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605 lines
29 KiB
Plaintext
@c Copyright (c) 2006 Free Software Foundation, Inc.
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@c Free Software Foundation, Inc.
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@c This is part of the GCC manual.
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@c For copying conditions, see the file gcc.texi.
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@c ---------------------------------------------------------------------
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@c Loop Representation
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@c ---------------------------------------------------------------------
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@node Loop Analysis and Representation
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@chapter Analysis and Representation of Loops
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GCC provides extensive infrastructure for work with natural loops, i.e.,
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strongly connected components of CFG with only one entry block. This
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chapter describes representation of loops in GCC, both on GIMPLE and in
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RTL, as well as the interfaces to loop-related analyses (induction
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variable analysis and number of iterations analysis).
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@menu
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* Loop representation:: Representation and analysis of loops.
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* Loop querying:: Getting information about loops.
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* Loop manipulation:: Loop manipulation functions.
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* LCSSA:: Loop-closed SSA form.
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* Scalar evolutions:: Induction variables on GIMPLE.
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* loop-iv:: Induction variables on RTL.
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* Number of iterations:: Number of iterations analysis.
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* Dependency analysis:: Data dependency analysis.
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* Lambda:: Linear loop transformations framework.
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@end menu
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@node Loop representation
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@section Loop representation
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@cindex Loop representation
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@cindex Loop analysis
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This chapter describes the representation of loops in GCC, and functions
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that can be used to build, modify and analyze this representation. Most
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of the interfaces and data structures are declared in @file{cfgloop.h}.
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At the moment, loop structures are analyzed and this information is
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updated only by the optimization passes that deal with loops, but some
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efforts are being made to make it available throughout most of the
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optimization passes.
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In general, a natural loop has one entry block (header) and possibly
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several back edges (latches) leading to the header from the inside of
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the loop. Loops with several latches may appear if several loops share
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a single header, or if there is a branching in the middle of the loop.
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The representation of loops in GCC however allows only loops with a
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single latch. During loop analysis, headers of such loops are split and
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forwarder blocks are created in order to disambiguate their structures.
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A heuristic based on profile information is used to determine whether
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the latches correspond to sub-loops or to control flow in a single loop.
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This means that the analysis sometimes changes the CFG, and if you run
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it in the middle of an optimization pass, you must be able to deal with
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the new blocks.
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Body of the loop is the set of blocks that are dominated by its header,
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and reachable from its latch against the direction of edges in CFG. The
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loops are organized in a containment hierarchy (tree) such that all the
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loops immediately contained inside loop L are the children of L in the
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tree. This tree is represented by the @code{struct loops} structure.
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The root of this tree is a fake loop that contains all blocks in the
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function. Each of the loops is represented in a @code{struct loop}
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structure. Each loop is assigned an index (@code{num} field of the
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@code{struct loop} structure), and the pointer to the loop is stored in
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the corresponding field of the @code{parray} field of the loops
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structure. Index of a sub-loop is always greater than the index of its
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super-loop. The indices do not have to be continuous, there may be
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empty (@code{NULL}) entries in the @code{parray} created by deleting
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loops. The index of a loop never changes. The first unused index is
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stored in the @code{num} field of the loops structure.
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Each basic block contains the reference to the innermost loop it belongs
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to (@code{loop_father}). For this reason, it is only possible to have
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one @code{struct loops} structure initialized at the same time for each
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CFG. It is recommended to use the global variable @code{current_loops}
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to contain the @code{struct loops} structure, especially if the loop
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structures are updated throughout several passes. Many of the loop
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manipulation functions assume that dominance information is up-to-date.
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The loops are analyzed through @code{loop_optimizer_init} function. The
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argument of this function is a set of flags represented in an integer
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bitmask. These flags specify what other properties of the loop
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structures should be calculated/enforced and preserved later:
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@itemize
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@item @code{LOOPS_HAVE_PREHEADERS}: Forwarder blocks are created in such
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a way that each loop has only one entry edge, and additionally, the
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source block of this entry edge has only one successor. This creates a
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natural place where the code can be moved out of the loop, and ensures
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that the entry edge of the loop leads from its immediate super-loop.
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@item @code{LOOPS_HAVE_SIMPLE_LATCHES}: Forwarder blocks are created to
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force the latch block of each loop to have only one successor. This
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ensures that the latch of the loop does not belong to any of its
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sub-loops, and makes manipulation with the loops significantly easier.
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Most of the loop manipulation functions assume that the loops are in
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this shape. Note that with this flag, the ``normal'' loop without any
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control flow inside and with one exit consists of two basic blocks.
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@item @code{LOOPS_HAVE_MARKED_IRREDUCIBLE_REGIONS}: Basic blocks and
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edges in the strongly connected components that are not natural loops
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(have more than one entry block) are marked with
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@code{BB_IRREDUCIBLE_LOOP} and @code{EDGE_IRREDUCIBLE_LOOP} flags. The
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flag is not set for blocks and edges that belong to natural loops that
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are in such an irreducible region (but it is set for the entry and exit
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edges of such a loop, if they lead to/from this region).
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@item @code{LOOPS_HAVE_MARKED_SINGLE_EXITS}: If a loop has exactly one
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exit edge, this edge is stored in @code{single_exit} field of the loop
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structure. @code{NULL} is stored there otherwise.
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@end itemize
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These properties may also be computed/enforced later, using functions
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@code{create_preheaders}, @code{force_single_succ_latches},
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@code{mark_irreducible_loops} and @code{mark_single_exit_loops}.
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The memory occupied by the loops structures should be freed with
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@code{loop_optimizer_finalize} function.
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The CFG manipulation functions in general do not update loop structures.
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Specialized versions that additionally do so are provided for the most
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common tasks. On GIMPLE, @code{cleanup_tree_cfg_loop} function can be
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used to cleanup CFG while updating the loops structures if
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@code{current_loops} is set.
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@node Loop querying
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@section Loop querying
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@cindex Loop querying
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The functions to query the information about loops are declared in
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@file{cfgloop.h}. Some of the information can be taken directly from
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the structures. @code{loop_father} field of each basic block contains
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the innermost loop to that the block belongs. The most useful fields of
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loop structure (that are kept up-to-date at all times) are:
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@itemize
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@item @code{header}, @code{latch}: Header and latch basic blocks of the
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loop.
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@item @code{num_nodes}: Number of basic blocks in the loop (including
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the basic blocks of the sub-loops).
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@item @code{depth}: The depth of the loop in the loops tree, i.e., the
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number of super-loops of the loop.
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@item @code{outer}, @code{inner}, @code{next}: The super-loop, the first
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sub-loop, and the sibling of the loop in the loops tree.
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@item @code{single_exit}: The exit edge of the loop, if the loop has
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exactly one exit and the loops were analyzed with
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LOOPS_HAVE_MARKED_SINGLE_EXITS.
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@end itemize
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There are other fields in the loop structures, many of them used only by
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some of the passes, or not updated during CFG changes; in general, they
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should not be accessed directly.
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The most important functions to query loop structures are:
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@itemize
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@item @code{flow_loops_dump}: Dumps the information about loops to a
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file.
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@item @code{verify_loop_structure}: Checks consistency of the loop
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structures.
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@item @code{loop_latch_edge}: Returns the latch edge of a loop.
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@item @code{loop_preheader_edge}: If loops have preheaders, returns
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the preheader edge of a loop.
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@item @code{flow_loop_nested_p}: Tests whether loop is a sub-loop of
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another loop.
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@item @code{flow_bb_inside_loop_p}: Tests whether a basic block belongs
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to a loop (including its sub-loops).
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@item @code{find_common_loop}: Finds the common super-loop of two loops.
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@item @code{superloop_at_depth}: Returns the super-loop of a loop with
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the given depth.
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@item @code{tree_num_loop_insns}, @code{num_loop_insns}: Estimates the
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number of insns in the loop, on GIMPLE and on RTL.
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@item @code{loop_exit_edge_p}: Tests whether edge is an exit from a
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loop.
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@item @code{mark_loop_exit_edges}: Marks all exit edges of all loops
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with @code{EDGE_LOOP_EXIT} flag.
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@item @code{get_loop_body}, @code{get_loop_body_in_dom_order},
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@code{get_loop_body_in_bfs_order}: Enumerates the basic blocks in the
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loop in depth-first search order in reversed CFG, ordered by dominance
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relation, and breath-first search order, respectively.
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@item @code{get_loop_exit_edges}: Enumerates the exit edges of a loop.
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@item @code{just_once_each_iteration_p}: Returns true if the basic block
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is executed exactly once during each iteration of a loop (that is, it
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does not belong to a sub-loop, and it dominates the latch of the loop).
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@end itemize
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@node Loop manipulation
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@section Loop manipulation
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@cindex Loop manipulation
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The loops tree can be manipulated using the following functions:
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@itemize
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@item @code{flow_loop_tree_node_add}: Adds a node to the tree.
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@item @code{flow_loop_tree_node_remove}: Removes a node from the tree.
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@item @code{add_bb_to_loop}: Adds a basic block to a loop.
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@item @code{remove_bb_from_loops}: Removes a basic block from loops.
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@end itemize
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The specialized versions of several low-level CFG functions that also
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update loop structures are provided:
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@itemize
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@item @code{loop_split_edge_with}: Splits an edge, and places a
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specified RTL code on it. On GIMPLE, the function can still be used,
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but the code must be NULL.
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@item @code{bsi_insert_on_edge_immediate_loop}: Inserts code on edge,
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splitting it if necessary. Only works on GIMPLE.
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@item @code{remove_path}: Removes an edge and all blocks it dominates.
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@item @code{loop_commit_inserts}: Commits insertions scheduled on edges,
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and sets loops for the new blocks. This function can only be used on
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GIMPLE.
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@item @code{split_loop_exit_edge}: Splits exit edge of the loop,
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ensuring that PHI node arguments remain in the loop (this ensures that
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loop-closed SSA form is preserved). Only useful on GIMPLE.
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@end itemize
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Finally, there are some higher-level loop transformations implemented.
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While some of them are written so that they should work on non-innermost
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loops, they are mostly untested in that case, and at the moment, they
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are only reliable for the innermost loops:
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@itemize
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@item @code{create_iv}: Creates a new induction variable. Only works on
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GIMPLE. @code{standard_iv_increment_position} can be used to find a
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suitable place for the iv increment.
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@item @code{duplicate_loop_to_header_edge},
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@code{tree_duplicate_loop_to_header_edge}: These functions (on RTL and
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on GIMPLE) duplicate the body of the loop prescribed number of times on
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one of the edges entering loop header, thus performing either loop
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unrolling or loop peeling. @code{can_duplicate_loop_p}
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(@code{can_unroll_loop_p} on GIMPLE) must be true for the duplicated
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loop.
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@item @code{loop_version}, @code{tree_ssa_loop_version}: These function
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create a copy of a loop, and a branch before them that selects one of
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them depending on the prescribed condition. This is useful for
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optimizations that need to verify some assumptions in runtime (one of
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the copies of the loop is usually left unchanged, while the other one is
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transformed in some way).
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@item @code{tree_unroll_loop}: Unrolls the loop, including peeling the
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extra iterations to make the number of iterations divisible by unroll
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factor, updating the exit condition, and removing the exits that now
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cannot be taken. Works only on GIMPLE.
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@end itemize
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@node LCSSA
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@section Loop-closed SSA form
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@cindex LCSSA
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@cindex Loop-closed SSA form
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Throughout the loop optimizations on tree level, one extra condition is
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enforced on the SSA form: No SSA name is used outside of the loop in
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that it is defined. The SSA form satisfying this condition is called
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``loop-closed SSA form'' -- LCSSA. To enforce LCSSA, PHI nodes must be
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created at the exits of the loops for the SSA names that are used
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outside of them. Only the real operands (not virtual SSA names) are
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held in LCSSA, in order to save memory.
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There are various benefits of LCSSA:
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@itemize
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@item Many optimizations (value range analysis, final value
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replacement) are interested in the values that are defined in the loop
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and used outside of it, i.e., exactly those for that we create new PHI
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nodes.
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@item In induction variable analysis, it is not necessary to specify the
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loop in that the analysis should be performed -- the scalar evolution
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analysis always returns the results with respect to the loop in that the
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SSA name is defined.
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@item It makes updating of SSA form during loop transformations simpler.
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Without LCSSA, operations like loop unrolling may force creation of PHI
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nodes arbitrarily far from the loop, while in LCSSA, the SSA form can be
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updated locally. However, since we only keep real operands in LCSSA, we
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cannot use this advantage (we could have local updating of real
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operands, but it is not much more efficient than to use generic SSA form
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updating for it as well; the amount of changes to SSA is the same).
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@end itemize
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However, it also means LCSSA must be updated. This is usually
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straightforward, unless you create a new value in loop and use it
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outside, or unless you manipulate loop exit edges (functions are
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provided to make these manipulations simple).
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@code{rewrite_into_loop_closed_ssa} is used to rewrite SSA form to
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LCSSA, and @code{verify_loop_closed_ssa} to check that the invariant of
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LCSSA is preserved.
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@node Scalar evolutions
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@section Scalar evolutions
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@cindex Scalar evolutions
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@cindex IV analysis on GIMPLE
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Scalar evolutions (SCEV) are used to represent results of induction
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variable analysis on GIMPLE. They enable us to represent variables with
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complicated behavior in a simple and consistent way (we only use it to
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express values of polynomial induction variables, but it is possible to
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extend it). The interfaces to SCEV analysis are declared in
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@file{tree-scalar-evolution.h}. To use scalar evolutions analysis,
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@code{scev_initialize} must be used. To stop using SCEV,
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@code{scev_finalize} should be used. SCEV analysis caches results in
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order to save time and memory. This cache however is made invalid by
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most of the loop transformations, including removal of code. If such a
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transformation is performed, @code{scev_reset} must be called to clean
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the caches.
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Given an SSA name, its behavior in loops can be analyzed using the
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@code{analyze_scalar_evolution} function. The returned SCEV however
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does not have to be fully analyzed and it may contain references to
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other SSA names defined in the loop. To resolve these (potentially
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recursive) references, @code{instantiate_parameters} or
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@code{resolve_mixers} functions must be used.
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@code{instantiate_parameters} is useful when you use the results of SCEV
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only for some analysis, and when you work with whole nest of loops at
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once. It will try replacing all SSA names by their SCEV in all loops,
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including the super-loops of the current loop, thus providing a complete
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information about the behavior of the variable in the loop nest.
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@code{resolve_mixers} is useful if you work with only one loop at a
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time, and if you possibly need to create code based on the value of the
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induction variable. It will only resolve the SSA names defined in the
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current loop, leaving the SSA names defined outside unchanged, even if
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their evolution in the outer loops is known.
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The SCEV is a normal tree expression, except for the fact that it may
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contain several special tree nodes. One of them is
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@code{SCEV_NOT_KNOWN}, used for SSA names whose value cannot be
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expressed. The other one is @code{POLYNOMIAL_CHREC}. Polynomial chrec
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has three arguments -- base, step and loop (both base and step may
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contain further polynomial chrecs). Type of the expression and of base
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and step must be the same. A variable has evolution
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@code{POLYNOMIAL_CHREC(base, step, loop)} if it is (in the specified
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loop) equivalent to @code{x_1} in the following example
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@smallexample
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while (...)
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@{
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x_1 = phi (base, x_2);
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x_2 = x_1 + step;
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@}
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@end smallexample
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Note that this includes the language restrictions on the operations.
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For example, if we compile C code and @code{x} has signed type, then the
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overflow in addition would cause undefined behavior, and we may assume
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that this does not happen. Hence, the value with this SCEV cannot
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overflow (which restricts the number of iterations of such a loop).
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In many cases, one wants to restrict the attention just to affine
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induction variables. In this case, the extra expressive power of SCEV
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is not useful, and may complicate the optimizations. In this case,
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@code{simple_iv} function may be used to analyze a value -- the result
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is a loop-invariant base and step.
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@node loop-iv
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@section IV analysis on RTL
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@cindex IV analysis on RTL
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The induction variable on RTL is simple and only allows analysis of
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affine induction variables, and only in one loop at once. The interface
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is declared in @file{cfgloop.h}. Before analyzing induction variables
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in a loop L, @code{iv_analysis_loop_init} function must be called on L.
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After the analysis (possibly calling @code{iv_analysis_loop_init} for
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several loops) is finished, @code{iv_analysis_done} should be called.
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The following functions can be used to access the results of the
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analysis:
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@itemize
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@item @code{iv_analyze}: Analyzes a single register used in the given
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insn. If no use of the register in this insn is found, the following
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insns are scanned, so that this function can be called on the insn
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returned by get_condition.
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@item @code{iv_analyze_result}: Analyzes result of the assignment in the
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given insn.
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@item @code{iv_analyze_expr}: Analyzes a more complicated expression.
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All its operands are analyzed by @code{iv_analyze}, and hence they must
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be used in the specified insn or one of the following insns.
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@end itemize
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The description of the induction variable is provided in @code{struct
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rtx_iv}. In order to handle subregs, the representation is a bit
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complicated; if the value of the @code{extend} field is not
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@code{UNKNOWN}, the value of the induction variable in the i-th
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iteration is
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@smallexample
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delta + mult * extend_@{extend_mode@} (subreg_@{mode@} (base + i * step)),
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@end smallexample
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with the following exception: if @code{first_special} is true, then the
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value in the first iteration (when @code{i} is zero) is @code{delta +
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mult * base}. However, if @code{extend} is equal to @code{UNKNOWN},
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then @code{first_special} must be false, @code{delta} 0, @code{mult} 1
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and the value in the i-th iteration is
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@smallexample
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subreg_@{mode@} (base + i * step)
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@end smallexample
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The function @code{get_iv_value} can be used to perform these
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calculations.
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@node Number of iterations
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@section Number of iterations analysis
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@cindex Number of iterations analysis
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Both on GIMPLE and on RTL, there are functions available to determine
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the number of iterations of a loop, with a similar interface. In many
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cases, it is not possible to determine number of iterations
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unconditionally -- the determined number is correct only if some
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assumptions are satisfied. The analysis tries to verify these
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conditions using the information contained in the program; if it fails,
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the conditions are returned together with the result. The following
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information and conditions are provided by the analysis:
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@itemize
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@item @code{assumptions}: If this condition is false, the rest of
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the information is invalid.
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@item @code{noloop_assumptions} on RTL, @code{may_be_zero} on GIMPLE: If
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this condition is true, the loop exits in the first iteration.
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@item @code{infinite}: If this condition is true, the loop is infinite.
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This condition is only available on RTL. On GIMPLE, conditions for
|
|
finiteness of the loop are included in @code{assumptions}.
|
|
@item @code{niter_expr} on RTL, @code{niter} on GIMPLE: The expression
|
|
that gives number of iterations. The number of iterations is defined as
|
|
the number of executions of the loop latch.
|
|
@end itemize
|
|
|
|
Both on GIMPLE and on RTL, it necessary for the induction variable
|
|
analysis framework to be initialized (SCEV on GIMPLE, loop-iv on RTL).
|
|
On GIMPLE, the results are stored to @code{struct tree_niter_desc}
|
|
structure. Number of iterations before the loop is exited through a
|
|
given exit can be determined using @code{number_of_iterations_exit}
|
|
function. On RTL, the results are returned in @code{struct niter_desc}
|
|
structure. The corresponding function is named
|
|
@code{check_simple_exit}. There are also functions that pass through
|
|
all the exits of a loop and try to find one with easy to determine
|
|
number of iterations -- @code{find_loop_niter} on GIMPLE and
|
|
@code{find_simple_exit} on RTL. Finally, there are functions that
|
|
provide the same information, but additionally cache it, so that
|
|
repeated calls to number of iterations are not so costly --
|
|
@code{number_of_iterations_in_loop} on GIMPLE and
|
|
@code{get_simple_loop_desc} on RTL.
|
|
|
|
Note that some of these functions may behave slightly differently than
|
|
others -- some of them return only the expression for the number of
|
|
iterations, and fail if there are some assumptions. The function
|
|
@code{number_of_iterations_in_loop} works only for single-exit loops,
|
|
and it returns the value for number of iterations higher by one with
|
|
respect to all other functions (i.e., it returns number of executions of
|
|
the exit statement, not of the loop latch).
|
|
|
|
@node Dependency analysis
|
|
@section Data Dependency Analysis
|
|
@cindex Data Dependency Analysis
|
|
|
|
The code for the data dependence analysis can be found in
|
|
@file{tree-data-ref.c} and its interface and data structures are
|
|
described in @file{tree-data-ref.h}. The function that computes the
|
|
data dependences for all the array and pointer references for a given
|
|
loop is @code{compute_data_dependences_for_loop}. This function is
|
|
currently used by the linear loop transform and the vectorization
|
|
passes. Before calling this function, one has to allocate two vectors:
|
|
a first vector will contain the set of data references that are
|
|
contained in the analyzed loop body, and the second vector will contain
|
|
the dependence relations between the data references. Thus if the
|
|
vector of data references is of size @code{n}, the vector containing the
|
|
dependence relations will contain @code{n*n} elements. However if the
|
|
analyzed loop contains side effects, such as calls that potentially can
|
|
interfere with the data references in the current analyzed loop, the
|
|
analysis stops while scanning the loop body for data references, and
|
|
inserts a single @code{chrec_dont_know} in the dependence relation
|
|
array.
|
|
|
|
The data references are discovered in a particular order during the
|
|
scanning of the loop body: the loop body is analyzed in execution order,
|
|
and the data references of each statement are pushed at the end of the
|
|
data reference array. Two data references syntactically occur in the
|
|
program in the same order as in the array of data references. This
|
|
syntactic order is important in some classical data dependence tests,
|
|
and mapping this order to the elements of this array avoids costly
|
|
queries to the loop body representation.
|
|
|
|
Three types of data references are currently handled: ARRAY_REF,
|
|
INDIRECT_REF and COMPONENT_REF. The data structure for the data reference
|
|
is @code{data_reference}, where @code{data_reference_p} is a name of a
|
|
pointer to the data reference structure. The structure contains the
|
|
following elements:
|
|
|
|
@itemize
|
|
@item @code{base_object_info}: Provides information about the base object
|
|
of the data reference and its access functions. These access functions
|
|
represent the evolution of the data reference in the loop relative to
|
|
its base, in keeping with the classical meaning of the data reference
|
|
access function for the support of arrays. For example, for a reference
|
|
@code{a.b[i][j]}, the base object is @code{a.b} and the access functions,
|
|
one for each array subscript, are:
|
|
@code{@{i_init, + i_step@}_1, @{j_init, +, j_step@}_2}.
|
|
|
|
@item @code{first_location_in_loop}: Provides information about the first
|
|
location accessed by the data reference in the loop and about the access
|
|
function used to represent evolution relative to this location. This data
|
|
is used to support pointers, and is not used for arrays (for which we
|
|
have base objects). Pointer accesses are represented as a one-dimensional
|
|
access that starts from the first location accessed in the loop. For
|
|
example:
|
|
|
|
@smallexample
|
|
for1 i
|
|
for2 j
|
|
*((int *)p + i + j) = a[i][j];
|
|
@end smallexample
|
|
|
|
The access function of the pointer access is @code{@{0, + 4B@}_for2}
|
|
relative to @code{p + i}. The access functions of the array are
|
|
@code{@{i_init, + i_step@}_for1} and @code{@{j_init, +, j_step@}_for2}
|
|
relative to @code{a}.
|
|
|
|
Usually, the object the pointer refers to is either unknown, or we can't
|
|
prove that the access is confined to the boundaries of a certain object.
|
|
|
|
Two data references can be compared only if at least one of these two
|
|
representations has all its fields filled for both data references.
|
|
|
|
The current strategy for data dependence tests is as follows:
|
|
If both @code{a} and @code{b} are represented as arrays, compare
|
|
@code{a.base_object} and @code{b.base_object};
|
|
if they are equal, apply dependence tests (use access functions based on
|
|
base_objects).
|
|
Else if both @code{a} and @code{b} are represented as pointers, compare
|
|
@code{a.first_location} and @code{b.first_location};
|
|
if they are equal, apply dependence tests (use access functions based on
|
|
first location).
|
|
However, if @code{a} and @code{b} are represented differently, only try
|
|
to prove that the bases are definitely different.
|
|
|
|
@item Aliasing information.
|
|
@item Alignment information.
|
|
@end itemize
|
|
|
|
The structure describing the relation between two data references is
|
|
@code{data_dependence_relation} and the shorter name for a pointer to
|
|
such a structure is @code{ddr_p}. This structure contains:
|
|
|
|
@itemize
|
|
@item a pointer to each data reference,
|
|
@item a tree node @code{are_dependent} that is set to @code{chrec_known}
|
|
if the analysis has proved that there is no dependence between these two
|
|
data references, @code{chrec_dont_know} if the analysis was not able to
|
|
determine any useful result and potentially there could exist a
|
|
dependence between these data references, and @code{are_dependent} is
|
|
set to @code{NULL_TREE} if there exist a dependence relation between the
|
|
data references, and the description of this dependence relation is
|
|
given in the @code{subscripts}, @code{dir_vects}, and @code{dist_vects}
|
|
arrays,
|
|
@item a boolean that determines whether the dependence relation can be
|
|
represented by a classical distance vector,
|
|
@item an array @code{subscripts} that contains a description of each
|
|
subscript of the data references. Given two array accesses a
|
|
subscript is the tuple composed of the access functions for a given
|
|
dimension. For example, given @code{A[f1][f2][f3]} and
|
|
@code{B[g1][g2][g3]}, there are three subscripts: @code{(f1, g1), (f2,
|
|
g2), (f3, g3)}.
|
|
@item two arrays @code{dir_vects} and @code{dist_vects} that contain
|
|
classical representations of the data dependences under the form of
|
|
direction and distance dependence vectors,
|
|
@item an array of loops @code{loop_nest} that contains the loops to
|
|
which the distance and direction vectors refer to.
|
|
@end itemize
|
|
|
|
Several functions for pretty printing the information extracted by the
|
|
data dependence analysis are available: @code{dump_ddrs} prints with a
|
|
maximum verbosity the details of a data dependence relations array,
|
|
@code{dump_dist_dir_vectors} prints only the classical distance and
|
|
direction vectors for a data dependence relations array, and
|
|
@code{dump_data_references} prints the details of the data references
|
|
contained in a data reference array.
|
|
|
|
@node Lambda
|
|
@section Linear loop transformations framework
|
|
@cindex Linear loop transformations framework
|
|
|
|
Lambda is a framework that allows transformations of loops using
|
|
non-singular matrix based transformations of the iteration space and
|
|
loop bounds. This allows compositions of skewing, scaling, interchange,
|
|
and reversal transformations. These transformations are often used to
|
|
improve cache behavior or remove inner loop dependencies to allow
|
|
parallelization and vectorization to take place.
|
|
|
|
To perform these transformations, Lambda requires that the loopnest be
|
|
converted into a internal form that can be matrix transformed easily.
|
|
To do this conversion, the function
|
|
@code{gcc_loopnest_to_lambda_loopnest} is provided. If the loop cannot
|
|
be transformed using lambda, this function will return NULL.
|
|
|
|
Once a @code{lambda_loopnest} is obtained from the conversion function,
|
|
it can be transformed by using @code{lambda_loopnest_transform}, which
|
|
takes a transformation matrix to apply. Note that it is up to the
|
|
caller to verify that the transformation matrix is legal to apply to the
|
|
loop (dependence respecting, etc). Lambda simply applies whatever
|
|
matrix it is told to provide. It can be extended to make legal matrices
|
|
out of any non-singular matrix, but this is not currently implemented.
|
|
Legality of a matrix for a given loopnest can be verified using
|
|
@code{lambda_transform_legal_p}.
|
|
|
|
Given a transformed loopnest, conversion back into gcc IR is done by
|
|
@code{lambda_loopnest_to_gcc_loopnest}. This function will modify the
|
|
loops so that they match the transformed loopnest.
|
|
|