2 @c Copyright (C) 2001, 2003, 2004, 2005, 2006, 2007, 2008 Free Software
4 @c This is part of the GCC manual.
5 @c For copying conditions, see the file gcc.texi.
7 @c ---------------------------------------------------------------------
9 @c ---------------------------------------------------------------------
12 @chapter Control Flow Graph
13 @cindex CFG, Control Flow Graph
16 A control flow graph (CFG) is a data structure built on top of the
17 intermediate code representation (the RTL or @code{tree} instruction
18 stream) abstracting the control flow behavior of a function that is
19 being compiled. The CFG is a directed graph where the vertices
20 represent basic blocks and edges represent possible transfer of
21 control flow from one basic block to another. The data structures
22 used to represent the control flow graph are defined in
26 * Basic Blocks:: The definition and representation of basic blocks.
27 * Edges:: Types of edges and their representation.
28 * Profile information:: Representation of frequencies and probabilities.
29 * Maintaining the CFG:: Keeping the control flow graph and up to date.
30 * Liveness information:: Using and maintaining liveness information.
39 A basic block is a straight-line sequence of code with only one entry
40 point and only one exit. In GCC, basic blocks are represented using
41 the @code{basic_block} data type.
43 @findex next_bb, prev_bb, FOR_EACH_BB
44 Two pointer members of the @code{basic_block} structure are the
45 pointers @code{next_bb} and @code{prev_bb}. These are used to keep
46 doubly linked chain of basic blocks in the same order as the
47 underlying instruction stream. The chain of basic blocks is updated
48 transparently by the provided API for manipulating the CFG@. The macro
49 @code{FOR_EACH_BB} can be used to visit all the basic blocks in
50 lexicographical order. Dominator traversals are also possible using
51 @code{walk_dominator_tree}. Given two basic blocks A and B, block A
52 dominates block B if A is @emph{always} executed before B@.
55 The @code{BASIC_BLOCK} array contains all basic blocks in an
56 unspecified order. Each @code{basic_block} structure has a field
57 that holds a unique integer identifier @code{index} that is the
58 index of the block in the @code{BASIC_BLOCK} array.
59 The total number of basic blocks in the function is
60 @code{n_basic_blocks}. Both the basic block indices and
61 the total number of basic blocks may vary during the compilation
62 process, as passes reorder, create, duplicate, and destroy basic
63 blocks. The index for any block should never be greater than
64 @code{last_basic_block}.
66 @findex ENTRY_BLOCK_PTR, EXIT_BLOCK_PTR
67 Special basic blocks represent possible entry and exit points of a
68 function. These blocks are called @code{ENTRY_BLOCK_PTR} and
69 @code{EXIT_BLOCK_PTR}. These blocks do not contain any code, and are
70 not elements of the @code{BASIC_BLOCK} array. Therefore they have
71 been assigned unique, negative index numbers.
73 Each @code{basic_block} also contains pointers to the first
74 instruction (the @dfn{head}) and the last instruction (the @dfn{tail})
75 or @dfn{end} of the instruction stream contained in a basic block. In
76 fact, since the @code{basic_block} data type is used to represent
77 blocks in both major intermediate representations of GCC (@code{tree}
78 and RTL), there are pointers to the head and end of a basic block for
81 @findex NOTE_INSN_BASIC_BLOCK, CODE_LABEL, notes
82 For RTL, these pointers are @code{rtx head, end}. In the RTL function
83 representation, the head pointer always points either to a
84 @code{NOTE_INSN_BASIC_BLOCK} or to a @code{CODE_LABEL}, if present.
85 In the RTL representation of a function, the instruction stream
86 contains not only the ``real'' instructions, but also @dfn{notes}.
87 Any function that moves or duplicates the basic blocks needs
88 to take care of updating of these notes. Many of these notes expect
89 that the instruction stream consists of linear regions, making such
90 updates difficult. The @code{NOTE_INSN_BASIC_BLOCK} note is the only
91 kind of note that may appear in the instruction stream contained in a
92 basic block. The instruction stream of a basic block always follows a
93 @code{NOTE_INSN_BASIC_BLOCK}, but zero or more @code{CODE_LABEL}
94 nodes can precede the block note. A basic block ends by control flow
95 instruction or last instruction before following @code{CODE_LABEL} or
96 @code{NOTE_INSN_BASIC_BLOCK}. A @code{CODE_LABEL} cannot appear in
97 the instruction stream of a basic block.
101 In addition to notes, the jump table vectors are also represented as
102 ``pseudo-instructions'' inside the insn stream. These vectors never
103 appear in the basic block and should always be placed just after the
104 table jump instructions referencing them. After removing the
105 table-jump it is often difficult to eliminate the code computing the
106 address and referencing the vector, so cleaning up these vectors is
107 postponed until after liveness analysis. Thus the jump table vectors
108 may appear in the insn stream unreferenced and without any purpose.
109 Before any edge is made @dfn{fall-thru}, the existence of such
110 construct in the way needs to be checked by calling
111 @code{can_fallthru} function.
113 @cindex block statement iterators
114 For the @code{tree} representation, the head and end of the basic block
115 are being pointed to by the @code{stmt_list} field, but this special
116 @code{tree} should never be referenced directly. Instead, at the tree
117 level abstract containers and iterators are used to access statements
118 and expressions in basic blocks. These iterators are called
119 @dfn{block statement iterators} (BSIs). Grep for @code{^bsi}
120 in the various @file{tree-*} files.
121 The following snippet will pretty-print all the statements of the
122 program in the GIMPLE representation.
127 block_stmt_iterator si;
129 for (si = bsi_start (bb); !bsi_end_p (si); bsi_next (&si))
131 tree stmt = bsi_stmt (si);
132 print_generic_stmt (stderr, stmt, 0);
141 @cindex edge in the flow graph
143 Edges represent possible control flow transfers from the end of some
144 basic block A to the head of another basic block B@. We say that A is
145 a predecessor of B, and B is a successor of A@. Edges are represented
146 in GCC with the @code{edge} data type. Each @code{edge} acts as a
147 link between two basic blocks: the @code{src} member of an edge
148 points to the predecessor basic block of the @code{dest} basic block.
149 The members @code{preds} and @code{succs} of the @code{basic_block} data
150 type point to type-safe vectors of edges to the predecessors and
151 successors of the block.
153 @cindex edge iterators
154 When walking the edges in an edge vector, @dfn{edge iterators} should
155 be used. Edge iterators are constructed using the
156 @code{edge_iterator} data structure and several methods are available
161 This function initializes an @code{edge_iterator} that points to the
162 first edge in a vector of edges.
165 This function initializes an @code{edge_iterator} that points to the
166 last edge in a vector of edges.
169 This predicate is @code{true} if an @code{edge_iterator} represents
170 the last edge in an edge vector.
172 @item ei_one_before_end_p
173 This predicate is @code{true} if an @code{edge_iterator} represents
174 the second last edge in an edge vector.
177 This function takes a pointer to an @code{edge_iterator} and makes it
178 point to the next edge in the sequence.
181 This function takes a pointer to an @code{edge_iterator} and makes it
182 point to the previous edge in the sequence.
185 This function returns the @code{edge} currently pointed to by an
186 @code{edge_iterator}.
189 This function returns the @code{edge} currently pointed to by an
190 @code{edge_iterator}, but returns @code{NULL} if the iterator is
191 pointing at the end of the sequence. This function has been provided
192 for existing code makes the assumption that a @code{NULL} edge
193 indicates the end of the sequence.
197 The convenience macro @code{FOR_EACH_EDGE} can be used to visit all of
198 the edges in a sequence of predecessor or successor edges. It must
199 not be used when an element might be removed during the traversal,
200 otherwise elements will be missed. Here is an example of how to use
207 FOR_EACH_EDGE (e, ei, bb->succs)
209 if (e->flags & EDGE_FALLTHRU)
215 There are various reasons why control flow may transfer from one block
216 to another. One possibility is that some instruction, for example a
217 @code{CODE_LABEL}, in a linearized instruction stream just always
218 starts a new basic block. In this case a @dfn{fall-thru} edge links
219 the basic block to the first following basic block. But there are
220 several other reasons why edges may be created. The @code{flags}
221 field of the @code{edge} data type is used to store information
222 about the type of edge we are dealing with. Each edge is of one of
227 No type flags are set for edges corresponding to jump instructions.
228 These edges are used for unconditional or conditional jumps and in
229 RTL also for table jumps. They are the easiest to manipulate as they
230 may be freely redirected when the flow graph is not in SSA form.
233 @findex EDGE_FALLTHRU, force_nonfallthru
234 Fall-thru edges are present in case where the basic block may continue
235 execution to the following one without branching. These edges have
236 the @code{EDGE_FALLTHRU} flag set. Unlike other types of edges, these
237 edges must come into the basic block immediately following in the
238 instruction stream. The function @code{force_nonfallthru} is
239 available to insert an unconditional jump in the case that redirection
240 is needed. Note that this may require creation of a new basic block.
242 @item exception handling
243 @cindex exception handling
244 @findex EDGE_ABNORMAL, EDGE_EH
245 Exception handling edges represent possible control transfers from a
246 trapping instruction to an exception handler. The definition of
247 ``trapping'' varies. In C++, only function calls can throw, but for
248 Java, exceptions like division by zero or segmentation fault are
249 defined and thus each instruction possibly throwing this kind of
250 exception needs to be handled as control flow instruction. Exception
251 edges have the @code{EDGE_ABNORMAL} and @code{EDGE_EH} flags set.
253 @findex purge_dead_edges
254 When updating the instruction stream it is easy to change possibly
255 trapping instruction to non-trapping, by simply removing the exception
256 edge. The opposite conversion is difficult, but should not happen
257 anyway. The edges can be eliminated via @code{purge_dead_edges} call.
259 @findex REG_EH_REGION, EDGE_ABNORMAL_CALL
260 In the RTL representation, the destination of an exception edge is
261 specified by @code{REG_EH_REGION} note attached to the insn.
262 In case of a trapping call the @code{EDGE_ABNORMAL_CALL} flag is set
263 too. In the @code{tree} representation, this extra flag is not set.
265 @findex may_trap_p, tree_could_trap_p
266 In the RTL representation, the predicate @code{may_trap_p} may be used
267 to check whether instruction still may trap or not. For the tree
268 representation, the @code{tree_could_trap_p} predicate is available,
269 but this predicate only checks for possible memory traps, as in
270 dereferencing an invalid pointer location.
275 @findex EDGE_ABNORMAL, EDGE_SIBCALL
276 Sibling calls or tail calls terminate the function in a non-standard
277 way and thus an edge to the exit must be present.
278 @code{EDGE_SIBCALL} and @code{EDGE_ABNORMAL} are set in such case.
279 These edges only exist in the RTL representation.
282 @cindex computed jump
283 @findex EDGE_ABNORMAL
284 Computed jumps contain edges to all labels in the function referenced
285 from the code. All those edges have @code{EDGE_ABNORMAL} flag set.
286 The edges used to represent computed jumps often cause compile time
287 performance problems, since functions consisting of many taken labels
288 and many computed jumps may have @emph{very} dense flow graphs, so
289 these edges need to be handled with special care. During the earlier
290 stages of the compilation process, GCC tries to avoid such dense flow
291 graphs by factoring computed jumps. For example, given the following
306 factoring the computed jumps results in the following code sequence
307 which has a much simpler flow graph:
323 However, the classic problem with this transformation is that it has a
324 runtime cost in there resulting code: An extra jump. Therefore, the
325 computed jumps are un-factored in the later passes of the compiler.
326 Be aware of that when you work on passes in that area. There have
327 been numerous examples already where the compile time for code with
328 unfactored computed jumps caused some serious headaches.
330 @item nonlocal goto handlers
331 @cindex nonlocal goto handler
332 @findex EDGE_ABNORMAL, EDGE_ABNORMAL_CALL
333 GCC allows nested functions to return into caller using a @code{goto}
334 to a label passed to as an argument to the callee. The labels passed
335 to nested functions contain special code to cleanup after function
336 call. Such sections of code are referred to as ``nonlocal goto
337 receivers''. If a function contains such nonlocal goto receivers, an
338 edge from the call to the label is created with the
339 @code{EDGE_ABNORMAL} and @code{EDGE_ABNORMAL_CALL} flags set.
341 @item function entry points
342 @cindex function entry point, alternate function entry point
343 @findex LABEL_ALTERNATE_NAME
344 By definition, execution of function starts at basic block 0, so there
345 is always an edge from the @code{ENTRY_BLOCK_PTR} to basic block 0.
346 There is no @code{tree} representation for alternate entry points at
347 this moment. In RTL, alternate entry points are specified by
348 @code{CODE_LABEL} with @code{LABEL_ALTERNATE_NAME} defined. This
349 feature is currently used for multiple entry point prologues and is
350 limited to post-reload passes only. This can be used by back-ends to
351 emit alternate prologues for functions called from different contexts.
352 In future full support for multiple entry functions defined by Fortran
353 90 needs to be implemented.
356 In the pre-reload representation a function terminates after the last
357 instruction in the insn chain and no explicit return instructions are
358 used. This corresponds to the fall-thru edge into exit block. After
359 reload, optimal RTL epilogues are used that use explicit (conditional)
360 return instructions that are represented by edges with no flags set.
365 @node Profile information
366 @section Profile information
368 @cindex profile representation
369 In many cases a compiler must make a choice whether to trade speed in
370 one part of code for speed in another, or to trade code size for code
371 speed. In such cases it is useful to know information about how often
372 some given block will be executed. That is the purpose for
373 maintaining profile within the flow graph.
374 GCC can handle profile information obtained through @dfn{profile
375 feedback}, but it can also estimate branch probabilities based on
376 statics and heuristics.
378 @cindex profile feedback
379 The feedback based profile is produced by compiling the program with
380 instrumentation, executing it on a train run and reading the numbers
381 of executions of basic blocks and edges back to the compiler while
382 re-compiling the program to produce the final executable. This method
383 provides very accurate information about where a program spends most
384 of its time on the train run. Whether it matches the average run of
385 course depends on the choice of train data set, but several studies
386 have shown that the behavior of a program usually changes just
387 marginally over different data sets.
389 @cindex Static profile estimation
390 @cindex branch prediction
392 When profile feedback is not available, the compiler may be asked to
393 attempt to predict the behavior of each branch in the program using a
394 set of heuristics (see @file{predict.def} for details) and compute
395 estimated frequencies of each basic block by propagating the
396 probabilities over the graph.
398 @findex frequency, count, BB_FREQ_BASE
399 Each @code{basic_block} contains two integer fields to represent
400 profile information: @code{frequency} and @code{count}. The
401 @code{frequency} is an estimation how often is basic block executed
402 within a function. It is represented as an integer scaled in the
403 range from 0 to @code{BB_FREQ_BASE}. The most frequently executed
404 basic block in function is initially set to @code{BB_FREQ_BASE} and
405 the rest of frequencies are scaled accordingly. During optimization,
406 the frequency of the most frequent basic block can both decrease (for
407 instance by loop unrolling) or grow (for instance by cross-jumping
408 optimization), so scaling sometimes has to be performed multiple
412 The @code{count} contains hard-counted numbers of execution measured
413 during training runs and is nonzero only when profile feedback is
414 available. This value is represented as the host's widest integer
415 (typically a 64 bit integer) of the special type @code{gcov_type}.
417 Most optimization passes can use only the frequency information of a
418 basic block, but a few passes may want to know hard execution counts.
419 The frequencies should always match the counts after scaling, however
420 during updating of the profile information numerical error may
421 accumulate into quite large errors.
423 @findex REG_BR_PROB_BASE, EDGE_FREQUENCY
424 Each edge also contains a branch probability field: an integer in the
425 range from 0 to @code{REG_BR_PROB_BASE}. It represents probability of
426 passing control from the end of the @code{src} basic block to the
427 @code{dest} basic block, i.e.@: the probability that control will flow
428 along this edge. The @code{EDGE_FREQUENCY} macro is available to
429 compute how frequently a given edge is taken. There is a @code{count}
430 field for each edge as well, representing same information as for a
433 The basic block frequencies are not represented in the instruction
434 stream, but in the RTL representation the edge frequencies are
435 represented for conditional jumps (via the @code{REG_BR_PROB}
436 macro) since they are used when instructions are output to the
437 assembly file and the flow graph is no longer maintained.
439 @cindex reverse probability
440 The probability that control flow arrives via a given edge to its
441 destination basic block is called @dfn{reverse probability} and is not
442 directly represented, but it may be easily computed from frequencies
445 @findex redirect_edge_and_branch
446 Updating profile information is a delicate task that can unfortunately
447 not be easily integrated with the CFG manipulation API@. Many of the
448 functions and hooks to modify the CFG, such as
449 @code{redirect_edge_and_branch}, do not have enough information to
450 easily update the profile, so updating it is in the majority of cases
451 left up to the caller. It is difficult to uncover bugs in the profile
452 updating code, because they manifest themselves only by producing
453 worse code, and checking profile consistency is not possible because
454 of numeric error accumulation. Hence special attention needs to be
455 given to this issue in each pass that modifies the CFG@.
457 @findex REG_BR_PROB_BASE, BB_FREQ_BASE, count
458 It is important to point out that @code{REG_BR_PROB_BASE} and
459 @code{BB_FREQ_BASE} are both set low enough to be possible to compute
460 second power of any frequency or probability in the flow graph, it is
461 not possible to even square the @code{count} field, as modern CPUs are
462 fast enough to execute $2^32$ operations quickly.
465 @node Maintaining the CFG
466 @section Maintaining the CFG
469 An important task of each compiler pass is to keep both the control
470 flow graph and all profile information up-to-date. Reconstruction of
471 the control flow graph after each pass is not an option, since it may be
472 very expensive and lost profile information cannot be reconstructed at
475 GCC has two major intermediate representations, and both use the
476 @code{basic_block} and @code{edge} data types to represent control
477 flow. Both representations share as much of the CFG maintenance code
478 as possible. For each representation, a set of @dfn{hooks} is defined
479 so that each representation can provide its own implementation of CFG
480 manipulation routines when necessary. These hooks are defined in
481 @file{cfghooks.h}. There are hooks for almost all common CFG
482 manipulations, including block splitting and merging, edge redirection
483 and creating and deleting basic blocks. These hooks should provide
484 everything you need to maintain and manipulate the CFG in both the RTL
485 and @code{tree} representation.
487 At the moment, the basic block boundaries are maintained transparently
488 when modifying instructions, so there rarely is a need to move them
489 manually (such as in case someone wants to output instruction outside
490 basic block explicitly).
491 Often the CFG may be better viewed as integral part of instruction
492 chain, than structure built on the top of it. However, in principle
493 the control flow graph for the @code{tree} representation is
494 @emph{not} an integral part of the representation, in that a function
495 tree may be expanded without first building a flow graph for the
496 @code{tree} representation at all. This happens when compiling
497 without any @code{tree} optimization enabled. When the @code{tree}
498 optimizations are enabled and the instruction stream is rewritten in
499 SSA form, the CFG is very tightly coupled with the instruction stream.
500 In particular, statement insertion and removal has to be done with
501 care. In fact, the whole @code{tree} representation can not be easily
502 used or maintained without proper maintenance of the CFG
505 @findex BLOCK_FOR_INSN, bb_for_stmt
506 In the RTL representation, each instruction has a
507 @code{BLOCK_FOR_INSN} value that represents pointer to the basic block
508 that contains the instruction. In the @code{tree} representation, the
509 function @code{bb_for_stmt} returns a pointer to the basic block
510 containing the queried statement.
512 @cindex block statement iterators
513 When changes need to be applied to a function in its @code{tree}
514 representation, @dfn{block statement iterators} should be used. These
515 iterators provide an integrated abstraction of the flow graph and the
516 instruction stream. Block statement iterators are constructed using
517 the @code{block_stmt_iterator} data structure and several modifier are
518 available, including the following:
522 This function initializes a @code{block_stmt_iterator} that points to
523 the first non-empty statement in a basic block.
526 This function initializes a @code{block_stmt_iterator} that points to
527 the last statement in a basic block.
530 This predicate is @code{true} if a @code{block_stmt_iterator}
531 represents the end of a basic block.
534 This function takes a @code{block_stmt_iterator} and makes it point to
538 This function takes a @code{block_stmt_iterator} and makes it point to
541 @item bsi_insert_after
542 This function inserts a statement after the @code{block_stmt_iterator}
543 passed in. The final parameter determines whether the statement
544 iterator is updated to point to the newly inserted statement, or left
545 pointing to the original statement.
547 @item bsi_insert_before
548 This function inserts a statement before the @code{block_stmt_iterator}
549 passed in. The final parameter determines whether the statement
550 iterator is updated to point to the newly inserted statement, or left
551 pointing to the original statement.
554 This function removes the @code{block_stmt_iterator} passed in and
555 rechains the remaining statements in a basic block, if any.
558 @findex BB_HEAD, BB_END
559 In the RTL representation, the macros @code{BB_HEAD} and @code{BB_END}
560 may be used to get the head and end @code{rtx} of a basic block. No
561 abstract iterators are defined for traversing the insn chain, but you
562 can just use @code{NEXT_INSN} and @code{PREV_INSN} instead. See
565 @findex purge_dead_edges
566 Usually a code manipulating pass simplifies the instruction stream and
567 the flow of control, possibly eliminating some edges. This may for
568 example happen when a conditional jump is replaced with an
569 unconditional jump, but also when simplifying possibly trapping
570 instruction to non-trapping while compiling Java. Updating of edges
571 is not transparent and each optimization pass is required to do so
572 manually. However only few cases occur in practice. The pass may
573 call @code{purge_dead_edges} on a given basic block to remove
574 superfluous edges, if any.
576 @findex redirect_edge_and_branch, redirect_jump
577 Another common scenario is redirection of branch instructions, but
578 this is best modeled as redirection of edges in the control flow graph
579 and thus use of @code{redirect_edge_and_branch} is preferred over more
580 low level functions, such as @code{redirect_jump} that operate on RTL
581 chain only. The CFG hooks defined in @file{cfghooks.h} should provide
582 the complete API required for manipulating and maintaining the CFG@.
585 It is also possible that a pass has to insert control flow instruction
586 into the middle of a basic block, thus creating an entry point in the
587 middle of the basic block, which is impossible by definition: The
588 block must be split to make sure it only has one entry point, i.e.@: the
589 head of the basic block. The CFG hook @code{split_block} may be used
590 when an instruction in the middle of a basic block has to become the
591 target of a jump or branch instruction.
593 @findex insert_insn_on_edge
594 @findex commit_edge_insertions
595 @findex bsi_insert_on_edge
596 @findex bsi_commit_edge_inserts
597 @cindex edge splitting
598 For a global optimizer, a common operation is to split edges in the
599 flow graph and insert instructions on them. In the RTL
600 representation, this can be easily done using the
601 @code{insert_insn_on_edge} function that emits an instruction
602 ``on the edge'', caching it for a later @code{commit_edge_insertions}
603 call that will take care of moving the inserted instructions off the
604 edge into the instruction stream contained in a basic block. This
605 includes the creation of new basic blocks where needed. In the
606 @code{tree} representation, the equivalent functions are
607 @code{bsi_insert_on_edge} which inserts a block statement
608 iterator on an edge, and @code{bsi_commit_edge_inserts} which flushes
609 the instruction to actual instruction stream.
611 While debugging the optimization pass, an @code{verify_flow_info}
612 function may be useful to find bugs in the control flow graph updating
615 Note that at present, the representation of control flow in the
616 @code{tree} representation is discarded before expanding to RTL@.
617 Long term the CFG should be maintained and ``expanded'' to the
618 RTL representation along with the function @code{tree} itself.
621 @node Liveness information
622 @section Liveness information
623 @cindex Liveness representation
624 Liveness information is useful to determine whether some register is
625 ``live'' at given point of program, i.e.@: that it contains a value that
626 may be used at a later point in the program. This information is
627 used, for instance, during register allocation, as the pseudo
628 registers only need to be assigned to a unique hard register or to a
629 stack slot if they are live. The hard registers and stack slots may
630 be freely reused for other values when a register is dead.
632 Liveness information is available in the back end starting with
633 @code{pass_df_initialize} and ending with @code{pass_df_finish}. Three
634 flavors of live analysis are available: With @code{LR}, it is possible
635 to determine at any point @code{P} in the function if the register may be
636 used on some path from @code{P} to the end of the function. With
637 @code{UR}, it is possible to determine if there is a path from the
638 beginning of the function to @code{P} that defines the variable.
639 @code{LIVE} is the intersection of the @code{LR} and @code{UR} and a
640 variable is live at @code{P} if there is both an assignment that reaches
641 it from the beginning of the function and a uses that can be reached on
642 some path from @code{P} to the end of the function.
644 In general @code{LIVE} is the most useful of the three. The macros
645 @code{DF_[LR,UR,LIVE]_[IN,OUT]} can be used to access this information.
646 The macros take a basic block number and return a bitmap that is indexed
647 by the register number. This information is only guaranteed to be up to
648 date after calls are made to @code{df_analyze}. See the file
649 @code{df-core.c} for details on using the dataflow.
652 @findex REG_DEAD, REG_UNUSED
653 The liveness information is stored partly in the RTL instruction stream
654 and partly in the flow graph. Local information is stored in the
655 instruction stream: Each instruction may contain @code{REG_DEAD} notes
656 representing that the value of a given register is no longer needed, or
657 @code{REG_UNUSED} notes representing that the value computed by the
658 instruction is never used. The second is useful for instructions
659 computing multiple values at once.