 /** Constructor for a SymConst size node.
1178 * Same as new_rd_SymConst, except that the constructor is tailored for
1179 * symconst_type_size.
1180 * Adds the SymConst to the start block of irg. */
1181 FIRM_API ir_node *new_rd_SymConst_size(dbg_info *db, ir_graph *irg,
1182 ir_mode *mode, ir_type *symbol);
1184 /** Constructor for a SymConst size node.
1186 * Same as new_rd_SymConst, except that the constructor is tailored for
1187 * symconst_type_align.
1188 * Adds the SymConst to the start block of irg.
1190 FIRM_API ir_node *new_rd_SymConst_align(dbg_info *db, ir_graph *irg,
1191 ir_mode *mode, ir_type *symbol);
1193 /** Constructor for a simpleSel node.
1195 * This is a shortcut for the new_rd_Sel() constructor. To be used for
1196 * Sel nodes that do not select from an array, i.e., have no index
1197 * inputs. It adds the two parameters 0, NULL.
1199 * @param *db A pointer for debug information.
1200 * @param *block The IR block the node belongs to.
1201 * @param *store The memory in which the object the entity should be
1202 * selected from is allocated.
1203 * @param *objptr The object from that the Sel operation selects a
1204 * single attribute out.
1205 * @param *ent The entity to select.
1207 FIRM_API ir_node *new_rd_simpleSel(dbg_info *db, ir_node *block, ir_node *store,
1208 ir_node *objptr, ir_entity *ent);
1210 /** Constructor for a remainderless Div node.
1212 * @param *db A pointer for debug information.
1213 * @param *block The IR block the node belongs to.
1214 * @param *memop The store needed to model exceptions
1215 * @param *op1 The first operand.
1216 * @param *op2 The second operand.
1217 * @param *mode The mode of the result.
1218 * @param state The pinned state.
1220 FIRM_API ir_node *new_rd_DivRL(dbg_info *db, ir_node *block, ir_node *memop,
1221 ir_node *op1, ir_node *op2, ir_mode *mode,
1222 op_pin_state state);
1224 /** Constructor for a strictConv node.
1226 * @param *db A pointer for debug information.
1227 * @param *block The IR block the node belongs to.
1228 * @param *op The operand.
1229 * @param *mode The mode of this the operand muss be converted .
1231 FIRM_API ir_node *new_rd_strictConv(dbg_info *db, ir_node *block,
1232 ir_node *op, ir_mode *mode);
1234 /** Constructor for a defaultProj node.
1236 * Represents the default control flow of a Switch-Cond node.
1238 * @param *db A pointer for debug information.
1239 * @param arg A node producing a tuple.
1240 * @param max_proj The end position of the value in the tuple.
1242 FIRM_API ir_node *new_rd_defaultProj(dbg_info *db, ir_node *arg, long max_proj);
1244 /** Constructor for an ASM pseudo node.
1246 * @param *db A pointer for debug information.
1247 * @param *block The block the node belong to.
1248 * @param arity The number of data inputs to the node.
1249 * @param *in The array of length arity of data inputs.
1250 * @param *inputs The array of length arity of input constraints.
1251 * @param n_outs The number of data outputs to the node.
1252 * @param *outputs The array of length n_outs of output constraints.
1253 * @param n_clobber The number of clobbered registers.
1254 * @param *clobber The array of length n_clobber of clobbered registers.
1255 * @param *asm_text The assembler text.
1257 FIRM_API ir_node *new_rd_ASM(dbg_info *db, ir_node *block,
1258 int arity, ir_node *in[], ir_asm_constraint *inputs,
1259 size_t n_outs, ir_asm_constraint *outputs,
1260 size_t n_clobber, ident *clobber[],
1263 /*-------------------------------------------------------------------------*/
1264 /* The raw interface without debug support */
1265 /*-------------------------------------------------------------------------*/
1267 /** Constructor for a Const node.
1269 * Adds the node to the start block.
1271 * Constructor for a Const node. The constant represents a target
1272 * value. Sets the type information to type_unknown. (No more
1273 * supported: If tv is entity derives a somehow useful type.)
1275 * @param *irg The IR graph the node belongs to.
1276 * @param *mode The mode of the operands and the results.
1277 * @param value A value from which the tarval is made.
1279 FIRM_API ir_node *new_r_Const_long(ir_graph *irg, ir_mode *mode, long value);
1281 /** Constructor for a SymConst node.
1283 * This is the constructor for a symbolic constant.
1284 * There are several kinds of symbolic constants:
1285 * - symconst_type_tag The symbolic constant represents a type tag. The
1286 * type the tag stands for is given explicitly.
1287 * - symconst_type_size The symbolic constant represents the size of a type.
1288 * The type of which the constant represents the size
1289 * is given explicitly.
1290 * - symconst_type_align The symbolic constant represents the alignment of a
1291 * type. The type of which the constant represents the
1292 * size is given explicitly.
1293 * - symconst_addr_ent The symbolic constant represents the address of an
1294 * entity (variable or method). The variable is given
1295 * explicitly by a firm entity.
1296 * - symconst_ofs_ent The symbolic constant represents the offset of an
1297 * entity in its owner type.
1298 * - symconst_enum_const The symbolic constant is a enumeration constant of
1299 * an enumeration type.
1301 * Inputs to the node:
1302 * No inputs except the block it belongs to.
1303 * Outputs of the node.
1304 * An unsigned integer (I_u) or a pointer (P).
1306 * Mention union in declaration so that the firmjni generator recognizes that
1307 * it can not cast the argument to an int.
1309 * @param *irg The IR graph the node belongs to.
1310 * @param mode The mode for the SymConst.
1311 * @param value A type, ident, entity or enum constant depending on the
1313 * @param kind The kind of the symbolic constant, see the list above
1315 FIRM_API ir_node *new_r_SymConst(ir_graph *irg, ir_mode *mode,
1316 union symconst_symbol value,
1317 symconst_kind kind);
1319 /** Constructor for a simpleSel node.
1321 * This is a shortcut for the new_d_Sel() constructor. To be used for
1322 * Sel nodes that do not select from an array, i.e., have no index
1323 * inputs. It adds the two parameters 0, NULL.
1325 * @param *block The IR block the node belongs to.
1326 * @param *store The memory in which the object the entity should be selected
1327 * from is allocated.
1328 * @param *objptr The object from that the Sel operation selects a
1329 * single attribute out.
1330 * @param *ent The entity to select.
1332 FIRM_API ir_node *new_r_simpleSel(ir_node *block, ir_node *store,
1333 ir_node *objptr, ir_entity *ent);
1335 /** Constructor for a remainderless Div node.
1337 * @param *block The IR block the node belongs to.
1338 * @param *memop The store needed to model exceptions
1339 * @param *op1 The first operand.
1340 * @param *op2 The second operand.
1341 * @param *mode The mode of the result.
1342 * @param state The pinned state.
1344 FIRM_API ir_node *new_r_DivRL(ir_node *block, ir_node *memop,
1345 ir_node *op1, ir_node *op2, ir_mode *mode,
1346 op_pin_state state);
1347 /** Constructor for a strict Conv node.
1349 * @param *block The IR block the node belongs to.
1350 * @param *op The operand.
1351 * @param *mode The mode of this the operand muss be converted .
1353 FIRM_API ir_node *new_r_strictConv(ir_node *block, ir_node *op, ir_mode *mode);
1355 /** Constructor for a defaultProj node.
1357 * Represents the default control flow of a Switch-Cond node.
1359 * @param arg A node producing a tuple.
1360 * @param max_proj The end position of the value in the tuple.
1362 FIRM_API ir_node *new_r_defaultProj(ir_node *arg, long max_proj);
1364 /** Constructor for an ASM pseudo node.
1366 * @param *block The block the node belong to.
1367 * @param arity The number of data inputs to the node.
1368 * @param *in The array of length arity of data inputs.
1369 * @param *inputs The array of length arity of input constraints.
1370 * @param n_outs The number of data outputs to the node.
1371 * @param *outputs The array of length n_outs of output constraints.
1372 * @param n_clobber The number of clobbered registers.
1373 * @param *clobber The array of length n_clobber of clobbered registers.
1374 * @param *asm_text The assembler text.
1376 FIRM_API ir_node *new_r_ASM(ir_node *block,
1377 int arity, ir_node *in[], ir_asm_constraint *inputs,
1378 size_t n_outs, ir_asm_constraint *outputs,
1379 size_t n_clobber, ident *clobber[],
1382 /*-----------------------------------------------------------------------*/
1383 /* The block oriented interface */
1384 /*-----------------------------------------------------------------------*/
1386 /** Sets the current block in which the following constructors place the
1387 * nodes they construct.
1389 * @param target The new current block.
1391 FIRM_API void set_cur_block(ir_node *target);
1392 FIRM_API void set_r_cur_block(ir_graph *irg, ir_node *target);
1394 /** Returns the current block of the current graph. */
1395 FIRM_API ir_node *get_cur_block(void);
1396 FIRM_API ir_node *get_r_cur_block(ir_graph *irg);
1399 * @see new_rd_Const_long()
1401 * @param *db A pointer for debug information.
1402 * @param *mode The mode of the operands and results.
1403 * @param value A value from which the tarval is made.
1405 FIRM_API ir_node *new_d_Const_long(dbg_info *db, ir_mode *mode, long value);
1407 /** Constructor for a SymConst node.
1409 * This is the constructor for a symbolic constant.
1410 * There are several kinds of symbolic constants:
1411 * - symconst_type_tag The symbolic constant represents a type tag. The
1412 * type the tag stands for is given explicitly.
1413 * - symconst_type_size The symbolic constant represents the size of a type.
1414 * The type of which the constant represents the size
1415 * is given explicitly.
1416 * - symconst_type_align The symbolic constant represents the alignment of a
1417 * type. The type of which the constant represents the
1418 * size is given explicitly.
1419 * - symconst_addr_ent The symbolic constant represents the address of an
1420 * entity (variable or method). The variable is given
1421 * explicitly by a firm entity.
1422 * - symconst_ofs_ent The symbolic constant represents the offset of an
1423 * entity in its owner type.
1424 * - symconst_enum_const The symbolic constant is a enumeration constant of
1425 * an enumeration type.
1427 * Inputs to the node:
1428 * No inputs except the block it belongs to.
1429 * Outputs of the node.
1430 * An unsigned integer (I_u) or a pointer (P).
1432 * Mention union in declaration so that the firmjni generator recognizes that
1433 * it can not cast the argument to an int.
1435 * @param *db A pointer for debug information.
1436 * @param mode The mode for the SymConst.
1437 * @param value A type, ident, entity or enum constant depending on the
1439 * @param kind The kind of the symbolic constant, see the list above
1441 FIRM_API ir_node *new_d_SymConst(dbg_info *db, ir_mode *mode,
1442 union symconst_symbol value,
1443 symconst_kind kind);
1445 /** Constructor for a simpleSel node.
1447 * This is a shortcut for the new_d_Sel() constructor. To be used for
1448 * Sel nodes that do not select from an array, i.e., have no index
1449 * inputs. It adds the two parameters 0, NULL.
1451 * @param *db A pointer for debug information.
1452 * @param *store The memory in which the object the entity should be
1453 * selected from is allocated.
1454 * @param *objptr The object from that the Sel operation selects a
1455 * single attribute out.
1456 * @param *ent The entity to select.
1458 FIRM_API ir_node *new_d_simpleSel(dbg_info *db, ir_node *store, ir_node *objptr,
1460 /** Constructor for a remainderless Div node.
1462 * Adds the node to the block in current_ir_block.
1464 * @param *db A pointer for debug information.
1465 * @param *memop The store needed to model exceptions
1466 * @param *op1 The first operand.
1467 * @param *op2 The second operand.
1468 * @param *mode The mode of the result.
1469 * @param state The pinned state.
1471 FIRM_API ir_node *new_d_DivRL(dbg_info *db, ir_node *memop,
1472 ir_node *op1, ir_node *op2, ir_mode *mode,
1473 op_pin_state state);
1474 /** Constructor for a strict Conv node.
1476 * Adds the node to the block in current_ir_block.
1478 * @param *db A pointer for debug information.
1479 * @param *op The operand.
1480 * @param *mode The mode of this the operand muss be converted .
1482 FIRM_API ir_node *new_d_strictConv(dbg_info *db, ir_node *op, ir_mode *mode);
1484 /** Constructor for a defaultProj node.
1486 * Represents the default control flow of a Switch-Cond node.
1487 * Adds the node to the block in current_ir_block.
1489 * @param *db A pointer for debug information.
1490 * @param arg A node producing a tuple.
1491 * @param max_proj The end position of the value in the tuple.
1493 FIRM_API ir_node *new_d_defaultProj(dbg_info *db, ir_node *arg, long max_proj);
1495 /** Constructor for an ASM pseudo node.
1497 * @param *db A pointer for debug information.
1498 * @param arity The number of data inputs to the node.
1499 * @param *in The array of length arity of data inputs.
1500 * @param *inputs The array of length arity of input constraints.
1501 * @param n_outs The number of data outputs to the node.
1502 * @param *outputs The array of length n_outs of output constraints.
1503 * @param n_clobber The number of clobbered registers.
1504 * @param *clobber The array of length n_clobber of clobbered registers.
1505 * @param *asm_text The assembler text.
1507 FIRM_API ir_node *new_d_ASM(dbg_info *db, int arity, ir_node *in[],
1508 ir_asm_constraint *inputs,
1509 size_t n_outs, ir_asm_constraint *outputs,
1510 size_t n_clobber, ident *clobber[],
1513 /*-----------------------------------------------------------------------*/
1514 /* The block oriented interface without debug support */
1515 /*-----------------------------------------------------------------------*/
1518 * Make a const from a long.
1519 * This is just convenience for the usual
1521 * new_Const(mode, tarval_from_long(mode, ...))
1524 * @param mode The mode for the const.
1525 * @param value The value of the constant.
1526 * @return A new const node.
1528 FIRM_API ir_node *new_Const_long(ir_mode *mode, long value);
1530 /** Constructor for a SymConst node.
1532 * This is the constructor for a symbolic constant.
1533 * There are several kinds of symbolic constants:
1534 * - symconst_type_tag The symbolic constant represents a type tag. The
1535 * type the tag stands for is given explicitly.
1536 * - symconst_type_size The symbolic constant represents the size of a type.
1537 * The type of which the constant represents the size
1538 * is given explicitly.
1539 * - symconst_type_align The symbolic constant represents the alignment of a
1540 * type. The type of which the constant represents the
1541 * size is given explicitly.
1542 * - symconst_addr_ent The symbolic constant represents the address of an
1543 * entity (variable or method). The variable is given
1544 * explicitly by a firm entity.
1545 * - symconst_ofs_ent The symbolic constant represents the offset of an
1546 * entity in its owner type.
1547 * - symconst_enum_const The symbolic constant is a enumeration constant of
1548 * an enumeration type.
1550 * Inputs to the node:
1551 * No inputs except the block it belongs to.
1552 * Outputs of the node.
1553 * An unsigned integer (I_u) or a pointer (P).
1555 * Mention union in declaration so that the firmjni generator recognizes that
1556 * it can not cast the argument to an int.
1558 * @param mode The mode for the SymConst.
1559 * @param value A type, ident, entity or enum constant depending on the
1561 * @param kind The kind of the symbolic constant, see the list above
1563 FIRM_API ir_node *new_SymConst(ir_mode *mode, union symconst_symbol value,
1564 symconst_kind kind);
1566 /** Constructor for a simpelSel node.
1568 * This is a shortcut for the new_Sel() constructor. To be used for
1569 * Sel nodes that do not select from an array, i.e., have no index
1570 * inputs. It adds the two parameters 0, NULL.
1572 * @param *store The memory in which the object the entity should be selected from is allocated.
1573 * @param *objptr The object from that the Sel operation selects a single attribute out.
1574 * @param *ent The entity to select.
1576 FIRM_API ir_node *new_simpleSel(ir_node *store, ir_node *objptr,
1579 /** Constructor for a remainderless Div node.
1581 * Adds the node to the block in current_ir_block.
1583 * @param *memop The store needed to model exceptions
1584 * @param *op1 The first operand.
1585 * @param *op2 The second operand.
1586 * @param *mode The mode of the result.
1587 * @param state The pinned state.
1589 FIRM_API ir_node *new_DivRL(ir_node *memop, ir_node *op1, ir_node *op2,
1590 ir_mode *mode, op_pin_state state);
1592 /** Constructor for a strict Conv node.
1594 * Adds the node to the block in current_ir_block.
1596 * @param *op The operand.
1597 * @param *mode The mode of this the operand muss be converted.
1599 FIRM_API ir_node *new_strictConv(ir_node *op, ir_mode *mode);
1601 /** Constructor for a defaultProj node.
1603 * Represents the default control flow of a Switch-Cond node.
1604 * Adds the node to the block in current_ir_block.
1606 * @param arg A node producing a tuple.
1607 * @param max_proj The end position of the value in the tuple.
1609 FIRM_API ir_node *new_defaultProj(ir_node *arg, long max_proj);
1611 /** Constructor for an ASM pseudo node.
1613 * @param arity The number of data inputs to the node.
1614 * @param *in The array of length arity of data inputs.
1615 * @param *inputs The array of length arity of input constraints.
1616 * @param n_outs The number of data outputs to the node.
1617 * @param *outputs The array of length n_outs of output constraints.
1618 * @param n_clobber The number of clobbered registers.
1619 * @param *clobber The array of length n_clobber of clobbered registers.
1620 * @param *asm_text The assembler text.
1622 FIRM_API ir_node *new_ASM(int arity, ir_node *in[], ir_asm_constraint *inputs,
1623 size_t n_outs, ir_asm_constraint *outputs,
1624 size_t n_clobber, ident *clobber[], ident *asm_text);
1626 /*---------------------------------------------------------------------*/
1627 /* The comfortable interface. */
1628 /* Supports automatic Phi node construction. */
1629 /* All routines of the block oriented interface except new_Block are */
1631 /*---------------------------------------------------------------------*/
1633 /** Create an immature Block.
1635 * An immature Block has an unknown number of predecessors. Predecessors
1636 * can be added with add_immBlock_pred(). Once all predecessors are
1637 * added the block must be matured.
1639 * Adds the block to the graph in current_ir_graph. Can be used with automatic
1640 * Phi node construction.
1641 * This constructor can only be used if the graph is in state_building.
1643 FIRM_API ir_node *new_d_immBlock(dbg_info *db);
1644 FIRM_API ir_node *new_immBlock(void);
1645 FIRM_API ir_node *new_r_immBlock(ir_graph *irg);
1646 FIRM_API ir_node *new_rd_immBlock(dbg_info *db, ir_graph *irg);
1648 /** Add a control flow edge to an immature block. */
1649 FIRM_API void add_immBlock_pred(ir_node *immblock, ir_node *jmp);
1651 /** Finalize a Block node, when all control flows are known. */
1652 FIRM_API void mature_immBlock(ir_node *block);
1654 /** Get the current value of a local variable.
1656 * Use this function to obtain the last definition of the local variable
1657 * associated with pos. Pos may not exceed the value passed as n_loc
1658 * to new_ir_graph. This call automatically inserts Phi nodes.
1660 * @param pos The position/id of the local variable.
1661 * @param *mode The mode of the value to get.
1663 FIRM_API ir_node *get_value(int pos, ir_mode *mode);
1664 FIRM_API ir_node *get_r_value(ir_graph *irg, int pos, ir_mode *mode);
1667 * Try to guess the mode of a local variable.
1668 * This is done by recursively going up the control flow graph until
1669 * we find a definition for the variable. The mode of the first found
1670 * definition is returned. NULL in case no definition is found.
1672 * @param pos The position/id of the local variable.
1674 FIRM_API ir_mode *ir_guess_mode(int pos);
1675 FIRM_API ir_mode *ir_r_guess_mode(ir_graph *irg, int pos);
1677 /** Remark a new definition of a variable.
1679 * Use this function to remember a new definition of the value
1680 * associated with pos. Pos may not exceed the value passed as n_loc
1681 * to new_ir_graph. This call is needed to automatically inserts Phi
1684 * @param pos The position/id of the local variable.
1685 * @param *value The new value written to the local variable.
1687 FIRM_API void set_value(int pos, ir_node *value);
1688 FIRM_API void set_r_value(ir_graph *irg, int pos, ir_node *value);
1691 * Find the value number for a node in the current block.
1693 * @param value the searched value
1695 * @return the value number of the value or -1 if this value has
1696 * no value number in the current block.
1698 FIRM_API int find_value(ir_node *value);
1699 FIRM_API int r_find_value(ir_graph *irg, ir_node *value);
1701 /** Get the current memory state.
1703 * Use this function to obtain the last definition of the memory
1704 * state. This call automatically inserts Phi nodes for the memory
1707 FIRM_API ir_node *get_store(void);
1708 FIRM_API ir_node *get_r_store(ir_graph *irg);
1710 /** Remark a new definition of the memory state.
1712 * Use this function to remember a new definition of the memory state.
1713 * This call is needed to automatically inserts Phi nodes.
1715 * @param *store The new memory state.
1717 FIRM_API void set_store(ir_node *store);
1718 FIRM_API void set_r_store(ir_graph *irg, ir_node *store);
1720 /** keep this node alive even if End is not control-reachable from it
1722 * @param ka The node to keep alive.
1724 FIRM_API void keep_alive(ir_node *ka);
1726 /* --- initialize and finalize IR construction --- */
1728 /** Puts the graph into state "phase_high" */
1729 FIRM_API void irg_finalize_cons(ir_graph *irg);
1731 /** Puts the program and all graphs into state phase_high.
1733 * This also remarks, the construction of types is finished,
1734 * e.g., that no more subtypes will be added. */
1735 FIRM_API void irp_finalize_cons(void);
1737 FIRM_API void ir_set_uninitialized_local_variable_func(
1738 uninitialized_local_variable_func_t *func);