-/* Copyright (C) 2002 by Universitaet Karlsruhe
-* All rights reserved.
-*/
+/*
+ * Project: libFIRM
+ * File name: ir/ana/irloop_t.h
+ * Purpose: Loop datastructure and access functions.
+ * Author: Goetz Lindenmaier
+ * Modified by:
+ * Created: 7.2002
+ * CVS-ID: $Id$
+ * Copyright: (c) 2002-2003 Universität Karlsruhe
+ * Licence: This file protected by GPL - GNU GENERAL PUBLIC LICENSE.
+ */
/**
* @file irloop.h
* Constructs loops data structure: indicates loop nesting.
*/
-/* $Id$ */
-
# ifndef _IRLOOP_H_
# define _IRLOOP_H_
# include "irgraph.h"
# include "irnode.h"
-
-/* @@@ Interprocedural backedges ... ???? */
-
+/* ------------------------------------------------------------------- */
/*
* Backedge information.
*
* The backedge information can only be used if the graph is not in
* phase phase_building.
*/
+/* ------------------------------------------------------------------- */
/** Returns true if the predesessor pos is a backedge. */
-bool is_backedge (ir_node *n, int pos);
+int is_inter_backedge(ir_node *n, int pos);
+int is_intra_backedge(ir_node *n, int pos);
+/** Returns non-zero if the predecessor pos is a backedge. */
+int is_backedge (ir_node *n, int pos);
/** Remarks that edge pos is a backedge. */
void set_backedge (ir_node *n, int pos);
/** Remarks that edge pos is not a backedge. */
void set_not_backedge (ir_node *n, int pos);
-/** Returns true if n has backedges. */
-bool has_backedges (ir_node *n);
+/** Returns non-zero if n has backedges. */
+int has_backedges (ir_node *n);
/** Sets backedge information to zero. */
void clear_backedges (ir_node *n);
+/* ------------------------------------------------------------------- */
/**
* The loops datastructure.
*
* @todo We could add a field pointing from a node to the containing loop,
* this would cost a lot of memory, though.
*/
+/* ------------------------------------------------------------------- */
+#ifndef _IR_LOOP_TYPEDEF_
+#define _IR_LOOP_TYPEDEF_
typedef struct ir_loop ir_loop;
+#endif
-/* Loop elements are loop nodes and ir nodes */
+/** Loop elements: loop nodes and ir nodes */
typedef union {
- firm_kind *kind; /* is either k_ir_node or k_ir_loop */
- ir_node *node; /* Pointer to a loop tree element */
- ir_loop *son; /* Pointer to a ir_graph element */
+ firm_kind *kind; /**< is either k_ir_node or k_ir_loop */
+ ir_node *node; /**< Pointer to an ir_node element */
+ ir_loop *son; /**< Pointer to an ir_loop element */
} loop_element;
+int is_ir_loop(const void *thing);
+
+/** Set the outermost loop in ir graph as basic access to loop tree. */
void set_irg_loop(ir_graph *irg, ir_loop *l);
+
+/* Returns the root loop info (if exists) for an irg. */
ir_loop *get_irg_loop(ir_graph *irg);
-/** Returns the loop n is contained in.
- assumes current_ir_graph set properly. */
+/** Returns the loop n is contained in. NULL if node is in no loop. */
ir_loop *get_irn_loop(ir_node *n);
/** Returns outer loop, itself if outermost. */
/* Sons are the inner loops contained in this loop. */
/** Returns the number of inner loops */
int get_loop_n_sons (ir_loop *loop);
+
+/** Returns the pos`th son loop (inner loop) of a loop.
+ Returns NULL if there is not a pos`th loop_node. */
ir_loop *get_loop_son (ir_loop *loop, int pos);
+
/** Returns the number of nodes contained in loop. */
int get_loop_n_nodes (ir_loop *loop);
+
+/** Returns the pos`th ir_node of a loop.
+ Returns NULL if there is not a pos`th ir_node. */
ir_node *get_loop_node (ir_loop *loop, int pos);
/** Returns the number of elements contained in loop. */
int get_loop_n_elements (ir_loop *loop);
+/** Returns a loop element. A loop element can be interpreted as a
+ kind pointer, an ir_node* or an ir_loop*. */
loop_element get_loop_element (ir_loop *loop, int pos);
-/*
- * Constructing and destructing the loop/backedge information.
+/** Returns the element number of the loop son in loop.
+ * Returns -1 if not found. O(|elements|). */
+int get_loop_element_pos(ir_loop *loop, void *le);
+
+/** Returns a unique node number for the loop node to make output
+ readable. If libfirm_debug is not set it returns the loop cast to
+ int. */
+int get_loop_loop_nr(ir_loop *loop);
+
+/** A field to connect additional information to a loop. Only valid
+ if libfirm_debug is set, else returns NULL. */
+void set_loop_link (ir_loop *loop, void *link);
+void *get_loop_link (const ir_loop *loop);
+
+/* ------------------------------------------------------------------- */
+/* Constructing and destructing the loop/backedge information. */
+/* ------------------------------------------------------------------- */
+
+/** Constructs backedge information and loop tree for a graph in intraprocedural view.
+ *
+ * The algorithm views the program representation as a pure graph.
+ * It assumes that only block and phi nodes may be loop headers.
+ * The resulting loop tree is a possible visiting order for dataflow
+ * analysis.
+ *
+ * @returns Maximal depth of loop tree.
+ *
+ * @remark
+ * One assumes, the Phi nodes in a block with a backedge have backedges
+ * at the same positions as the block. This is not the case, as
+ * the scc algorithms does not respect the program semantics in this case.
+ * Take a swap in a loop (t = i; i = j; j = t;) This results in two Phi
+ * nodes. They form a cycle. Once the scc algorithm deleted one of the
+ * edges, the cycle is removed. The second Phi node does not get a
+ * backedge!
*/
+/* @@@ Well, maybe construct_loop_information or analyze_loops ? */
+int construct_backedges(ir_graph *irg);
-/** Constructs backedge information for irg in intraprocedural view. */
-void construct_backedges(ir_graph *irg);
+/** Constructs backedges for all irgs in interprocedural view.
+ *
+ * @see As construct_backedges(), but for interprocedural view.
+ *
+ * @remark
+ * All loops in the graph will be marked as such, not only
+ * realizeable loops and recursions in the program. E.g., if the
+ * same funcion is called twice, there is a loop between the first
+ * function return and the second call.
+ *
+ * @returns Maximal depth of loop tree.
+*/
+int construct_ip_backedges(void);
+
+/** Construct loop tree only for control flow.
+ *
+ * This constructs loop information resembling the program structure.
+ * It is useful for loop optimizations and analyses, as, e.g., finding
+ * iteration variables or loop invariant code motion.
+ *
+ * This algorithm computes only back edge information for Block nodes, not
+ * for Phi nodes.
+ *
+ * @returns Maximal depth of loop tree. */
+int construct_cf_backedges(ir_graph *irg);
+
+/** Construct interprocedural loop tree for control flow.
+ *
+ * @see construct_cf_backedges() and construct_ip_backedges().
+ */
+int construct_ip_cf_backedges (void);
+
+/** Removes all loop information.
+ * Resets all backedges. Works for any construction algorithm.
+ */
+void free_loop_information(ir_graph *irg);
+void free_all_loop_information (void);
+
+
+
+
+/* ------------------------------------------------------------------- */
+/* Simple analyses based on the loop information */
+/* ------------------------------------------------------------------- */
+
+/** Test whether a value is loop invariant.
+ *
+ * @param n The node to be tested.
+ * @param block A block node.
+ *
+ * Returns non-zero, if the node n is not changed in the loop block
+ * belongs to or in inner loops of this block. */
+int is_loop_invariant(ir_node *n, ir_node *block);
-/** Constructs backedges for all irgs in interprocedural view. All
- loops in the graph will be marked as such, not only realizeable
- loops and recursions in the program. E.g., if the same funcion is
- called twice, there is a loop between the first funcion return and
- the second call. */
-void construct_ip_backedges(void);
#endif /* _IRLOOP_H_ */