Next: Profile information, Previous: Basic Blocks, Up: Control Flow
Edges represent possible control flow transfers from the end of some
basic block A to the head of another basic block B. We say that A is
a predecessor of B, and B is a successor of A. Edges are represented
in GCC with the edge
data type. Each edge
acts as a
link between two basic blocks: The src
member of an edge
points to the predecessor basic block of the dest
basic block.
The members preds
and succs
of the basic_block
data
type point to type-safe vectors of edges to the predecessors and
successors of the block.
When walking the edges in an edge vector, edge iterators should
be used. Edge iterators are constructed using the
edge_iterator
data structure and several methods are available
to operate on them:
ei_start
edge_iterator
that points to the
first edge in a vector of edges.
ei_last
edge_iterator
that points to the
last edge in a vector of edges.
ei_end_p
true
if an edge_iterator
represents
the last edge in an edge vector.
ei_one_before_end_p
true
if an edge_iterator
represents
the second last edge in an edge vector.
ei_next
edge_iterator
and makes it
point to the next edge in the sequence.
ei_prev
edge_iterator
and makes it
point to the previous edge in the sequence.
ei_edge
edge
currently pointed to by an
edge_iterator
.
ei_safe_safe
edge
currently pointed to by an
edge_iterator
, but returns NULL
if the iterator is
pointing at the end of the sequence. This function has been provided
for existing code makes the assumption that a NULL
edge
indicates the end of the sequence.
The convenience macro FOR_EACH_EDGE
can be used to visit all of
the edges in a sequence of predecessor or successor edges. It must
not be used when an element might be removed during the traversal,
otherwise elements will be missed. Here is an example of how to use
the macro:
edge e; edge_iterator ei; FOR_EACH_EDGE (e, ei, bb->succs) { if (e->flags & EDGE_FALLTHRU) break; }
There are various reasons why control flow may transfer from one block
to another. One possibility is that some instruction, for example a
CODE_LABEL
, in a linearized instruction stream just always
starts a new basic block. In this case a fall-thru edge links
the basic block to the first following basic block. But there are
several other reasons why edges may be created. The flags
field of the edge
data type is used to store information
about the type of edge we are dealing with. Each edge is of one of
the following types:
EDGE_FALLTHRU
flag set. Unlike other types of edges, these
edges must come into the basic block immediately following in the
instruction stream. The function force_nonfallthru
is
available to insert an unconditional jump in the case that redirection
is needed. Note that this may require creation of a new basic block.
EDGE_ABNORMAL
and EDGE_EH
flags set.
When updating the instruction stream it is easy to change possibly
trapping instruction to non-trapping, by simply removing the exception
edge. The opposite conversion is difficult, but should not happen
anyway. The edges can be eliminated via purge_dead_edges
call.
In the RTL representation, the destination of an exception edge is
specified by REG_EH_REGION
note attached to the insn.
In case of a trapping call the EDGE_ABNORMAL_CALL
flag is set
too. In the GIMPLE
representation, this extra flag is not set.
In the RTL representation, the predicate may_trap_p
may be used
to check whether instruction still may trap or not. For the tree
representation, the tree_could_trap_p
predicate is available,
but this predicate only checks for possible memory traps, as in
dereferencing an invalid pointer location.
EDGE_SIBCALL
and EDGE_ABNORMAL
are set in such case.
These edges only exist in the RTL representation.
EDGE_ABNORMAL
flag set.
The edges used to represent computed jumps often cause compile time
performance problems, since functions consisting of many taken labels
and many computed jumps may have very dense flow graphs, so
these edges need to be handled with special care. During the earlier
stages of the compilation process, GCC tries to avoid such dense flow
graphs by factoring computed jumps. For example, given the following
series of jumps,
goto *x; [ ... ] goto *x; [ ... ] goto *x; [ ... ]
factoring the computed jumps results in the following code sequence which has a much simpler flow graph:
goto y; [ ... ] goto y; [ ... ] goto y; [ ... ] y: goto *x;
However, the classic problem with this transformation is that it has a
runtime cost in there resulting code: An extra jump. Therefore, the
computed jumps are un-factored in the later passes of the compiler
(in the pass called pass_duplicate_computed_gotos
).
Be aware of that when you work on passes in that area. There have
been numerous examples already where the compile time for code with
unfactored computed jumps caused some serious headaches.
goto
to a label passed to as an argument to the callee. The labels passed
to nested functions contain special code to cleanup after function
call. Such sections of code are referred to as “nonlocal goto
receivers”. If a function contains such nonlocal goto receivers, an
edge from the call to the label is created with the
EDGE_ABNORMAL
and EDGE_ABNORMAL_CALL
flags set.
ENTRY_BLOCK_PTR
to basic block 0.
There is no GIMPLE
representation for alternate entry points at
this moment. In RTL, alternate entry points are specified by
CODE_LABEL
with LABEL_ALTERNATE_NAME
defined. This
feature is currently used for multiple entry point prologues and is
limited to post-reload passes only. This can be used by back-ends to
emit alternate prologues for functions called from different contexts.
In future full support for multiple entry functions defined by Fortran
90 needs to be implemented.