1 ;;;; structures for the second (virtual machine) intermediate
2 ;;;; representation in the compiler, IR2
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 largest number of TNs whose liveness changes that we can have
17 (def!constant local-tn-limit
64)
19 (deftype local-tn-number
() `(integer 0 (,local-tn-limit
)))
20 (deftype local-tn-count
() `(integer 0 ,local-tn-limit
))
21 (deftype local-tn-vector
() `(simple-vector ,local-tn-limit
))
22 (deftype local-tn-bit-vector
() `(simple-bit-vector ,local-tn-limit
))
24 ;;; type of an SC number
25 (deftype sc-number
() `(integer 0 (,sc-number-limit
)))
27 ;;; types for vectors indexed by SC numbers
28 (deftype sc-vector
() `(simple-vector ,sc-number-limit
))
29 (deftype sc-bit-vector
() `(simple-bit-vector ,sc-number-limit
))
31 ;;; the different policies we can use to determine the coding strategy
32 (deftype ltn-policy
()
33 '(member :safe
:small
:fast
:fast-safe
))
37 ;;; A PRIMITIVE-TYPE is used to represent the aspects of type
38 ;;; interesting to the VM. Selection of IR2 translation templates is
39 ;;; done on the basis of the primitive types of the operands, and the
40 ;;; primitive type of a value is used to constrain the possible
41 ;;; representations of that value.
42 (defstruct (primitive-type (:copier nil
))
43 ;; the name of this PRIMITIVE-TYPE
44 (name nil
:type symbol
)
45 ;; a list of the SC numbers for all the SCs that a TN of this type
46 ;; can be allocated in
48 ;; the Lisp type equivalent to this type. If this type could never be
49 ;; returned by PRIMITIVE-TYPE, then this is the NIL (or empty) type
50 (specifier (missing-arg) :type type-specifier
)
51 ;; the template used to check that an object is of this type. This is a
52 ;; template of one argument and one result, both of primitive-type T. If
53 ;; the argument is of the correct type, then it is delivered into the
54 ;; result. If the type is incorrect, then an error is signalled.
55 (check nil
:type
(or template null
)))
57 (defprinter (primitive-type)
60 ;;;; IR1 annotations used for IR2 conversion
63 ;;; Holds the IR2-BLOCK structure. If there are overflow blocks,
64 ;;; then this points to the first IR2-BLOCK. The BLOCK-INFO of the
65 ;;; dummy component head and tail are dummy IR2 blocks that begin
66 ;;; and end the emission order thread.
69 ;;; Holds the IR2-COMPONENT structure.
72 ;;; Holds the IR2-LVAR structure. LVARs whose values aren't used
73 ;;; won't have any. XXX
76 ;;; If non-null, then a TN in which the affected dynamic
77 ;;; environment pointer should be saved after the binding is
81 ;;; Holds the IR2-PHYSENV structure.
84 ;;; Holds the RETURN-INFO structure.
87 ;;; Holds the IR2-NLX-INFO structure.
90 ;;; If a non-set lexical variable, the TN that holds the value in
91 ;;; the home environment. If a constant, then the corresponding
92 ;;; constant TN. If an XEP lambda, then the corresponding
93 ;;; Entry-Info structure.
95 ;;; BASIC-COMBINATION-INFO
96 ;;; The template chosen by LTN, or
97 ;;; :FULL if this is definitely a full call.
98 ;;; :FUNNY if this is an oddball thing with IR2-convert.
99 ;;; :LOCAL if this is a local call.
102 ;;; After LTN analysis, this is true only in combination nodes that are
103 ;;; truly tail recursive.
105 ;;; An IR2-BLOCK holds information about a block that is used during
106 ;;; and after IR2 conversion. It is stored in the BLOCK-INFO slot for
107 ;;; the associated block.
108 (defstruct (ir2-block (:include block-annotation
)
109 (:constructor make-ir2-block
(block))
111 ;; the IR2-BLOCK's number, which differs from BLOCK's BLOCK-NUMBER
112 ;; if any blocks are split. This is assigned by lifetime analysis.
113 (number nil
:type
(or index null
))
114 ;; information about unknown-values LVARs that is used by stack
115 ;; analysis to do stack simulation. An UNKNOWN-VALUES LVAR is PUSHED
116 ;; if its DEST is in another block. Similarly, a LVAR is POPPED if
117 ;; its DEST is in this block but has its uses elsewhere. The LVARs
118 ;; are in the order that are pushed/popped in the block. Note that
119 ;; the args to a single MV-COMBINATION appear reversed in POPPED,
120 ;; since we must effectively pop the last argument first. All pops
121 ;; must come before all pushes (although internal MV uses may be
122 ;; interleaved.) POPPED is computed by LTN, and PUSHED is computed
123 ;; by stack analysis.
124 (pushed () :type list
)
125 (popped () :type list
)
126 ;; the result of stack analysis: lists of all the unknown-values
127 ;; LVARs on the stack at the block start and end, topmost LVAR
129 (start-stack () :type list
)
130 (end-stack () :type list
)
131 ;; the first and last VOP in this block. If there are none, both
133 (start-vop nil
:type
(or vop null
))
134 (last-vop nil
:type
(or vop null
))
135 ;; the number of local TNs actually allocated
136 (local-tn-count 0 :type local-tn-count
)
137 ;; a vector that maps local TN numbers to TNs. Some entries may be
138 ;; NIL, indicating that that number is unused. (This allows us to
139 ;; delete local conflict information without compressing the LTN
142 ;; If an entry is :MORE, then this block contains only a single VOP.
143 ;; This VOP has so many more arguments and/or results that they
144 ;; cannot all be assigned distinct LTN numbers. In this case, we
145 ;; assign all the more args one LTN number, and all the more results
146 ;; another LTN number. We can do this, since more operands are
147 ;; referenced simultaneously as far as conflict analysis is
148 ;; concerned. Note that all these :MORE TNs will be global TNs.
149 (local-tns (make-array local-tn-limit
) :type local-tn-vector
)
150 ;; Bit-vectors used during lifetime analysis to keep track of
151 ;; references to local TNs. When indexed by the LTN number, the
152 ;; index for a TN is non-zero in WRITTEN if it is ever written in
153 ;; the block, and in LIVE-OUT if the first reference is a read.
154 (written (make-array local-tn-limit
:element-type
'bit
156 :type local-tn-bit-vector
)
157 (live-out (make-array local-tn-limit
:element-type
'bit
)
158 :type local-tn-bit-vector
)
159 ;; This is similar to the above, but is updated by lifetime flow
160 ;; analysis to have a 1 for LTN numbers of TNs live at the end of
161 ;; the block. This takes into account all TNs that aren't :LIVE.
162 (live-in (make-array local-tn-limit
:element-type
'bit
:initial-element
0)
163 :type local-tn-bit-vector
)
164 ;; a thread running through the global-conflicts structures for this
165 ;; block, sorted by TN number
166 (global-tns nil
:type
(or global-conflicts null
))
167 ;; the assembler label that points to the beginning of the code for
168 ;; this block, or NIL when we haven't assigned a label yet
170 ;; list of LOCATION-INFO structures describing all the interesting
171 ;; (to the debugger) locations in this block
172 (locations nil
:type list
))
174 (defprinter (ir2-block)
175 (pushed :test pushed
)
176 (popped :test popped
)
177 (start-vop :test start-vop
)
178 (last-vop :test last-vop
)
179 (local-tn-count :test
(not (zerop local-tn-count
)))
180 (%label
:test %label
))
182 ;;; An IR2-LVAR structure is used to annotate LVARs that are used as a
183 ;;; function result LVARs or that receive MVs.
185 (:constructor make-ir2-lvar
(primitive-type))
187 ;; If this is :DELAYED, then this is a single value LVAR for which
188 ;; the evaluation of the use is to be postponed until the evaluation
189 ;; of destination. This can be done for ref nodes or predicates
190 ;; whose destination is an IF.
192 ;; If this is :FIXED, then this LVAR has a fixed number of values,
193 ;; with the TNs in LOCS.
195 ;; If this is :UNKNOWN, then this is an unknown-values LVAR, using
196 ;; the passing locations in LOCS.
198 ;; If this is :UNUSED, then this LVAR should never actually be used
199 ;; as the destination of a value: it is only used tail-recursively.
200 (kind :fixed
:type
(member :delayed
:fixed
:unknown
:unused
))
201 ;; The primitive-type of the first value of this LVAR. This is
202 ;; primarily for internal use during LTN, but it also records the
203 ;; type restriction on delayed references. In multiple-value
204 ;; contexts, this is null to indicate that it is meaningless. This
205 ;; is always (primitive-type (lvar-type cont)), which may be more
206 ;; restrictive than the tn-primitive-type of the value TN. This is
207 ;; becase the value TN must hold any possible type that could be
208 ;; computed (before type checking.) XXX
209 (primitive-type nil
:type
(or primitive-type null
))
210 ;; Locations used to hold the values of the LVAR. If the number of
211 ;; values if fixed, then there is one TN per value. If the number of
212 ;; values is unknown, then this is a two-list of TNs holding the
213 ;; start of the values glob and the number of values. Note that
214 ;; since type checking is the responsibility of the values receiver,
215 ;; these TNs primitive type is only based on the proven type
217 (locs nil
:type list
)
218 (stack-pointer nil
:type
(or tn null
)))
220 (defprinter (ir2-lvar)
225 ;;; An IR2-COMPONENT serves mostly to accumulate non-code information
226 ;;; about the component being compiled.
227 (defstruct (ir2-component (:copier nil
))
228 ;; the counter used to allocate global TN numbers
229 (global-tn-counter 0 :type index
)
230 ;; NORMAL-TNS is the head of the list of all the normal TNs that
231 ;; need to be packed, linked through the Next slot. We place TNs on
232 ;; this list when we allocate them so that Pack can find them.
234 ;; RESTRICTED-TNS are TNs that must be packed within a finite SC. We
235 ;; pack these TNs first to ensure that the restrictions will be
236 ;; satisfied (if possible).
238 ;; WIRED-TNs are TNs that must be packed at a specific location. The
239 ;; SC and OFFSET are already filled in.
241 ;; CONSTANT-TNs are non-packed TNs that represent constants.
242 ;; :CONSTANT TNs may eventually be converted to :CACHED-CONSTANT
245 ;; FIXME: What is :CACHED-CONSTANT?
246 (normal-tns nil
:type
(or tn null
))
247 (restricted-tns nil
:type
(or tn null
))
248 (wired-tns nil
:type
(or tn null
))
249 (constant-tns nil
:type
(or tn null
))
250 ;; a list of all the :COMPONENT TNs (live throughout the component).
251 ;; These TNs will also appear in the {NORMAL,RESTRICTED,WIRED} TNs
252 ;; as appropriate to their location.
253 (component-tns () :type list
)
254 ;; If this component has a NFP, then this is it.
255 (nfp nil
:type
(or tn null
))
256 ;; a list of the explicitly specified save TNs (kind
257 ;; :SPECIFIED-SAVE). These TNs will also appear in the
258 ;; {NORMAL,RESTRICTED,WIRED} TNs as appropriate to their location.
259 (specified-save-tns () :type list
)
260 ;; a list of all the blocks whose IR2-BLOCK has a non-null value for
261 ;; POPPED. This slot is initialized by LTN-ANALYZE as an input to
263 (values-receivers nil
:type list
)
264 ;; an adjustable vector that records all the constants in the
265 ;; constant pool. A non-immediate :CONSTANT TN with offset 0 refers
266 ;; to the constant in element 0, etc. Normal constants are
267 ;; represented by the placing the CONSTANT leaf in this vector. A
268 ;; load-time constant is distinguished by being a cons (KIND .
269 ;; WHAT). KIND is a keyword indicating how the constant is computed,
270 ;; and WHAT is some context.
272 ;; These load-time constants are recognized:
274 ;; (:entry . <function>)
275 ;; Is replaced by the code pointer for the specified function.
276 ;; This is how compiled code (including DEFUN) gets its hands on
277 ;; a function. <function> is the XEP lambda for the called
278 ;; function; its LEAF-INFO should be an ENTRY-INFO structure.
280 ;; (:label . <label>)
281 ;; Is replaced with the byte offset of that label from the start
282 ;; of the code vector (including the header length.)
284 ;; A null entry in this vector is a placeholder for implementation
285 ;; overhead that is eventually stuffed in somehow.
286 (constants (make-array 10 :fill-pointer
0 :adjustable t
) :type vector
)
287 ;; some kind of info about the component's run-time representation.
288 ;; This is filled in by the VM supplied SELECT-COMPONENT-FORMAT function.
290 ;; a list of the ENTRY-INFO structures describing all of the entries
291 ;; into this component. Filled in by entry analysis.
292 (entries nil
:type list
)
293 ;; head of the list of :ALIAS TNs in this component, threaded by TN-NEXT
294 (alias-tns nil
:type
(or tn null
))
295 ;; SPILLED-VOPS is a hashtable translating from "interesting" VOPs
296 ;; to a list of the TNs spilled at that VOP. This is used when
297 ;; computing debug info so that we don't consider the TN's value to
298 ;; be valid when it is in fact somewhere else. SPILLED-TNS has T for
299 ;; every "interesting" TN that is ever spilled, providing a
300 ;; representation that is more convenient some places.
301 (spilled-vops (make-hash-table :test
'eq
) :type hash-table
)
302 (spilled-tns (make-hash-table :test
'eq
) :type hash-table
)
303 ;; dynamic vop count info. This is needed by both ir2-convert and
304 ;; setup-dynamic-count-info. (But only if we are generating code to
305 ;; collect dynamic statistics.)
307 (dyncount-info nil
:type
(or null dyncount-info
)))
309 ;;; An ENTRY-INFO condenses all the information that the dumper needs
310 ;;; to create each XEP's function entry data structure. ENTRY-INFO
311 ;;; structures are sometimes created before they are initialized,
312 ;;; since IR2 conversion may need to compile a forward reference. In
313 ;;; this case the slots aren't actually initialized until entry
315 (defstruct (entry-info (:copier nil
))
316 ;; TN, containing closure (if needed) for this function in the home
318 (closure-tn nil
:type
(or null tn
))
319 ;; a label pointing to the entry vector for this function, or NIL
320 ;; before ENTRY-ANALYZE runs
321 (offset nil
:type
(or label null
))
322 ;; If this function was defined using DEFUN, then this is the name
323 ;; of the function, a symbol or (SETF <symbol>). Otherwise, this is
324 ;; some string that is intended to be informative.
325 (name "<not computed>" :type
(or simple-string list symbol
))
326 ;; the argument list that the function was defined with.
327 (arguments nil
:type list
)
328 ;; a function type specifier representing the arguments and results
330 (type 'function
:type
(or list
(member function
)))
331 ;; xref information for the XEP
332 (xref nil
:type
(or null simple-vector
)))
334 ;;; An IR2-PHYSENV is used to annotate non-LET LAMBDAs with their
335 ;;; passing locations. It is stored in the PHYSENV-INFO.
336 (defstruct (ir2-physenv (:copier nil
))
337 ;; TN info for closed-over things within the function: an alist
338 ;; mapping from NLX-INFOs and LAMBDA-VARs to TNs holding the
339 ;; corresponding thing within this function
341 ;; Elements of this list have a one-to-one correspondence with
342 ;; elements of the PHYSENV-CLOSURE list of the PHYSENV object that
344 (closure (missing-arg) :type list
:read-only t
)
345 ;; the TNs that hold the OLD-FP and RETURN-PC within the function.
346 ;; We always save these so that the debugger can do a backtrace,
347 ;; even if the function has no return (and thus never uses them).
348 ;; Null only temporarily.
349 (old-fp nil
:type
(or tn null
))
350 (return-pc nil
:type
(or tn null
))
351 ;; The passing location for the RETURN-PC. The return PC is treated
352 ;; differently from the other arguments, since in some
353 ;; implementations we may use a call instruction that requires the
354 ;; return PC to be passed in a particular place.
355 (return-pc-pass (missing-arg) :type tn
:read-only t
)
356 ;; True if this function has a frame on the number stack. This is
357 ;; set by representation selection whenever it is possible that some
358 ;; function in our tail set will make use of the number stack.
359 (number-stack-p nil
:type boolean
)
360 ;; a list of all the :ENVIRONMENT TNs live in this environment
361 (live-tns nil
:type list
)
362 ;; a list of all the :DEBUG-ENVIRONMENT TNs live in this environment
363 (debug-live-tns nil
:type list
)
364 ;; a label that marks the start of elsewhere code for this function,
365 ;; or null until this label is assigned by codegen. Used for
366 ;; maintaining the debug source map.
367 (elsewhere-start nil
:type
(or label null
))
368 ;; a label that marks the first location in this function at which
369 ;; the environment is properly initialized, i.e. arguments moved
370 ;; from their passing locations, etc. This is the start of the
371 ;; function as far as the debugger is concerned.
372 (environment-start nil
:type
(or label null
)))
373 (defprinter (ir2-physenv)
379 ;;; A RETURN-INFO is used by GTN to represent the return strategy and
380 ;;; locations for all the functions in a given TAIL-SET. It is stored
381 ;;; in the TAIL-SET-INFO.
382 (defstruct (return-info (:copier nil
))
383 ;; The return convention used:
384 ;; -- If :UNKNOWN, we use the standard return convention.
385 ;; -- If :FIXED, we use the known-values convention.
386 (kind (missing-arg) :type
(member :fixed
:unknown
))
387 ;; the number of values returned, or :UNKNOWN if we don't know.
388 ;; COUNT may be known when KIND is :UNKNOWN, since we may choose the
389 ;; standard return convention for other reasons.
390 (count (missing-arg) :type
(or index
(member :unknown
)))
391 ;; If count isn't :UNKNOWN, then this is a list of the
392 ;; primitive-types of each value.
393 (types () :type list
)
394 ;; If kind is :FIXED, then this is the list of the TNs that we
395 ;; return the values in.
396 (locations () :type list
))
397 (defprinter (return-info)
403 (defstruct (ir2-nlx-info (:copier nil
))
404 ;; If the kind is :ENTRY (a lexical exit), then in the home
405 ;; environment, this holds a VALUE-CELL object containing the unwind
406 ;; block pointer. In the other cases nobody directly references the
407 ;; unwind-block, so we leave this slot null.
408 (home nil
:type
(or tn null
))
409 ;; the saved control stack pointer
410 (save-sp (missing-arg) :type tn
)
411 ;; the list of dynamic state save TNs
412 (dynamic-state (list* (make-stack-pointer-tn)
413 (make-dynamic-state-tns))
415 ;; the target label for NLX entry
416 (target (gen-label) :type label
))
417 (defprinter (ir2-nlx-info)
422 (defstruct (cloop (:conc-name loop-
)
424 (:constructor make-loop
)
426 ;; The kind of loop that this is. These values are legal:
429 ;; This is the outermost loop structure, and represents all the
430 ;; code in a component.
433 ;; A normal loop with only one entry.
436 ;; A segment of a "strange loop" in a non-reducible flow graph.
437 (kind (required-argument) :type
(member :outer
:natural
:strange
))
438 ;; The first and last blocks in the loop. There may be more than one tail,
439 ;; since there may be multiple back branches to the same head.
440 (head nil
:type
(or cblock null
))
441 (tail nil
:type list
)
442 ;; A list of all the blocks in this loop or its inferiors that have a
443 ;; successor outside of the loop.
444 (exits nil
:type list
)
445 ;; The loop that this loop is nested within. This is null in the outermost
447 (superior nil
:type
(or cloop null
))
448 ;; A list of the loops nested directly within this one.
449 (inferiors nil
:type list
)
450 (depth 0 :type fixnum
)
451 ;; The head of the list of blocks directly within this loop. We must recurse
452 ;; on INFERIORS to find all the blocks.
453 (blocks nil
:type
(or null cblock
)))
455 (defprinter (cloop :conc-name loop-
)
462 ;;;; VOPs and templates
464 ;;; A VOP is a Virtual Operation. It represents an operation and the
465 ;;; operands to the operation.
466 (def!struct
(vop (:constructor make-vop
(block node info args results
))
468 ;; VOP-INFO structure containing static info about the operation
469 (info nil
:type
(or vop-info null
))
470 ;; the IR2-BLOCK this VOP is in
471 (block (missing-arg) :type ir2-block
)
472 ;; VOPs evaluated after and before this one. Null at the
473 ;; beginning/end of the block, and temporarily during IR2
475 (next nil
:type
(or vop null
))
476 (prev nil
:type
(or vop null
))
477 ;; heads of the TN-REF lists for operand TNs, linked using the
479 (args nil
:type
(or tn-ref null
))
480 (results nil
:type
(or tn-ref null
))
481 ;; head of the list of write refs for each explicitly allocated
482 ;; temporary, linked together using the ACROSS slot
483 (temps nil
:type
(or tn-ref null
))
484 ;; head of the list of all TN-REFs for references in this VOP,
485 ;; linked by the NEXT-REF slot. There will be one entry for each
486 ;; operand and two (a read and a write) for each temporary.
487 (refs nil
:type
(or tn-ref null
))
488 ;; stuff that is passed uninterpreted from IR2 conversion to
489 ;; codegen. The meaning of this slot is totally dependent on the VOP.
491 ;; the node that generated this VOP, for keeping track of debug info
492 (node nil
:type
(or node null
))
493 ;; LOCAL-TN-BIT-VECTOR representing the set of TNs live after args
494 ;; are read and before results are written. This is only filled in
495 ;; when VOP-INFO-SAVE-P is non-null.
496 (save-set nil
:type
(or local-tn-bit-vector null
)))
498 (info :prin1
(vop-info-name info
))
501 (codegen-info :test codegen-info
))
503 ;;; A TN-REF object contains information about a particular reference
504 ;;; to a TN. The information in TN-REFs largely determines how TNs are
506 (def!struct
(tn-ref (:constructor make-tn-ref
(tn write-p
))
509 (tn (missing-arg) :type tn
)
510 ;; Is this is a write reference? (as opposed to a read reference)
511 (write-p nil
:type boolean
)
512 ;; the link for a list running through all TN-REFs for this TN of
513 ;; the same kind (read or write)
514 (next nil
:type
(or tn-ref null
))
515 ;; the VOP where the reference happens, or NIL temporarily
516 (vop nil
:type
(or vop null
))
517 ;; the link for a list of all TN-REFs in VOP, in reverse order of
519 (next-ref nil
:type
(or tn-ref null
))
520 ;; the link for a list of the TN-REFs in VOP of the same kind
521 ;; (argument, result, temp)
522 (across nil
:type
(or tn-ref null
))
523 ;; If true, this is a TN-REF also in VOP whose TN we would like
524 ;; packed in the same location as our TN. Read and write refs are
525 ;; always paired: TARGET in the read points to the write, and
527 (target nil
:type
(or null tn-ref
))
528 ;; the load TN allocated for this operand, if any
529 (load-tn nil
:type
(or tn null
)))
533 (vop :test vop
:prin1
(vop-info-name (vop-info vop
))))
535 ;;; A TEMPLATE object represents a particular IR2 coding strategy for
536 ;;; a known function.
537 (def!struct
(template (:constructor nil
)
538 #-sb-xc-host
(:pure t
))
539 ;; the symbol name of this VOP. This is used when printing the VOP
540 ;; and is also used to provide a handle for definition and
542 (name nil
:type symbol
)
543 ;; the arg/result type restrictions. We compute this from the
544 ;; PRIMITIVE-TYPE restrictions to make life easier for IR1 phases
545 ;; that need to anticipate LTN's template selection.
546 (type (missing-arg) :type ctype
)
547 ;; lists of restrictions on the argument and result types. A
548 ;; restriction may take several forms:
549 ;; -- The restriction * is no restriction at all.
550 ;; -- A restriction (:OR <primitive-type>*) means that the operand
551 ;; must have one of the specified primitive types.
552 ;; -- A restriction (:CONSTANT <predicate> <type-spec>) means that the
553 ;; argument (not a result) must be a compile-time constant that
554 ;; satisfies the specified predicate function. In this case, the
555 ;; constant value will be passed as an info argument rather than
556 ;; as a normal argument. <type-spec> is a Lisp type specifier for
557 ;; the type tested by the predicate, used when we want to represent
558 ;; the type constraint as a Lisp function type.
560 ;; If RESULT-TYPES is :CONDITIONAL, then this is an IF-FOO style
561 ;; conditional that yields its result as a control transfer. The
562 ;; emit function takes two info arguments: the target label and a
563 ;; boolean flag indicating whether to negate the sense of the test.
564 (arg-types nil
:type list
)
565 (result-types nil
:type
(or list
(member :conditional
)))
566 ;; the primitive type restriction applied to each extra argument or
567 ;; result following the fixed operands. If NIL, no extra
568 ;; args/results are allowed. Otherwise, either * or a (:OR ...) list
569 ;; as described for the {ARG,RESULT}-TYPES.
570 (more-args-type nil
:type
(or (member nil
*) cons
))
571 (more-results-type nil
:type
(or (member nil
*) cons
))
572 ;; If true, this is a function that is called with no arguments to
573 ;; see whether this template can be emitted. This is used to
574 ;; conditionally compile for different target hardware
575 ;; configuarations (e.g. FP hardware.)
576 (guard nil
:type
(or function null
))
577 ;; the policy under which this template is the best translation.
578 ;; Note that LTN might use this template under other policies if it
579 ;; can't figure out anything better to do.
580 (ltn-policy (missing-arg) :type ltn-policy
)
581 ;; the base cost for this template, given optimistic assumptions
582 ;; such as no operand loading, etc.
583 (cost (missing-arg) :type index
)
584 ;; If true, then this is a short noun-like phrase describing what
585 ;; this VOP "does", i.e. the implementation strategy. This is for
586 ;; use in efficiency notes.
587 (note nil
:type
(or string null
))
588 ;; the number of trailing arguments to VOP or %PRIMITIVE that we
589 ;; bundle into a list and pass into the emit function. This provides
590 ;; a way to pass uninterpreted stuff directly to the code generator.
591 (info-arg-count 0 :type index
)
592 ;; a function that emits the VOPs for this template. Arguments:
593 ;; 1] Node for source context.
594 ;; 2] IR2-BLOCK that we place the VOP in.
595 ;; 3] This structure.
596 ;; 4] Head of argument TN-REF list.
597 ;; 5] Head of result TN-REF list.
598 ;; 6] If INFO-ARG-COUNT is non-zero, then a list of the magic
601 ;; Two values are returned: the first and last VOP emitted. This vop
602 ;; sequence must be linked into the VOP Next/Prev chain for the
603 ;; block. At least one VOP is always emitted.
604 (emit-function (missing-arg) :type function
))
605 (defprinter (template)
609 (more-args-type :test more-args-type
:prin1 more-args-type
)
610 (more-results-type :test more-results-type
:prin1 more-results-type
)
614 (info-arg-count :test
(not (zerop info-arg-count
))))
616 ;;; A VOP-INFO object holds the constant information for a given
617 ;;; virtual operation. We include TEMPLATE so that functions with a
618 ;;; direct VOP equivalent can be translated easily.
619 (def!struct
(vop-info
621 (:make-load-form-fun ignore-it
))
622 ;; side effects of this VOP and side effects that affect the value
624 (effects (missing-arg) :type attributes
)
625 (affected (missing-arg) :type attributes
)
626 ;; If true, causes special casing of TNs live after this VOP that
628 ;; -- If T, all such TNs that are allocated in a SC with a defined
629 ;; save-sc will be saved in a TN in the save SC before the VOP
630 ;; and restored after the VOP. This is used by call VOPs. A bit
631 ;; vector representing the live TNs is stored in the VOP-SAVE-SET.
632 ;; -- If :FORCE-TO-STACK, all such TNs will made into :ENVIRONMENT TNs
633 ;; and forced to be allocated in SCs without any save-sc. This is
634 ;; used by NLX entry vops.
635 ;; -- If :COMPUTE-ONLY, just compute the save set, don't do any saving.
636 ;; This is used to get the live variables for debug info.
637 (save-p nil
:type
(member t nil
:force-to-stack
:compute-only
))
638 ;; info for automatic emission of move-arg VOPs by representation
639 ;; selection. If NIL, then do nothing special. If non-null, then
640 ;; there must be a more arg. Each more arg is moved to its passing
641 ;; location using the appropriate representation-specific MOVE-ARG
642 ;; VOP. The first (fixed) argument must be the control-stack frame
643 ;; pointer for the frame to move into. The first info arg is the
644 ;; list of passing locations.
646 ;; Additional constraints depend on the value:
652 ;; The second (fixed) arg is the NFP for the called function (from
656 ;; If needed, the old NFP is computed using COMPUTE-OLD-NFP.
657 (move-args nil
:type
(member nil
:full-call
:local-call
:known-return
))
658 ;; a list of sc-vectors representing the loading costs of each fixed
659 ;; argument and result
660 (arg-costs nil
:type list
)
661 (result-costs nil
:type list
)
662 ;; if true, SC-VECTORs representing the loading costs for any more
664 (more-arg-costs nil
:type
(or sc-vector null
))
665 (more-result-costs nil
:type
(or sc-vector null
))
666 ;; lists of SC-VECTORs mapping each SC to the SCs that we can load
667 ;; into. If a SC is directly acceptable to the VOP, then the entry
668 ;; is T. Otherwise, it is a list of the SC numbers of all the SCs
669 ;; that we can load into. This list will be empty if there is no
670 ;; load function which loads from that SC to an SC allowed by the
671 ;; operand SC restriction.
672 (arg-load-scs nil
:type list
)
673 (result-load-scs nil
:type list
)
674 ;; if true, a function that is called with the VOP to do operand
675 ;; targeting. This is done by modifying the TN-REF-TARGET slots in
676 ;; the TN-REFS so that they point to other TN-REFS in the same VOP.
677 (target-fun nil
:type
(or null function
))
678 ;; a function that emits assembly code for a use of this VOP when it
679 ;; is called with the VOP structure. This is null if this VOP has no
680 ;; specified generator (i.e. if it exists only to be inherited by
682 (generator-function nil
:type
(or function null
))
683 ;; a list of things that are used to parameterize an inherited
684 ;; generator. This allows the same generator function to be used for
685 ;; a group of VOPs with similar implementations.
686 (variant nil
:type list
)
687 ;; the number of arguments and results. Each regular arg/result
688 ;; counts as one, and all the more args/results together count as 1.
689 (num-args 0 :type index
)
690 (num-results 0 :type index
)
691 ;; a vector of the temporaries the vop needs. See EMIT-GENERIC-VOP
692 ;; in vmdef for information on how the temps are encoded.
693 (temps nil
:type
(or null
(specializable-vector (unsigned-byte 16))))
694 ;; the order all the refs for this vop should be put in. Each
695 ;; operand is assigned a number in the following ordering: args,
696 ;; more-args, results, more-results, temps. This vector represents
697 ;; the order the operands should be put into in the next-ref link.
698 (ref-ordering nil
:type
(or null
(specializable-vector (unsigned-byte 8))))
699 ;; a vector of the various targets that should be done. Each element
700 ;; encodes the source ref (shifted 8, it is also encoded in
701 ;; MAX-VOP-TN-REFS) and the dest ref index.
702 (targets nil
:type
(or null
(specializable-vector (unsigned-byte 16)))))
706 ;;; copied from docs/internals/retargeting.tex by WHN 19990707:
708 ;;; A Storage Base represents a physical storage resource such as a
709 ;;; register set or stack frame. Storage bases for non-global
710 ;;; resources such as the stack are relativized by the environment
711 ;;; that the TN is allocated in. Packing conflict information is kept
712 ;;; in the storage base, but non-packed storage resources such as
713 ;;; closure environments also have storage bases.
715 ;;; Some storage bases:
716 ;;; General purpose registers
717 ;;; Floating point registers
718 ;;; Boxed (control) stack environment
719 ;;; Unboxed (number) stack environment
720 ;;; Closure environment
722 ;;; A storage class is a potentially arbitrary set of the elements in
723 ;;; a storage base. Although conceptually there may be a hierarchy of
724 ;;; storage classes such as "all registers", "boxed registers", "boxed
725 ;;; scratch registers", this doesn't exist at the implementation
726 ;;; level. Such things can be done by specifying storage classes whose
727 ;;; locations overlap. A TN shouldn't have lots of overlapping SC's as
728 ;;; legal SC's, since time would be wasted repeatedly attempting to
729 ;;; pack in the same locations.
734 ;;; Reg: any register (immediate objects)
735 ;;; Save-Reg: a boxed register near r15 (registers easily saved in a call)
736 ;;; Boxed-Reg: any boxed register (any boxed object)
737 ;;; Unboxed-Reg: any unboxed register (any unboxed object)
738 ;;; Float-Reg, Double-Float-Reg: float in FP register.
739 ;;; Stack: boxed object on the stack (on control stack)
740 ;;; Word: any 32bit unboxed object on nstack.
741 ;;; Double: any 64bit unboxed object on nstack.
743 ;;; The SB structure represents the global information associated with
745 (def!struct
(sb (:make-load-form-fun just-dump-it-normally
))
746 ;; name, for printing and reference
747 (name nil
:type symbol
)
748 ;; the kind of storage base (which determines the packing
750 (kind :non-packed
:type
(member :finite
:unbounded
:non-packed
))
751 ;; the number of elements in the SB. If finite, this is the total
752 ;; size. If unbounded, this is the size that the SB is initially
754 (size 0 :type index
))
758 ;;; A FINITE-SB holds information needed by the packing algorithm for
760 (def!struct
(finite-sb (:include sb
))
761 ;; the number of locations currently allocated in this SB
762 (current-size 0 :type index
)
763 ;; the last location packed in, used by pack to scatter TNs to
764 ;; prevent a few locations from getting all the TNs, and thus
765 ;; getting overcrowded, reducing the possibilities for targeting.
766 (last-offset 0 :type index
)
767 ;; a vector containing, for each location in this SB, a vector
768 ;; indexed by IR2 block numbers, holding local conflict bit vectors.
769 ;; A TN must not be packed in a given location within a particular
770 ;; block if the LTN number for that TN in that block corresponds to
771 ;; a set bit in the bit-vector.
772 (conflicts '#() :type simple-vector
)
773 ;; a vector containing, for each location in this SB, a bit-vector
774 ;; indexed by IR2 block numbers. If the bit corresponding to a block
775 ;; is set, then the location is in use somewhere in the block, and
776 ;; thus has a conflict for always-live TNs.
777 (always-live '#() :type simple-vector
)
778 (always-live-count '#() :type simple-vector
)
779 ;; a vector containing the TN currently live in each location in the
780 ;; SB, or NIL if the location is unused. This is used during load-tn pack.
781 (live-tns '#() :type simple-vector
)
782 ;; the number of blocks for which the ALWAYS-LIVE and CONFLICTS
783 ;; might not be virgin, and thus must be reinitialized when PACK
784 ;; starts. Less then the length of those vectors when not all of the
785 ;; length was used on the previously packed component.
786 (last-block-count 0 :type index
))
788 ;;; the SC structure holds the storage base that storage is allocated
789 ;;; in and information used to select locations within the SB
790 (def!struct
(sc (:copier nil
))
791 ;; name, for printing and reference
792 (name nil
:type symbol
)
793 ;; the number used to index SC cost vectors
794 (number 0 :type sc-number
)
795 ;; the storage base that this SC allocates storage from
796 (sb nil
:type
(or sb null
))
797 ;; the size of elements in this SC, in units of locations in the SB
798 (element-size 0 :type index
)
799 ;; if our SB is finite, a list of the locations in this SC
800 (locations nil
:type list
)
801 ;; a list of the alternate (save) SCs for this SC
802 (alternate-scs nil
:type list
)
803 ;; a list of the constant SCs that can me moved into this SC
804 (constant-scs nil
:type list
)
805 ;; true if the values in this SC needs to be saved across calls
806 (save-p nil
:type boolean
)
807 ;; vectors mapping from SC numbers to information about how to load
808 ;; from the index SC to this one. MOVE-FUNS holds the names of
809 ;; the functions used to do loading, and LOAD-COSTS holds the cost
810 ;; of the corresponding move functions. If loading is impossible,
811 ;; then the entries are NIL. LOAD-COSTS is initialized to have a 0
813 (move-funs (make-array sc-number-limit
:initial-element nil
)
815 (load-costs (make-array sc-number-limit
:initial-element nil
)
817 ;; a vector mapping from SC numbers to possibly
818 ;; representation-specific move and coerce VOPs. Each entry is a
819 ;; list of VOP-INFOs for VOPs that move/coerce an object in the
820 ;; index SC's representation into this SC's representation. This
821 ;; vector is filled out with entries for all SCs that can somehow be
822 ;; coerced into this SC, not just those VOPs defined to directly
823 ;; move into this SC (i.e. it allows for operand loading on the move
826 ;; When there are multiple applicable VOPs, the template arg and
827 ;; result type restrictions are used to determine which one to use.
828 ;; The list is sorted by increasing cost, so the first applicable
829 ;; VOP should be used.
831 ;; Move (or move-arg) VOPs with descriptor results shouldn't have
832 ;; TNs wired in the standard argument registers, since there may
833 ;; already be live TNs wired in those locations holding the values
834 ;; that we are setting up for unknown-values return.
835 (move-vops (make-array sc-number-limit
:initial-element nil
)
837 ;; the costs corresponding to the MOVE-VOPS. Separate because this
838 ;; info is needed at meta-compile time, while the MOVE-VOPs don't
839 ;; exist till load time. If no move is defined, then the entry is
841 (move-costs (make-array sc-number-limit
:initial-element nil
)
843 ;; similar to Move-VOPs, except that we only ever use the entries
844 ;; for this SC and its alternates, since we never combine complex
845 ;; representation conversion with argument passing.
846 (move-arg-vops (make-array sc-number-limit
:initial-element nil
)
848 ;; true if this SC or one of its alternates in in the NUMBER-STACK SB.
849 (number-stack-p nil
:type boolean
)
850 ;; alignment restriction. The offset must be an even multiple of this.
851 (alignment 1 :type
(and index
(integer 1)))
852 ;; a list of locations that we avoid packing in during normal
853 ;; register allocation to ensure that these locations will be free
854 ;; for operand loading. This prevents load-TN packing from thrashing
855 ;; by spilling a lot.
856 (reserve-locations nil
:type list
))
862 (def!struct
(tn (:include sset-element
)
863 (:constructor make-random-tn
)
864 (:constructor make-tn
(number kind primitive-type sc
))
866 ;; The kind of TN this is:
869 ;; A normal, non-constant TN, representing a variable or temporary.
870 ;; Lifetime information is computed so that packing can be done.
873 ;; A TN that has hidden references (debugger or NLX), and thus must be
874 ;; allocated for the duration of the environment it is referenced in.
876 ;; :DEBUG-ENVIRONMENT
877 ;; Like :ENVIRONMENT, but is used for TNs that we want to be able to
878 ;; target to/from and that don't absolutely have to be live
879 ;; everywhere. These TNs are live in all blocks in the environment
880 ;; that don't reference this TN.
883 ;; A TN that implicitly conflicts with all other TNs. No conflict
888 ;; A TN used for saving a :NORMAL TN across function calls. The
889 ;; lifetime information slots are unitialized: get the original
890 ;; TN our of the SAVE-TN slot and use it for conflicts. SAVE-ONCE
891 ;; is like :SAVE, except that it is only save once at the single
892 ;; writer of the original TN.
895 ;; A TN that was explicitly specified as the save TN for another TN.
896 ;; When we actually get around to doing the saving, this will be
897 ;; changed to :SAVE or :SAVE-ONCE.
900 ;; A load-TN used to compute an argument or result that is
901 ;; restricted to some finite SB. Load TNs don't have any conflict
902 ;; information. Load TN pack uses a special local conflict
903 ;; determination method.
906 ;; Represents a constant, with TN-LEAF a CONSTANT leaf. Lifetime
907 ;; information isn't computed, since the value isn't allocated by
908 ;; pack, but is instead generated as a load at each use. Since
909 ;; lifetime analysis isn't done on :CONSTANT TNs, they don't have
910 ;; LOCAL-NUMBERs and similar stuff.
913 ;; A special kind of TN used to represent initialization of local
914 ;; call arguments in the caller. It provides another name for the
915 ;; argument TN so that lifetime analysis doesn't get confused by
916 ;; self-recursive calls. Lifetime analysis treats this the same
917 ;; as :NORMAL, but then at the end merges the conflict info into
918 ;; the original TN and replaces all uses of the alias with the
919 ;; original TN. SAVE-TN holds the aliased TN.
921 :type
(member :normal
:environment
:debug-environment
922 :save
:save-once
:specified-save
:load
:constant
924 ;; the primitive-type for this TN's value. Null in restricted or
926 (primitive-type nil
:type
(or primitive-type null
))
927 ;; If this TN represents a variable or constant, then this is the
928 ;; corresponding LEAF.
929 (leaf nil
:type
(or leaf null
))
930 ;; thread that links TNs together so that we can find them
931 (next nil
:type
(or tn null
))
932 ;; head of TN-REF lists for reads and writes of this TN
933 (reads nil
:type
(or tn-ref null
))
934 (writes nil
:type
(or tn-ref null
))
935 ;; a link we use when building various temporary TN lists
936 (next* nil
:type
(or tn null
))
937 ;; some block that contains a reference to this TN, or NIL if we
938 ;; haven't seen any reference yet. If the TN is local, then this is
939 ;; the block it is local to.
940 (local nil
:type
(or ir2-block null
))
941 ;; If a local TN, the block relative number for this TN. Global TNs
942 ;; whose liveness changes within a block are also assigned a local
943 ;; number during the conflicts analysis of that block. If the TN has
944 ;; no local number within the block, then this is NIL.
945 (local-number nil
:type
(or local-tn-number null
))
946 ;; If this object is a local TN, this slot is a bit-vector with 1
947 ;; for the local-number of every TN that we conflict with.
948 (local-conflicts (make-array local-tn-limit
951 :type local-tn-bit-vector
)
952 ;; head of the list of GLOBAL-CONFLICTS structures for a global TN.
953 ;; This list is sorted by block number (i.e. reverse DFO), allowing
954 ;; the intersection between the lifetimes for two global TNs to be
955 ;; easily found. If null, then this TN is a local TN.
956 (global-conflicts nil
:type
(or global-conflicts null
))
957 ;; During lifetime analysis, this is used as a pointer into the
958 ;; conflicts chain, for scanning through blocks in reverse DFO.
959 (current-conflict nil
)
960 ;; In a :SAVE TN, this is the TN saved. In a :NORMAL or :ENVIRONMENT
961 ;; TN, this is the associated save TN. In TNs with no save TN, this
963 (save-tn nil
:type
(or tn null
))
964 ;; After pack, the SC we packed into. Beforehand, the SC we want to
965 ;; pack into, or null if we don't know.
966 (sc nil
:type
(or sc null
))
967 ;; the offset within the SB that this TN is packed into. This is what
968 ;; indicates that the TN is packed
969 (offset nil
:type
(or index null
))
970 ;; some kind of info about how important this TN is
971 (cost 0 :type fixnum
)
972 ;; If a :ENVIRONMENT or :DEBUG-ENVIRONMENT TN, this is the
973 ;; physical environment that the TN is live throughout.
974 (physenv nil
:type
(or physenv null
))
975 ;; The depth of the deepest loop that this TN is used in.
976 (loop-depth 0 :type fixnum
))
977 (def!method print-object
((tn tn
) stream
)
978 (print-unreadable-object (tn stream
:type t
)
979 ;; KLUDGE: The distinction between PRINT-TN and PRINT-OBJECT on TN is
980 ;; not very mnemonic. -- WHN 20000124
981 (print-tn-guts tn stream
)))
983 ;;; The GLOBAL-CONFLICTS structure represents the conflicts for global
984 ;;; TNs. Each global TN has a list of these structures, one for each
985 ;;; block that it is live in. In addition to repsenting the result of
986 ;;; lifetime analysis, the global conflicts structure is used during
987 ;;; lifetime analysis to represent the set of TNs live at the start of
989 (defstruct (global-conflicts
990 (:constructor make-global-conflicts
(kind tn block number
))
992 ;; the IR2-BLOCK that this structure represents the conflicts for
993 (block (missing-arg) :type ir2-block
)
994 ;; thread running through all the GLOBAL-CONFLICTSs for BLOCK. This
995 ;; thread is sorted by TN number
996 (next-blockwise nil
:type
(or global-conflicts null
))
997 ;; the way that TN is used by BLOCK
1000 ;; The TN is read before it is written. It starts the block live,
1001 ;; but is written within the block.
1004 ;; The TN is written before any read. It starts the block dead,
1005 ;; and need not have a read within the block.
1008 ;; The TN is read, but never written. It starts the block live,
1009 ;; and is not killed by the block. Lifetime analysis will promote
1010 ;; :READ-ONLY TNs to :LIVE if they are live at the block end.
1013 ;; The TN is not referenced. It is live everywhere in the block.
1014 (kind :read-only
:type
(member :read
:write
:read-only
:live
))
1015 ;; a local conflicts vector representing conflicts with TNs live in
1016 ;; BLOCK. The index for the local TN number of each TN we conflict
1017 ;; with in this block is 1. To find the full conflict set, the :LIVE
1018 ;; TNs for BLOCK must also be included. This slot is not meaningful
1019 ;; when KIND is :LIVE.
1020 (conflicts (make-array local-tn-limit
1023 :type local-tn-bit-vector
)
1024 ;; the TN we are recording conflicts for.
1025 (tn (missing-arg) :type tn
)
1026 ;; thread through all the GLOBAL-CONFLICTSs for TN
1027 (next-tnwise nil
:type
(or global-conflicts null
))
1028 ;; TN's local TN number in BLOCK. :LIVE TNs don't have local numbers.
1029 (number nil
:type
(or local-tn-number null
)))
1030 (defprinter (global-conflicts)
1034 (number :test number
))