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1724 lines
60 KiB
Plaintext
@c Copyright (c) 2004, 2005 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 Tree SSA
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@c ---------------------------------------------------------------------
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@node Tree SSA
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@chapter Analysis and Optimization of GIMPLE Trees
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@cindex Tree SSA
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@cindex Optimization infrastructure for GIMPLE
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GCC uses three main intermediate languages to represent the program
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during compilation: GENERIC, GIMPLE and RTL@. GENERIC is a
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language-independent representation generated by each front end. It
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is used to serve as an interface between the parser and optimizer.
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GENERIC is a common representation that is able to represent programs
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written in all the languages supported by GCC@.
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GIMPLE and RTL are used to optimize the program. GIMPLE is used for
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target and language independent optimizations (e.g., inlining,
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constant propagation, tail call elimination, redundancy elimination,
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etc). Much like GENERIC, GIMPLE is a language independent, tree based
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representation. However, it differs from GENERIC in that the GIMPLE
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grammar is more restrictive: expressions contain no more than 3
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operands (except function calls), it has no control flow structures
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and expressions with side-effects are only allowed on the right hand
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side of assignments. See the chapter describing GENERIC and GIMPLE
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for more details.
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This chapter describes the data structures and functions used in the
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GIMPLE optimizers (also known as ``tree optimizers'' or ``middle
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end''). In particular, it focuses on all the macros, data structures,
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functions and programming constructs needed to implement optimization
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passes for GIMPLE@.
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@menu
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* GENERIC:: A high-level language-independent representation.
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* GIMPLE:: A lower-level factored tree representation.
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* Annotations:: Attributes for statements and variables.
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* Statement Operands:: Variables referenced by GIMPLE statements.
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* SSA:: Static Single Assignment representation.
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* Alias analysis:: Representing aliased loads and stores.
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@end menu
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@node GENERIC
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@section GENERIC
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@cindex GENERIC
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The purpose of GENERIC is simply to provide a language-independent way of
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representing an entire function in trees. To this end, it was necessary to
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add a few new tree codes to the back end, but most everything was already
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there. If you can express it with the codes in @code{gcc/tree.def}, it's
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GENERIC@.
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Early on, there was a great deal of debate about how to think about
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statements in a tree IL@. In GENERIC, a statement is defined as any
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expression whose value, if any, is ignored. A statement will always
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have @code{TREE_SIDE_EFFECTS} set (or it will be discarded), but a
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non-statement expression may also have side effects. A
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@code{CALL_EXPR}, for instance.
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It would be possible for some local optimizations to work on the
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GENERIC form of a function; indeed, the adapted tree inliner works
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fine on GENERIC, but the current compiler performs inlining after
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lowering to GIMPLE (a restricted form described in the next section).
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Indeed, currently the frontends perform this lowering before handing
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off to @code{tree_rest_of_compilation}, but this seems inelegant.
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If necessary, a front end can use some language-dependent tree codes
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in its GENERIC representation, so long as it provides a hook for
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converting them to GIMPLE and doesn't expect them to work with any
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(hypothetical) optimizers that run before the conversion to GIMPLE@.
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The intermediate representation used while parsing C and C++ looks
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very little like GENERIC, but the C and C++ gimplifier hooks are
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perfectly happy to take it as input and spit out GIMPLE@.
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@node GIMPLE
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@section GIMPLE
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@cindex GIMPLE
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GIMPLE is a simplified subset of GENERIC for use in optimization. The
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particular subset chosen (and the name) was heavily influenced by the
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SIMPLE IL used by the McCAT compiler project at McGill University,
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though we have made some different choices. For one thing, SIMPLE
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doesn't support @code{goto}; a production compiler can't afford that
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kind of restriction.
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GIMPLE retains much of the structure of the parse trees: lexical
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scopes are represented as containers, rather than markers. However,
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expressions are broken down into a 3-address form, using temporary
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variables to hold intermediate values. Also, control structures are
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lowered to gotos.
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In GIMPLE no container node is ever used for its value; if a
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@code{COND_EXPR} or @code{BIND_EXPR} has a value, it is stored into a
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temporary within the controlled blocks, and that temporary is used in
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place of the container.
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The compiler pass which lowers GENERIC to GIMPLE is referred to as the
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@samp{gimplifier}. The gimplifier works recursively, replacing complex
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statements with sequences of simple statements.
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@c Currently, the only way to
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@c tell whether or not an expression is in GIMPLE form is by recursively
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@c examining it; in the future there will probably be a flag to help avoid
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@c redundant work. FIXME FIXME
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@menu
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* Interfaces::
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* Temporaries::
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* GIMPLE Expressions::
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* Statements::
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* GIMPLE Example::
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* Rough GIMPLE Grammar::
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@end menu
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@node Interfaces
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@subsection Interfaces
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@cindex gimplification
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The tree representation of a function is stored in
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@code{DECL_SAVED_TREE}. It is lowered to GIMPLE by a call to
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@code{gimplify_function_tree}.
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If a front end wants to include language-specific tree codes in the tree
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representation which it provides to the back end, it must provide a
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definition of @code{LANG_HOOKS_GIMPLIFY_EXPR} which knows how to
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convert the front end trees to GIMPLE@. Usually such a hook will involve
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much of the same code for expanding front end trees to RTL@. This function
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can return fully lowered GIMPLE, or it can return GENERIC trees and let the
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main gimplifier lower them the rest of the way; this is often simpler.
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GIMPLE that is not fully lowered is known as ``high GIMPLE'' and
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consists of the IL before the pass @code{pass_lower_cf}. High GIMPLE
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still contains lexical scopes and nested expressions, while low GIMPLE
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exposes all of the implicit jumps for control expressions like
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@code{COND_EXPR}.
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The C and C++ front ends currently convert directly from front end
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trees to GIMPLE, and hand that off to the back end rather than first
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converting to GENERIC@. Their gimplifier hooks know about all the
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@code{_STMT} nodes and how to convert them to GENERIC forms. There
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was some work done on a genericization pass which would run first, but
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the existence of @code{STMT_EXPR} meant that in order to convert all
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of the C statements into GENERIC equivalents would involve walking the
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entire tree anyway, so it was simpler to lower all the way. This
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might change in the future if someone writes an optimization pass
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which would work better with higher-level trees, but currently the
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optimizers all expect GIMPLE@.
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A front end which wants to use the tree optimizers (and already has
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some sort of whole-function tree representation) only needs to provide
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a definition of @code{LANG_HOOKS_GIMPLIFY_EXPR}, call
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@code{gimplify_function_tree} to lower to GIMPLE, and then hand off to
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@code{tree_rest_of_compilation} to compile and output the function.
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You can tell the compiler to dump a C-like representation of the GIMPLE
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form with the flag @option{-fdump-tree-gimple}.
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@node Temporaries
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@subsection Temporaries
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@cindex Temporaries
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When gimplification encounters a subexpression which is too complex, it
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creates a new temporary variable to hold the value of the subexpression,
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and adds a new statement to initialize it before the current statement.
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These special temporaries are known as @samp{expression temporaries}, and are
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allocated using @code{get_formal_tmp_var}. The compiler tries to
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always evaluate identical expressions into the same temporary, to simplify
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elimination of redundant calculations.
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We can only use expression temporaries when we know that it will not be
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reevaluated before its value is used, and that it will not be otherwise
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modified@footnote{These restrictions are derived from those in Morgan 4.8.}.
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Other temporaries can be allocated using
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@code{get_initialized_tmp_var} or @code{create_tmp_var}.
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Currently, an expression like @code{a = b + 5} is not reduced any
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further. We tried converting it to something like
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@smallexample
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T1 = b + 5;
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a = T1;
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@end smallexample
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but this bloated the representation for minimal benefit. However, a
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variable which must live in memory cannot appear in an expression; its
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value is explicitly loaded into a temporary first. Similarly, storing
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the value of an expression to a memory variable goes through a
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temporary.
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@node GIMPLE Expressions
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@subsection Expressions
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@cindex GIMPLE Expressions
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In general, expressions in GIMPLE consist of an operation and the
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appropriate number of simple operands; these operands must either be a
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GIMPLE rvalue (@code{is_gimple_val}), i.e.@: a constant or a register
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variable. More complex operands are factored out into temporaries, so
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that
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@smallexample
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a = b + c + d
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@end smallexample
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becomes
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@smallexample
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T1 = b + c;
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a = T1 + d;
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@end smallexample
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The same rule holds for arguments to a @code{CALL_EXPR}.
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The target of an assignment is usually a variable, but can also be an
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@code{INDIRECT_REF} or a compound lvalue as described below.
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@menu
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* Compound Expressions::
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* Compound Lvalues::
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* Conditional Expressions::
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* Logical Operators::
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@end menu
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@node Compound Expressions
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@subsubsection Compound Expressions
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@cindex Compound Expressions
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The left-hand side of a C comma expression is simply moved into a separate
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statement.
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@node Compound Lvalues
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@subsubsection Compound Lvalues
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@cindex Compound Lvalues
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Currently compound lvalues involving array and structure field references
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are not broken down; an expression like @code{a.b[2] = 42} is not reduced
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any further (though complex array subscripts are). This restriction is a
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workaround for limitations in later optimizers; if we were to convert this
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to
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@smallexample
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T1 = &a.b;
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T1[2] = 42;
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@end smallexample
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alias analysis would not remember that the reference to @code{T1[2]} came
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by way of @code{a.b}, so it would think that the assignment could alias
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another member of @code{a}; this broke @code{struct-alias-1.c}. Future
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optimizer improvements may make this limitation unnecessary.
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@node Conditional Expressions
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@subsubsection Conditional Expressions
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@cindex Conditional Expressions
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A C @code{?:} expression is converted into an @code{if} statement with
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each branch assigning to the same temporary. So,
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@smallexample
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a = b ? c : d;
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@end smallexample
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becomes
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@smallexample
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if (b)
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T1 = c;
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else
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T1 = d;
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a = T1;
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@end smallexample
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Tree level if-conversion pass re-introduces @code{?:} expression, if appropriate.
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It is used to vectorize loops with conditions using vector conditional operations.
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Note that in GIMPLE, @code{if} statements are also represented using
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@code{COND_EXPR}, as described below.
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@node Logical Operators
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@subsubsection Logical Operators
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@cindex Logical Operators
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Except when they appear in the condition operand of a @code{COND_EXPR},
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logical `and' and `or' operators are simplified as follows:
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@code{a = b && c} becomes
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@smallexample
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T1 = (bool)b;
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if (T1)
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T1 = (bool)c;
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a = T1;
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@end smallexample
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Note that @code{T1} in this example cannot be an expression temporary,
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because it has two different assignments.
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@node Statements
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@subsection Statements
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@cindex Statements
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Most statements will be assignment statements, represented by
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@code{MODIFY_EXPR}. A @code{CALL_EXPR} whose value is ignored can
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also be a statement. No other C expressions can appear at statement level;
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a reference to a volatile object is converted into a @code{MODIFY_EXPR}.
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In GIMPLE form, type of @code{MODIFY_EXPR} is not meaningful. Instead, use type
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of LHS or RHS@.
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There are also several varieties of complex statements.
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@menu
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* Blocks::
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* Statement Sequences::
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* Empty Statements::
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* Loops::
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* Selection Statements::
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* Jumps::
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* Cleanups::
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* GIMPLE Exception Handling::
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@end menu
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@node Blocks
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@subsubsection Blocks
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@cindex Blocks
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Block scopes and the variables they declare in GENERIC and GIMPLE are
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expressed using the @code{BIND_EXPR} code, which in previous versions of
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GCC was primarily used for the C statement-expression extension.
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Variables in a block are collected into @code{BIND_EXPR_VARS} in
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declaration order. Any runtime initialization is moved out of
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@code{DECL_INITIAL} and into a statement in the controlled block. When
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gimplifying from C or C++, this initialization replaces the
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@code{DECL_STMT}.
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Variable-length arrays (VLAs) complicate this process, as their size often
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refers to variables initialized earlier in the block. To handle this, we
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currently split the block at that point, and move the VLA into a new, inner
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@code{BIND_EXPR}. This strategy may change in the future.
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@code{DECL_SAVED_TREE} for a GIMPLE function will always be a
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@code{BIND_EXPR} which contains declarations for the temporary variables
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used in the function.
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A C++ program will usually contain more @code{BIND_EXPR}s than there are
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syntactic blocks in the source code, since several C++ constructs have
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implicit scopes associated with them. On the other hand, although the C++
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front end uses pseudo-scopes to handle cleanups for objects with
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destructors, these don't translate into the GIMPLE form; multiple
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declarations at the same level use the same @code{BIND_EXPR}.
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@node Statement Sequences
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@subsubsection Statement Sequences
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@cindex Statement Sequences
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Multiple statements at the same nesting level are collected into a
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@code{STATEMENT_LIST}. Statement lists are modified and traversed
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using the interface in @samp{tree-iterator.h}.
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@node Empty Statements
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@subsubsection Empty Statements
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@cindex Empty Statements
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Whenever possible, statements with no effect are discarded. But if they
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are nested within another construct which cannot be discarded for some
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reason, they are instead replaced with an empty statement, generated by
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@code{build_empty_stmt}. Initially, all empty statements were shared,
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after the pattern of the Java front end, but this caused a lot of trouble in
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practice.
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An empty statement is represented as @code{(void)0}.
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@node Loops
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@subsubsection Loops
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@cindex Loops
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At one time loops were expressed in GIMPLE using @code{LOOP_EXPR}, but
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now they are lowered to explicit gotos.
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@node Selection Statements
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@subsubsection Selection Statements
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@cindex Selection Statements
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A simple selection statement, such as the C @code{if} statement, is
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expressed in GIMPLE using a void @code{COND_EXPR}. If only one branch is
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used, the other is filled with an empty statement.
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Normally, the condition expression is reduced to a simple comparison. If
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it is a shortcut (@code{&&} or @code{||}) expression, however, we try to
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break up the @code{if} into multiple @code{if}s so that the implied shortcut
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is taken directly, much like the transformation done by @code{do_jump} in
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the RTL expander.
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A @code{SWITCH_EXPR} in GIMPLE contains the condition and a
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@code{TREE_VEC} of @code{CASE_LABEL_EXPR}s describing the case values
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and corresponding @code{LABEL_DECL}s to jump to. The body of the
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@code{switch} is moved after the @code{SWITCH_EXPR}.
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@node Jumps
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@subsubsection Jumps
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@cindex Jumps
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Other jumps are expressed by either @code{GOTO_EXPR} or @code{RETURN_EXPR}.
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The operand of a @code{GOTO_EXPR} must be either a label or a variable
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containing the address to jump to.
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The operand of a @code{RETURN_EXPR} is either @code{NULL_TREE},
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@code{RESULT_DECL}, or a @code{MODIFY_EXPR} which sets the return value. It
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would be nice to move the @code{MODIFY_EXPR} into a separate statement, but the
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special return semantics in @code{expand_return} make that difficult. It may
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still happen in the future, perhaps by moving most of that logic into
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@code{expand_assignment}.
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@node Cleanups
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@subsubsection Cleanups
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@cindex Cleanups
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Destructors for local C++ objects and similar dynamic cleanups are
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represented in GIMPLE by a @code{TRY_FINALLY_EXPR}.
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@code{TRY_FINALLY_EXPR} has two operands, both of which are a sequence
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of statements to execute. The first sequence is executed. When it
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completes the second sequence is executed.
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The first sequence may complete in the following ways:
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@enumerate
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@item Execute the last statement in the sequence and fall off the
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end.
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@item Execute a goto statement (@code{GOTO_EXPR}) to an ordinary
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label outside the sequence.
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@item Execute a return statement (@code{RETURN_EXPR}).
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@item Throw an exception. This is currently not explicitly represented in
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GIMPLE.
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@end enumerate
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The second sequence is not executed if the first sequence completes by
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calling @code{setjmp} or @code{exit} or any other function that does
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not return. The second sequence is also not executed if the first
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sequence completes via a non-local goto or a computed goto (in general
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the compiler does not know whether such a goto statement exits the
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first sequence or not, so we assume that it doesn't).
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After the second sequence is executed, if it completes normally by
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falling off the end, execution continues wherever the first sequence
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would have continued, by falling off the end, or doing a goto, etc.
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@code{TRY_FINALLY_EXPR} complicates the flow graph, since the cleanup
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needs to appear on every edge out of the controlled block; this
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reduces the freedom to move code across these edges. Therefore, the
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EH lowering pass which runs before most of the optimization passes
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eliminates these expressions by explicitly adding the cleanup to each
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edge. Rethrowing the exception is represented using @code{RESX_EXPR}.
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@node GIMPLE Exception Handling
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@subsubsection Exception Handling
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@cindex GIMPLE Exception Handling
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Other exception handling constructs are represented using
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@code{TRY_CATCH_EXPR}. @code{TRY_CATCH_EXPR} has two operands. The
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first operand is a sequence of statements to execute. If executing
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these statements does not throw an exception, then the second operand
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is ignored. Otherwise, if an exception is thrown, then the second
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operand of the @code{TRY_CATCH_EXPR} is checked. The second operand
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may have the following forms:
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@enumerate
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@item A sequence of statements to execute. When an exception occurs,
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these statements are executed, and then the exception is rethrown.
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@item A sequence of @code{CATCH_EXPR} expressions. Each @code{CATCH_EXPR}
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has a list of applicable exception types and handler code. If the
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thrown exception matches one of the caught types, the associated
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handler code is executed. If the handler code falls off the bottom,
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execution continues after the original @code{TRY_CATCH_EXPR}.
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@item An @code{EH_FILTER_EXPR} expression. This has a list of
|
|
permitted exception types, and code to handle a match failure. If the
|
|
thrown exception does not match one of the allowed types, the
|
|
associated match failure code is executed. If the thrown exception
|
|
does match, it continues unwinding the stack looking for the next
|
|
handler.
|
|
|
|
@end enumerate
|
|
|
|
Currently throwing an exception is not directly represented in GIMPLE,
|
|
since it is implemented by calling a function. At some point in the future
|
|
we will want to add some way to express that the call will throw an
|
|
exception of a known type.
|
|
|
|
Just before running the optimizers, the compiler lowers the high-level
|
|
EH constructs above into a set of @samp{goto}s, magic labels, and EH
|
|
regions. Continuing to unwind at the end of a cleanup is represented
|
|
with a @code{RESX_EXPR}.
|
|
|
|
@node GIMPLE Example
|
|
@subsection GIMPLE Example
|
|
@cindex GIMPLE Example
|
|
|
|
@smallexample
|
|
struct A @{ A(); ~A(); @};
|
|
|
|
int i;
|
|
int g();
|
|
void f()
|
|
@{
|
|
A a;
|
|
int j = (--i, i ? 0 : 1);
|
|
|
|
for (int x = 42; x > 0; --x)
|
|
@{
|
|
i += g()*4 + 32;
|
|
@}
|
|
@}
|
|
@end smallexample
|
|
|
|
becomes
|
|
|
|
@smallexample
|
|
void f()
|
|
@{
|
|
int i.0;
|
|
int T.1;
|
|
int iftmp.2;
|
|
int T.3;
|
|
int T.4;
|
|
int T.5;
|
|
int T.6;
|
|
|
|
@{
|
|
struct A a;
|
|
int j;
|
|
|
|
__comp_ctor (&a);
|
|
try
|
|
@{
|
|
i.0 = i;
|
|
T.1 = i.0 - 1;
|
|
i = T.1;
|
|
i.0 = i;
|
|
if (i.0 == 0)
|
|
iftmp.2 = 1;
|
|
else
|
|
iftmp.2 = 0;
|
|
j = iftmp.2;
|
|
@{
|
|
int x;
|
|
|
|
x = 42;
|
|
goto test;
|
|
loop:;
|
|
|
|
T.3 = g ();
|
|
T.4 = T.3 * 4;
|
|
i.0 = i;
|
|
T.5 = T.4 + i.0;
|
|
T.6 = T.5 + 32;
|
|
i = T.6;
|
|
x = x - 1;
|
|
|
|
test:;
|
|
if (x > 0)
|
|
goto loop;
|
|
else
|
|
goto break_;
|
|
break_:;
|
|
@}
|
|
@}
|
|
finally
|
|
@{
|
|
__comp_dtor (&a);
|
|
@}
|
|
@}
|
|
@}
|
|
@end smallexample
|
|
|
|
@node Rough GIMPLE Grammar
|
|
@subsection Rough GIMPLE Grammar
|
|
@cindex Rough GIMPLE Grammar
|
|
|
|
@smallexample
|
|
function : FUNCTION_DECL
|
|
DECL_SAVED_TREE -> compound-stmt
|
|
|
|
compound-stmt: STATEMENT_LIST
|
|
members -> stmt
|
|
|
|
stmt : block
|
|
| if-stmt
|
|
| switch-stmt
|
|
| goto-stmt
|
|
| return-stmt
|
|
| resx-stmt
|
|
| label-stmt
|
|
| try-stmt
|
|
| modify-stmt
|
|
| call-stmt
|
|
|
|
block : BIND_EXPR
|
|
BIND_EXPR_VARS -> chain of DECLs
|
|
BIND_EXPR_BLOCK -> BLOCK
|
|
BIND_EXPR_BODY -> compound-stmt
|
|
|
|
if-stmt : COND_EXPR
|
|
op0 -> condition
|
|
op1 -> compound-stmt
|
|
op2 -> compound-stmt
|
|
|
|
switch-stmt : SWITCH_EXPR
|
|
op0 -> val
|
|
op1 -> NULL
|
|
op2 -> TREE_VEC of CASE_LABEL_EXPRs
|
|
The CASE_LABEL_EXPRs are sorted by CASE_LOW,
|
|
and default is last.
|
|
|
|
goto-stmt : GOTO_EXPR
|
|
op0 -> LABEL_DECL | val
|
|
|
|
return-stmt : RETURN_EXPR
|
|
op0 -> return-value
|
|
|
|
return-value : NULL
|
|
| RESULT_DECL
|
|
| MODIFY_EXPR
|
|
op0 -> RESULT_DECL
|
|
op1 -> lhs
|
|
|
|
resx-stmt : RESX_EXPR
|
|
|
|
label-stmt : LABEL_EXPR
|
|
op0 -> LABEL_DECL
|
|
|
|
try-stmt : TRY_CATCH_EXPR
|
|
op0 -> compound-stmt
|
|
op1 -> handler
|
|
| TRY_FINALLY_EXPR
|
|
op0 -> compound-stmt
|
|
op1 -> compound-stmt
|
|
|
|
handler : catch-seq
|
|
| EH_FILTER_EXPR
|
|
| compound-stmt
|
|
|
|
catch-seq : STATEMENT_LIST
|
|
members -> CATCH_EXPR
|
|
|
|
modify-stmt : MODIFY_EXPR
|
|
op0 -> lhs
|
|
op1 -> rhs
|
|
|
|
call-stmt : CALL_EXPR
|
|
op0 -> val | OBJ_TYPE_REF
|
|
op1 -> call-arg-list
|
|
|
|
call-arg-list: TREE_LIST
|
|
members -> lhs | CONST
|
|
|
|
addr-expr-arg: ID
|
|
| compref
|
|
|
|
addressable : addr-expr-arg
|
|
| indirectref
|
|
|
|
with-size-arg: addressable
|
|
| call-stmt
|
|
|
|
indirectref : INDIRECT_REF
|
|
op0 -> val
|
|
|
|
lhs : addressable
|
|
| bitfieldref
|
|
| WITH_SIZE_EXPR
|
|
op0 -> with-size-arg
|
|
op1 -> val
|
|
|
|
min-lval : ID
|
|
| indirectref
|
|
|
|
bitfieldref : BIT_FIELD_REF
|
|
op0 -> inner-compref
|
|
op1 -> CONST
|
|
op2 -> var
|
|
|
|
compref : inner-compref
|
|
| TARGET_MEM_REF
|
|
op0 -> ID
|
|
op1 -> val
|
|
op2 -> val
|
|
op3 -> CONST
|
|
op4 -> CONST
|
|
| REALPART_EXPR
|
|
op0 -> inner-compref
|
|
| IMAGPART_EXPR
|
|
op0 -> inner-compref
|
|
|
|
inner-compref: min-lval
|
|
| COMPONENT_REF
|
|
op0 -> inner-compref
|
|
op1 -> FIELD_DECL
|
|
op2 -> val
|
|
| ARRAY_REF
|
|
op0 -> inner-compref
|
|
op1 -> val
|
|
op2 -> val
|
|
op3 -> val
|
|
| ARRAY_RANGE_REF
|
|
op0 -> inner-compref
|
|
op1 -> val
|
|
op2 -> val
|
|
op3 -> val
|
|
| VIEW_CONVERT_EXPR
|
|
op0 -> inner-compref
|
|
|
|
condition : val
|
|
| RELOP
|
|
op0 -> val
|
|
op1 -> val
|
|
|
|
val : ID
|
|
| CONST
|
|
|
|
rhs : lhs
|
|
| CONST
|
|
| call-stmt
|
|
| ADDR_EXPR
|
|
op0 -> addr-expr-arg
|
|
| UNOP
|
|
op0 -> val
|
|
| BINOP
|
|
op0 -> val
|
|
op1 -> val
|
|
| RELOP
|
|
op0 -> val
|
|
op1 -> val
|
|
| COND_EXPR
|
|
op0 -> condition
|
|
op1 -> val
|
|
op2 -> val
|
|
@end smallexample
|
|
|
|
@node Annotations
|
|
@section Annotations
|
|
@cindex annotations
|
|
|
|
The optimizers need to associate attributes with statements and
|
|
variables during the optimization process. For instance, we need to
|
|
know what basic block a statement belongs to or whether a variable
|
|
has aliases. All these attributes are stored in data structures
|
|
called annotations which are then linked to the field @code{ann} in
|
|
@code{struct tree_common}.
|
|
|
|
Presently, we define annotations for statements (@code{stmt_ann_t}),
|
|
variables (@code{var_ann_t}) and SSA names (@code{ssa_name_ann_t}).
|
|
Annotations are defined and documented in @file{tree-flow.h}.
|
|
|
|
|
|
@node Statement Operands
|
|
@section Statement Operands
|
|
@cindex operands
|
|
@cindex virtual operands
|
|
@cindex real operands
|
|
@findex update_stmt
|
|
|
|
Almost every GIMPLE statement will contain a reference to a variable
|
|
or memory location. Since statements come in different shapes and
|
|
sizes, their operands are going to be located at various spots inside
|
|
the statement's tree. To facilitate access to the statement's
|
|
operands, they are organized into lists associated inside each
|
|
statement's annotation. Each element in an operand list is a pointer
|
|
to a @code{VAR_DECL}, @code{PARM_DECL} or @code{SSA_NAME} tree node.
|
|
This provides a very convenient way of examining and replacing
|
|
operands.
|
|
|
|
Data flow analysis and optimization is done on all tree nodes
|
|
representing variables. Any node for which @code{SSA_VAR_P} returns
|
|
nonzero is considered when scanning statement operands. However, not
|
|
all @code{SSA_VAR_P} variables are processed in the same way. For the
|
|
purposes of optimization, we need to distinguish between references to
|
|
local scalar variables and references to globals, statics, structures,
|
|
arrays, aliased variables, etc. The reason is simple, the compiler
|
|
can gather complete data flow information for a local scalar. On the
|
|
other hand, a global variable may be modified by a function call, it
|
|
may not be possible to keep track of all the elements of an array or
|
|
the fields of a structure, etc.
|
|
|
|
The operand scanner gathers two kinds of operands: @dfn{real} and
|
|
@dfn{virtual}. An operand for which @code{is_gimple_reg} returns true
|
|
is considered real, otherwise it is a virtual operand. We also
|
|
distinguish between uses and definitions. An operand is used if its
|
|
value is loaded by the statement (e.g., the operand at the RHS of an
|
|
assignment). If the statement assigns a new value to the operand, the
|
|
operand is considered a definition (e.g., the operand at the LHS of
|
|
an assignment).
|
|
|
|
Virtual and real operands also have very different data flow
|
|
properties. Real operands are unambiguous references to the
|
|
full object that they represent. For instance, given
|
|
|
|
@smallexample
|
|
@{
|
|
int a, b;
|
|
a = b
|
|
@}
|
|
@end smallexample
|
|
|
|
Since @code{a} and @code{b} are non-aliased locals, the statement
|
|
@code{a = b} will have one real definition and one real use because
|
|
variable @code{b} is completely modified with the contents of
|
|
variable @code{a}. Real definition are also known as @dfn{killing
|
|
definitions}. Similarly, the use of @code{a} reads all its bits.
|
|
|
|
In contrast, virtual operands are used with variables that can have
|
|
a partial or ambiguous reference. This includes structures, arrays,
|
|
globals, and aliased variables. In these cases, we have two types of
|
|
definitions. For globals, structures, and arrays, we can determine from
|
|
a statement whether a variable of these types has a killing definition.
|
|
If the variable does, then the statement is marked as having a
|
|
@dfn{must definition} of that variable. However, if a statement is only
|
|
defining a part of the variable (i.e.@: a field in a structure), or if we
|
|
know that a statement might define the variable but we cannot say for sure,
|
|
then we mark that statement as having a @dfn{may definition}. For
|
|
instance, given
|
|
|
|
@smallexample
|
|
@{
|
|
int a, b, *p;
|
|
|
|
if (...)
|
|
p = &a;
|
|
else
|
|
p = &b;
|
|
*p = 5;
|
|
return *p;
|
|
@}
|
|
@end smallexample
|
|
|
|
The assignment @code{*p = 5} may be a definition of @code{a} or
|
|
@code{b}. If we cannot determine statically where @code{p} is
|
|
pointing to at the time of the store operation, we create virtual
|
|
definitions to mark that statement as a potential definition site for
|
|
@code{a} and @code{b}. Memory loads are similarly marked with virtual
|
|
use operands. Virtual operands are shown in tree dumps right before
|
|
the statement that contains them. To request a tree dump with virtual
|
|
operands, use the @option{-vops} option to @option{-fdump-tree}:
|
|
|
|
@smallexample
|
|
@{
|
|
int a, b, *p;
|
|
|
|
if (...)
|
|
p = &a;
|
|
else
|
|
p = &b;
|
|
# a = V_MAY_DEF <a>
|
|
# b = V_MAY_DEF <b>
|
|
*p = 5;
|
|
|
|
# VUSE <a>
|
|
# VUSE <b>
|
|
return *p;
|
|
@}
|
|
@end smallexample
|
|
|
|
Notice that @code{V_MAY_DEF} operands have two copies of the referenced
|
|
variable. This indicates that this is not a killing definition of
|
|
that variable. In this case we refer to it as a @dfn{may definition}
|
|
or @dfn{aliased store}. The presence of the second copy of the
|
|
variable in the @code{V_MAY_DEF} operand will become important when the
|
|
function is converted into SSA form. This will be used to link all
|
|
the non-killing definitions to prevent optimizations from making
|
|
incorrect assumptions about them.
|
|
|
|
Operands are updated as soon as the statement is finished via a call
|
|
to @code{update_stmt}. If statement elements are changed via
|
|
@code{SET_USE} or @code{SET_DEF}, then no further action is required
|
|
(i.e., those macros take care of updating the statement). If changes
|
|
are made by manipulating the statement's tree directly, then a call
|
|
must be made to @code{update_stmt} when complete. Calling one of the
|
|
@code{bsi_insert} routines or @code{bsi_replace} performs an implicit
|
|
call to @code{update_stmt}.
|
|
|
|
@subsection Operand Iterators And Access Routines
|
|
@cindex Operand Iterators
|
|
@cindex Operand Access Routines
|
|
|
|
Operands are collected by @file{tree-ssa-operands.c}. They are stored
|
|
inside each statement's annotation and can be accessed through either the
|
|
operand iterators or an access routine.
|
|
|
|
The following access routines are available for examining operands:
|
|
|
|
@enumerate
|
|
@item @code{SINGLE_SSA_@{USE,DEF,TREE@}_OPERAND}: These accessors will return
|
|
NULL unless there is exactly one operand matching the specified flags. If
|
|
there is exactly one operand, the operand is returned as either a @code{tree},
|
|
@code{def_operand_p}, or @code{use_operand_p}.
|
|
|
|
@smallexample
|
|
tree t = SINGLE_SSA_TREE_OPERAND (stmt, flags);
|
|
use_operand_p u = SINGLE_SSA_USE_OPERAND (stmt, SSA_ALL_VIRTUAL_USES);
|
|
def_operand_p d = SINGLE_SSA_DEF_OPERAND (stmt, SSA_OP_ALL_DEFS);
|
|
@end smallexample
|
|
|
|
@item @code{ZERO_SSA_OPERANDS}: This macro returns true if there are no
|
|
operands matching the specified flags.
|
|
|
|
@smallexample
|
|
if (ZERO_SSA_OPERANDS (stmt, SSA_OP_ALL_VIRTUALS))
|
|
return;
|
|
@end smallexample
|
|
|
|
@item @code{NUM_SSA_OPERANDS}: This macro Returns the number of operands
|
|
matching 'flags'. This actually executes a loop to perform the count, so
|
|
only use this if it is really needed.
|
|
|
|
@smallexample
|
|
int count = NUM_SSA_OPERANDS (stmt, flags)
|
|
@end smallexample
|
|
@end enumerate
|
|
|
|
|
|
If you wish to iterate over some or all operands, use the
|
|
@code{FOR_EACH_SSA_@{USE,DEF,TREE@}_OPERAND} iterator. For example, to print
|
|
all the operands for a statement:
|
|
|
|
@smallexample
|
|
void
|
|
print_ops (tree stmt)
|
|
@{
|
|
ssa_op_iter;
|
|
tree var;
|
|
|
|
FOR_EACH_SSA_TREE_OPERAND (var, stmt, iter, SSA_OP_ALL_OPERANDS)
|
|
print_generic_expr (stderr, var, TDF_SLIM);
|
|
@}
|
|
@end smallexample
|
|
|
|
|
|
How to choose the appropriate iterator:
|
|
|
|
@enumerate
|
|
@item Determine whether you are need to see the operand pointers, or just the
|
|
trees, and choose the appropriate macro:
|
|
|
|
@smallexample
|
|
Need Macro:
|
|
---- -------
|
|
use_operand_p FOR_EACH_SSA_USE_OPERAND
|
|
def_operand_p FOR_EACH_SSA_DEF_OPERAND
|
|
tree FOR_EACH_SSA_TREE_OPERAND
|
|
@end smallexample
|
|
|
|
@item You need to declare a variable of the type you are interested
|
|
in, and an ssa_op_iter structure which serves as the loop
|
|
controlling variable.
|
|
|
|
@item Determine which operands you wish to use, and specify the flags of
|
|
those you are interested in. They are documented in
|
|
@file{tree-ssa-operands.h}:
|
|
|
|
@smallexample
|
|
#define SSA_OP_USE 0x01 /* @r{Real USE operands.} */
|
|
#define SSA_OP_DEF 0x02 /* @r{Real DEF operands.} */
|
|
#define SSA_OP_VUSE 0x04 /* @r{VUSE operands.} */
|
|
#define SSA_OP_VMAYUSE 0x08 /* @r{USE portion of V_MAY_DEFS.} */
|
|
#define SSA_OP_VMAYDEF 0x10 /* @r{DEF portion of V_MAY_DEFS.} */
|
|
#define SSA_OP_VMUSTDEF 0x20 /* @r{V_MUST_DEF definitions.} */
|
|
|
|
/* @r{These are commonly grouped operand flags.} */
|
|
#define SSA_OP_VIRTUAL_USES (SSA_OP_VUSE | SSA_OP_VMAYUSE)
|
|
#define SSA_OP_VIRTUAL_DEFS (SSA_OP_VMAYDEF | SSA_OP_VMUSTDEF)
|
|
#define SSA_OP_ALL_USES (SSA_OP_VIRTUAL_USES | SSA_OP_USE)
|
|
#define SSA_OP_ALL_DEFS (SSA_OP_VIRTUAL_DEFS | SSA_OP_DEF)
|
|
#define SSA_OP_ALL_OPERANDS (SSA_OP_ALL_USES | SSA_OP_ALL_DEFS)
|
|
@end smallexample
|
|
@end enumerate
|
|
|
|
So if you want to look at the use pointers for all the @code{USE} and
|
|
@code{VUSE} operands, you would do something like:
|
|
|
|
@smallexample
|
|
use_operand_p use_p;
|
|
ssa_op_iter iter;
|
|
|
|
FOR_EACH_SSA_USE_OPERAND (use_p, stmt, iter, (SSA_OP_USE | SSA_OP_VUSE))
|
|
@{
|
|
process_use_ptr (use_p);
|
|
@}
|
|
@end smallexample
|
|
|
|
The @code{TREE} macro is basically the same as the @code{USE} and
|
|
@code{DEF} macros, only with the use or def dereferenced via
|
|
@code{USE_FROM_PTR (use_p)} and @code{DEF_FROM_PTR (def_p)}. Since we
|
|
aren't using operand pointers, use and defs flags can be mixed.
|
|
|
|
@smallexample
|
|
tree var;
|
|
ssa_op_iter iter;
|
|
|
|
FOR_EACH_SSA_TREE_OPERAND (var, stmt, iter, SSA_OP_VUSE | SSA_OP_VMUSTDEF)
|
|
@{
|
|
print_generic_expr (stderr, var, TDF_SLIM);
|
|
@}
|
|
@end smallexample
|
|
|
|
@code{V_MAY_DEF}s are broken into two flags, one for the
|
|
@code{DEF} portion (@code{SSA_OP_VMAYDEF}) and one for the USE portion
|
|
(@code{SSA_OP_VMAYUSE}). If all you want to look at are the
|
|
@code{V_MAY_DEF}s together, there is a fourth iterator macro for this,
|
|
which returns both a def_operand_p and a use_operand_p for each
|
|
@code{V_MAY_DEF} in the statement. Note that you don't need any flags for
|
|
this one.
|
|
|
|
@smallexample
|
|
use_operand_p use_p;
|
|
def_operand_p def_p;
|
|
ssa_op_iter iter;
|
|
|
|
FOR_EACH_SSA_MAYDEF_OPERAND (def_p, use_p, stmt, iter)
|
|
@{
|
|
my_code;
|
|
@}
|
|
@end smallexample
|
|
|
|
@code{V_MUST_DEF}s are broken into two flags, one for the
|
|
@code{DEF} portion (@code{SSA_OP_VMUSTDEF}) and one for the kill portion
|
|
(@code{SSA_OP_VMUSTKILL}). If all you want to look at are the
|
|
@code{V_MUST_DEF}s together, there is a fourth iterator macro for this,
|
|
which returns both a def_operand_p and a use_operand_p for each
|
|
@code{V_MUST_DEF} in the statement. Note that you don't need any flags for
|
|
this one.
|
|
|
|
@smallexample
|
|
use_operand_p kill_p;
|
|
def_operand_p def_p;
|
|
ssa_op_iter iter;
|
|
|
|
FOR_EACH_SSA_MUSTDEF_OPERAND (def_p, kill_p, stmt, iter)
|
|
@{
|
|
my_code;
|
|
@}
|
|
@end smallexample
|
|
|
|
|
|
There are many examples in the code as well, as well as the
|
|
documentation in @file{tree-ssa-operands.h}.
|
|
|
|
There are also a couple of variants on the stmt iterators regarding PHI
|
|
nodes.
|
|
|
|
@code{FOR_EACH_PHI_ARG} Works exactly like
|
|
@code{FOR_EACH_SSA_USE_OPERAND}, except it works over @code{PHI} arguments
|
|
instead of statement operands.
|
|
|
|
@smallexample
|
|
/* Look at every virtual PHI use. */
|
|
FOR_EACH_PHI_ARG (use_p, phi_stmt, iter, SSA_OP_VIRTUAL_USES)
|
|
@{
|
|
my_code;
|
|
@}
|
|
|
|
/* Look at every real PHI use. */
|
|
FOR_EACH_PHI_ARG (use_p, phi_stmt, iter, SSA_OP_USES)
|
|
my_code;
|
|
|
|
/* Look at every every PHI use. */
|
|
FOR_EACH_PHI_ARG (use_p, phi_stmt, iter, SSA_OP_ALL_USES)
|
|
my_code;
|
|
@end smallexample
|
|
|
|
@code{FOR_EACH_PHI_OR_STMT_@{USE,DEF@}} works exactly like
|
|
@code{FOR_EACH_SSA_@{USE,DEF@}_OPERAND}, except it will function on
|
|
either a statement or a @code{PHI} node. These should be used when it is
|
|
appropriate but they are not quite as efficient as the individual
|
|
@code{FOR_EACH_PHI} and @code{FOR_EACH_SSA} routines.
|
|
|
|
@smallexample
|
|
FOR_EACH_PHI_OR_STMT_USE (use_operand_p, stmt, iter, flags)
|
|
@{
|
|
my_code;
|
|
@}
|
|
|
|
FOR_EACH_PHI_OR_STMT_DEF (def_operand_p, phi, iter, flags)
|
|
@{
|
|
my_code;
|
|
@}
|
|
@end smallexample
|
|
|
|
@subsection Immediate Uses
|
|
@cindex Immediate Uses
|
|
|
|
Immediate use information is now always available. Using the immediate use
|
|
iterators, you may examine every use of any @code{SSA_NAME}. For instance,
|
|
to change each use of @code{ssa_var} to @code{ssa_var2} and call fold_stmt on
|
|
each stmt after that is done:
|
|
|
|
@smallexample
|
|
use_operand_p imm_use_p;
|
|
imm_use_iterator iterator;
|
|
tree ssa_var, stmt;
|
|
|
|
|
|
FOR_EACH_IMM_USE_STMT (stmt, iterator, ssa_var)
|
|
@{
|
|
FOR_EACH_IMM_USE_ON_STMT (imm_use_p, iterator)
|
|
SET_USE (imm_use_p, ssa_var_2);
|
|
fold_stmt (stmt);
|
|
@}
|
|
@end smallexample
|
|
|
|
There are 2 iterators which can be used. @code{FOR_EACH_IMM_USE_FAST} is
|
|
used when the immediate uses are not changed, i.e., you are looking at the
|
|
uses, but not setting them.
|
|
|
|
If they do get changed, then care must be taken that things are not changed
|
|
under the iterators, so use the @code{FOR_EACH_IMM_USE_STMT} and
|
|
@code{FOR_EACH_IMM_USE_ON_STMT} iterators. They attempt to preserve the
|
|
sanity of the use list by moving all the uses for a statement into
|
|
a controlled position, and then iterating over those uses. Then the
|
|
optimization can manipulate the stmt when all the uses have been
|
|
processed. This is a little slower than the FAST version since it adds a
|
|
placeholder element and must sort through the list a bit for each statement.
|
|
This placeholder element must be also be removed if the loop is
|
|
terminated early. The macro @code{BREAK_FROM_IMM_USE_SAFE} is provided
|
|
to do this :
|
|
|
|
@smallexample
|
|
FOR_EACH_IMM_USE_STMT (stmt, iterator, ssa_var)
|
|
@{
|
|
if (stmt == last_stmt)
|
|
BREAK_FROM_SAFE_IMM_USE (iter);
|
|
|
|
FOR_EACH_IMM_USE_ON_STMT (imm_use_p, iterator)
|
|
SET_USE (imm_use_p, ssa_var_2);
|
|
fold_stmt (stmt);
|
|
@}
|
|
@end smallexample
|
|
|
|
There are checks in @code{verify_ssa} which verify that the immediate use list
|
|
is up to date, as well as checking that an optimization didn't break from the
|
|
loop without using this macro. It is safe to simply 'break'; from a
|
|
@code{FOR_EACH_IMM_USE_FAST} traverse.
|
|
|
|
Some useful functions and macros:
|
|
@enumerate
|
|
@item @code{has_zero_uses (ssa_var)} : Returns true if there are no uses of
|
|
@code{ssa_var}.
|
|
@item @code{has_single_use (ssa_var)} : Returns true if there is only a
|
|
single use of @code{ssa_var}.
|
|
@item @code{single_imm_use (ssa_var, use_operand_p *ptr, tree *stmt)} :
|
|
Returns true if there is only a single use of @code{ssa_var}, and also returns
|
|
the use pointer and statement it occurs in in the second and third parameters.
|
|
@item @code{num_imm_uses (ssa_var)} : Returns the number of immediate uses of
|
|
@code{ssa_var}. It is better not to use this if possible since it simply
|
|
utilizes a loop to count the uses.
|
|
@item @code{PHI_ARG_INDEX_FROM_USE (use_p)} : Given a use within a @code{PHI}
|
|
node, return the index number for the use. An assert is triggered if the use
|
|
isn't located in a @code{PHI} node.
|
|
@item @code{USE_STMT (use_p)} : Return the statement a use occurs in.
|
|
@end enumerate
|
|
|
|
Note that uses are not put into an immediate use list until their statement is
|
|
actually inserted into the instruction stream via a @code{bsi_*} routine.
|
|
|
|
It is also still possible to utilize lazy updating of statements, but this
|
|
should be used only when absolutely required. Both alias analysis and the
|
|
dominator optimizations currently do this.
|
|
|
|
When lazy updating is being used, the immediate use information is out of date
|
|
and cannot be used reliably. Lazy updating is achieved by simply marking
|
|
statements modified via calls to @code{mark_stmt_modified} instead of
|
|
@code{update_stmt}. When lazy updating is no longer required, all the
|
|
modified statements must have @code{update_stmt} called in order to bring them
|
|
up to date. This must be done before the optimization is finished, or
|
|
@code{verify_ssa} will trigger an abort.
|
|
|
|
This is done with a simple loop over the instruction stream:
|
|
@smallexample
|
|
block_stmt_iterator bsi;
|
|
basic_block bb;
|
|
FOR_EACH_BB (bb)
|
|
@{
|
|
for (bsi = bsi_start (bb); !bsi_end_p (bsi); bsi_next (&bsi))
|
|
update_stmt_if_modified (bsi_stmt (bsi));
|
|
@}
|
|
@end smallexample
|
|
|
|
@node SSA
|
|
@section Static Single Assignment
|
|
@cindex SSA
|
|
@cindex static single assignment
|
|
|
|
Most of the tree optimizers rely on the data flow information provided
|
|
by the Static Single Assignment (SSA) form. We implement the SSA form
|
|
as described in @cite{R. Cytron, J. Ferrante, B. Rosen, M. Wegman, and
|
|
K. Zadeck. Efficiently Computing Static Single Assignment Form and the
|
|
Control Dependence Graph. ACM Transactions on Programming Languages
|
|
and Systems, 13(4):451-490, October 1991}.
|
|
|
|
The SSA form is based on the premise that program variables are
|
|
assigned in exactly one location in the program. Multiple assignments
|
|
to the same variable create new versions of that variable. Naturally,
|
|
actual programs are seldom in SSA form initially because variables
|
|
tend to be assigned multiple times. The compiler modifies the program
|
|
representation so that every time a variable is assigned in the code,
|
|
a new version of the variable is created. Different versions of the
|
|
same variable are distinguished by subscripting the variable name with
|
|
its version number. Variables used in the right-hand side of
|
|
expressions are renamed so that their version number matches that of
|
|
the most recent assignment.
|
|
|
|
We represent variable versions using @code{SSA_NAME} nodes. The
|
|
renaming process in @file{tree-ssa.c} wraps every real and
|
|
virtual operand with an @code{SSA_NAME} node which contains
|
|
the version number and the statement that created the
|
|
@code{SSA_NAME}. Only definitions and virtual definitions may
|
|
create new @code{SSA_NAME} nodes.
|
|
|
|
Sometimes, flow of control makes it impossible to determine what is the
|
|
most recent version of a variable. In these cases, the compiler
|
|
inserts an artificial definition for that variable called
|
|
@dfn{PHI function} or @dfn{PHI node}. This new definition merges
|
|
all the incoming versions of the variable to create a new name
|
|
for it. For instance,
|
|
|
|
@smallexample
|
|
if (...)
|
|
a_1 = 5;
|
|
else if (...)
|
|
a_2 = 2;
|
|
else
|
|
a_3 = 13;
|
|
|
|
# a_4 = PHI <a_1, a_2, a_3>
|
|
return a_4;
|
|
@end smallexample
|
|
|
|
Since it is not possible to determine which of the three branches
|
|
will be taken at runtime, we don't know which of @code{a_1},
|
|
@code{a_2} or @code{a_3} to use at the return statement. So, the
|
|
SSA renamer creates a new version @code{a_4} which is assigned
|
|
the result of ``merging'' @code{a_1}, @code{a_2} and @code{a_3}.
|
|
Hence, PHI nodes mean ``one of these operands. I don't know
|
|
which''.
|
|
|
|
The following macros can be used to examine PHI nodes
|
|
|
|
@defmac PHI_RESULT (@var{phi})
|
|
Returns the @code{SSA_NAME} created by PHI node @var{phi} (i.e.,
|
|
@var{phi}'s LHS)@.
|
|
@end defmac
|
|
|
|
@defmac PHI_NUM_ARGS (@var{phi})
|
|
Returns the number of arguments in @var{phi}. This number is exactly
|
|
the number of incoming edges to the basic block holding @var{phi}@.
|
|
@end defmac
|
|
|
|
@defmac PHI_ARG_ELT (@var{phi}, @var{i})
|
|
Returns a tuple representing the @var{i}th argument of @var{phi}@.
|
|
Each element of this tuple contains an @code{SSA_NAME} @var{var} and
|
|
the incoming edge through which @var{var} flows.
|
|
@end defmac
|
|
|
|
@defmac PHI_ARG_EDGE (@var{phi}, @var{i})
|
|
Returns the incoming edge for the @var{i}th argument of @var{phi}.
|
|
@end defmac
|
|
|
|
@defmac PHI_ARG_DEF (@var{phi}, @var{i})
|
|
Returns the @code{SSA_NAME} for the @var{i}th argument of @var{phi}.
|
|
@end defmac
|
|
|
|
|
|
@subsection Preserving the SSA form
|
|
@findex update_ssa
|
|
@cindex preserving SSA form
|
|
Some optimization passes make changes to the function that
|
|
invalidate the SSA property. This can happen when a pass has
|
|
added new symbols or changed the program so that variables that
|
|
were previously aliased aren't anymore. Whenever something like this
|
|
happens, the affected symbols must be renamed into SSA form again.
|
|
Transformations that emit new code or replicate existing statements
|
|
will also need to update the SSA form@.
|
|
|
|
Since GCC implements two different SSA forms for register and virtual
|
|
variables, keeping the SSA form up to date depends on whether you are
|
|
updating register or virtual names. In both cases, the general idea
|
|
behind incremental SSA updates is similar: when new SSA names are
|
|
created, they typically are meant to replace other existing names in
|
|
the program@.
|
|
|
|
For instance, given the following code:
|
|
|
|
@smallexample
|
|
1 L0:
|
|
2 x_1 = PHI (0, x_5)
|
|
3 if (x_1 < 10)
|
|
4 if (x_1 > 7)
|
|
5 y_2 = 0
|
|
6 else
|
|
7 y_3 = x_1 + x_7
|
|
8 endif
|
|
9 x_5 = x_1 + 1
|
|
10 goto L0;
|
|
11 endif
|
|
@end smallexample
|
|
|
|
Suppose that we insert new names @code{x_10} and @code{x_11} (lines
|
|
@code{4} and @code{8})@.
|
|
|
|
@smallexample
|
|
1 L0:
|
|
2 x_1 = PHI (0, x_5)
|
|
3 if (x_1 < 10)
|
|
4 x_10 = ...
|
|
5 if (x_1 > 7)
|
|
6 y_2 = 0
|
|
7 else
|
|
8 x_11 = ...
|
|
9 y_3 = x_1 + x_7
|
|
10 endif
|
|
11 x_5 = x_1 + 1
|
|
12 goto L0;
|
|
13 endif
|
|
@end smallexample
|
|
|
|
We want to replace all the uses of @code{x_1} with the new definitions
|
|
of @code{x_10} and @code{x_11}. Note that the only uses that should
|
|
be replaced are those at lines @code{5}, @code{9} and @code{11}.
|
|
Also, the use of @code{x_7} at line @code{9} should @emph{not} be
|
|
replaced (this is why we cannot just mark symbol @code{x} for
|
|
renaming)@.
|
|
|
|
Additionally, we may need to insert a PHI node at line @code{11}
|
|
because that is a merge point for @code{x_10} and @code{x_11}. So the
|
|
use of @code{x_1} at line @code{11} will be replaced with the new PHI
|
|
node. The insertion of PHI nodes is optional. They are not strictly
|
|
necessary to preserve the SSA form, and depending on what the caller
|
|
inserted, they may not even be useful for the optimizers@.
|
|
|
|
Updating the SSA form is a two step process. First, the pass has to
|
|
identify which names need to be updated and/or which symbols need to
|
|
be renamed into SSA form for the first time. When new names are
|
|
introduced to replace existing names in the program, the mapping
|
|
between the old and the new names are registered by calling
|
|
@code{register_new_name_mapping} (note that if your pass creates new
|
|
code by duplicating basic blocks, the call to @code{tree_duplicate_bb}
|
|
will set up the necessary mappings automatically). On the other hand,
|
|
if your pass exposes a new symbol that should be put in SSA form for
|
|
the first time, the new symbol should be registered with
|
|
@code{mark_sym_for_renaming}.
|
|
|
|
After the replacement mappings have been registered and new symbols
|
|
marked for renaming, a call to @code{update_ssa} makes the registered
|
|
changes. This can be done with an explicit call or by creating
|
|
@code{TODO} flags in the @code{tree_opt_pass} structure for your pass.
|
|
There are several @code{TODO} flags that control the behavior of
|
|
@code{update_ssa}:
|
|
|
|
@itemize @bullet
|
|
@item @code{TODO_update_ssa}. Update the SSA form inserting PHI nodes
|
|
for newly exposed symbols and virtual names marked for updating.
|
|
When updating real names, only insert PHI nodes for a real name
|
|
@code{O_j} in blocks reached by all the new and old definitions for
|
|
@code{O_j}. If the iterated dominance frontier for @code{O_j}
|
|
is not pruned, we may end up inserting PHI nodes in blocks that
|
|
have one or more edges with no incoming definition for
|
|
@code{O_j}. This would lead to uninitialized warnings for
|
|
@code{O_j}'s symbol@.
|
|
|
|
@item @code{TODO_update_ssa_no_phi}. Update the SSA form without
|
|
inserting any new PHI nodes at all. This is used by passes that
|
|
have either inserted all the PHI nodes themselves or passes that
|
|
need only to patch use-def and def-def chains for virtuals
|
|
(e.g., DCE)@.
|
|
|
|
|
|
@item @code{TODO_update_ssa_full_phi}. Insert PHI nodes everywhere
|
|
they are needed. No pruning of the IDF is done. This is used
|
|
by passes that need the PHI nodes for @code{O_j} even if it
|
|
means that some arguments will come from the default definition
|
|
of @code{O_j}'s symbol (e.g., @code{pass_linear_transform})@.
|
|
|
|
WARNING: If you need to use this flag, chances are that your
|
|
pass may be doing something wrong. Inserting PHI nodes for an
|
|
old name where not all edges carry a new replacement may lead to
|
|
silent codegen errors or spurious uninitialized warnings@.
|
|
|
|
@item @code{TODO_update_ssa_only_virtuals}. Passes that update the
|
|
SSA form on their own may want to delegate the updating of
|
|
virtual names to the generic updater. Since FUD chains are
|
|
easier to maintain, this simplifies the work they need to do.
|
|
NOTE: If this flag is used, any OLD->NEW mappings for real names
|
|
are explicitly destroyed and only the symbols marked for
|
|
renaming are processed@.
|
|
@end itemize
|
|
|
|
@subsection Preserving the virtual SSA form
|
|
@cindex preserving virtual SSA form
|
|
|
|
The virtual SSA form is harder to preserve than the non-virtual SSA form
|
|
mainly because the set of virtual operands for a statement may change at
|
|
what some would consider unexpected times. In general, any time you
|
|
have modified a statement that has virtual operands, you should verify
|
|
whether the list of virtual operands has changed, and if so, mark the
|
|
newly exposed symbols by calling @code{mark_new_vars_to_rename}.
|
|
|
|
There is one additional caveat to preserving virtual SSA form. When the
|
|
entire set of virtual operands may be eliminated due to better
|
|
disambiguation, a bare SMT will be added to the list of virtual
|
|
operands, to signify the non-visible aliases that the are still being
|
|
referenced. If the set of bare SMT's may change,
|
|
@code{TODO_update_smt_usage} should be added to the todo flags.
|
|
|
|
With the current pruning code, this can only occur when constants are
|
|
propagated into array references that were previously non-constant, or
|
|
address expressions are propagated into their uses.
|
|
|
|
@subsection Examining @code{SSA_NAME} nodes
|
|
@cindex examining SSA_NAMEs
|
|
|
|
The following macros can be used to examine @code{SSA_NAME} nodes
|
|
|
|
@defmac SSA_NAME_DEF_STMT (@var{var})
|
|
Returns the statement @var{s} that creates the @code{SSA_NAME}
|
|
@var{var}. If @var{s} is an empty statement (i.e., @code{IS_EMPTY_STMT
|
|
(@var{s})} returns @code{true}), it means that the first reference to
|
|
this variable is a USE or a VUSE@.
|
|
@end defmac
|
|
|
|
@defmac SSA_NAME_VERSION (@var{var})
|
|
Returns the version number of the @code{SSA_NAME} object @var{var}.
|
|
@end defmac
|
|
|
|
|
|
@subsection Walking use-def chains
|
|
|
|
@deftypefn {Tree SSA function} void walk_use_def_chains (@var{var}, @var{fn}, @var{data})
|
|
|
|
Walks use-def chains starting at the @code{SSA_NAME} node @var{var}.
|
|
Calls function @var{fn} at each reaching definition found. Function
|
|
@var{FN} takes three arguments: @var{var}, its defining statement
|
|
(@var{def_stmt}) and a generic pointer to whatever state information
|
|
that @var{fn} may want to maintain (@var{data}). Function @var{fn} is
|
|
able to stop the walk by returning @code{true}, otherwise in order to
|
|
continue the walk, @var{fn} should return @code{false}.
|
|
|
|
Note, that if @var{def_stmt} is a @code{PHI} node, the semantics are
|
|
slightly different. For each argument @var{arg} of the PHI node, this
|
|
function will:
|
|
|
|
@enumerate
|
|
@item Walk the use-def chains for @var{arg}.
|
|
@item Call @code{FN (@var{arg}, @var{phi}, @var{data})}.
|
|
@end enumerate
|
|
|
|
Note how the first argument to @var{fn} is no longer the original
|
|
variable @var{var}, but the PHI argument currently being examined.
|
|
If @var{fn} wants to get at @var{var}, it should call
|
|
@code{PHI_RESULT} (@var{phi}).
|
|
@end deftypefn
|
|
|
|
@subsection Walking the dominator tree
|
|
|
|
@deftypefn {Tree SSA function} void walk_dominator_tree (@var{walk_data}, @var{bb})
|
|
|
|
This function walks the dominator tree for the current CFG calling a
|
|
set of callback functions defined in @var{struct dom_walk_data} in
|
|
@file{domwalk.h}. The call back functions you need to define give you
|
|
hooks to execute custom code at various points during traversal:
|
|
|
|
@enumerate
|
|
@item Once to initialize any local data needed while processing
|
|
@var{bb} and its children. This local data is pushed into an
|
|
internal stack which is automatically pushed and popped as the
|
|
walker traverses the dominator tree.
|
|
|
|
@item Once before traversing all the statements in the @var{bb}.
|
|
|
|
@item Once for every statement inside @var{bb}.
|
|
|
|
@item Once after traversing all the statements and before recursing
|
|
into @var{bb}'s dominator children.
|
|
|
|
@item It then recurses into all the dominator children of @var{bb}.
|
|
|
|
@item After recursing into all the dominator children of @var{bb} it
|
|
can, optionally, traverse every statement in @var{bb} again
|
|
(i.e., repeating steps 2 and 3).
|
|
|
|
@item Once after walking the statements in @var{bb} and @var{bb}'s
|
|
dominator children. At this stage, the block local data stack
|
|
is popped.
|
|
@end enumerate
|
|
@end deftypefn
|
|
|
|
@node Alias analysis
|
|
@section Alias analysis
|
|
@cindex alias
|
|
@cindex flow-sensitive alias analysis
|
|
@cindex flow-insensitive alias analysis
|
|
|
|
Alias analysis proceeds in 4 main phases:
|
|
|
|
@enumerate
|
|
@item Structural alias analysis.
|
|
|
|
This phase walks the types for structure variables, and determines which
|
|
of the fields can overlap using offset and size of each field. For each
|
|
field, a ``subvariable'' called a ``Structure field tag'' (SFT)@ is
|
|
created, which represents that field as a separate variable. All
|
|
accesses that could possibly overlap with a given field will have
|
|
virtual operands for the SFT of that field.
|
|
|
|
@smallexample
|
|
struct foo
|
|
@{
|
|
int a;
|
|
int b;
|
|
@}
|
|
struct foo temp;
|
|
int bar (void)
|
|
@{
|
|
int tmp1, tmp2, tmp3;
|
|
SFT.0_2 = V_MUST_DEF <SFT.0_1>
|
|
temp.a = 5;
|
|
SFT.1_4 = V_MUST_DEF <SFT.1_3>
|
|
temp.b = 6;
|
|
|
|
VUSE <SFT.1_4>
|
|
tmp1_5 = temp.b;
|
|
VUSE <SFT.0_2>
|
|
tmp2_6 = temp.a;
|
|
|
|
tmp3_7 = tmp1_5 + tmp2_6;
|
|
return tmp3_7;
|
|
@}
|
|
@end smallexample
|
|
|
|
If you copy the symbol tag for a variable for some reason, you probably
|
|
also want to copy the subvariables for that variable.
|
|
|
|
@item Points-to and escape analysis.
|
|
|
|
This phase walks the use-def chains in the SSA web looking for
|
|
three things:
|
|
|
|
@itemize @bullet
|
|
@item Assignments of the form @code{P_i = &VAR}
|
|
@item Assignments of the form P_i = malloc()
|
|
@item Pointers and ADDR_EXPR that escape the current function.
|
|
@end itemize
|
|
|
|
The concept of `escaping' is the same one used in the Java world.
|
|
When a pointer or an ADDR_EXPR escapes, it means that it has been
|
|
exposed outside of the current function. So, assignment to
|
|
global variables, function arguments and returning a pointer are
|
|
all escape sites.
|
|
|
|
This is where we are currently limited. Since not everything is
|
|
renamed into SSA, we lose track of escape properties when a
|
|
pointer is stashed inside a field in a structure, for instance.
|
|
In those cases, we are assuming that the pointer does escape.
|
|
|
|
We use escape analysis to determine whether a variable is
|
|
call-clobbered. Simply put, if an ADDR_EXPR escapes, then the
|
|
variable is call-clobbered. If a pointer P_i escapes, then all
|
|
the variables pointed-to by P_i (and its memory tag) also escape.
|
|
|
|
@item Compute flow-sensitive aliases
|
|
|
|
We have two classes of memory tags. Memory tags associated with
|
|
the pointed-to data type of the pointers in the program. These
|
|
tags are called ``symbol memory tag'' (SMT)@. The other class are
|
|
those associated with SSA_NAMEs, called ``name memory tag'' (NMT)@.
|
|
The basic idea is that when adding operands for an INDIRECT_REF
|
|
*P_i, we will first check whether P_i has a name tag, if it does
|
|
we use it, because that will have more precise aliasing
|
|
information. Otherwise, we use the standard symbol tag.
|
|
|
|
In this phase, we go through all the pointers we found in
|
|
points-to analysis and create alias sets for the name memory tags
|
|
associated with each pointer P_i. If P_i escapes, we mark
|
|
call-clobbered the variables it points to and its tag.
|
|
|
|
|
|
@item Compute flow-insensitive aliases
|
|
|
|
This pass will compare the alias set of every symbol memory tag and
|
|
every addressable variable found in the program. Given a symbol
|
|
memory tag SMT and an addressable variable V@. If the alias sets
|
|
of SMT and V conflict (as computed by may_alias_p), then V is
|
|
marked as an alias tag and added to the alias set of SMT@.
|
|
@end enumerate
|
|
|
|
For instance, consider the following function:
|
|
|
|
@smallexample
|
|
foo (int i)
|
|
@{
|
|
int *p, *q, a, b;
|
|
|
|
if (i > 10)
|
|
p = &a;
|
|
else
|
|
q = &b;
|
|
|
|
*p = 3;
|
|
*q = 5;
|
|
a = b + 2;
|
|
return *p;
|
|
@}
|
|
@end smallexample
|
|
|
|
After aliasing analysis has finished, the symbol memory tag for
|
|
pointer @code{p} will have two aliases, namely variables @code{a} and
|
|
@code{b}.
|
|
Every time pointer @code{p} is dereferenced, we want to mark the
|
|
operation as a potential reference to @code{a} and @code{b}.
|
|
|
|
@smallexample
|
|
foo (int i)
|
|
@{
|
|
int *p, a, b;
|
|
|
|
if (i_2 > 10)
|
|
p_4 = &a;
|
|
else
|
|
p_6 = &b;
|
|
# p_1 = PHI <p_4(1), p_6(2)>;
|
|
|
|
# a_7 = V_MAY_DEF <a_3>;
|
|
# b_8 = V_MAY_DEF <b_5>;
|
|
*p_1 = 3;
|
|
|
|
# a_9 = V_MAY_DEF <a_7>
|
|
# VUSE <b_8>
|
|
a_9 = b_8 + 2;
|
|
|
|
# VUSE <a_9>;
|
|
# VUSE <b_8>;
|
|
return *p_1;
|
|
@}
|
|
@end smallexample
|
|
|
|
In certain cases, the list of may aliases for a pointer may grow
|
|
too large. This may cause an explosion in the number of virtual
|
|
operands inserted in the code. Resulting in increased memory
|
|
consumption and compilation time.
|
|
|
|
When the number of virtual operands needed to represent aliased
|
|
loads and stores grows too large (configurable with @option{--param
|
|
max-aliased-vops}), alias sets are grouped to avoid severe
|
|
compile-time slow downs and memory consumption. The alias
|
|
grouping heuristic proceeds as follows:
|
|
|
|
@enumerate
|
|
@item Sort the list of pointers in decreasing number of contributed
|
|
virtual operands.
|
|
|
|
@item Take the first pointer from the list and reverse the role
|
|
of the memory tag and its aliases. Usually, whenever an
|
|
aliased variable Vi is found to alias with a memory tag
|
|
T, we add Vi to the may-aliases set for T@. Meaning that
|
|
after alias analysis, we will have:
|
|
|
|
@smallexample
|
|
may-aliases(T) = @{ V1, V2, V3, ..., Vn @}
|
|
@end smallexample
|
|
|
|
This means that every statement that references T, will get
|
|
@code{n} virtual operands for each of the Vi tags. But, when
|
|
alias grouping is enabled, we make T an alias tag and add it
|
|
to the alias set of all the Vi variables:
|
|
|
|
@smallexample
|
|
may-aliases(V1) = @{ T @}
|
|
may-aliases(V2) = @{ T @}
|
|
...
|
|
may-aliases(Vn) = @{ T @}
|
|
@end smallexample
|
|
|
|
This has two effects: (a) statements referencing T will only get
|
|
a single virtual operand, and, (b) all the variables Vi will now
|
|
appear to alias each other. So, we lose alias precision to
|
|
improve compile time. But, in theory, a program with such a high
|
|
level of aliasing should not be very optimizable in the first
|
|
place.
|
|
|
|
@item Since variables may be in the alias set of more than one
|
|
memory tag, the grouping done in step (2) needs to be extended
|
|
to all the memory tags that have a non-empty intersection with
|
|
the may-aliases set of tag T@. For instance, if we originally
|
|
had these may-aliases sets:
|
|
|
|
@smallexample
|
|
may-aliases(T) = @{ V1, V2, V3 @}
|
|
may-aliases(R) = @{ V2, V4 @}
|
|
@end smallexample
|
|
|
|
In step (2) we would have reverted the aliases for T as:
|
|
|
|
@smallexample
|
|
may-aliases(V1) = @{ T @}
|
|
may-aliases(V2) = @{ T @}
|
|
may-aliases(V3) = @{ T @}
|
|
@end smallexample
|
|
|
|
But note that now V2 is no longer aliased with R@. We could
|
|
add R to may-aliases(V2), but we are in the process of
|
|
grouping aliases to reduce virtual operands so what we do is
|
|
add V4 to the grouping to obtain:
|
|
|
|
@smallexample
|
|
may-aliases(V1) = @{ T @}
|
|
may-aliases(V2) = @{ T @}
|
|
may-aliases(V3) = @{ T @}
|
|
may-aliases(V4) = @{ T @}
|
|
@end smallexample
|
|
|
|
@item If the total number of virtual operands due to aliasing is
|
|
still above the threshold set by max-alias-vops, go back to (2).
|
|
@end enumerate
|