1 ;;;; structures for the first intermediate representation in the
4 ;;;; This software is part of the SBCL system. See the README file for
7 ;;;; This software is derived from the CMU CL system, which was
8 ;;;; written at Carnegie Mellon University and released into the
9 ;;;; public domain. The software is in the public domain and is
10 ;;;; provided with absolutely no warranty. See the COPYING and CREDITS
11 ;;;; files for more information.
15 ;;; The front-end data structure (IR1) is composed of nodes,
16 ;;; representing actual evaluations. Linear sequences of nodes in
17 ;;; control-flow order are combined into blocks (but see
18 ;;; JOIN-SUCCESSOR-IF-POSSIBLE for precise conditions); control
19 ;;; transfers inside a block are represented with CTRANs and between
20 ;;; blocks -- with BLOCK-SUCC/BLOCK-PRED lists; data transfers are
21 ;;; represented with LVARs.
23 ;;; "Lead-in" Control TRANsfer [to some node]
25 (:make-load-form-fun ignore-it)
26 (:constructor make-ctran))
27 ;; an indication of the way that this continuation is currently used
30 ;; A continuation for which all control-related slots have the
31 ;; default values. A continuation is unused during IR1 conversion
32 ;; until it is assigned a block, and may be also be temporarily
33 ;; unused during later manipulations of IR1. In a consistent
34 ;; state there should never be any mention of :UNUSED
35 ;; continuations. NEXT can have a non-null value if the next node
36 ;; has already been determined.
39 ;; The continuation that is the START of BLOCK.
42 ;; A continuation that is the NEXT of some node in BLOCK.
43 (kind :unused :type (member :unused :inside-block :block-start))
44 ;; A NODE which is to be evaluated next. Null only temporary.
45 (next nil :type (or node null))
46 ;; the node where this CTRAN is used, if unique. This is always null
47 ;; in :UNUSED and :BLOCK-START CTRANs, and is never null in
48 ;; :INSIDE-BLOCK continuations.
49 (use nil :type (or node null))
50 ;; the basic block this continuation is in. This is null only in
51 ;; :UNUSED continuations.
52 (block nil :type (or cblock null)))
54 (def!method print-object ((x ctran) stream)
55 (print-unreadable-object (x stream :type t :identity t)
56 (format stream "~D" (cont-num x))))
58 ;;; Linear VARiable. Multiple-value (possibly of unknown number)
61 (:make-load-form-fun ignore-it)
62 (:constructor make-lvar (&optional dest)))
63 ;; The node which receives this value. NIL only temporarily.
64 (dest nil :type (or node null))
65 ;; cached type of this lvar's value. If NIL, then this must be
66 ;; recomputed: see LVAR-DERIVED-TYPE.
67 (%derived-type nil :type (or ctype null))
68 ;; the node (if unique) or a list of nodes where this lvar is used.
69 (uses nil :type (or node list))
70 ;; set to true when something about this lvar's value has
71 ;; changed. See REOPTIMIZE-LVAR. This provides a way for IR1
72 ;; optimize to determine which operands to a node have changed. If
73 ;; the optimizer for this node type doesn't care, it can elect not
74 ;; to clear this flag.
75 (reoptimize t :type boolean)
76 ;; Cached type which is checked by DEST. If NIL, then this must be
77 ;; recomputed: see LVAR-EXTERNALLY-CHECKABLE-TYPE.
78 (%externally-checkable-type nil :type (or null ctype))
79 ;; if the LVAR value is DYNAMIC-EXTENT, CLEANUP protecting it.
80 (dynamic-extent nil :type (or null cleanup))
81 ;; something or other that the back end annotates this lvar with
84 (def!method print-object ((x lvar) stream)
85 (print-unreadable-object (x stream :type t :identity t)
86 (format stream "~D" (cont-num x))))
88 (def!struct (node (:constructor nil)
89 (:include sset-element (number (incf *compiler-sset-counter*)))
91 ;; unique ID for debugging
92 #!+sb-show (id (new-object-id) :read-only t)
93 ;; True if this node needs to be optimized. This is set to true
94 ;; whenever something changes about the value of an lvar whose DEST
96 (reoptimize t :type boolean)
97 ;; the ctran indicating what we do controlwise after evaluating this
98 ;; node. This is null if the node is the last in its block.
99 (next nil :type (or ctran null))
100 ;; the ctran that this node is the NEXT of. This is null during IR1
101 ;; conversion when we haven't linked the node in yet or in nodes
102 ;; that have been deleted from the IR1 by UNLINK-NODE.
103 (prev nil :type (or ctran null))
104 ;; the lexical environment this node was converted in
105 (lexenv *lexenv* :type lexenv)
106 ;; a representation of the source code responsible for generating
109 ;; For a form introduced by compilation (does not appear in the
110 ;; original source), the path begins with a list of all the
111 ;; enclosing introduced forms. This list is from the inside out,
112 ;; with the form immediately responsible for this node at the head
115 ;; Following the introduced forms is a representation of the
116 ;; location of the enclosing original source form. This transition
117 ;; is indicated by the magic ORIGINAL-SOURCE-START marker. The first
118 ;; element of the original source is the "form number", which is the
119 ;; ordinal number of this form in a depth-first, left-to-right walk
120 ;; of the truly-top-level form in which this appears.
122 ;; Following is a list of integers describing the path taken through
123 ;; the source to get to this point:
124 ;; (K L M ...) => (NTH K (NTH L (NTH M ...)))
126 ;; The last element in the list is the top level form number, which
127 ;; is the ordinal number (in this call to the compiler) of the truly
128 ;; top level form containing the original source.
129 (source-path *current-path* :type list)
130 ;; If this node is in a tail-recursive position, then this is set to
131 ;; T. At the end of IR1 (in physical environment analysis) this is
132 ;; computed for all nodes (after cleanup code has been emitted).
133 ;; Before then, a non-null value indicates that IR1 optimization has
134 ;; converted a tail local call to a direct transfer.
136 ;; If the back-end breaks tail-recursion for some reason, then it
137 ;; can null out this slot.
138 (tail-p nil :type boolean))
140 (def!struct (valued-node (:conc-name node-)
144 ;; the bottom-up derived type for this node.
145 (derived-type *wild-type* :type ctype)
146 ;; Lvar, receiving the values, produced by this node. May be NIL if
147 ;; the value is unused.
148 (lvar nil :type (or lvar null)))
150 ;;; Flags that are used to indicate various things about a block, such
151 ;;; as what optimizations need to be done on it:
152 ;;; -- REOPTIMIZE is set when something interesting happens the uses of a
153 ;;; lvar whose DEST is in this block. This indicates that the
154 ;;; value-driven (forward) IR1 optimizations should be done on this block.
155 ;;; -- FLUSH-P is set when code in this block becomes potentially flushable,
156 ;;; usually due to an lvar's DEST becoming null.
157 ;;; -- TYPE-CHECK is true when the type check phase should be run on this
158 ;;; block. IR1 optimize can introduce new blocks after type check has
159 ;;; already run. We need to check these blocks, but there is no point in
160 ;;; checking blocks we have already checked.
161 ;;; -- DELETE-P is true when this block is used to indicate that this block
162 ;;; has been determined to be unreachable and should be deleted. IR1
163 ;;; phases should not attempt to examine or modify blocks with DELETE-P
164 ;;; set, since they may:
165 ;;; - be in the process of being deleted, or
166 ;;; - have no successors.
167 ;;; -- TYPE-ASSERTED, TEST-MODIFIED
168 ;;; These flags are used to indicate that something in this block
169 ;;; might be of interest to constraint propagation. TYPE-ASSERTED
170 ;;; is set when an lvar type assertion is strengthened.
171 ;;; TEST-MODIFIED is set whenever the test for the ending IF has
172 ;;; changed (may be true when there is no IF.)
173 (!def-boolean-attribute block
174 reoptimize flush-p type-check delete-p type-asserted test-modified)
176 ;;; FIXME: Tweak so that definitions of e.g. BLOCK-DELETE-P is
177 ;;; findable by grep for 'def.*block-delete-p'.
178 (macrolet ((frob (slot)
179 `(defmacro ,(symbolicate "BLOCK-" slot) (block)
180 `(block-attributep (block-flags ,block) ,',slot))))
186 (frob test-modified))
188 ;;; The CBLOCK structure represents a basic block. We include
189 ;;; SSET-ELEMENT so that we can have sets of blocks. Initially the
190 ;;; SSET-ELEMENT-NUMBER is null, DFO analysis numbers in reverse DFO.
191 ;;; During IR2 conversion, IR1 blocks are re-numbered in forward emit
192 ;;; order. This latter numbering also forms the basis of the block
193 ;;; numbering in the debug-info (though that is relative to the start
194 ;;; of the function.)
195 (def!struct (cblock (:include sset-element)
196 (:constructor make-block (start))
197 (:constructor make-block-key)
199 (:predicate block-p))
200 ;; a list of all the blocks that are predecessors/successors of this
201 ;; block. In well-formed IR1, most blocks will have one successor.
202 ;; The only exceptions are:
203 ;; 1. component head blocks (any number)
204 ;; 2. blocks ending in an IF (1 or 2)
205 ;; 3. blocks with DELETE-P set (zero)
206 (pred nil :type list)
207 (succ nil :type list)
208 ;; the ctran which heads this block (a :BLOCK-START), or NIL when we
209 ;; haven't made the start ctran yet (and in the dummy component head
211 (start nil :type (or ctran null))
212 ;; the last node in this block. This is NIL when we are in the
213 ;; process of building a block (and in the dummy component head and
215 (last nil :type (or node null))
216 ;; the forward and backward links in the depth-first ordering of the
217 ;; blocks. These slots are NIL at beginning/end.
218 (next nil :type (or null cblock))
219 (prev nil :type (or null cblock))
220 ;; This block's attributes: see above.
221 (flags (block-attributes reoptimize flush-p type-check type-asserted
224 ;; in constraint propagation: list of LAMBDA-VARs killed in this block
225 ;; in copy propagation: list of killed TNs
227 ;; other sets used in constraint propagation and/or copy propagation
231 ;; Set of all blocks that dominate this block. NIL is interpreted
232 ;; as "all blocks in component".
233 (dominators nil :type (or null sset))
234 ;; the LOOP that this block belongs to
235 (loop nil :type (or null cloop))
236 ;; next block in the loop.
237 (loop-next nil :type (or null cblock))
238 ;; the component this block is in, or NIL temporarily during IR1
239 ;; conversion and in deleted blocks
241 (aver-live-component *current-component*)
243 :type (or component null))
244 ;; a flag used by various graph-walking code to determine whether
245 ;; this block has been processed already or what. We make this
246 ;; initially NIL so that FIND-INITIAL-DFO doesn't have to scan the
247 ;; entire initial component just to clear the flags.
249 ;; some kind of info used by the back end
251 ;; what macroexpansions and source transforms happened "in" this block, used
253 (xrefs nil :type list)
254 ;; Cache the physenv of a block during lifetime analysis. :NONE if
255 ;; no cached value has been stored yet.
256 (physenv-cache :none :type (or null physenv (member :none))))
257 (def!method print-object ((cblock cblock) stream)
258 (print-unreadable-object (cblock stream :type t :identity t)
259 (format stream "~W :START c~W"
260 (block-number cblock)
261 (cont-num (block-start cblock)))))
263 ;;; The BLOCK-ANNOTATION class is inherited (via :INCLUDE) by
264 ;;; different BLOCK-INFO annotation structures so that code
265 ;;; (specifically control analysis) can be shared.
266 (def!struct (block-annotation (:constructor nil)
268 ;; The IR1 block that this block is in the INFO for.
269 (block (missing-arg) :type cblock)
270 ;; the next and previous block in emission order (not DFO). This
271 ;; determines which block we drop though to, and is also used to
272 ;; chain together overflow blocks that result from splitting of IR2
273 ;; blocks in lifetime analysis.
274 (next nil :type (or block-annotation null))
275 (prev nil :type (or block-annotation null)))
277 ;;; A COMPONENT structure provides a handle on a connected piece of
278 ;;; the flow graph. Most of the passes in the compiler operate on
279 ;;; COMPONENTs rather than on the entire flow graph.
281 ;;; According to the CMU CL internals/front.tex, the reason for
282 ;;; separating compilation into COMPONENTs is
283 ;;; to increase the efficiency of large block compilations. In
284 ;;; addition to improving locality of reference and reducing the
285 ;;; size of flow analysis problems, this allows back-end data
286 ;;; structures to be reclaimed after the compilation of each
288 (def!struct (component (:copier nil)
294 (outer-loop (make-loop :kind :outer :head head)))))
295 ;; unique ID for debugging
296 #!+sb-show (id (new-object-id) :read-only t)
297 ;; the kind of component
299 ;; (The terminology here is left over from before
300 ;; sbcl-0.pre7.34.flaky5.2, when there was no such thing as
301 ;; FUNCTIONAL-HAS-EXTERNAL-REFERENCES-P, so that Python was
302 ;; incapable of building standalone :EXTERNAL functions, but instead
303 ;; had to implement things like #'CL:COMPILE as FUNCALL of a little
304 ;; toplevel stub whose sole purpose was to return an :EXTERNAL
307 ;; The possibilities are:
309 ;; an ordinary component, containing non-top-level code
311 ;; a component containing only load-time code
313 ;; In the old system, before FUNCTIONAL-HAS-EXTERNAL-REFERENCES-P
314 ;; was defined, this was necessarily a component containing both
315 ;; top level and run-time code. Now this state is also used for
316 ;; a component with HAS-EXTERNAL-REFERENCES-P functionals in it.
318 ;; the result of initial IR1 conversion, on which component
319 ;; analysis has not been done
321 ;; debris left over from component analysis
323 ;; See also COMPONENT-TOPLEVELISH-P.
324 (kind nil :type (member nil :toplevel :complex-toplevel :initial :deleted))
325 ;; the blocks that are the dummy head and tail of the DFO
327 ;; Entry/exit points have these blocks as their
328 ;; predecessors/successors. The start and return from each
329 ;; non-deleted function is linked to the component head and
330 ;; tail. Until physical environment analysis links NLX entry stubs
331 ;; to the component head, every successor of the head is a function
332 ;; start (i.e. begins with a BIND node.)
333 (head (missing-arg) :type cblock)
334 (tail (missing-arg) :type cblock)
335 ;; New blocks are inserted before this.
336 (last-block (missing-arg) :type cblock)
337 ;; This becomes a list of the CLAMBDA structures for all functions
338 ;; in this component. OPTIONAL-DISPATCHes are represented only by
339 ;; their XEP and other associated lambdas. This doesn't contain any
340 ;; deleted or LET lambdas.
342 ;; Note that logical associations between CLAMBDAs and COMPONENTs
343 ;; seem to exist for a while before this is initialized. See e.g.
344 ;; the NEW-FUNCTIONALS slot. In particular, I got burned by writing
345 ;; some code to use this value to decide which components need
346 ;; LOCALL-ANALYZE-COMPONENT, when it turns out that
347 ;; LOCALL-ANALYZE-COMPONENT had a role in initializing this value
348 ;; (and DFO stuff does too, maybe). Also, even after it's
349 ;; initialized, it might change as CLAMBDAs are deleted or merged.
351 (lambdas () :type list)
352 ;; a list of FUNCTIONALs for functions that are newly converted, and
353 ;; haven't been local-call analyzed yet. Initially functions are not
354 ;; in the LAMBDAS list. Local call analysis moves them there
355 ;; (possibly as LETs, or implicitly as XEPs if an OPTIONAL-DISPATCH.)
356 ;; Between runs of local call analysis there may be some debris of
357 ;; converted or even deleted functions in this list.
358 (new-functionals () :type list)
359 ;; If this is :MAYBE, then there is stuff in this component that
360 ;; could benefit from further IR1 optimization. T means that
361 ;; reoptimization is necessary.
362 (reoptimize t :type (member nil :maybe t))
363 ;; If this is true, then the control flow in this component was
364 ;; messed up by IR1 optimizations, so the DFO should be recomputed.
365 (reanalyze nil :type boolean)
366 ;; some sort of name for the code in this component
367 (name "<unknown>" :type t)
368 ;; When I am a child, this is :NO-IR2-YET.
369 ;; In my adulthood, IR2 stores notes to itself here.
370 ;; After I have left the great wheel and am staring into the GC, this
371 ;; is set to :DEAD to indicate that it's a gruesome error to operate
372 ;; on me (e.g. by using me as *CURRENT-COMPONENT*, or by pushing
373 ;; LAMBDAs onto my NEW-FUNCTIONALS, as in sbcl-0.pre7.115).
374 (info :no-ir2-yet :type (or ir2-component (member :no-ir2-yet :dead)))
375 ;; count of the number of inline expansions we have done while
376 ;; compiling this component, to detect infinite or exponential
378 (inline-expansions 0 :type index)
379 ;; a map from combination nodes to things describing how an
380 ;; optimization of the node failed. The description is an alist
381 ;; (TRANSFORM . ARGS), where TRANSFORM is the structure describing
382 ;; the transform that failed, and ARGS is either a list of format
383 ;; arguments for the note, or the FUN-TYPE that would have
384 ;; enabled the transformation but failed to match.
385 (failed-optimizations (make-hash-table :test 'eq) :type hash-table)
386 ;; This is similar to NEW-FUNCTIONALS, but is used when a function
387 ;; has already been analyzed, but new references have been added by
388 ;; inline expansion. Unlike NEW-FUNCTIONALS, this is not disjoint
389 ;; from COMPONENT-LAMBDAS.
390 (reanalyze-functionals nil :type list)
391 (delete-blocks nil :type list)
392 (nlx-info-generated-p nil :type boolean)
393 ;; this is filled by physical environment analysis
394 (dx-lvars nil :type list)
395 ;; The default LOOP in the component.
396 (outer-loop (missing-arg) :type cloop)
397 ;; The current sset index
398 (sset-number 0 :type fixnum))
399 (defprinter (component :identity t)
402 (reanalyze :test reanalyze))
404 ;;; Check that COMPONENT is suitable for roles which involve adding
405 ;;; new code. (gotta love imperative programming with lotso in-place
407 (defun aver-live-component (component)
408 ;; FIXME: As of sbcl-0.pre7.115, we're asserting that
409 ;; COMPILE-COMPONENT hasn't happened yet. Might it be even better
410 ;; (certainly stricter, possibly also correct...) to assert that
411 ;; IR1-FINALIZE hasn't happened yet?
412 (aver (not (eql (component-info component) :dead))))
414 ;;; Before sbcl-0.7.0, there were :TOPLEVEL things which were magical
415 ;;; in multiple ways. That's since been refactored into the orthogonal
416 ;;; properties "optimized for locall with no arguments" and "externally
417 ;;; visible/referenced (so don't delete it)". The code <0.7.0 did a lot
418 ;;; of tests a la (EQ KIND :TOP_LEVEL) in the "don't delete it?" sense;
419 ;;; this function is a sort of literal translation of those tests into
422 ;;; FIXME: After things settle down, bare :TOPLEVEL might go away, at
423 ;;; which time it might be possible to replace the COMPONENT-KIND
424 ;;; :TOPLEVEL mess with a flag COMPONENT-HAS-EXTERNAL-REFERENCES-P
425 ;;; along the lines of FUNCTIONAL-HAS-EXTERNAL-REFERENCES-P.
426 (defun lambda-toplevelish-p (clambda)
427 (or (eql (lambda-kind clambda) :toplevel)
428 (lambda-has-external-references-p clambda)))
429 (defun component-toplevelish-p (component)
430 (member (component-kind component)
431 '(:toplevel :complex-toplevel)))
433 ;;; A CLEANUP structure represents some dynamic binding action. Blocks
434 ;;; are annotated with the current CLEANUP so that dynamic bindings
435 ;;; can be removed when control is transferred out of the binding
436 ;;; environment. We arrange for changes in dynamic bindings to happen
437 ;;; at block boundaries, so that cleanup code may easily be inserted.
438 ;;; The "mess-up" action is explicitly represented by a funny function
439 ;;; call or ENTRY node.
441 ;;; We guarantee that CLEANUPs only need to be done at block
442 ;;; boundaries by requiring that the exit ctrans initially head their
443 ;;; blocks, and then by not merging blocks when there is a cleanup
445 (def!struct (cleanup (:copier nil))
446 ;; the kind of thing that has to be cleaned up
448 :type (member :special-bind :catch :unwind-protect
449 :block :tagbody :dynamic-extent))
450 ;; the node that messes things up. This is the last node in the
451 ;; non-messed-up environment. Null only temporarily. This could be
452 ;; deleted due to unreachability.
453 (mess-up nil :type (or node null))
454 ;; For all kinds, except :DYNAMIC-EXTENT: a list of all the NLX-INFO
455 ;; structures whose NLX-INFO-CLEANUP is this cleanup. This is filled
456 ;; in by physical environment analysis.
458 ;; For :DYNAMIC-EXTENT: a list of all DX LVARs, preserved by this
459 ;; cleanup. This is filled when the cleanup is created (now by
460 ;; locall call analysis) and is rechecked by physical environment
461 ;; analysis. (For closures this is a list of the allocating node -
462 ;; during IR1, and a list of the argument LVAR of the allocator -
463 ;; after physical environment analysis.)
464 (info nil :type list))
465 (defprinter (cleanup :identity t)
470 ;;; A PHYSENV represents the result of physical environment analysis.
472 ;;; As far as I can tell from reverse engineering, this IR1 structure
473 ;;; represents the physical environment (which is probably not the
474 ;;; standard Lispy term for this concept, but I dunno what is the
475 ;;; standard term): those things in the lexical environment which a
476 ;;; LAMBDA actually interacts with. Thus in
477 ;;; (DEFUN FROB-THINGS (THINGS)
478 ;;; (DOLIST (THING THINGS)
479 ;;; (BLOCK FROBBING-ONE-THING
480 ;;; (MAPCAR (LAMBDA (PATTERN)
481 ;;; (WHEN (FITS-P THING PATTERN)
482 ;;; (RETURN-FROM FROB-THINGS (LIST :FIT THING PATTERN))))
484 ;;; the variables THINGS, THING, and PATTERN and the block names
485 ;;; FROB-THINGS and FROBBING-ONE-THING are all in the inner LAMBDA's
486 ;;; lexical environment, but of those only THING, PATTERN, and
487 ;;; FROB-THINGS are in its physical environment. In IR1, we largely
488 ;;; just collect the names of these things; in IR2 an IR2-PHYSENV
489 ;;; structure is attached to INFO and used to keep track of
490 ;;; associations between these names and less-abstract things (like
491 ;;; TNs, or eventually stack slots and registers). -- WHN 2001-09-29
492 (def!struct (physenv (:copier nil))
493 ;; the function that allocates this physical environment
494 (lambda (missing-arg) :type clambda :read-only t)
495 ;; This ultimately converges to a list of all the LAMBDA-VARs and
496 ;; NLX-INFOs needed from enclosing environments by code in this
497 ;; physical environment. In the meantime, it may be
498 ;; * NIL at object creation time
499 ;; * a superset of the correct result, generated somewhat later
500 ;; * smaller and smaller sets converging to the correct result as
501 ;; we notice and delete unused elements in the superset
502 (closure nil :type list)
503 ;; a list of NLX-INFO structures describing all the non-local exits
504 ;; into this physical environment
505 (nlx-info nil :type list)
506 ;; some kind of info used by the back end
508 (defprinter (physenv :identity t)
510 (closure :test closure)
511 (nlx-info :test nlx-info))
513 ;;; An TAIL-SET structure is used to accumulate information about
514 ;;; tail-recursive local calls. The "tail set" is effectively the
515 ;;; transitive closure of the "is called tail-recursively by"
518 ;;; All functions in the same tail set share the same TAIL-SET
519 ;;; structure. Initially each function has its own TAIL-SET, but when
520 ;;; IR1-OPTIMIZE-RETURN notices a tail local call, it joins the tail
521 ;;; sets of the called function and the calling function.
523 ;;; The tail set is somewhat approximate, because it is too early to
524 ;;; be sure which calls will be tail-recursive. Any call that *might*
525 ;;; end up tail-recursive causes TAIL-SET merging.
526 (def!struct (tail-set)
527 ;; a list of all the LAMBDAs in this tail set
528 (funs nil :type list)
529 ;; our current best guess of the type returned by these functions.
530 ;; This is the union across all the functions of the return node's
531 ;; RESULT-TYPE, excluding local calls.
532 (type *wild-type* :type ctype)
533 ;; some info used by the back end
535 (defprinter (tail-set :identity t)
540 ;;; An NLX-INFO structure is used to collect various information about
541 ;;; non-local exits. This is effectively an annotation on the
542 ;;; continuation, although it is accessed by searching in the
543 ;;; PHYSENV-NLX-INFO.
544 (def!struct (nlx-info
545 (:constructor make-nlx-info (cleanup
548 (block (first (block-succ
549 (node-block exit))))))
550 (:make-load-form-fun ignore-it))
551 ;; the cleanup associated with this exit. In a catch or
552 ;; unwind-protect, this is the :CATCH or :UNWIND-PROTECT cleanup,
553 ;; and not the cleanup for the escape block. The CLEANUP-KIND of
554 ;; this thus provides a good indication of what kind of exit is
556 (cleanup (missing-arg) :type cleanup)
557 ;; the ``continuation'' exited to (the block, succeeding the EXIT
558 ;; nodes). If this exit is from an escape function (CATCH or
559 ;; UNWIND-PROTECT), then physical environment analysis deletes the
560 ;; escape function and instead has the %NLX-ENTRY use this
563 ;; This slot is used as a sort of name to allow us to find the
564 ;; NLX-INFO that corresponds to a given exit. For this purpose, the
565 ;; ENTRY must also be used to disambiguate, since exits to different
566 ;; places may deliver their result to the same continuation.
567 (block (missing-arg) :type cblock)
568 ;; the entry stub inserted by physical environment analysis. This is
569 ;; a block containing a call to the %NLX-ENTRY funny function that
570 ;; has the original exit destination as its successor. Null only
572 (target nil :type (or cblock null))
573 ;; for a lexical exit it determines whether tag existence check is
575 (safe-p nil :type boolean)
576 ;; some kind of info used by the back end
578 (defprinter (nlx-info :identity t)
585 ;;; Variables, constants and functions are all represented by LEAF
586 ;;; structures. A reference to a LEAF is indicated by a REF node. This
587 ;;; allows us to easily substitute one for the other without actually
588 ;;; hacking the flow graph.
589 (def!struct (leaf (:make-load-form-fun ignore-it)
590 (:include sset-element (number (incf *compiler-sset-counter*)))
592 ;; unique ID for debugging
593 #!+sb-show (id (new-object-id) :read-only t)
594 ;; (For public access to this slot, use LEAF-SOURCE-NAME.)
596 ;; the name of LEAF as it appears in the source, e.g. 'FOO or '(SETF
597 ;; FOO) or 'N or '*Z*, or the special .ANONYMOUS. value if there's
598 ;; no name for this thing in the source (as can happen for
599 ;; FUNCTIONALs, e.g. for anonymous LAMBDAs or for functions for
600 ;; top-level forms; and can also happen for anonymous constants) or
601 ;; perhaps also if the match between the name and the thing is
602 ;; skewed enough (e.g. for macro functions or method functions) that
603 ;; we don't want to have that name affect compilation
605 ;; (We use .ANONYMOUS. here more or less the way we'd ordinarily use
606 ;; NIL, but we're afraid to use NIL because it's a symbol which could
607 ;; be the name of a leaf, if only the constant named NIL.)
609 ;; The value of this slot in can affect ordinary runtime behavior,
610 ;; e.g. of special variables and known functions, not just debugging.
612 ;; See also the LEAF-DEBUG-NAME function and the
613 ;; FUNCTIONAL-%DEBUG-NAME slot.
614 (%source-name (missing-arg)
615 :type (or symbol (and cons (satisfies legal-fun-name-p)))
617 ;; the type which values of this leaf must have
618 (type *universal-type* :type ctype)
619 ;; the type which values of this leaf have last been defined to have
620 ;; (but maybe won't have in future, in case of redefinition)
621 (defined-type *universal-type* :type ctype)
622 ;; where the TYPE information came from (in order, from strongest to weakest):
623 ;; :DECLARED, from a declaration.
624 ;; :DEFINED-HERE, from examination of the definition in the same file.
625 ;; :DEFINED, from examination of the definition elsewhere.
626 ;; :DEFINED-METHOD, implicit, piecemeal declarations from CLOS.
627 ;; :ASSUMED, from uses of the object.
628 (where-from :assumed :type (member :declared :assumed :defined-here :defined :defined-method))
629 ;; list of the REF nodes for this leaf
631 ;; true if there was ever a REF or SET node for this leaf. This may
632 ;; be true when REFS and SETS are null, since code can be deleted.
633 (ever-used nil :type boolean)
634 ;; is it declared dynamic-extent, or truly-dynamic-extent?
635 (extent nil :type (member nil :maybe-dynamic :always-dynamic :indefinite))
636 ;; some kind of info used by the back end
639 (defun leaf-dynamic-extent (leaf)
640 (let ((extent (leaf-extent leaf)))
641 (unless (member extent '(nil :indefinite))
644 ;;; LEAF name operations
646 ;;; KLUDGE: wants CLOS..
647 (defun leaf-has-source-name-p (leaf)
648 (not (eq (leaf-%source-name leaf)
650 (defun leaf-source-name (leaf)
651 (aver (leaf-has-source-name-p leaf))
652 (leaf-%source-name leaf))
653 (defun leaf-debug-name (leaf)
654 (if (functional-p leaf)
655 ;; FUNCTIONALs have additional %DEBUG-NAME behavior.
656 (functional-debug-name leaf)
657 ;; Other objects just use their source name.
659 ;; (As of sbcl-0.pre7.85, there are a few non-FUNCTIONAL
660 ;; anonymous objects, (anonymous constants..) and those would
661 ;; fail here if we ever tried to get debug names from them, but
662 ;; it looks as though it's never interesting to get debug names
663 ;; from them, so it's moot. -- WHN)
664 (leaf-source-name leaf)))
665 (defun leaf-%debug-name (leaf)
666 (when (functional-p leaf)
667 (functional-%debug-name leaf)))
669 ;;; The CONSTANT structure is used to represent known constant values.
670 ;;; Since the same constant leaf may be shared between named and anonymous
671 ;;; constants, %SOURCE-NAME is never used.
672 (def!struct (constant (:constructor make-constant (value
674 (type (ctype-of value))
675 (%source-name '.anonymous.)
676 (where-from :defined)))
678 ;; the value of the constant
679 (value (missing-arg) :type t)
680 ;; Boxed TN for this constant, if any.
681 (boxed-tn nil :type (or null tn)))
682 (defprinter (constant :identity t)
685 ;;; The BASIC-VAR structure represents information common to all
686 ;;; variables which don't correspond to known local functions.
687 (def!struct (basic-var (:include leaf)
689 ;; Lists of the set nodes for this variable.
690 (sets () :type list))
692 ;;; The GLOBAL-VAR structure represents a value hung off of the symbol
694 (def!struct (global-var (:include basic-var))
695 ;; kind of variable described
697 :type (member :special :global-function :global :unknown)))
698 (defprinter (global-var :identity t)
701 (type :test (not (eq type *universal-type*)))
702 (defined-type :test (not (eq defined-type *universal-type*)))
703 (where-from :test (not (eq where-from :assumed)))
706 ;;; A DEFINED-FUN represents a function that is defined in the same
707 ;;; compilation block, or that has an inline expansion, or that has a
708 ;;; non-NIL INLINEP value. Whenever we change the INLINEP state (i.e.
709 ;;; an inline proclamation) we copy the structure so that former
710 ;;; INLINEP values are preserved.
711 (def!struct (defined-fun (:include global-var
712 (where-from :defined)
713 (kind :global-function)))
714 ;; The values of INLINEP and INLINE-EXPANSION initialized from the
715 ;; global environment.
716 (inlinep nil :type inlinep)
717 (inline-expansion nil :type (or cons null))
718 ;; List of functionals corresponding to this DEFINED-FUN: either from the
719 ;; conversion of a NAMED-LAMBDA, or from inline-expansion (see
720 ;; RECOGNIZE-KNOWN-CALL) - we need separate functionals for each policy in
721 ;; which the function is used.
722 (functionals nil :type list))
723 (defprinter (defined-fun :identity t)
727 (functionals :test functionals))
731 ;;; We default the WHERE-FROM and TYPE slots to :DEFINED and FUNCTION.
732 ;;; We don't normally manipulate function types for defined functions,
733 ;;; but if someone wants to know, an approximation is there.
734 (def!struct (functional (:include leaf
735 (%source-name '.anonymous.)
736 (where-from :defined)
737 (type (specifier-type 'function))))
738 ;; (For public access to this slot, use LEAF-DEBUG-NAME.)
740 ;; the name of FUNCTIONAL for debugging purposes, or NIL if we
741 ;; should just let the SOURCE-NAME fall through
743 ;; Unlike the SOURCE-NAME slot, this slot's value should never
744 ;; affect ordinary code behavior, only debugging/diagnostic behavior.
746 ;; Ha. Ah, the starry-eyed idealism of the writer of the above
747 ;; paragraph. FUNCTION-LAMBDA-EXPRESSION's behaviour, as of
748 ;; sbcl-0.7.11.x, differs if the name of the a function is a string
749 ;; or not, as if it is a valid function name then it can look for an
752 ;; E.g. for the function which implements (DEFUN FOO ...), we could
756 ;; for the function which implements the top level form
757 ;; (IN-PACKAGE :FOO) we could have
759 ;; %DEBUG-NAME=(TOP-LEVEL-FORM (IN-PACKAGE :FOO)
760 ;; for the function which implements FOO in
761 ;; (DEFUN BAR (...) (FLET ((FOO (...) ...)) ...))
764 ;; %DEBUG-NAME=(FLET FOO)
765 ;; and for the function which implements FOO in
766 ;; (DEFMACRO FOO (...) ...)
768 ;; %SOURCE-NAME=FOO (or maybe .ANONYMOUS.?)
769 ;; %DEBUG-NAME=(MACRO-FUNCTION FOO)
771 :type (or null (not (satisfies legal-fun-name-p)))
773 ;; some information about how this function is used. These values
777 ;; an ordinary function, callable using local call
780 ;; a lambda that is used in only one local call, and has in
781 ;; effect been substituted directly inline. The return node is
782 ;; deleted, and the result is computed with the actual result
783 ;; lvar for the call.
786 ;; Similar to :LET (as per FUNCTIONAL-LETLIKE-P), but the call
790 ;; similar to a LET (as per FUNCTIONAL-SOMEWHAT-LETLIKE-P), but
791 ;; can have other than one call as long as there is at most
792 ;; one non-tail call.
795 ;; a lambda that is an entry point for an OPTIONAL-DISPATCH.
796 ;; Similar to NIL, but requires greater caution, since local call
797 ;; analysis may create new references to this function. Also, the
798 ;; function cannot be deleted even if it has *no* references. The
799 ;; OPTIONAL-DISPATCH is in the LAMDBA-OPTIONAL-DISPATCH.
802 ;; an external entry point lambda. The function it is an entry
803 ;; for is in the ENTRY-FUN slot.
806 ;; a top level lambda, holding a compiled top level form.
807 ;; Compiled very much like NIL, but provides an indication of
808 ;; top level context. A :TOPLEVEL lambda should have *no*
809 ;; references. Its ENTRY-FUN is a self-pointer.
812 ;; After a component is compiled, we clobber any top level code
813 ;; references to its non-closure XEPs with dummy FUNCTIONAL
814 ;; structures having this kind. This prevents the retained
815 ;; top level code from holding onto the IR for the code it
820 ;; special functions used internally by CATCH and UNWIND-PROTECT.
821 ;; These are pretty much like a normal function (NIL), but are
822 ;; treated specially by local call analysis and stuff. Neither
823 ;; kind should ever be given an XEP even though they appear as
824 ;; args to funny functions. An :ESCAPE function is never actually
825 ;; called, and thus doesn't need to have code generated for it.
828 ;; This function has been found to be uncallable, and has been
829 ;; marked for deletion.
832 ;; Effectless [MV-]LET; has no BIND node.
833 (kind nil :type (member nil :optional :deleted :external :toplevel
834 :escape :cleanup :let :mv-let :assignment
835 :zombie :toplevel-xep))
836 ;; Is this a function that some external entity (e.g. the fasl dumper)
837 ;; refers to, so that even when it appears to have no references, it
838 ;; shouldn't be deleted? In the old days (before
839 ;; sbcl-0.pre7.37.flaky5.2) this was sort of implicitly true when
840 ;; KIND was :TOPLEVEL. Now it must be set explicitly, both for
841 ;; :TOPLEVEL functions and for any other kind of functions that we
842 ;; want to dump or return from #'CL:COMPILE or whatever.
843 (has-external-references-p nil)
844 ;; In a normal function, this is the external entry point (XEP)
845 ;; lambda for this function, if any. Each function that is used
846 ;; other than in a local call has an XEP, and all of the
847 ;; non-local-call references are replaced with references to the
850 ;; In an XEP lambda (indicated by the :EXTERNAL kind), this is the
851 ;; function that the XEP is an entry-point for. The body contains
852 ;; local calls to all the actual entry points in the function. In a
853 ;; :TOPLEVEL lambda (which is its own XEP) this is a self-pointer.
855 ;; With all other kinds, this is null.
856 (entry-fun nil :type (or functional null))
857 ;; the value of any inline/notinline declaration for a local
858 ;; function (or NIL in any case if no inline expansion is available)
859 (inlinep nil :type inlinep)
860 ;; If we have a lambda that can be used as in inline expansion for
861 ;; this function, then this is it. If there is no source-level
862 ;; lambda corresponding to this function then this is null (but then
863 ;; INLINEP will always be NIL as well.)
864 (inline-expansion nil :type list)
865 ;; the lexical environment that the INLINE-EXPANSION should be converted in
866 (lexenv *lexenv* :type lexenv)
867 ;; the original function or macro lambda list, or :UNSPECIFIED if
868 ;; this is a compiler created function
869 (arg-documentation nil :type (or list (member :unspecified)))
870 ;; the documentation string for the lambda
871 (documentation nil :type (or null string))
872 ;; Node, allocating closure for this lambda. May be NIL when we are
873 ;; sure that no closure is needed.
874 (allocator nil :type (or null combination))
875 ;; various rare miscellaneous info that drives code generation & stuff
876 (plist () :type list)
877 ;; xref information for this functional (only used for functions with an
880 ;; True if this functional was created from an inline expansion. This
881 ;; is either T, or the GLOBAL-VAR for which it is an expansion.
882 (inline-expanded nil))
883 (defprinter (functional :identity t)
888 ;;; Is FUNCTIONAL LET-converted? (where we're indifferent to whether
889 ;;; it returns one value or multiple values)
890 (defun functional-letlike-p (functional)
891 (member (functional-kind functional)
894 ;;; Is FUNCTIONAL sorta LET-converted? (where even an :ASSIGNMENT counts)
896 ;;; FIXME: I (WHN) don't understand this one well enough to give a good
897 ;;; definition or even a good function name, it's just a literal copy
898 ;;; of a CMU CL idiom. Does anyone have a better name or explanation?
899 (defun functional-somewhat-letlike-p (functional)
900 (or (functional-letlike-p functional)
901 (eql (functional-kind functional) :assignment)))
903 ;;; FUNCTIONAL name operations
904 (defun functional-debug-name (functional)
905 ;; FUNCTIONAL-%DEBUG-NAME takes precedence over FUNCTIONAL-SOURCE-NAME
906 ;; here because we want different debug names for the functions in
907 ;; DEFUN FOO and FLET FOO even though they have the same source name.
908 (or (functional-%debug-name functional)
909 ;; Note that this will cause an error if the function is
910 ;; anonymous. In SBCL (as opposed to CMU CL) we make all
911 ;; FUNCTIONALs have debug names. The CMU CL code didn't bother
912 ;; in many FUNCTIONALs, especially those which were likely to be
913 ;; optimized away before the user saw them. However, getting
914 ;; that right requires a global understanding of the code,
915 ;; which seems bad, so we just require names for everything.
916 (leaf-source-name functional)))
918 ;;; The CLAMBDA only deals with required lexical arguments. Special,
919 ;;; optional, keyword and rest arguments are handled by transforming
920 ;;; into simpler stuff.
921 (def!struct (clambda (:include functional)
923 (:predicate lambda-p)
924 (:constructor make-lambda)
925 (:copier copy-lambda))
926 ;; list of LAMBDA-VAR descriptors for arguments
927 (vars nil :type list :read-only t)
928 ;; If this function was ever a :OPTIONAL function (an entry-point
929 ;; for an OPTIONAL-DISPATCH), then this is that OPTIONAL-DISPATCH.
930 ;; The optional dispatch will be :DELETED if this function is no
932 (optional-dispatch nil :type (or optional-dispatch null))
933 ;; the BIND node for this LAMBDA. This node marks the beginning of
934 ;; the lambda, and serves to explicitly represent the lambda binding
935 ;; semantics within the flow graph representation. This is null in
936 ;; deleted functions, and also in LETs where we deleted the call and
937 ;; bind (because there are no variables left), but have not yet
938 ;; actually deleted the LAMBDA yet.
939 (bind nil :type (or bind null))
940 ;; the RETURN node for this LAMBDA, or NIL if it has been
941 ;; deleted. This marks the end of the lambda, receiving the result
942 ;; of the body. In a LET, the return node is deleted, and the body
943 ;; delivers the value to the actual lvar. The return may also be
944 ;; deleted if it is unreachable.
945 (return nil :type (or creturn null))
946 ;; If this CLAMBDA is a LET, then this slot holds the LAMBDA whose
947 ;; LETS list we are in, otherwise it is a self-pointer.
948 (home nil :type (or clambda null))
949 ;; all the lambdas that have been LET-substituted in this lambda.
950 ;; This is only non-null in lambdas that aren't LETs.
951 (lets nil :type list)
952 ;; all the ENTRY nodes in this function and its LETs, or null in a LET
953 (entries nil :type list)
954 ;; CLAMBDAs which are locally called by this lambda, and other
955 ;; objects (closed-over LAMBDA-VARs and XEPs) which this lambda
956 ;; depends on in such a way that DFO shouldn't put them in separate
958 (calls-or-closes (make-sset) :type (or null sset))
959 ;; the TAIL-SET that this LAMBDA is in. This is null during creation.
961 ;; In CMU CL, and old SBCL, this was also NILed out when LET
962 ;; conversion happened. That caused some problems, so as of
963 ;; sbcl-0.pre7.37.flaky5.2 when I was trying to get the compiler to
964 ;; emit :EXTERNAL functions directly, and so now the value
965 ;; is no longer NILed out in LET conversion, but instead copied
966 ;; (so that any further optimizations on the rest of the tail
967 ;; set won't modify the value) if necessary.
968 (tail-set nil :type (or tail-set null))
969 ;; the structure which represents the phsical environment that this
970 ;; function's variables are allocated in. This is filled in by
971 ;; physical environment analysis. In a LET, this is EQ to our home's
972 ;; physical environment.
973 (physenv nil :type (or physenv null))
974 ;; In a LET, this is the NODE-LEXENV of the combination node. We
975 ;; retain it so that if the LET is deleted (due to a lack of vars),
976 ;; we will still have caller's lexenv to figure out which cleanup is
978 (call-lexenv nil :type (or lexenv null))
979 ;; list of embedded lambdas
980 (children nil :type list)
981 (parent nil :type (or clambda null))
982 (allow-instrumenting *allow-instrumenting* :type boolean)
983 ;; True if this is a system introduced lambda: it may contain user code, but
984 ;; the lambda itself is not, and the bindings introduced by it are considered
985 ;; transparent by the nested DX analysis.
986 (system-lambda-p nil :type boolean))
987 (defprinter (clambda :conc-name lambda- :identity t)
992 (type :test (not (eq type *universal-type*)))
993 (where-from :test (not (eq where-from :assumed)))
994 (vars :prin1 (mapcar #'leaf-source-name vars)))
996 ;;; The OPTIONAL-DISPATCH leaf is used to represent hairy lambdas. It
997 ;;; is a FUNCTIONAL, like LAMBDA. Each legal number of arguments has a
998 ;;; function which is called when that number of arguments is passed.
999 ;;; The function is called with all the arguments actually passed. If
1000 ;;; additional arguments are legal, then the LEXPR style MORE-ENTRY
1001 ;;; handles them. The value returned by the function is the value
1002 ;;; which results from calling the OPTIONAL-DISPATCH.
1004 ;;; The theory is that each entry-point function calls the next entry
1005 ;;; point tail-recursively, passing all the arguments passed in and
1006 ;;; the default for the argument the entry point is for. The last
1007 ;;; entry point calls the real body of the function. In the presence
1008 ;;; of SUPPLIED-P args and other hair, things are more complicated. In
1009 ;;; general, there is a distinct internal function that takes the
1010 ;;; SUPPLIED-P args as parameters. The preceding entry point calls
1011 ;;; this function with NIL filled in for the SUPPLIED-P args, while
1012 ;;; the current entry point calls it with T in the SUPPLIED-P
1015 ;;; Note that it is easy to turn a call with a known number of
1016 ;;; arguments into a direct call to the appropriate entry-point
1017 ;;; function, so functions that are compiled together can avoid doing
1019 (def!struct (optional-dispatch (:include functional))
1020 ;; the original parsed argument list, for anyone who cares
1021 (arglist nil :type list)
1022 ;; true if &ALLOW-OTHER-KEYS was supplied
1023 (allowp nil :type boolean)
1024 ;; true if &KEY was specified (which doesn't necessarily mean that
1025 ;; there are any &KEY arguments..)
1026 (keyp nil :type boolean)
1027 ;; the number of required arguments. This is the smallest legal
1028 ;; number of arguments.
1029 (min-args 0 :type unsigned-byte)
1030 ;; the total number of required and optional arguments. Args at
1031 ;; positions >= to this are &REST, &KEY or illegal args.
1032 (max-args 0 :type unsigned-byte)
1033 ;; list of the (maybe delayed) LAMBDAs which are the entry points
1034 ;; for non-rest, non-key calls. The entry for MIN-ARGS is first,
1035 ;; MIN-ARGS+1 second, ... MAX-ARGS last. The last entry-point always
1036 ;; calls the main entry; in simple cases it may be the main entry.
1037 (entry-points nil :type list)
1038 ;; an entry point which takes MAX-ARGS fixed arguments followed by
1039 ;; an argument context pointer and an argument count. This entry
1040 ;; point deals with listifying rest args and parsing keywords. This
1041 ;; is null when extra arguments aren't legal.
1042 (more-entry nil :type (or clambda null))
1043 ;; the main entry-point into the function, which takes all arguments
1044 ;; including keywords as fixed arguments. The format of the
1045 ;; arguments must be determined by examining the arglist. This may
1046 ;; be used by callers that supply at least MAX-ARGS arguments and
1047 ;; know what they are doing.
1048 (main-entry nil :type (or clambda null)))
1049 (defprinter (optional-dispatch :identity t)
1053 (type :test (not (eq type *universal-type*)))
1054 (where-from :test (not (eq where-from :assumed)))
1060 (entry-points :test entry-points)
1061 (more-entry :test more-entry)
1064 ;;; The ARG-INFO structure allows us to tack various information onto
1065 ;;; LAMBDA-VARs during IR1 conversion. If we use one of these things,
1066 ;;; then the var will have to be massaged a bit before it is simple
1068 (def!struct arg-info
1069 ;; true if this arg is to be specially bound
1070 (specialp nil :type boolean)
1071 ;; the kind of argument being described. Required args only have arg
1072 ;; info structures if they are special.
1074 :type (member :required :optional :keyword :rest
1075 :more-context :more-count))
1076 ;; If true, this is the VAR for SUPPLIED-P variable of a keyword or
1077 ;; optional arg. This is true for keywords with non-constant
1078 ;; defaults even when there is no user-specified supplied-p var.
1079 (supplied-p nil :type (or lambda-var null))
1080 ;; the default for a keyword or optional, represented as the
1081 ;; original Lisp code. This is set to NIL in &KEY arguments that are
1082 ;; defaulted using the SUPPLIED-P arg.
1084 ;; For &REST arguments this may contain information about more context
1085 ;; the rest list comes from.
1086 (default nil :type t)
1087 ;; the actual key for a &KEY argument. Note that in ANSI CL this is
1088 ;; not necessarily a keyword: (DEFUN FOO (&KEY ((BAR BAR))) ...).
1089 (key nil :type symbol))
1090 (defprinter (arg-info :identity t)
1091 (specialp :test specialp)
1093 (supplied-p :test supplied-p)
1094 (default :test default)
1097 ;;; The LAMBDA-VAR structure represents a lexical lambda variable.
1098 ;;; This structure is also used during IR1 conversion to describe
1099 ;;; lambda arguments which may ultimately turn out not to be simple
1102 ;;; LAMBDA-VARs with no REFs are considered to be deleted; physical
1103 ;;; environment analysis isn't done on these variables, so the back
1104 ;;; end must check for and ignore unreferenced variables. Note that a
1105 ;;; deleted LAMBDA-VAR may have sets; in this case the back end is
1106 ;;; still responsible for propagating the SET-VALUE to the set's CONT.
1107 (!def-boolean-attribute lambda-var
1108 ;; true if this variable has been declared IGNORE
1110 ;; This is set by physical environment analysis if it chooses an
1111 ;; indirect (value cell) representation for this variable because it
1112 ;; is both set and closed over.
1114 ;; true if the last reference has been deleted (and new references
1115 ;; should not be made)
1117 ;; This is set by physical environment analysis if, should it be an
1118 ;; indirect lambda-var, an actual value cell object must be
1119 ;; allocated for this variable because one or more of the closures
1120 ;; that refer to it are not dynamic-extent. Note that both
1121 ;; attributes must be set for the value-cell object to be created.
1125 (def!struct (lambda-var (:include basic-var))
1126 (flags (lambda-var-attributes)
1128 ;; the CLAMBDA that this var belongs to. This may be null when we are
1129 ;; building a lambda during IR1 conversion.
1130 (home nil :type (or null clambda))
1131 ;; The following two slots are only meaningful during IR1 conversion
1132 ;; of hairy lambda vars:
1134 ;; The ARG-INFO structure which holds information obtained from
1135 ;; &keyword parsing.
1136 (arg-info nil :type (or arg-info null))
1137 ;; if true, the GLOBAL-VAR structure for the special variable which
1138 ;; is to be bound to the value of this argument
1139 (specvar nil :type (or global-var null))
1140 ;; Set of the CONSTRAINTs on this variable. Used by constraint
1141 ;; propagation. This is left null by the lambda pre-pass if it
1142 ;; determine that this is a set closure variable, and is thus not a
1143 ;; good subject for flow analysis.
1144 (constraints nil :type (or null t #| FIXME: conset |#))
1145 ;; Content-addressed indices for the CONSTRAINTs on this variable.
1146 ;; These are solely used by FIND-CONSTRAINT
1147 (ctype-constraints nil :type (or null hash-table))
1148 (eq-constraints nil :type (or null hash-table))
1149 ;; sorted sets of constraints we like to iterate over
1150 (eql-var-constraints nil :type (or null (array t 1)))
1151 (inheritable-constraints nil :type (or null (array t 1)))
1152 (private-constraints nil :type (or null (array t 1)))
1153 ;; Initial type of a LET variable as last seen by PROPAGATE-FROM-SETS.
1154 (last-initial-type *universal-type* :type ctype)
1155 ;; The FOP handle of the lexical variable represented by LAMBDA-VAR
1156 ;; in the fopcompiler.
1158 (defprinter (lambda-var :identity t)
1161 (type :test (not (eq type *universal-type*)))
1162 (where-from :test (not (eq where-from :assumed)))
1163 (flags :test (not (zerop flags))
1164 :prin1 (decode-lambda-var-attributes flags))
1165 (arg-info :test arg-info)
1166 (specvar :test specvar))
1168 (defmacro lambda-var-ignorep (var)
1169 `(lambda-var-attributep (lambda-var-flags ,var) ignore))
1170 (defmacro lambda-var-indirect (var)
1171 `(lambda-var-attributep (lambda-var-flags ,var) indirect))
1172 (defmacro lambda-var-deleted (var)
1173 `(lambda-var-attributep (lambda-var-flags ,var) deleted))
1174 (defmacro lambda-var-explicit-value-cell (var)
1175 `(lambda-var-attributep (lambda-var-flags ,var) explicit-value-cell))
1177 ;;;; basic node types
1179 ;;; A REF represents a reference to a LEAF. REF-REOPTIMIZE is
1180 ;;; initially (and forever) NIL, since REFs don't receive any values
1181 ;;; and don't have any IR1 optimizer.
1182 (def!struct (ref (:include valued-node (reoptimize nil))
1183 (:constructor make-ref
1185 &optional (%source-name '.anonymous.)
1186 &aux (leaf-type (leaf-type leaf))
1188 (make-single-value-type leaf-type))))
1190 ;; The leaf referenced.
1191 (leaf nil :type leaf)
1192 ;; CONSTANT nodes are always anonymous, since we wish to coalesce named and
1193 ;; unnamed constants that are equivalent, we need to keep track of the
1194 ;; reference name for XREF.
1195 (%source-name (missing-arg) :type symbol :read-only t))
1196 (defprinter (ref :identity t)
1198 (%source-name :test (neq %source-name '.anonymous.))
1201 ;;; Naturally, the IF node always appears at the end of a block.
1202 (def!struct (cif (:include node)
1205 (:constructor make-if)
1207 ;; LVAR for the predicate
1208 (test (missing-arg) :type lvar)
1209 ;; the blocks that we execute next in true and false case,
1210 ;; respectively (may be the same)
1211 (consequent (missing-arg) :type cblock)
1212 (consequent-constraints nil :type (or null t #| FIXME: conset |#))
1213 (alternative (missing-arg) :type cblock)
1214 (alternative-constraints nil :type (or null t #| FIXME: conset |#)))
1215 (defprinter (cif :conc-name if- :identity t)
1216 (test :prin1 (lvar-uses test))
1220 (def!struct (cset (:include valued-node
1221 (derived-type (make-single-value-type
1225 (:constructor make-set)
1227 ;; descriptor for the variable set
1228 (var (missing-arg) :type basic-var)
1229 ;; LVAR for the value form
1230 (value (missing-arg) :type lvar))
1231 (defprinter (cset :conc-name set- :identity t)
1233 (value :prin1 (lvar-uses value)))
1235 ;;; The BASIC-COMBINATION structure is used to represent both normal
1236 ;;; and multiple value combinations. In a let-like function call, this
1237 ;;; node appears at the end of its block and the body of the called
1238 ;;; function appears as the successor; the NODE-LVAR is null.
1239 (def!struct (basic-combination (:include valued-node)
1242 ;; LVAR for the function
1243 (fun (missing-arg) :type lvar)
1244 ;; list of LVARs for the args. In a local call, an argument lvar may
1245 ;; be replaced with NIL to indicate that the corresponding variable
1246 ;; is unreferenced, and thus no argument value need be passed.
1247 (args nil :type list)
1248 ;; the kind of function call being made. :LOCAL means that this is a
1249 ;; local call to a function in the same component, and that argument
1250 ;; syntax checking has been done, etc. Calls to known global
1251 ;; functions are represented by storing :KNOWN in this slot and the
1252 ;; FUN-INFO for that function in the FUN-INFO slot. :FULL is a call
1253 ;; to an (as yet) unknown function, or to a known function declared
1254 ;; NOTINLINE. :ERROR is like :FULL, but means that we have
1255 ;; discovered that the call contains an error, and should not be
1256 ;; reconsidered for optimization.
1257 (kind :full :type (member :local :full :error :known))
1258 ;; if a call to a known global function, contains the FUN-INFO.
1259 (fun-info nil :type (or fun-info null))
1260 ;; Untrusted type we have asserted for this combination.
1261 (type-validated-for-leaf nil)
1262 ;; some kind of information attached to this node by the back end
1266 ;;; The COMBINATION node represents all normal function calls,
1267 ;;; including FUNCALL. This is distinct from BASIC-COMBINATION so that
1268 ;;; an MV-COMBINATION isn't COMBINATION-P.
1269 (def!struct (combination (:include basic-combination)
1270 (:constructor make-combination (fun))
1272 (defprinter (combination :identity t)
1274 (fun :prin1 (lvar-uses fun))
1275 (args :prin1 (mapcar (lambda (x)
1281 ;;; An MV-COMBINATION is to MULTIPLE-VALUE-CALL as a COMBINATION is to
1282 ;;; FUNCALL. This is used to implement all the multiple-value
1283 ;;; receiving forms.
1284 (def!struct (mv-combination (:include basic-combination)
1285 (:constructor make-mv-combination (fun))
1287 (defprinter (mv-combination)
1288 (fun :prin1 (lvar-uses fun))
1289 (args :prin1 (mapcar #'lvar-uses args)))
1291 ;;; The BIND node marks the beginning of a lambda body and represents
1292 ;;; the creation and initialization of the variables.
1293 (def!struct (bind (:include node)
1295 ;; the lambda we are binding variables for. Null when we are
1296 ;; creating the LAMBDA during IR1 translation.
1297 (lambda nil :type (or clambda null)))
1301 ;;; The RETURN node marks the end of a lambda body. It collects the
1302 ;;; return values and represents the control transfer on return. This
1303 ;;; is also where we stick information used for TAIL-SET type
1305 (def!struct (creturn (:include node)
1306 (:conc-name return-)
1307 (:predicate return-p)
1308 (:constructor make-return)
1309 (:copier copy-return))
1310 ;; the lambda we are returning from. Null temporarily during
1312 (lambda nil :type (or clambda null))
1313 ;; the lvar which yields the value of the lambda
1314 (result (missing-arg) :type lvar)
1315 ;; the union of the node-derived-type of all uses of the result
1316 ;; other than by a local call, intersected with the result's
1317 ;; asserted-type. If there are no non-call uses, this is
1319 (result-type *wild-type* :type ctype))
1320 (defprinter (creturn :conc-name return- :identity t)
1324 ;;; The CAST node represents type assertions. The check for
1325 ;;; TYPE-TO-CHECK is performed and then the VALUE is declared to be of
1326 ;;; type ASSERTED-TYPE.
1327 (def!struct (cast (:include valued-node)
1328 (:constructor %make-cast))
1329 (asserted-type (missing-arg) :type ctype)
1330 (type-to-check (missing-arg) :type ctype)
1331 ;; an indication of what we have proven about how this type
1332 ;; assertion is satisfied:
1335 ;; No type check is necessary (VALUE type is a subtype of the TYPE-TO-CHECK.)
1338 ;; Type check will be performed by NODE-DEST.
1341 ;; A type check is needed.
1342 (%type-check t :type (member t :external nil))
1343 ;; the lvar which is checked
1344 (value (missing-arg) :type lvar))
1345 (defprinter (cast :identity t)
1351 ;;;; non-local exit support
1353 ;;;; In IR1, we insert special nodes to mark potentially non-local
1356 ;;; The ENTRY node serves to mark the start of the dynamic extent of a
1357 ;;; lexical exit. It is the mess-up node for the corresponding :ENTRY
1359 (def!struct (entry (:include node)
1361 ;; All of the EXIT nodes for potential non-local exits to this point.
1362 (exits nil :type list)
1363 ;; The cleanup for this entry. NULL only temporarily.
1364 (cleanup nil :type (or cleanup null)))
1365 (defprinter (entry :identity t)
1368 ;;; The EXIT node marks the place at which exit code would be emitted,
1369 ;;; if necessary. This is interposed between the uses of the exit
1370 ;;; continuation and the exit continuation's DEST. Instead of using
1371 ;;; the returned value being delivered directly to the exit
1372 ;;; continuation, it is delivered to our VALUE lvar. The original exit
1373 ;;; lvar is the exit node's LVAR; physenv analysis also makes it the
1374 ;;; lvar of %NLX-ENTRY call.
1375 (def!struct (exit (:include valued-node)
1377 ;; the ENTRY node that this is an exit for. If null, this is a
1378 ;; degenerate exit. A degenerate exit is used to "fill" an empty
1379 ;; block (which isn't allowed in IR1.) In a degenerate exit, Value
1380 ;; is always also null.
1381 (entry nil :type (or entry null))
1382 ;; the lvar yielding the value we are to exit with. If NIL, then no
1383 ;; value is desired (as in GO).
1384 (value nil :type (or lvar null))
1385 (nlx-info nil :type (or nlx-info null)))
1386 (defprinter (exit :identity t)
1389 (value :test value))
1391 ;;;; miscellaneous IR1 structures
1393 (def!struct (undefined-warning
1394 #-no-ansi-print-object
1395 (:print-object (lambda (x s)
1396 (print-unreadable-object (x s :type t)
1397 (prin1 (undefined-warning-name x) s))))
1399 ;; the name of the unknown thing
1400 (name nil :type (or symbol list))
1401 ;; the kind of reference to NAME
1402 (kind (missing-arg) :type (member :function :type :variable))
1403 ;; the number of times this thing was used
1404 (count 0 :type unsigned-byte)
1405 ;; a list of COMPILER-ERROR-CONTEXT structures describing places
1406 ;; where this thing was used. Note that we only record the first
1407 ;; *UNDEFINED-WARNING-LIMIT* calls.
1408 (warnings () :type list))
1410 ;;; a helper for the POLICY macro, defined late here so that the
1411 ;;; various type tests can be inlined
1412 (declaim (ftype (function ((or list lexenv node functional)) list)
1414 (defun %coerce-to-policy (thing)
1415 (let ((result (etypecase thing
1417 (lexenv (lexenv-policy thing))
1418 (node (lexenv-policy (node-lexenv thing)))
1419 (functional (lexenv-policy (functional-lexenv thing))))))
1420 ;; Test the first element of the list as a rudimentary sanity
1421 ;; that it really does look like a valid policy.
1422 (aver (or (null result) (policy-quality-name-p (caar result))))
1426 ;;;; Freeze some structure types to speed type testing.
1429 (declaim (freeze-type node leaf lexenv ctran lvar cblock component cleanup
1430 physenv tail-set nlx-info))