3 * Copyright (C) 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
4 * 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009 by Larry Wall
7 * You may distribute under the terms of either the GNU General Public
8 * License or the Artistic License, as specified in the README file.
13 * 'I wonder what the Entish is for "yes" and "no",' he thought.
16 * [p.480 of _The Lord of the Rings_, III/iv: "Treebeard"]
22 * This file contains the code that creates, manipulates and destroys
23 * scalar values (SVs). The other types (AV, HV, GV, etc.) reuse the
24 * structure of an SV, so their creation and destruction is handled
25 * here; higher-level functions are in av.c, hv.c, and so on. Opcode
26 * level functions (eg. substr, split, join) for each of the types are
39 /* Missing proto on LynxOS */
40 char *gconvert(double, int, int, char *);
44 # define SNPRINTF_G(nv, buffer, size, ndig) \
45 quadmath_snprintf(buffer, size, "%.*Qg", (int)ndig, (NV)(nv))
47 # define SNPRINTF_G(nv, buffer, size, ndig) \
48 PERL_UNUSED_RESULT(Gconvert((NV)(nv), (int)ndig, 0, buffer))
51 #ifndef SV_COW_THRESHOLD
52 # define SV_COW_THRESHOLD 0 /* COW iff len > K */
54 #ifndef SV_COWBUF_THRESHOLD
55 # define SV_COWBUF_THRESHOLD 1250 /* COW iff len > K */
57 #ifndef SV_COW_MAX_WASTE_THRESHOLD
58 # define SV_COW_MAX_WASTE_THRESHOLD 80 /* COW iff (len - cur) < K */
60 #ifndef SV_COWBUF_WASTE_THRESHOLD
61 # define SV_COWBUF_WASTE_THRESHOLD 80 /* COW iff (len - cur) < K */
63 #ifndef SV_COW_MAX_WASTE_FACTOR_THRESHOLD
64 # define SV_COW_MAX_WASTE_FACTOR_THRESHOLD 2 /* COW iff len < (cur * K) */
66 #ifndef SV_COWBUF_WASTE_FACTOR_THRESHOLD
67 # define SV_COWBUF_WASTE_FACTOR_THRESHOLD 2 /* COW iff len < (cur * K) */
69 /* Work around compiler warnings about unsigned >= THRESHOLD when thres-
72 # define GE_COW_THRESHOLD(cur) ((cur) >= SV_COW_THRESHOLD)
74 # define GE_COW_THRESHOLD(cur) 1
76 #if SV_COWBUF_THRESHOLD
77 # define GE_COWBUF_THRESHOLD(cur) ((cur) >= SV_COWBUF_THRESHOLD)
79 # define GE_COWBUF_THRESHOLD(cur) 1
81 #if SV_COW_MAX_WASTE_THRESHOLD
82 # define GE_COW_MAX_WASTE_THRESHOLD(cur,len) (((len)-(cur)) < SV_COW_MAX_WASTE_THRESHOLD)
84 # define GE_COW_MAX_WASTE_THRESHOLD(cur,len) 1
86 #if SV_COWBUF_WASTE_THRESHOLD
87 # define GE_COWBUF_WASTE_THRESHOLD(cur,len) (((len)-(cur)) < SV_COWBUF_WASTE_THRESHOLD)
89 # define GE_COWBUF_WASTE_THRESHOLD(cur,len) 1
91 #if SV_COW_MAX_WASTE_FACTOR_THRESHOLD
92 # define GE_COW_MAX_WASTE_FACTOR_THRESHOLD(cur,len) ((len) < SV_COW_MAX_WASTE_FACTOR_THRESHOLD * (cur))
94 # define GE_COW_MAX_WASTE_FACTOR_THRESHOLD(cur,len) 1
96 #if SV_COWBUF_WASTE_FACTOR_THRESHOLD
97 # define GE_COWBUF_WASTE_FACTOR_THRESHOLD(cur,len) ((len) < SV_COWBUF_WASTE_FACTOR_THRESHOLD * (cur))
99 # define GE_COWBUF_WASTE_FACTOR_THRESHOLD(cur,len) 1
102 #define CHECK_COW_THRESHOLD(cur,len) (\
103 GE_COW_THRESHOLD((cur)) && \
104 GE_COW_MAX_WASTE_THRESHOLD((cur),(len)) && \
105 GE_COW_MAX_WASTE_FACTOR_THRESHOLD((cur),(len)) \
107 #define CHECK_COWBUF_THRESHOLD(cur,len) (\
108 GE_COWBUF_THRESHOLD((cur)) && \
109 GE_COWBUF_WASTE_THRESHOLD((cur),(len)) && \
110 GE_COWBUF_WASTE_FACTOR_THRESHOLD((cur),(len)) \
113 #ifdef PERL_UTF8_CACHE_ASSERT
114 /* if adding more checks watch out for the following tests:
115 * t/op/index.t t/op/length.t t/op/pat.t t/op/substr.t
116 * lib/utf8.t lib/Unicode/Collate/t/index.t
119 # define ASSERT_UTF8_CACHE(cache) \
120 STMT_START { if (cache) { assert((cache)[0] <= (cache)[1]); \
121 assert((cache)[2] <= (cache)[3]); \
122 assert((cache)[3] <= (cache)[1]);} \
125 # define ASSERT_UTF8_CACHE(cache) NOOP
128 #ifdef PERL_OLD_COPY_ON_WRITE
129 #define SV_COW_NEXT_SV(sv) INT2PTR(SV *,SvUVX(sv))
130 #define SV_COW_NEXT_SV_SET(current,next) SvUV_set(current, PTR2UV(next))
133 /* ============================================================================
135 =head1 Allocation and deallocation of SVs.
136 An SV (or AV, HV, etc.) is allocated in two parts: the head (struct
137 sv, av, hv...) contains type and reference count information, and for
138 many types, a pointer to the body (struct xrv, xpv, xpviv...), which
139 contains fields specific to each type. Some types store all they need
140 in the head, so don't have a body.
142 In all but the most memory-paranoid configurations (ex: PURIFY), heads
143 and bodies are allocated out of arenas, which by default are
144 approximately 4K chunks of memory parcelled up into N heads or bodies.
145 Sv-bodies are allocated by their sv-type, guaranteeing size
146 consistency needed to allocate safely from arrays.
148 For SV-heads, the first slot in each arena is reserved, and holds a
149 link to the next arena, some flags, and a note of the number of slots.
150 Snaked through each arena chain is a linked list of free items; when
151 this becomes empty, an extra arena is allocated and divided up into N
152 items which are threaded into the free list.
154 SV-bodies are similar, but they use arena-sets by default, which
155 separate the link and info from the arena itself, and reclaim the 1st
156 slot in the arena. SV-bodies are further described later.
158 The following global variables are associated with arenas:
160 PL_sv_arenaroot pointer to list of SV arenas
161 PL_sv_root pointer to list of free SV structures
163 PL_body_arenas head of linked-list of body arenas
164 PL_body_roots[] array of pointers to list of free bodies of svtype
165 arrays are indexed by the svtype needed
167 A few special SV heads are not allocated from an arena, but are
168 instead directly created in the interpreter structure, eg PL_sv_undef.
169 The size of arenas can be changed from the default by setting
170 PERL_ARENA_SIZE appropriately at compile time.
172 The SV arena serves the secondary purpose of allowing still-live SVs
173 to be located and destroyed during final cleanup.
175 At the lowest level, the macros new_SV() and del_SV() grab and free
176 an SV head. (If debugging with -DD, del_SV() calls the function S_del_sv()
177 to return the SV to the free list with error checking.) new_SV() calls
178 more_sv() / sv_add_arena() to add an extra arena if the free list is empty.
179 SVs in the free list have their SvTYPE field set to all ones.
181 At the time of very final cleanup, sv_free_arenas() is called from
182 perl_destruct() to physically free all the arenas allocated since the
183 start of the interpreter.
185 The function visit() scans the SV arenas list, and calls a specified
186 function for each SV it finds which is still live - ie which has an SvTYPE
187 other than all 1's, and a non-zero SvREFCNT. visit() is used by the
188 following functions (specified as [function that calls visit()] / [function
189 called by visit() for each SV]):
191 sv_report_used() / do_report_used()
192 dump all remaining SVs (debugging aid)
194 sv_clean_objs() / do_clean_objs(),do_clean_named_objs(),
195 do_clean_named_io_objs(),do_curse()
196 Attempt to free all objects pointed to by RVs,
197 try to do the same for all objects indir-
198 ectly referenced by typeglobs too, and
199 then do a final sweep, cursing any
200 objects that remain. Called once from
201 perl_destruct(), prior to calling sv_clean_all()
204 sv_clean_all() / do_clean_all()
205 SvREFCNT_dec(sv) each remaining SV, possibly
206 triggering an sv_free(). It also sets the
207 SVf_BREAK flag on the SV to indicate that the
208 refcnt has been artificially lowered, and thus
209 stopping sv_free() from giving spurious warnings
210 about SVs which unexpectedly have a refcnt
211 of zero. called repeatedly from perl_destruct()
212 until there are no SVs left.
214 =head2 Arena allocator API Summary
216 Private API to rest of sv.c
220 new_XPVNV(), del_XPVGV(),
225 sv_report_used(), sv_clean_objs(), sv_clean_all(), sv_free_arenas()
229 * ========================================================================= */
232 * "A time to plant, and a time to uproot what was planted..."
236 # define MEM_LOG_NEW_SV(sv, file, line, func) \
237 Perl_mem_log_new_sv(sv, file, line, func)
238 # define MEM_LOG_DEL_SV(sv, file, line, func) \
239 Perl_mem_log_del_sv(sv, file, line, func)
241 # define MEM_LOG_NEW_SV(sv, file, line, func) NOOP
242 # define MEM_LOG_DEL_SV(sv, file, line, func) NOOP
245 #ifdef DEBUG_LEAKING_SCALARS
246 # define FREE_SV_DEBUG_FILE(sv) STMT_START { \
247 if ((sv)->sv_debug_file) PerlMemShared_free((sv)->sv_debug_file); \
249 # define DEBUG_SV_SERIAL(sv) \
250 DEBUG_m(PerlIO_printf(Perl_debug_log, "0x%"UVxf": (%05ld) del_SV\n", \
251 PTR2UV(sv), (long)(sv)->sv_debug_serial))
253 # define FREE_SV_DEBUG_FILE(sv)
254 # define DEBUG_SV_SERIAL(sv) NOOP
258 # define SvARENA_CHAIN(sv) ((sv)->sv_u.svu_rv)
259 # define SvARENA_CHAIN_SET(sv,val) (sv)->sv_u.svu_rv = MUTABLE_SV((val))
260 /* Whilst I'd love to do this, it seems that things like to check on
262 # define POISON_SV_HEAD(sv) PoisonNew(sv, 1, struct STRUCT_SV)
264 # define POISON_SV_HEAD(sv) PoisonNew(&SvANY(sv), 1, void *), \
265 PoisonNew(&SvREFCNT(sv), 1, U32)
267 # define SvARENA_CHAIN(sv) SvANY(sv)
268 # define SvARENA_CHAIN_SET(sv,val) SvANY(sv) = (void *)(val)
269 # define POISON_SV_HEAD(sv)
272 /* Mark an SV head as unused, and add to free list.
274 * If SVf_BREAK is set, skip adding it to the free list, as this SV had
275 * its refcount artificially decremented during global destruction, so
276 * there may be dangling pointers to it. The last thing we want in that
277 * case is for it to be reused. */
279 #define plant_SV(p) \
281 const U32 old_flags = SvFLAGS(p); \
282 MEM_LOG_DEL_SV(p, __FILE__, __LINE__, FUNCTION__); \
283 DEBUG_SV_SERIAL(p); \
284 FREE_SV_DEBUG_FILE(p); \
286 SvFLAGS(p) = SVTYPEMASK; \
287 if (!(old_flags & SVf_BREAK)) { \
288 SvARENA_CHAIN_SET(p, PL_sv_root); \
294 #define uproot_SV(p) \
297 PL_sv_root = MUTABLE_SV(SvARENA_CHAIN(p)); \
302 /* make some more SVs by adding another arena */
308 char *chunk; /* must use New here to match call to */
309 Newx(chunk,PERL_ARENA_SIZE,char); /* Safefree() in sv_free_arenas() */
310 sv_add_arena(chunk, PERL_ARENA_SIZE, 0);
315 /* new_SV(): return a new, empty SV head */
317 #ifdef DEBUG_LEAKING_SCALARS
318 /* provide a real function for a debugger to play with */
320 S_new_SV(pTHX_ const char *file, int line, const char *func)
327 sv = S_more_sv(aTHX);
331 sv->sv_debug_optype = PL_op ? PL_op->op_type : 0;
332 sv->sv_debug_line = (U16) (PL_parser && PL_parser->copline != NOLINE
338 sv->sv_debug_inpad = 0;
339 sv->sv_debug_parent = NULL;
340 sv->sv_debug_file = PL_curcop ? savesharedpv(CopFILE(PL_curcop)): NULL;
342 sv->sv_debug_serial = PL_sv_serial++;
344 MEM_LOG_NEW_SV(sv, file, line, func);
345 DEBUG_m(PerlIO_printf(Perl_debug_log, "0x%"UVxf": (%05ld) new_SV (from %s:%d [%s])\n",
346 PTR2UV(sv), (long)sv->sv_debug_serial, file, line, func));
350 # define new_SV(p) (p)=S_new_SV(aTHX_ __FILE__, __LINE__, FUNCTION__)
358 (p) = S_more_sv(aTHX); \
362 MEM_LOG_NEW_SV(p, __FILE__, __LINE__, FUNCTION__); \
367 /* del_SV(): return an empty SV head to the free list */
380 S_del_sv(pTHX_ SV *p)
382 PERL_ARGS_ASSERT_DEL_SV;
387 for (sva = PL_sv_arenaroot; sva; sva = MUTABLE_SV(SvANY(sva))) {
388 const SV * const sv = sva + 1;
389 const SV * const svend = &sva[SvREFCNT(sva)];
390 if (p >= sv && p < svend) {
396 Perl_ck_warner_d(aTHX_ packWARN(WARN_INTERNAL),
397 "Attempt to free non-arena SV: 0x%"UVxf
398 pTHX__FORMAT, PTR2UV(p) pTHX__VALUE);
405 #else /* ! DEBUGGING */
407 #define del_SV(p) plant_SV(p)
409 #endif /* DEBUGGING */
412 * Bodyless IVs and NVs!
414 * Since 5.9.2, we can avoid allocating a body for SVt_IV-type SVs.
415 * Since the larger IV-holding variants of SVs store their integer
416 * values in their respective bodies, the family of SvIV() accessor
417 * macros would naively have to branch on the SV type to find the
418 * integer value either in the HEAD or BODY. In order to avoid this
419 * expensive branch, a clever soul has deployed a great hack:
420 * We set up the SvANY pointer such that instead of pointing to a
421 * real body, it points into the memory before the location of the
422 * head. We compute this pointer such that the location of
423 * the integer member of the hypothetical body struct happens to
424 * be the same as the location of the integer member of the bodyless
425 * SV head. This now means that the SvIV() family of accessors can
426 * always read from the (hypothetical or real) body via SvANY.
428 * Since the 5.21 dev series, we employ the same trick for NVs
429 * if the architecture can support it (NVSIZE <= IVSIZE).
432 /* The following two macros compute the necessary offsets for the above
433 * trick and store them in SvANY for SvIV() (and friends) to use. */
434 #define SET_SVANY_FOR_BODYLESS_IV(sv) \
435 SvANY(sv) = (XPVIV*)((char*)&(sv->sv_u.svu_iv) - STRUCT_OFFSET(XPVIV, xiv_iv))
437 #define SET_SVANY_FOR_BODYLESS_NV(sv) \
438 SvANY(sv) = (XPVNV*)((char*)&(sv->sv_u.svu_nv) - STRUCT_OFFSET(XPVNV, xnv_u.xnv_nv))
441 =head1 SV Manipulation Functions
443 =for apidoc sv_add_arena
445 Given a chunk of memory, link it to the head of the list of arenas,
446 and split it into a list of free SVs.
452 S_sv_add_arena(pTHX_ char *const ptr, const U32 size, const U32 flags)
454 SV *const sva = MUTABLE_SV(ptr);
458 PERL_ARGS_ASSERT_SV_ADD_ARENA;
460 /* The first SV in an arena isn't an SV. */
461 SvANY(sva) = (void *) PL_sv_arenaroot; /* ptr to next arena */
462 SvREFCNT(sva) = size / sizeof(SV); /* number of SV slots */
463 SvFLAGS(sva) = flags; /* FAKE if not to be freed */
465 PL_sv_arenaroot = sva;
466 PL_sv_root = sva + 1;
468 svend = &sva[SvREFCNT(sva) - 1];
471 SvARENA_CHAIN_SET(sv, (sv + 1));
475 /* Must always set typemask because it's always checked in on cleanup
476 when the arenas are walked looking for objects. */
477 SvFLAGS(sv) = SVTYPEMASK;
480 SvARENA_CHAIN_SET(sv, 0);
484 SvFLAGS(sv) = SVTYPEMASK;
487 /* visit(): call the named function for each non-free SV in the arenas
488 * whose flags field matches the flags/mask args. */
491 S_visit(pTHX_ SVFUNC_t f, const U32 flags, const U32 mask)
496 PERL_ARGS_ASSERT_VISIT;
498 for (sva = PL_sv_arenaroot; sva; sva = MUTABLE_SV(SvANY(sva))) {
499 const SV * const svend = &sva[SvREFCNT(sva)];
501 for (sv = sva + 1; sv < svend; ++sv) {
502 if (SvTYPE(sv) != (svtype)SVTYPEMASK
503 && (sv->sv_flags & mask) == flags
516 /* called by sv_report_used() for each live SV */
519 do_report_used(pTHX_ SV *const sv)
521 if (SvTYPE(sv) != (svtype)SVTYPEMASK) {
522 PerlIO_printf(Perl_debug_log, "****\n");
529 =for apidoc sv_report_used
531 Dump the contents of all SVs not yet freed (debugging aid).
537 Perl_sv_report_used(pTHX)
540 visit(do_report_used, 0, 0);
546 /* called by sv_clean_objs() for each live SV */
549 do_clean_objs(pTHX_ SV *const ref)
553 SV * const target = SvRV(ref);
554 if (SvOBJECT(target)) {
555 DEBUG_D((PerlIO_printf(Perl_debug_log, "Cleaning object ref:\n "), sv_dump(ref)));
556 if (SvWEAKREF(ref)) {
557 sv_del_backref(target, ref);
563 SvREFCNT_dec_NN(target);
570 /* clear any slots in a GV which hold objects - except IO;
571 * called by sv_clean_objs() for each live GV */
574 do_clean_named_objs(pTHX_ SV *const sv)
577 assert(SvTYPE(sv) == SVt_PVGV);
578 assert(isGV_with_GP(sv));
582 /* freeing GP entries may indirectly free the current GV;
583 * hold onto it while we mess with the GP slots */
586 if ( ((obj = GvSV(sv) )) && SvOBJECT(obj)) {
587 DEBUG_D((PerlIO_printf(Perl_debug_log,
588 "Cleaning named glob SV object:\n "), sv_dump(obj)));
590 SvREFCNT_dec_NN(obj);
592 if ( ((obj = MUTABLE_SV(GvAV(sv)) )) && SvOBJECT(obj)) {
593 DEBUG_D((PerlIO_printf(Perl_debug_log,
594 "Cleaning named glob AV object:\n "), sv_dump(obj)));
596 SvREFCNT_dec_NN(obj);
598 if ( ((obj = MUTABLE_SV(GvHV(sv)) )) && SvOBJECT(obj)) {
599 DEBUG_D((PerlIO_printf(Perl_debug_log,
600 "Cleaning named glob HV object:\n "), sv_dump(obj)));
602 SvREFCNT_dec_NN(obj);
604 if ( ((obj = MUTABLE_SV(GvCV(sv)) )) && SvOBJECT(obj)) {
605 DEBUG_D((PerlIO_printf(Perl_debug_log,
606 "Cleaning named glob CV object:\n "), sv_dump(obj)));
608 SvREFCNT_dec_NN(obj);
610 SvREFCNT_dec_NN(sv); /* undo the inc above */
613 /* clear any IO slots in a GV which hold objects (except stderr, defout);
614 * called by sv_clean_objs() for each live GV */
617 do_clean_named_io_objs(pTHX_ SV *const sv)
620 assert(SvTYPE(sv) == SVt_PVGV);
621 assert(isGV_with_GP(sv));
622 if (!GvGP(sv) || sv == (SV*)PL_stderrgv || sv == (SV*)PL_defoutgv)
626 if ( ((obj = MUTABLE_SV(GvIO(sv)) )) && SvOBJECT(obj)) {
627 DEBUG_D((PerlIO_printf(Perl_debug_log,
628 "Cleaning named glob IO object:\n "), sv_dump(obj)));
630 SvREFCNT_dec_NN(obj);
632 SvREFCNT_dec_NN(sv); /* undo the inc above */
635 /* Void wrapper to pass to visit() */
637 do_curse(pTHX_ SV * const sv) {
638 if ((PL_stderrgv && GvGP(PL_stderrgv) && (SV*)GvIO(PL_stderrgv) == sv)
639 || (PL_defoutgv && GvGP(PL_defoutgv) && (SV*)GvIO(PL_defoutgv) == sv))
645 =for apidoc sv_clean_objs
647 Attempt to destroy all objects not yet freed.
653 Perl_sv_clean_objs(pTHX)
656 PL_in_clean_objs = TRUE;
657 visit(do_clean_objs, SVf_ROK, SVf_ROK);
658 /* Some barnacles may yet remain, clinging to typeglobs.
659 * Run the non-IO destructors first: they may want to output
660 * error messages, close files etc */
661 visit(do_clean_named_objs, SVt_PVGV|SVpgv_GP, SVTYPEMASK|SVp_POK|SVpgv_GP);
662 visit(do_clean_named_io_objs, SVt_PVGV|SVpgv_GP, SVTYPEMASK|SVp_POK|SVpgv_GP);
663 /* And if there are some very tenacious barnacles clinging to arrays,
664 closures, or what have you.... */
665 visit(do_curse, SVs_OBJECT, SVs_OBJECT);
666 olddef = PL_defoutgv;
667 PL_defoutgv = NULL; /* disable skip of PL_defoutgv */
668 if (olddef && isGV_with_GP(olddef))
669 do_clean_named_io_objs(aTHX_ MUTABLE_SV(olddef));
670 olderr = PL_stderrgv;
671 PL_stderrgv = NULL; /* disable skip of PL_stderrgv */
672 if (olderr && isGV_with_GP(olderr))
673 do_clean_named_io_objs(aTHX_ MUTABLE_SV(olderr));
674 SvREFCNT_dec(olddef);
675 PL_in_clean_objs = FALSE;
678 /* called by sv_clean_all() for each live SV */
681 do_clean_all(pTHX_ SV *const sv)
683 if (sv == (const SV *) PL_fdpid || sv == (const SV *)PL_strtab) {
684 /* don't clean pid table and strtab */
687 DEBUG_D((PerlIO_printf(Perl_debug_log, "Cleaning loops: SV at 0x%"UVxf"\n", PTR2UV(sv)) ));
688 SvFLAGS(sv) |= SVf_BREAK;
693 =for apidoc sv_clean_all
695 Decrement the refcnt of each remaining SV, possibly triggering a
696 cleanup. This function may have to be called multiple times to free
697 SVs which are in complex self-referential hierarchies.
703 Perl_sv_clean_all(pTHX)
706 PL_in_clean_all = TRUE;
707 cleaned = visit(do_clean_all, 0,0);
712 ARENASETS: a meta-arena implementation which separates arena-info
713 into struct arena_set, which contains an array of struct
714 arena_descs, each holding info for a single arena. By separating
715 the meta-info from the arena, we recover the 1st slot, formerly
716 borrowed for list management. The arena_set is about the size of an
717 arena, avoiding the needless malloc overhead of a naive linked-list.
719 The cost is 1 arena-set malloc per ~320 arena-mallocs, + the unused
720 memory in the last arena-set (1/2 on average). In trade, we get
721 back the 1st slot in each arena (ie 1.7% of a CV-arena, less for
722 smaller types). The recovery of the wasted space allows use of
723 small arenas for large, rare body types, by changing array* fields
724 in body_details_by_type[] below.
727 char *arena; /* the raw storage, allocated aligned */
728 size_t size; /* its size ~4k typ */
729 svtype utype; /* bodytype stored in arena */
734 /* Get the maximum number of elements in set[] such that struct arena_set
735 will fit within PERL_ARENA_SIZE, which is probably just under 4K, and
736 therefore likely to be 1 aligned memory page. */
738 #define ARENAS_PER_SET ((PERL_ARENA_SIZE - sizeof(struct arena_set*) \
739 - 2 * sizeof(int)) / sizeof (struct arena_desc))
742 struct arena_set* next;
743 unsigned int set_size; /* ie ARENAS_PER_SET */
744 unsigned int curr; /* index of next available arena-desc */
745 struct arena_desc set[ARENAS_PER_SET];
749 =for apidoc sv_free_arenas
751 Deallocate the memory used by all arenas. Note that all the individual SV
752 heads and bodies within the arenas must already have been freed.
758 Perl_sv_free_arenas(pTHX)
764 /* Free arenas here, but be careful about fake ones. (We assume
765 contiguity of the fake ones with the corresponding real ones.) */
767 for (sva = PL_sv_arenaroot; sva; sva = svanext) {
768 svanext = MUTABLE_SV(SvANY(sva));
769 while (svanext && SvFAKE(svanext))
770 svanext = MUTABLE_SV(SvANY(svanext));
777 struct arena_set *aroot = (struct arena_set*) PL_body_arenas;
780 struct arena_set *current = aroot;
783 assert(aroot->set[i].arena);
784 Safefree(aroot->set[i].arena);
792 i = PERL_ARENA_ROOTS_SIZE;
794 PL_body_roots[i] = 0;
801 Here are mid-level routines that manage the allocation of bodies out
802 of the various arenas. There are 5 kinds of arenas:
804 1. SV-head arenas, which are discussed and handled above
805 2. regular body arenas
806 3. arenas for reduced-size bodies
809 Arena types 2 & 3 are chained by body-type off an array of
810 arena-root pointers, which is indexed by svtype. Some of the
811 larger/less used body types are malloced singly, since a large
812 unused block of them is wasteful. Also, several svtypes dont have
813 bodies; the data fits into the sv-head itself. The arena-root
814 pointer thus has a few unused root-pointers (which may be hijacked
815 later for arena types 4,5)
817 3 differs from 2 as an optimization; some body types have several
818 unused fields in the front of the structure (which are kept in-place
819 for consistency). These bodies can be allocated in smaller chunks,
820 because the leading fields arent accessed. Pointers to such bodies
821 are decremented to point at the unused 'ghost' memory, knowing that
822 the pointers are used with offsets to the real memory.
825 =head1 SV-Body Allocation
829 Allocation of SV-bodies is similar to SV-heads, differing as follows;
830 the allocation mechanism is used for many body types, so is somewhat
831 more complicated, it uses arena-sets, and has no need for still-live
834 At the outermost level, (new|del)_X*V macros return bodies of the
835 appropriate type. These macros call either (new|del)_body_type or
836 (new|del)_body_allocated macro pairs, depending on specifics of the
837 type. Most body types use the former pair, the latter pair is used to
838 allocate body types with "ghost fields".
840 "ghost fields" are fields that are unused in certain types, and
841 consequently don't need to actually exist. They are declared because
842 they're part of a "base type", which allows use of functions as
843 methods. The simplest examples are AVs and HVs, 2 aggregate types
844 which don't use the fields which support SCALAR semantics.
846 For these types, the arenas are carved up into appropriately sized
847 chunks, we thus avoid wasted memory for those unaccessed members.
848 When bodies are allocated, we adjust the pointer back in memory by the
849 size of the part not allocated, so it's as if we allocated the full
850 structure. (But things will all go boom if you write to the part that
851 is "not there", because you'll be overwriting the last members of the
852 preceding structure in memory.)
854 We calculate the correction using the STRUCT_OFFSET macro on the first
855 member present. If the allocated structure is smaller (no initial NV
856 actually allocated) then the net effect is to subtract the size of the NV
857 from the pointer, to return a new pointer as if an initial NV were actually
858 allocated. (We were using structures named *_allocated for this, but
859 this turned out to be a subtle bug, because a structure without an NV
860 could have a lower alignment constraint, but the compiler is allowed to
861 optimised accesses based on the alignment constraint of the actual pointer
862 to the full structure, for example, using a single 64 bit load instruction
863 because it "knows" that two adjacent 32 bit members will be 8-byte aligned.)
865 This is the same trick as was used for NV and IV bodies. Ironically it
866 doesn't need to be used for NV bodies any more, because NV is now at
867 the start of the structure. IV bodies, and also in some builds NV bodies,
868 don't need it either, because they are no longer allocated.
870 In turn, the new_body_* allocators call S_new_body(), which invokes
871 new_body_inline macro, which takes a lock, and takes a body off the
872 linked list at PL_body_roots[sv_type], calling Perl_more_bodies() if
873 necessary to refresh an empty list. Then the lock is released, and
874 the body is returned.
876 Perl_more_bodies allocates a new arena, and carves it up into an array of N
877 bodies, which it strings into a linked list. It looks up arena-size
878 and body-size from the body_details table described below, thus
879 supporting the multiple body-types.
881 If PURIFY is defined, or PERL_ARENA_SIZE=0, arenas are not used, and
882 the (new|del)_X*V macros are mapped directly to malloc/free.
884 For each sv-type, struct body_details bodies_by_type[] carries
885 parameters which control these aspects of SV handling:
887 Arena_size determines whether arenas are used for this body type, and if
888 so, how big they are. PURIFY or PERL_ARENA_SIZE=0 set this field to
889 zero, forcing individual mallocs and frees.
891 Body_size determines how big a body is, and therefore how many fit into
892 each arena. Offset carries the body-pointer adjustment needed for
893 "ghost fields", and is used in *_allocated macros.
895 But its main purpose is to parameterize info needed in
896 Perl_sv_upgrade(). The info here dramatically simplifies the function
897 vs the implementation in 5.8.8, making it table-driven. All fields
898 are used for this, except for arena_size.
900 For the sv-types that have no bodies, arenas are not used, so those
901 PL_body_roots[sv_type] are unused, and can be overloaded. In
902 something of a special case, SVt_NULL is borrowed for HE arenas;
903 PL_body_roots[HE_SVSLOT=SVt_NULL] is filled by S_more_he, but the
904 bodies_by_type[SVt_NULL] slot is not used, as the table is not
909 struct body_details {
910 U8 body_size; /* Size to allocate */
911 U8 copy; /* Size of structure to copy (may be shorter) */
912 U8 offset; /* Size of unalloced ghost fields to first alloced field*/
913 PERL_BITFIELD8 type : 4; /* We have space for a sanity check. */
914 PERL_BITFIELD8 cant_upgrade : 1;/* Cannot upgrade this type */
915 PERL_BITFIELD8 zero_nv : 1; /* zero the NV when upgrading from this */
916 PERL_BITFIELD8 arena : 1; /* Allocated from an arena */
917 U32 arena_size; /* Size of arena to allocate */
925 /* With -DPURFIY we allocate everything directly, and don't use arenas.
926 This seems a rather elegant way to simplify some of the code below. */
927 #define HASARENA FALSE
929 #define HASARENA TRUE
931 #define NOARENA FALSE
933 /* Size the arenas to exactly fit a given number of bodies. A count
934 of 0 fits the max number bodies into a PERL_ARENA_SIZE.block,
935 simplifying the default. If count > 0, the arena is sized to fit
936 only that many bodies, allowing arenas to be used for large, rare
937 bodies (XPVFM, XPVIO) without undue waste. The arena size is
938 limited by PERL_ARENA_SIZE, so we can safely oversize the
941 #define FIT_ARENA0(body_size) \
942 ((size_t)(PERL_ARENA_SIZE / body_size) * body_size)
943 #define FIT_ARENAn(count,body_size) \
944 ( count * body_size <= PERL_ARENA_SIZE) \
945 ? count * body_size \
946 : FIT_ARENA0 (body_size)
947 #define FIT_ARENA(count,body_size) \
949 ? FIT_ARENAn (count, body_size) \
950 : FIT_ARENA0 (body_size))
952 /* Calculate the length to copy. Specifically work out the length less any
953 final padding the compiler needed to add. See the comment in sv_upgrade
954 for why copying the padding proved to be a bug. */
956 #define copy_length(type, last_member) \
957 STRUCT_OFFSET(type, last_member) \
958 + sizeof (((type*)SvANY((const SV *)0))->last_member)
960 static const struct body_details bodies_by_type[] = {
961 /* HEs use this offset for their arena. */
962 { 0, 0, 0, SVt_NULL, FALSE, NONV, NOARENA, 0 },
964 /* IVs are in the head, so the allocation size is 0. */
966 sizeof(IV), /* This is used to copy out the IV body. */
967 STRUCT_OFFSET(XPVIV, xiv_iv), SVt_IV, FALSE, NONV,
968 NOARENA /* IVS don't need an arena */, 0
973 STRUCT_OFFSET(XPVNV, xnv_u),
974 SVt_NV, FALSE, HADNV, NOARENA, 0 },
976 { sizeof(NV), sizeof(NV),
977 STRUCT_OFFSET(XPVNV, xnv_u),
978 SVt_NV, FALSE, HADNV, HASARENA, FIT_ARENA(0, sizeof(NV)) },
981 { sizeof(XPV) - STRUCT_OFFSET(XPV, xpv_cur),
982 copy_length(XPV, xpv_len) - STRUCT_OFFSET(XPV, xpv_cur),
983 + STRUCT_OFFSET(XPV, xpv_cur),
984 SVt_PV, FALSE, NONV, HASARENA,
985 FIT_ARENA(0, sizeof(XPV) - STRUCT_OFFSET(XPV, xpv_cur)) },
987 { sizeof(XINVLIST) - STRUCT_OFFSET(XPV, xpv_cur),
988 copy_length(XINVLIST, is_offset) - STRUCT_OFFSET(XPV, xpv_cur),
989 + STRUCT_OFFSET(XPV, xpv_cur),
990 SVt_INVLIST, TRUE, NONV, HASARENA,
991 FIT_ARENA(0, sizeof(XINVLIST) - STRUCT_OFFSET(XPV, xpv_cur)) },
993 { sizeof(XPVIV) - STRUCT_OFFSET(XPV, xpv_cur),
994 copy_length(XPVIV, xiv_u) - STRUCT_OFFSET(XPV, xpv_cur),
995 + STRUCT_OFFSET(XPV, xpv_cur),
996 SVt_PVIV, FALSE, NONV, HASARENA,
997 FIT_ARENA(0, sizeof(XPVIV) - STRUCT_OFFSET(XPV, xpv_cur)) },
999 { sizeof(XPVNV) - STRUCT_OFFSET(XPV, xpv_cur),
1000 copy_length(XPVNV, xnv_u) - STRUCT_OFFSET(XPV, xpv_cur),
1001 + STRUCT_OFFSET(XPV, xpv_cur),
1002 SVt_PVNV, FALSE, HADNV, HASARENA,
1003 FIT_ARENA(0, sizeof(XPVNV) - STRUCT_OFFSET(XPV, xpv_cur)) },
1005 { sizeof(XPVMG), copy_length(XPVMG, xnv_u), 0, SVt_PVMG, FALSE, HADNV,
1006 HASARENA, FIT_ARENA(0, sizeof(XPVMG)) },
1011 SVt_REGEXP, TRUE, NONV, HASARENA,
1012 FIT_ARENA(0, sizeof(regexp))
1015 { sizeof(XPVGV), sizeof(XPVGV), 0, SVt_PVGV, TRUE, HADNV,
1016 HASARENA, FIT_ARENA(0, sizeof(XPVGV)) },
1018 { sizeof(XPVLV), sizeof(XPVLV), 0, SVt_PVLV, TRUE, HADNV,
1019 HASARENA, FIT_ARENA(0, sizeof(XPVLV)) },
1022 copy_length(XPVAV, xav_alloc),
1024 SVt_PVAV, TRUE, NONV, HASARENA,
1025 FIT_ARENA(0, sizeof(XPVAV)) },
1028 copy_length(XPVHV, xhv_max),
1030 SVt_PVHV, TRUE, NONV, HASARENA,
1031 FIT_ARENA(0, sizeof(XPVHV)) },
1036 SVt_PVCV, TRUE, NONV, HASARENA,
1037 FIT_ARENA(0, sizeof(XPVCV)) },
1042 SVt_PVFM, TRUE, NONV, NOARENA,
1043 FIT_ARENA(20, sizeof(XPVFM)) },
1048 SVt_PVIO, TRUE, NONV, HASARENA,
1049 FIT_ARENA(24, sizeof(XPVIO)) },
1052 #define new_body_allocated(sv_type) \
1053 (void *)((char *)S_new_body(aTHX_ sv_type) \
1054 - bodies_by_type[sv_type].offset)
1056 /* return a thing to the free list */
1058 #define del_body(thing, root) \
1060 void ** const thing_copy = (void **)thing; \
1061 *thing_copy = *root; \
1062 *root = (void*)thing_copy; \
1066 #if !(NVSIZE <= IVSIZE)
1067 # define new_XNV() safemalloc(sizeof(XPVNV))
1069 #define new_XPVNV() safemalloc(sizeof(XPVNV))
1070 #define new_XPVMG() safemalloc(sizeof(XPVMG))
1072 #define del_XPVGV(p) safefree(p)
1076 #if !(NVSIZE <= IVSIZE)
1077 # define new_XNV() new_body_allocated(SVt_NV)
1079 #define new_XPVNV() new_body_allocated(SVt_PVNV)
1080 #define new_XPVMG() new_body_allocated(SVt_PVMG)
1082 #define del_XPVGV(p) del_body(p + bodies_by_type[SVt_PVGV].offset, \
1083 &PL_body_roots[SVt_PVGV])
1087 /* no arena for you! */
1089 #define new_NOARENA(details) \
1090 safemalloc((details)->body_size + (details)->offset)
1091 #define new_NOARENAZ(details) \
1092 safecalloc((details)->body_size + (details)->offset, 1)
1095 Perl_more_bodies (pTHX_ const svtype sv_type, const size_t body_size,
1096 const size_t arena_size)
1098 void ** const root = &PL_body_roots[sv_type];
1099 struct arena_desc *adesc;
1100 struct arena_set *aroot = (struct arena_set *) PL_body_arenas;
1104 const size_t good_arena_size = Perl_malloc_good_size(arena_size);
1105 #if defined(DEBUGGING) && defined(PERL_GLOBAL_STRUCT)
1108 #if defined(DEBUGGING) && !defined(PERL_GLOBAL_STRUCT_PRIVATE)
1109 static bool done_sanity_check;
1111 /* PERL_GLOBAL_STRUCT_PRIVATE cannot coexist with global
1112 * variables like done_sanity_check. */
1113 if (!done_sanity_check) {
1114 unsigned int i = SVt_LAST;
1116 done_sanity_check = TRUE;
1119 assert (bodies_by_type[i].type == i);
1125 /* may need new arena-set to hold new arena */
1126 if (!aroot || aroot->curr >= aroot->set_size) {
1127 struct arena_set *newroot;
1128 Newxz(newroot, 1, struct arena_set);
1129 newroot->set_size = ARENAS_PER_SET;
1130 newroot->next = aroot;
1132 PL_body_arenas = (void *) newroot;
1133 DEBUG_m(PerlIO_printf(Perl_debug_log, "new arenaset %p\n", (void*)aroot));
1136 /* ok, now have arena-set with at least 1 empty/available arena-desc */
1137 curr = aroot->curr++;
1138 adesc = &(aroot->set[curr]);
1139 assert(!adesc->arena);
1141 Newx(adesc->arena, good_arena_size, char);
1142 adesc->size = good_arena_size;
1143 adesc->utype = sv_type;
1144 DEBUG_m(PerlIO_printf(Perl_debug_log, "arena %d added: %p size %"UVuf"\n",
1145 curr, (void*)adesc->arena, (UV)good_arena_size));
1147 start = (char *) adesc->arena;
1149 /* Get the address of the byte after the end of the last body we can fit.
1150 Remember, this is integer division: */
1151 end = start + good_arena_size / body_size * body_size;
1153 /* computed count doesn't reflect the 1st slot reservation */
1154 #if defined(MYMALLOC) || defined(HAS_MALLOC_GOOD_SIZE)
1155 DEBUG_m(PerlIO_printf(Perl_debug_log,
1156 "arena %p end %p arena-size %d (from %d) type %d "
1158 (void*)start, (void*)end, (int)good_arena_size,
1159 (int)arena_size, sv_type, (int)body_size,
1160 (int)good_arena_size / (int)body_size));
1162 DEBUG_m(PerlIO_printf(Perl_debug_log,
1163 "arena %p end %p arena-size %d type %d size %d ct %d\n",
1164 (void*)start, (void*)end,
1165 (int)arena_size, sv_type, (int)body_size,
1166 (int)good_arena_size / (int)body_size));
1168 *root = (void *)start;
1171 /* Where the next body would start: */
1172 char * const next = start + body_size;
1175 /* This is the last body: */
1176 assert(next == end);
1178 *(void **)start = 0;
1182 *(void**) start = (void *)next;
1187 /* grab a new thing from the free list, allocating more if necessary.
1188 The inline version is used for speed in hot routines, and the
1189 function using it serves the rest (unless PURIFY).
1191 #define new_body_inline(xpv, sv_type) \
1193 void ** const r3wt = &PL_body_roots[sv_type]; \
1194 xpv = (PTR_TBL_ENT_t*) (*((void **)(r3wt)) \
1195 ? *((void **)(r3wt)) : Perl_more_bodies(aTHX_ sv_type, \
1196 bodies_by_type[sv_type].body_size,\
1197 bodies_by_type[sv_type].arena_size)); \
1198 *(r3wt) = *(void**)(xpv); \
1204 S_new_body(pTHX_ const svtype sv_type)
1207 new_body_inline(xpv, sv_type);
1213 static const struct body_details fake_rv =
1214 { 0, 0, 0, SVt_IV, FALSE, NONV, NOARENA, 0 };
1217 =for apidoc sv_upgrade
1219 Upgrade an SV to a more complex form. Generally adds a new body type to the
1220 SV, then copies across as much information as possible from the old body.
1221 It croaks if the SV is already in a more complex form than requested. You
1222 generally want to use the C<SvUPGRADE> macro wrapper, which checks the type
1223 before calling C<sv_upgrade>, and hence does not croak. See also
1230 Perl_sv_upgrade(pTHX_ SV *const sv, svtype new_type)
1234 const svtype old_type = SvTYPE(sv);
1235 const struct body_details *new_type_details;
1236 const struct body_details *old_type_details
1237 = bodies_by_type + old_type;
1238 SV *referant = NULL;
1240 PERL_ARGS_ASSERT_SV_UPGRADE;
1242 if (old_type == new_type)
1245 /* This clause was purposefully added ahead of the early return above to
1246 the shared string hackery for (sort {$a <=> $b} keys %hash), with the
1247 inference by Nick I-S that it would fix other troublesome cases. See
1248 changes 7162, 7163 (f130fd4589cf5fbb24149cd4db4137c8326f49c1 and parent)
1250 Given that shared hash key scalars are no longer PVIV, but PV, there is
1251 no longer need to unshare so as to free up the IVX slot for its proper
1252 purpose. So it's safe to move the early return earlier. */
1254 if (new_type > SVt_PVMG && SvIsCOW(sv)) {
1255 sv_force_normal_flags(sv, 0);
1258 old_body = SvANY(sv);
1260 /* Copying structures onto other structures that have been neatly zeroed
1261 has a subtle gotcha. Consider XPVMG
1263 +------+------+------+------+------+-------+-------+
1264 | NV | CUR | LEN | IV | MAGIC | STASH |
1265 +------+------+------+------+------+-------+-------+
1266 0 4 8 12 16 20 24 28
1268 where NVs are aligned to 8 bytes, so that sizeof that structure is
1269 actually 32 bytes long, with 4 bytes of padding at the end:
1271 +------+------+------+------+------+-------+-------+------+
1272 | NV | CUR | LEN | IV | MAGIC | STASH | ??? |
1273 +------+------+------+------+------+-------+-------+------+
1274 0 4 8 12 16 20 24 28 32
1276 so what happens if you allocate memory for this structure:
1278 +------+------+------+------+------+-------+-------+------+------+...
1279 | NV | CUR | LEN | IV | MAGIC | STASH | GP | NAME |
1280 +------+------+------+------+------+-------+-------+------+------+...
1281 0 4 8 12 16 20 24 28 32 36
1283 zero it, then copy sizeof(XPVMG) bytes on top of it? Not quite what you
1284 expect, because you copy the area marked ??? onto GP. Now, ??? may have
1285 started out as zero once, but it's quite possible that it isn't. So now,
1286 rather than a nicely zeroed GP, you have it pointing somewhere random.
1289 (In fact, GP ends up pointing at a previous GP structure, because the
1290 principle cause of the padding in XPVMG getting garbage is a copy of
1291 sizeof(XPVMG) bytes from a XPVGV structure in sv_unglob. Right now
1292 this happens to be moot because XPVGV has been re-ordered, with GP
1293 no longer after STASH)
1295 So we are careful and work out the size of used parts of all the
1303 referant = SvRV(sv);
1304 old_type_details = &fake_rv;
1305 if (new_type == SVt_NV)
1306 new_type = SVt_PVNV;
1308 if (new_type < SVt_PVIV) {
1309 new_type = (new_type == SVt_NV)
1310 ? SVt_PVNV : SVt_PVIV;
1315 if (new_type < SVt_PVNV) {
1316 new_type = SVt_PVNV;
1320 assert(new_type > SVt_PV);
1321 STATIC_ASSERT_STMT(SVt_IV < SVt_PV);
1322 STATIC_ASSERT_STMT(SVt_NV < SVt_PV);
1329 /* Because the XPVMG of PL_mess_sv isn't allocated from the arena,
1330 there's no way that it can be safely upgraded, because perl.c
1331 expects to Safefree(SvANY(PL_mess_sv)) */
1332 assert(sv != PL_mess_sv);
1335 if (UNLIKELY(old_type_details->cant_upgrade))
1336 Perl_croak(aTHX_ "Can't upgrade %s (%" UVuf ") to %" UVuf,
1337 sv_reftype(sv, 0), (UV) old_type, (UV) new_type);
1340 if (UNLIKELY(old_type > new_type))
1341 Perl_croak(aTHX_ "sv_upgrade from type %d down to type %d",
1342 (int)old_type, (int)new_type);
1344 new_type_details = bodies_by_type + new_type;
1346 SvFLAGS(sv) &= ~SVTYPEMASK;
1347 SvFLAGS(sv) |= new_type;
1349 /* This can't happen, as SVt_NULL is <= all values of new_type, so one of
1350 the return statements above will have triggered. */
1351 assert (new_type != SVt_NULL);
1354 assert(old_type == SVt_NULL);
1355 SET_SVANY_FOR_BODYLESS_IV(sv);
1359 assert(old_type == SVt_NULL);
1360 #if NVSIZE <= IVSIZE
1361 SET_SVANY_FOR_BODYLESS_NV(sv);
1363 SvANY(sv) = new_XNV();
1369 assert(new_type_details->body_size);
1372 assert(new_type_details->arena);
1373 assert(new_type_details->arena_size);
1374 /* This points to the start of the allocated area. */
1375 new_body_inline(new_body, new_type);
1376 Zero(new_body, new_type_details->body_size, char);
1377 new_body = ((char *)new_body) - new_type_details->offset;
1379 /* We always allocated the full length item with PURIFY. To do this
1380 we fake things so that arena is false for all 16 types.. */
1381 new_body = new_NOARENAZ(new_type_details);
1383 SvANY(sv) = new_body;
1384 if (new_type == SVt_PVAV) {
1388 if (old_type_details->body_size) {
1391 /* It will have been zeroed when the new body was allocated.
1392 Lets not write to it, in case it confuses a write-back
1398 #ifndef NODEFAULT_SHAREKEYS
1399 HvSHAREKEYS_on(sv); /* key-sharing on by default */
1401 /* start with PERL_HASH_DEFAULT_HvMAX+1 buckets: */
1402 HvMAX(sv) = PERL_HASH_DEFAULT_HvMAX;
1405 /* SVt_NULL isn't the only thing upgraded to AV or HV.
1406 The target created by newSVrv also is, and it can have magic.
1407 However, it never has SvPVX set.
1409 if (old_type == SVt_IV) {
1411 } else if (old_type >= SVt_PV) {
1412 assert(SvPVX_const(sv) == 0);
1415 if (old_type >= SVt_PVMG) {
1416 SvMAGIC_set(sv, ((XPVMG*)old_body)->xmg_u.xmg_magic);
1417 SvSTASH_set(sv, ((XPVMG*)old_body)->xmg_stash);
1419 sv->sv_u.svu_array = NULL; /* or svu_hash */
1424 /* XXX Is this still needed? Was it ever needed? Surely as there is
1425 no route from NV to PVIV, NOK can never be true */
1426 assert(!SvNOKp(sv));
1440 assert(new_type_details->body_size);
1441 /* We always allocated the full length item with PURIFY. To do this
1442 we fake things so that arena is false for all 16 types.. */
1443 if(new_type_details->arena) {
1444 /* This points to the start of the allocated area. */
1445 new_body_inline(new_body, new_type);
1446 Zero(new_body, new_type_details->body_size, char);
1447 new_body = ((char *)new_body) - new_type_details->offset;
1449 new_body = new_NOARENAZ(new_type_details);
1451 SvANY(sv) = new_body;
1453 if (old_type_details->copy) {
1454 /* There is now the potential for an upgrade from something without
1455 an offset (PVNV or PVMG) to something with one (PVCV, PVFM) */
1456 int offset = old_type_details->offset;
1457 int length = old_type_details->copy;
1459 if (new_type_details->offset > old_type_details->offset) {
1460 const int difference
1461 = new_type_details->offset - old_type_details->offset;
1462 offset += difference;
1463 length -= difference;
1465 assert (length >= 0);
1467 Copy((char *)old_body + offset, (char *)new_body + offset, length,
1471 #ifndef NV_ZERO_IS_ALLBITS_ZERO
1472 /* If NV 0.0 is stores as all bits 0 then Zero() already creates a
1473 * correct 0.0 for us. Otherwise, if the old body didn't have an
1474 * NV slot, but the new one does, then we need to initialise the
1475 * freshly created NV slot with whatever the correct bit pattern is
1477 if (old_type_details->zero_nv && !new_type_details->zero_nv
1478 && !isGV_with_GP(sv))
1482 if (UNLIKELY(new_type == SVt_PVIO)) {
1483 IO * const io = MUTABLE_IO(sv);
1484 GV *iogv = gv_fetchpvs("IO::File::", GV_ADD, SVt_PVHV);
1487 /* Clear the stashcache because a new IO could overrule a package
1489 DEBUG_o(Perl_deb(aTHX_ "sv_upgrade clearing PL_stashcache\n"));
1490 hv_clear(PL_stashcache);
1492 SvSTASH_set(io, MUTABLE_HV(SvREFCNT_inc(GvHV(iogv))));
1493 IoPAGE_LEN(sv) = 60;
1495 if (UNLIKELY(new_type == SVt_REGEXP))
1496 sv->sv_u.svu_rx = (regexp *)new_body;
1497 else if (old_type < SVt_PV) {
1498 /* referant will be NULL unless the old type was SVt_IV emulating
1500 sv->sv_u.svu_rv = referant;
1504 Perl_croak(aTHX_ "panic: sv_upgrade to unknown type %lu",
1505 (unsigned long)new_type);
1508 /* if this is zero, this is a body-less SVt_NULL, SVt_IV/SVt_RV,
1509 and sometimes SVt_NV */
1510 if (old_type_details->body_size) {
1514 /* Note that there is an assumption that all bodies of types that
1515 can be upgraded came from arenas. Only the more complex non-
1516 upgradable types are allowed to be directly malloc()ed. */
1517 assert(old_type_details->arena);
1518 del_body((void*)((char*)old_body + old_type_details->offset),
1519 &PL_body_roots[old_type]);
1525 =for apidoc sv_backoff
1527 Remove any string offset. You should normally use the C<SvOOK_off> macro
1534 Perl_sv_backoff(SV *const sv)
1537 const char * const s = SvPVX_const(sv);
1539 PERL_ARGS_ASSERT_SV_BACKOFF;
1542 assert(SvTYPE(sv) != SVt_PVHV);
1543 assert(SvTYPE(sv) != SVt_PVAV);
1545 SvOOK_offset(sv, delta);
1547 SvLEN_set(sv, SvLEN(sv) + delta);
1548 SvPV_set(sv, SvPVX(sv) - delta);
1549 Move(s, SvPVX(sv), SvCUR(sv)+1, char);
1550 SvFLAGS(sv) &= ~SVf_OOK;
1557 Expands the character buffer in the SV. If necessary, uses C<sv_unref> and
1558 upgrades the SV to C<SVt_PV>. Returns a pointer to the character buffer.
1559 Use the C<SvGROW> wrapper instead.
1564 static void S_sv_uncow(pTHX_ SV * const sv, const U32 flags);
1567 Perl_sv_grow(pTHX_ SV *const sv, STRLEN newlen)
1571 PERL_ARGS_ASSERT_SV_GROW;
1575 if (SvTYPE(sv) < SVt_PV) {
1576 sv_upgrade(sv, SVt_PV);
1577 s = SvPVX_mutable(sv);
1579 else if (SvOOK(sv)) { /* pv is offset? */
1581 s = SvPVX_mutable(sv);
1582 if (newlen > SvLEN(sv))
1583 newlen += 10 * (newlen - SvCUR(sv)); /* avoid copy each time */
1587 if (SvIsCOW(sv)) S_sv_uncow(aTHX_ sv, 0);
1588 s = SvPVX_mutable(sv);
1591 #ifdef PERL_NEW_COPY_ON_WRITE
1592 /* the new COW scheme uses SvPVX(sv)[SvLEN(sv)-1] (if spare)
1593 * to store the COW count. So in general, allocate one more byte than
1594 * asked for, to make it likely this byte is always spare: and thus
1595 * make more strings COW-able.
1596 * If the new size is a big power of two, don't bother: we assume the
1597 * caller wanted a nice 2^N sized block and will be annoyed at getting
1599 * Only increment if the allocation isn't MEM_SIZE_MAX,
1600 * otherwise it will wrap to 0.
1602 if (newlen & 0xff && newlen != MEM_SIZE_MAX)
1606 #if defined(PERL_USE_MALLOC_SIZE) && defined(Perl_safesysmalloc_size)
1607 #define PERL_UNWARANTED_CHUMMINESS_WITH_MALLOC
1610 if (newlen > SvLEN(sv)) { /* need more room? */
1611 STRLEN minlen = SvCUR(sv);
1612 minlen += (minlen >> PERL_STRLEN_EXPAND_SHIFT) + 10;
1613 if (newlen < minlen)
1615 #ifndef PERL_UNWARANTED_CHUMMINESS_WITH_MALLOC
1617 /* Don't round up on the first allocation, as odds are pretty good that
1618 * the initial request is accurate as to what is really needed */
1620 STRLEN rounded = PERL_STRLEN_ROUNDUP(newlen);
1621 if (rounded > newlen)
1625 if (SvLEN(sv) && s) {
1626 s = (char*)saferealloc(s, newlen);
1629 s = (char*)safemalloc(newlen);
1630 if (SvPVX_const(sv) && SvCUR(sv)) {
1631 Move(SvPVX_const(sv), s, (newlen < SvCUR(sv)) ? newlen : SvCUR(sv), char);
1635 #ifdef PERL_UNWARANTED_CHUMMINESS_WITH_MALLOC
1636 /* Do this here, do it once, do it right, and then we will never get
1637 called back into sv_grow() unless there really is some growing
1639 SvLEN_set(sv, Perl_safesysmalloc_size(s));
1641 SvLEN_set(sv, newlen);
1648 =for apidoc sv_setiv
1650 Copies an integer into the given SV, upgrading first if necessary.
1651 Does not handle 'set' magic. See also C<sv_setiv_mg>.
1657 Perl_sv_setiv(pTHX_ SV *const sv, const IV i)
1659 PERL_ARGS_ASSERT_SV_SETIV;
1661 SV_CHECK_THINKFIRST_COW_DROP(sv);
1662 switch (SvTYPE(sv)) {
1665 sv_upgrade(sv, SVt_IV);
1668 sv_upgrade(sv, SVt_PVIV);
1672 if (!isGV_with_GP(sv))
1679 /* diag_listed_as: Can't coerce %s to %s in %s */
1680 Perl_croak(aTHX_ "Can't coerce %s to integer in %s", sv_reftype(sv,0),
1684 (void)SvIOK_only(sv); /* validate number */
1690 =for apidoc sv_setiv_mg
1692 Like C<sv_setiv>, but also handles 'set' magic.
1698 Perl_sv_setiv_mg(pTHX_ SV *const sv, const IV i)
1700 PERL_ARGS_ASSERT_SV_SETIV_MG;
1707 =for apidoc sv_setuv
1709 Copies an unsigned integer into the given SV, upgrading first if necessary.
1710 Does not handle 'set' magic. See also C<sv_setuv_mg>.
1716 Perl_sv_setuv(pTHX_ SV *const sv, const UV u)
1718 PERL_ARGS_ASSERT_SV_SETUV;
1720 /* With the if statement to ensure that integers are stored as IVs whenever
1722 u=1.49 s=0.52 cu=72.49 cs=10.64 scripts=270 tests=20865
1725 u=1.35 s=0.47 cu=73.45 cs=11.43 scripts=270 tests=20865
1727 If you wish to remove the following if statement, so that this routine
1728 (and its callers) always return UVs, please benchmark to see what the
1729 effect is. Modern CPUs may be different. Or may not :-)
1731 if (u <= (UV)IV_MAX) {
1732 sv_setiv(sv, (IV)u);
1741 =for apidoc sv_setuv_mg
1743 Like C<sv_setuv>, but also handles 'set' magic.
1749 Perl_sv_setuv_mg(pTHX_ SV *const sv, const UV u)
1751 PERL_ARGS_ASSERT_SV_SETUV_MG;
1758 =for apidoc sv_setnv
1760 Copies a double into the given SV, upgrading first if necessary.
1761 Does not handle 'set' magic. See also C<sv_setnv_mg>.
1767 Perl_sv_setnv(pTHX_ SV *const sv, const NV num)
1769 PERL_ARGS_ASSERT_SV_SETNV;
1771 SV_CHECK_THINKFIRST_COW_DROP(sv);
1772 switch (SvTYPE(sv)) {
1775 sv_upgrade(sv, SVt_NV);
1779 sv_upgrade(sv, SVt_PVNV);
1783 if (!isGV_with_GP(sv))
1790 /* diag_listed_as: Can't coerce %s to %s in %s */
1791 Perl_croak(aTHX_ "Can't coerce %s to number in %s", sv_reftype(sv,0),
1796 (void)SvNOK_only(sv); /* validate number */
1801 =for apidoc sv_setnv_mg
1803 Like C<sv_setnv>, but also handles 'set' magic.
1809 Perl_sv_setnv_mg(pTHX_ SV *const sv, const NV num)
1811 PERL_ARGS_ASSERT_SV_SETNV_MG;
1817 /* Return a cleaned-up, printable version of sv, for non-numeric, or
1818 * not incrementable warning display.
1819 * Originally part of S_not_a_number().
1820 * The return value may be != tmpbuf.
1824 S_sv_display(pTHX_ SV *const sv, char *tmpbuf, STRLEN tmpbuf_size) {
1827 PERL_ARGS_ASSERT_SV_DISPLAY;
1830 SV *dsv = newSVpvs_flags("", SVs_TEMP);
1831 pv = sv_uni_display(dsv, sv, 10, UNI_DISPLAY_ISPRINT);
1834 const char * const limit = tmpbuf + tmpbuf_size - 8;
1835 /* each *s can expand to 4 chars + "...\0",
1836 i.e. need room for 8 chars */
1838 const char *s = SvPVX_const(sv);
1839 const char * const end = s + SvCUR(sv);
1840 for ( ; s < end && d < limit; s++ ) {
1842 if (! isASCII(ch) && !isPRINT_LC(ch)) {
1846 /* Map to ASCII "equivalent" of Latin1 */
1847 ch = LATIN1_TO_NATIVE(NATIVE_TO_LATIN1(ch) & 127);
1853 else if (ch == '\r') {
1857 else if (ch == '\f') {
1861 else if (ch == '\\') {
1865 else if (ch == '\0') {
1869 else if (isPRINT_LC(ch))
1888 /* Print an "isn't numeric" warning, using a cleaned-up,
1889 * printable version of the offending string
1893 S_not_a_number(pTHX_ SV *const sv)
1898 PERL_ARGS_ASSERT_NOT_A_NUMBER;
1900 pv = sv_display(sv, tmpbuf, sizeof(tmpbuf));
1903 Perl_warner(aTHX_ packWARN(WARN_NUMERIC),
1904 /* diag_listed_as: Argument "%s" isn't numeric%s */
1905 "Argument \"%s\" isn't numeric in %s", pv,
1908 Perl_warner(aTHX_ packWARN(WARN_NUMERIC),
1909 /* diag_listed_as: Argument "%s" isn't numeric%s */
1910 "Argument \"%s\" isn't numeric", pv);
1914 S_not_incrementable(pTHX_ SV *const sv) {
1918 PERL_ARGS_ASSERT_NOT_INCREMENTABLE;
1920 pv = sv_display(sv, tmpbuf, sizeof(tmpbuf));
1922 Perl_warner(aTHX_ packWARN(WARN_NUMERIC),
1923 "Argument \"%s\" treated as 0 in increment (++)", pv);
1927 =for apidoc looks_like_number
1929 Test if the content of an SV looks like a number (or is a number).
1930 C<Inf> and C<Infinity> are treated as numbers (so will not issue a
1931 non-numeric warning), even if your atof() doesn't grok them. Get-magic is
1938 Perl_looks_like_number(pTHX_ SV *const sv)
1944 PERL_ARGS_ASSERT_LOOKS_LIKE_NUMBER;
1946 if (SvPOK(sv) || SvPOKp(sv)) {
1947 sbegin = SvPV_nomg_const(sv, len);
1950 return SvFLAGS(sv) & (SVf_NOK|SVp_NOK|SVf_IOK|SVp_IOK);
1951 numtype = grok_number(sbegin, len, NULL);
1952 return ((numtype & IS_NUMBER_TRAILING)) ? 0 : numtype;
1956 S_glob_2number(pTHX_ GV * const gv)
1958 PERL_ARGS_ASSERT_GLOB_2NUMBER;
1960 /* We know that all GVs stringify to something that is not-a-number,
1961 so no need to test that. */
1962 if (ckWARN(WARN_NUMERIC))
1964 SV *const buffer = sv_newmortal();
1965 gv_efullname3(buffer, gv, "*");
1966 not_a_number(buffer);
1968 /* We just want something true to return, so that S_sv_2iuv_common
1969 can tail call us and return true. */
1973 /* Actually, ISO C leaves conversion of UV to IV undefined, but
1974 until proven guilty, assume that things are not that bad... */
1979 As 64 bit platforms often have an NV that doesn't preserve all bits of
1980 an IV (an assumption perl has been based on to date) it becomes necessary
1981 to remove the assumption that the NV always carries enough precision to
1982 recreate the IV whenever needed, and that the NV is the canonical form.
1983 Instead, IV/UV and NV need to be given equal rights. So as to not lose
1984 precision as a side effect of conversion (which would lead to insanity
1985 and the dragon(s) in t/op/numconvert.t getting very angry) the intent is
1986 1) to distinguish between IV/UV/NV slots that have a valid conversion cached
1987 where precision was lost, and IV/UV/NV slots that have a valid conversion
1988 which has lost no precision
1989 2) to ensure that if a numeric conversion to one form is requested that
1990 would lose precision, the precise conversion (or differently
1991 imprecise conversion) is also performed and cached, to prevent
1992 requests for different numeric formats on the same SV causing
1993 lossy conversion chains. (lossless conversion chains are perfectly
1998 SvIOKp is true if the IV slot contains a valid value
1999 SvIOK is true only if the IV value is accurate (UV if SvIOK_UV true)
2000 SvNOKp is true if the NV slot contains a valid value
2001 SvNOK is true only if the NV value is accurate
2004 while converting from PV to NV, check to see if converting that NV to an
2005 IV(or UV) would lose accuracy over a direct conversion from PV to
2006 IV(or UV). If it would, cache both conversions, return NV, but mark
2007 SV as IOK NOKp (ie not NOK).
2009 While converting from PV to IV, check to see if converting that IV to an
2010 NV would lose accuracy over a direct conversion from PV to NV. If it
2011 would, cache both conversions, flag similarly.
2013 Before, the SV value "3.2" could become NV=3.2 IV=3 NOK, IOK quite
2014 correctly because if IV & NV were set NV *always* overruled.
2015 Now, "3.2" will become NV=3.2 IV=3 NOK, IOKp, because the flag's meaning
2016 changes - now IV and NV together means that the two are interchangeable:
2017 SvIVX == (IV) SvNVX && SvNVX == (NV) SvIVX;
2019 The benefit of this is that operations such as pp_add know that if
2020 SvIOK is true for both left and right operands, then integer addition
2021 can be used instead of floating point (for cases where the result won't
2022 overflow). Before, floating point was always used, which could lead to
2023 loss of precision compared with integer addition.
2025 * making IV and NV equal status should make maths accurate on 64 bit
2027 * may speed up maths somewhat if pp_add and friends start to use
2028 integers when possible instead of fp. (Hopefully the overhead in
2029 looking for SvIOK and checking for overflow will not outweigh the
2030 fp to integer speedup)
2031 * will slow down integer operations (callers of SvIV) on "inaccurate"
2032 values, as the change from SvIOK to SvIOKp will cause a call into
2033 sv_2iv each time rather than a macro access direct to the IV slot
2034 * should speed up number->string conversion on integers as IV is
2035 favoured when IV and NV are equally accurate
2037 ####################################################################
2038 You had better be using SvIOK_notUV if you want an IV for arithmetic:
2039 SvIOK is true if (IV or UV), so you might be getting (IV)SvUV.
2040 On the other hand, SvUOK is true iff UV.
2041 ####################################################################
2043 Your mileage will vary depending your CPU's relative fp to integer
2047 #ifndef NV_PRESERVES_UV
2048 # define IS_NUMBER_UNDERFLOW_IV 1
2049 # define IS_NUMBER_UNDERFLOW_UV 2
2050 # define IS_NUMBER_IV_AND_UV 2
2051 # define IS_NUMBER_OVERFLOW_IV 4
2052 # define IS_NUMBER_OVERFLOW_UV 5
2054 /* sv_2iuv_non_preserve(): private routine for use by sv_2iv() and sv_2uv() */
2056 /* For sv_2nv these three cases are "SvNOK and don't bother casting" */
2058 S_sv_2iuv_non_preserve(pTHX_ SV *const sv
2064 PERL_ARGS_ASSERT_SV_2IUV_NON_PRESERVE;
2065 PERL_UNUSED_CONTEXT;
2067 DEBUG_c(PerlIO_printf(Perl_debug_log,"sv_2iuv_non '%s', IV=0x%"UVxf" NV=%"NVgf" inttype=%"UVXf"\n", SvPVX_const(sv), SvIVX(sv), SvNVX(sv), (UV)numtype));
2068 if (SvNVX(sv) < (NV)IV_MIN) {
2069 (void)SvIOKp_on(sv);
2071 SvIV_set(sv, IV_MIN);
2072 return IS_NUMBER_UNDERFLOW_IV;
2074 if (SvNVX(sv) > (NV)UV_MAX) {
2075 (void)SvIOKp_on(sv);
2078 SvUV_set(sv, UV_MAX);
2079 return IS_NUMBER_OVERFLOW_UV;
2081 (void)SvIOKp_on(sv);
2083 /* Can't use strtol etc to convert this string. (See truth table in
2085 if (SvNVX(sv) <= (UV)IV_MAX) {
2086 SvIV_set(sv, I_V(SvNVX(sv)));
2087 if ((NV)(SvIVX(sv)) == SvNVX(sv)) {
2088 SvIOK_on(sv); /* Integer is precise. NOK, IOK */
2090 /* Integer is imprecise. NOK, IOKp */
2092 return SvNVX(sv) < 0 ? IS_NUMBER_UNDERFLOW_UV : IS_NUMBER_IV_AND_UV;
2095 SvUV_set(sv, U_V(SvNVX(sv)));
2096 if ((NV)(SvUVX(sv)) == SvNVX(sv)) {
2097 if (SvUVX(sv) == UV_MAX) {
2098 /* As we know that NVs don't preserve UVs, UV_MAX cannot
2099 possibly be preserved by NV. Hence, it must be overflow.
2101 return IS_NUMBER_OVERFLOW_UV;
2103 SvIOK_on(sv); /* Integer is precise. NOK, UOK */
2105 /* Integer is imprecise. NOK, IOKp */
2107 return IS_NUMBER_OVERFLOW_IV;
2109 #endif /* !NV_PRESERVES_UV*/
2111 /* If numtype is infnan, set the NV of the sv accordingly.
2112 * If numtype is anything else, try setting the NV using Atof(PV). */
2114 # pragma warning(push)
2115 # pragma warning(disable:4756;disable:4056)
2118 S_sv_setnv(pTHX_ SV* sv, int numtype)
2120 bool pok = cBOOL(SvPOK(sv));
2122 if ((numtype & IS_NUMBER_INFINITY)) {
2123 SvNV_set(sv, (numtype & IS_NUMBER_NEG) ? -NV_INF : NV_INF);
2126 else if ((numtype & IS_NUMBER_NAN)) {
2127 SvNV_set(sv, NV_NAN);
2131 SvNV_set(sv, Atof(SvPVX_const(sv)));
2132 /* Purposefully no true nok here, since we don't want to blow
2133 * away the possible IOK/UV of an existing sv. */
2136 SvNOK_only(sv); /* No IV or UV please, this is pure infnan. */
2138 SvPOK_on(sv); /* PV is okay, though. */
2142 # pragma warning(pop)
2146 S_sv_2iuv_common(pTHX_ SV *const sv)
2148 PERL_ARGS_ASSERT_SV_2IUV_COMMON;
2151 /* erm. not sure. *should* never get NOKp (without NOK) from sv_2nv
2152 * without also getting a cached IV/UV from it at the same time
2153 * (ie PV->NV conversion should detect loss of accuracy and cache
2154 * IV or UV at same time to avoid this. */
2155 /* IV-over-UV optimisation - choose to cache IV if possible */
2157 if (SvTYPE(sv) == SVt_NV)
2158 sv_upgrade(sv, SVt_PVNV);
2160 (void)SvIOKp_on(sv); /* Must do this first, to clear any SvOOK */
2161 /* < not <= as for NV doesn't preserve UV, ((NV)IV_MAX+1) will almost
2162 certainly cast into the IV range at IV_MAX, whereas the correct
2163 answer is the UV IV_MAX +1. Hence < ensures that dodgy boundary
2165 #if defined(NAN_COMPARE_BROKEN) && defined(Perl_isnan)
2166 if (Perl_isnan(SvNVX(sv))) {
2172 if (SvNVX(sv) < (NV)IV_MAX + 0.5) {
2173 SvIV_set(sv, I_V(SvNVX(sv)));
2174 if (SvNVX(sv) == (NV) SvIVX(sv)
2175 #ifndef NV_PRESERVES_UV
2176 && SvIVX(sv) != IV_MIN /* avoid negating IV_MIN below */
2177 && (((UV)1 << NV_PRESERVES_UV_BITS) >
2178 (UV)(SvIVX(sv) > 0 ? SvIVX(sv) : -SvIVX(sv)))
2179 /* Don't flag it as "accurately an integer" if the number
2180 came from a (by definition imprecise) NV operation, and
2181 we're outside the range of NV integer precision */
2185 SvIOK_on(sv); /* Can this go wrong with rounding? NWC */
2187 /* scalar has trailing garbage, eg "42a" */
2189 DEBUG_c(PerlIO_printf(Perl_debug_log,
2190 "0x%"UVxf" iv(%"NVgf" => %"IVdf") (precise)\n",
2196 /* IV not precise. No need to convert from PV, as NV
2197 conversion would already have cached IV if it detected
2198 that PV->IV would be better than PV->NV->IV
2199 flags already correct - don't set public IOK. */
2200 DEBUG_c(PerlIO_printf(Perl_debug_log,
2201 "0x%"UVxf" iv(%"NVgf" => %"IVdf") (imprecise)\n",
2206 /* Can the above go wrong if SvIVX == IV_MIN and SvNVX < IV_MIN,
2207 but the cast (NV)IV_MIN rounds to a the value less (more
2208 negative) than IV_MIN which happens to be equal to SvNVX ??
2209 Analogous to 0xFFFFFFFFFFFFFFFF rounding up to NV (2**64) and
2210 NV rounding back to 0xFFFFFFFFFFFFFFFF, so UVX == UV(NVX) and
2211 (NV)UVX == NVX are both true, but the values differ. :-(
2212 Hopefully for 2s complement IV_MIN is something like
2213 0x8000000000000000 which will be exact. NWC */
2216 SvUV_set(sv, U_V(SvNVX(sv)));
2218 (SvNVX(sv) == (NV) SvUVX(sv))
2219 #ifndef NV_PRESERVES_UV
2220 /* Make sure it's not 0xFFFFFFFFFFFFFFFF */
2221 /*&& (SvUVX(sv) != UV_MAX) irrelevant with code below */
2222 && (((UV)1 << NV_PRESERVES_UV_BITS) > SvUVX(sv))
2223 /* Don't flag it as "accurately an integer" if the number
2224 came from a (by definition imprecise) NV operation, and
2225 we're outside the range of NV integer precision */
2231 DEBUG_c(PerlIO_printf(Perl_debug_log,
2232 "0x%"UVxf" 2iv(%"UVuf" => %"IVdf") (as unsigned)\n",
2238 else if (SvPOKp(sv)) {
2240 const int numtype = grok_number(SvPVX_const(sv), SvCUR(sv), &value);
2241 /* We want to avoid a possible problem when we cache an IV/ a UV which
2242 may be later translated to an NV, and the resulting NV is not
2243 the same as the direct translation of the initial string
2244 (eg 123.456 can shortcut to the IV 123 with atol(), but we must
2245 be careful to ensure that the value with the .456 is around if the
2246 NV value is requested in the future).
2248 This means that if we cache such an IV/a UV, we need to cache the
2249 NV as well. Moreover, we trade speed for space, and do not
2250 cache the NV if we are sure it's not needed.
2253 /* SVt_PVNV is one higher than SVt_PVIV, hence this order */
2254 if ((numtype & (IS_NUMBER_IN_UV | IS_NUMBER_NOT_INT))
2255 == IS_NUMBER_IN_UV) {
2256 /* It's definitely an integer, only upgrade to PVIV */
2257 if (SvTYPE(sv) < SVt_PVIV)
2258 sv_upgrade(sv, SVt_PVIV);
2260 } else if (SvTYPE(sv) < SVt_PVNV)
2261 sv_upgrade(sv, SVt_PVNV);
2263 if ((numtype & (IS_NUMBER_INFINITY | IS_NUMBER_NAN))) {
2264 if (ckWARN(WARN_NUMERIC) && ((numtype & IS_NUMBER_TRAILING)))
2266 S_sv_setnv(aTHX_ sv, numtype);
2270 /* If NVs preserve UVs then we only use the UV value if we know that
2271 we aren't going to call atof() below. If NVs don't preserve UVs
2272 then the value returned may have more precision than atof() will
2273 return, even though value isn't perfectly accurate. */
2274 if ((numtype & (IS_NUMBER_IN_UV
2275 #ifdef NV_PRESERVES_UV
2278 )) == IS_NUMBER_IN_UV) {
2279 /* This won't turn off the public IOK flag if it was set above */
2280 (void)SvIOKp_on(sv);
2282 if (!(numtype & IS_NUMBER_NEG)) {
2284 if (value <= (UV)IV_MAX) {
2285 SvIV_set(sv, (IV)value);
2287 /* it didn't overflow, and it was positive. */
2288 SvUV_set(sv, value);
2292 /* 2s complement assumption */
2293 if (value <= (UV)IV_MIN) {
2294 SvIV_set(sv, value == (UV)IV_MIN
2295 ? IV_MIN : -(IV)value);
2297 /* Too negative for an IV. This is a double upgrade, but
2298 I'm assuming it will be rare. */
2299 if (SvTYPE(sv) < SVt_PVNV)
2300 sv_upgrade(sv, SVt_PVNV);
2304 SvNV_set(sv, -(NV)value);
2305 SvIV_set(sv, IV_MIN);
2309 /* For !NV_PRESERVES_UV and IS_NUMBER_IN_UV and IS_NUMBER_NOT_INT we
2310 will be in the previous block to set the IV slot, and the next
2311 block to set the NV slot. So no else here. */
2313 if ((numtype & (IS_NUMBER_IN_UV | IS_NUMBER_NOT_INT))
2314 != IS_NUMBER_IN_UV) {
2315 /* It wasn't an (integer that doesn't overflow the UV). */
2316 S_sv_setnv(aTHX_ sv, numtype);
2318 if (! numtype && ckWARN(WARN_NUMERIC))
2321 DEBUG_c(PerlIO_printf(Perl_debug_log, "0x%"UVxf" 2iv(%" NVgf ")\n",
2322 PTR2UV(sv), SvNVX(sv)));
2324 #ifdef NV_PRESERVES_UV
2325 (void)SvIOKp_on(sv);
2327 #if defined(NAN_COMPARE_BROKEN) && defined(Perl_isnan)
2328 if (Perl_isnan(SvNVX(sv))) {
2334 if (SvNVX(sv) < (NV)IV_MAX + 0.5) {
2335 SvIV_set(sv, I_V(SvNVX(sv)));
2336 if ((NV)(SvIVX(sv)) == SvNVX(sv)) {
2339 NOOP; /* Integer is imprecise. NOK, IOKp */
2341 /* UV will not work better than IV */
2343 if (SvNVX(sv) > (NV)UV_MAX) {
2345 /* Integer is inaccurate. NOK, IOKp, is UV */
2346 SvUV_set(sv, UV_MAX);
2348 SvUV_set(sv, U_V(SvNVX(sv)));
2349 /* 0xFFFFFFFFFFFFFFFF not an issue in here, NVs
2350 NV preservse UV so can do correct comparison. */
2351 if ((NV)(SvUVX(sv)) == SvNVX(sv)) {
2354 NOOP; /* Integer is imprecise. NOK, IOKp, is UV */
2359 #else /* NV_PRESERVES_UV */
2360 if ((numtype & (IS_NUMBER_IN_UV | IS_NUMBER_NOT_INT))
2361 == (IS_NUMBER_IN_UV | IS_NUMBER_NOT_INT)) {
2362 /* The IV/UV slot will have been set from value returned by
2363 grok_number above. The NV slot has just been set using
2366 assert (SvIOKp(sv));
2368 if (((UV)1 << NV_PRESERVES_UV_BITS) >
2369 U_V(SvNVX(sv) > 0 ? SvNVX(sv) : -SvNVX(sv))) {
2370 /* Small enough to preserve all bits. */
2371 (void)SvIOKp_on(sv);
2373 SvIV_set(sv, I_V(SvNVX(sv)));
2374 if ((NV)(SvIVX(sv)) == SvNVX(sv))
2376 /* Assumption: first non-preserved integer is < IV_MAX,
2377 this NV is in the preserved range, therefore: */
2378 if (!(U_V(SvNVX(sv) > 0 ? SvNVX(sv) : -SvNVX(sv))
2380 Perl_croak(aTHX_ "sv_2iv assumed (U_V(fabs((double)SvNVX(sv))) < (UV)IV_MAX) but SvNVX(sv)=%"NVgf" U_V is 0x%"UVxf", IV_MAX is 0x%"UVxf"\n", SvNVX(sv), U_V(SvNVX(sv)), (UV)IV_MAX);
2384 0 0 already failed to read UV.
2385 0 1 already failed to read UV.
2386 1 0 you won't get here in this case. IV/UV
2387 slot set, public IOK, Atof() unneeded.
2388 1 1 already read UV.
2389 so there's no point in sv_2iuv_non_preserve() attempting
2390 to use atol, strtol, strtoul etc. */
2392 sv_2iuv_non_preserve (sv, numtype);
2394 sv_2iuv_non_preserve (sv);
2398 #endif /* NV_PRESERVES_UV */
2399 /* It might be more code efficient to go through the entire logic above
2400 and conditionally set with SvIOKp_on() rather than SvIOK(), but it
2401 gets complex and potentially buggy, so more programmer efficient
2402 to do it this way, by turning off the public flags: */
2404 SvFLAGS(sv) &= ~(SVf_IOK|SVf_NOK);
2408 if (isGV_with_GP(sv))
2409 return glob_2number(MUTABLE_GV(sv));
2411 if (!PL_localizing && ckWARN(WARN_UNINITIALIZED))
2413 if (SvTYPE(sv) < SVt_IV)
2414 /* Typically the caller expects that sv_any is not NULL now. */
2415 sv_upgrade(sv, SVt_IV);
2416 /* Return 0 from the caller. */
2423 =for apidoc sv_2iv_flags
2425 Return the integer value of an SV, doing any necessary string
2426 conversion. If flags includes SV_GMAGIC, does an mg_get() first.
2427 Normally used via the C<SvIV(sv)> and C<SvIVx(sv)> macros.
2433 Perl_sv_2iv_flags(pTHX_ SV *const sv, const I32 flags)
2435 PERL_ARGS_ASSERT_SV_2IV_FLAGS;
2437 assert (SvTYPE(sv) != SVt_PVAV && SvTYPE(sv) != SVt_PVHV
2438 && SvTYPE(sv) != SVt_PVFM);
2440 if (SvGMAGICAL(sv) && (flags & SV_GMAGIC))
2446 if (flags & SV_SKIP_OVERLOAD)
2448 tmpstr = AMG_CALLunary(sv, numer_amg);
2449 if (tmpstr && (!SvROK(tmpstr) || (SvRV(tmpstr) != SvRV(sv)))) {
2450 return SvIV(tmpstr);
2453 return PTR2IV(SvRV(sv));
2456 if (SvVALID(sv) || isREGEXP(sv)) {
2457 /* FBMs use the space for SvIVX and SvNVX for other purposes, and use
2458 the same flag bit as SVf_IVisUV, so must not let them cache IVs.
2459 In practice they are extremely unlikely to actually get anywhere
2460 accessible by user Perl code - the only way that I'm aware of is when
2461 a constant subroutine which is used as the second argument to index.
2463 Regexps have no SvIVX and SvNVX fields.
2465 assert(isREGEXP(sv) || SvPOKp(sv));
2468 const char * const ptr =
2469 isREGEXP(sv) ? RX_WRAPPED((REGEXP*)sv) : SvPVX_const(sv);
2471 = grok_number(ptr, SvCUR(sv), &value);
2473 if ((numtype & (IS_NUMBER_IN_UV | IS_NUMBER_NOT_INT))
2474 == IS_NUMBER_IN_UV) {
2475 /* It's definitely an integer */
2476 if (numtype & IS_NUMBER_NEG) {
2477 if (value < (UV)IV_MIN)
2480 if (value < (UV)IV_MAX)
2485 /* Quite wrong but no good choices. */
2486 if ((numtype & IS_NUMBER_INFINITY)) {
2487 return (numtype & IS_NUMBER_NEG) ? IV_MIN : IV_MAX;
2488 } else if ((numtype & IS_NUMBER_NAN)) {
2489 return 0; /* So wrong. */
2493 if (ckWARN(WARN_NUMERIC))
2496 return I_V(Atof(ptr));
2500 if (SvTHINKFIRST(sv)) {
2501 #ifdef PERL_OLD_COPY_ON_WRITE
2503 sv_force_normal_flags(sv, 0);
2506 if (SvREADONLY(sv) && !SvOK(sv)) {
2507 if (ckWARN(WARN_UNINITIALIZED))
2514 if (S_sv_2iuv_common(aTHX_ sv))
2518 DEBUG_c(PerlIO_printf(Perl_debug_log, "0x%"UVxf" 2iv(%"IVdf")\n",
2519 PTR2UV(sv),SvIVX(sv)));
2520 return SvIsUV(sv) ? (IV)SvUVX(sv) : SvIVX(sv);
2524 =for apidoc sv_2uv_flags
2526 Return the unsigned integer value of an SV, doing any necessary string
2527 conversion. If flags includes SV_GMAGIC, does an mg_get() first.
2528 Normally used via the C<SvUV(sv)> and C<SvUVx(sv)> macros.
2534 Perl_sv_2uv_flags(pTHX_ SV *const sv, const I32 flags)
2536 PERL_ARGS_ASSERT_SV_2UV_FLAGS;
2538 if (SvGMAGICAL(sv) && (flags & SV_GMAGIC))
2544 if (flags & SV_SKIP_OVERLOAD)
2546 tmpstr = AMG_CALLunary(sv, numer_amg);
2547 if (tmpstr && (!SvROK(tmpstr) || (SvRV(tmpstr) != SvRV(sv)))) {
2548 return SvUV(tmpstr);
2551 return PTR2UV(SvRV(sv));
2554 if (SvVALID(sv) || isREGEXP(sv)) {
2555 /* FBMs use the space for SvIVX and SvNVX for other purposes, and use
2556 the same flag bit as SVf_IVisUV, so must not let them cache IVs.
2557 Regexps have no SvIVX and SvNVX fields. */
2558 assert(isREGEXP(sv) || SvPOKp(sv));
2561 const char * const ptr =
2562 isREGEXP(sv) ? RX_WRAPPED((REGEXP*)sv) : SvPVX_const(sv);
2564 = grok_number(ptr, SvCUR(sv), &value);
2566 if ((numtype & (IS_NUMBER_IN_UV | IS_NUMBER_NOT_INT))
2567 == IS_NUMBER_IN_UV) {
2568 /* It's definitely an integer */
2569 if (!(numtype & IS_NUMBER_NEG))
2573 /* Quite wrong but no good choices. */
2574 if ((numtype & IS_NUMBER_INFINITY)) {
2575 return UV_MAX; /* So wrong. */
2576 } else if ((numtype & IS_NUMBER_NAN)) {
2577 return 0; /* So wrong. */
2581 if (ckWARN(WARN_NUMERIC))
2584 return U_V(Atof(ptr));
2588 if (SvTHINKFIRST(sv)) {
2589 #ifdef PERL_OLD_COPY_ON_WRITE
2591 sv_force_normal_flags(sv, 0);
2594 if (SvREADONLY(sv) && !SvOK(sv)) {
2595 if (ckWARN(WARN_UNINITIALIZED))
2602 if (S_sv_2iuv_common(aTHX_ sv))
2606 DEBUG_c(PerlIO_printf(Perl_debug_log, "0x%"UVxf" 2uv(%"UVuf")\n",
2607 PTR2UV(sv),SvUVX(sv)));
2608 return SvIsUV(sv) ? SvUVX(sv) : (UV)SvIVX(sv);
2612 =for apidoc sv_2nv_flags
2614 Return the num value of an SV, doing any necessary string or integer
2615 conversion. If flags includes SV_GMAGIC, does an mg_get() first.
2616 Normally used via the C<SvNV(sv)> and C<SvNVx(sv)> macros.
2622 Perl_sv_2nv_flags(pTHX_ SV *const sv, const I32 flags)
2624 PERL_ARGS_ASSERT_SV_2NV_FLAGS;
2626 assert (SvTYPE(sv) != SVt_PVAV && SvTYPE(sv) != SVt_PVHV
2627 && SvTYPE(sv) != SVt_PVFM);
2628 if (SvGMAGICAL(sv) || SvVALID(sv) || isREGEXP(sv)) {
2629 /* FBMs use the space for SvIVX and SvNVX for other purposes, and use
2630 the same flag bit as SVf_IVisUV, so must not let them cache NVs.
2631 Regexps have no SvIVX and SvNVX fields. */
2633 if (flags & SV_GMAGIC)
2637 if (SvPOKp(sv) && !SvIOKp(sv)) {
2638 ptr = SvPVX_const(sv);
2640 if (!SvIOKp(sv) && ckWARN(WARN_NUMERIC) &&
2641 !grok_number(ptr, SvCUR(sv), NULL))
2647 return (NV)SvUVX(sv);
2649 return (NV)SvIVX(sv);
2655 ptr = RX_WRAPPED((REGEXP *)sv);
2658 assert(SvTYPE(sv) >= SVt_PVMG);
2659 /* This falls through to the report_uninit near the end of the
2661 } else if (SvTHINKFIRST(sv)) {
2666 if (flags & SV_SKIP_OVERLOAD)
2668 tmpstr = AMG_CALLunary(sv, numer_amg);
2669 if (tmpstr && (!SvROK(tmpstr) || (SvRV(tmpstr) != SvRV(sv)))) {
2670 return SvNV(tmpstr);
2673 return PTR2NV(SvRV(sv));
2675 #ifdef PERL_OLD_COPY_ON_WRITE
2677 sv_force_normal_flags(sv, 0);
2680 if (SvREADONLY(sv) && !SvOK(sv)) {
2681 if (ckWARN(WARN_UNINITIALIZED))
2686 if (SvTYPE(sv) < SVt_NV) {
2687 /* The logic to use SVt_PVNV if necessary is in sv_upgrade. */
2688 sv_upgrade(sv, SVt_NV);
2690 STORE_NUMERIC_LOCAL_SET_STANDARD();
2691 PerlIO_printf(Perl_debug_log,
2692 "0x%"UVxf" num(%" NVgf ")\n",
2693 PTR2UV(sv), SvNVX(sv));
2694 RESTORE_NUMERIC_LOCAL();
2697 else if (SvTYPE(sv) < SVt_PVNV)
2698 sv_upgrade(sv, SVt_PVNV);
2703 SvNV_set(sv, SvIsUV(sv) ? (NV)SvUVX(sv) : (NV)SvIVX(sv));
2704 #ifdef NV_PRESERVES_UV
2710 /* Only set the public NV OK flag if this NV preserves the IV */
2711 /* Check it's not 0xFFFFFFFFFFFFFFFF */
2713 SvIsUV(sv) ? ((SvUVX(sv) != UV_MAX)&&(SvUVX(sv) == U_V(SvNVX(sv))))
2714 : (SvIVX(sv) == I_V(SvNVX(sv))))
2720 else if (SvPOKp(sv)) {
2722 const int numtype = grok_number(SvPVX_const(sv), SvCUR(sv), &value);
2723 if (!SvIOKp(sv) && !numtype && ckWARN(WARN_NUMERIC))
2725 #ifdef NV_PRESERVES_UV
2726 if ((numtype & (IS_NUMBER_IN_UV | IS_NUMBER_NOT_INT))
2727 == IS_NUMBER_IN_UV) {
2728 /* It's definitely an integer */
2729 SvNV_set(sv, (numtype & IS_NUMBER_NEG) ? -(NV)value : (NV)value);
2731 S_sv_setnv(aTHX_ sv, numtype);
2738 SvNV_set(sv, Atof(SvPVX_const(sv)));
2739 /* Only set the public NV OK flag if this NV preserves the value in
2740 the PV at least as well as an IV/UV would.
2741 Not sure how to do this 100% reliably. */
2742 /* if that shift count is out of range then Configure's test is
2743 wonky. We shouldn't be in here with NV_PRESERVES_UV_BITS ==
2745 if (((UV)1 << NV_PRESERVES_UV_BITS) >
2746 U_V(SvNVX(sv) > 0 ? SvNVX(sv) : -SvNVX(sv))) {
2747 SvNOK_on(sv); /* Definitely small enough to preserve all bits */
2748 } else if (!(numtype & IS_NUMBER_IN_UV)) {
2749 /* Can't use strtol etc to convert this string, so don't try.
2750 sv_2iv and sv_2uv will use the NV to convert, not the PV. */
2753 /* value has been set. It may not be precise. */
2754 if ((numtype & IS_NUMBER_NEG) && (value >= (UV)IV_MIN)) {
2755 /* 2s complement assumption for (UV)IV_MIN */
2756 SvNOK_on(sv); /* Integer is too negative. */
2761 if (numtype & IS_NUMBER_NEG) {
2762 /* -IV_MIN is undefined, but we should never reach
2763 * this point with both IS_NUMBER_NEG and value ==
2765 assert(value != (UV)IV_MIN);
2766 SvIV_set(sv, -(IV)value);
2767 } else if (value <= (UV)IV_MAX) {
2768 SvIV_set(sv, (IV)value);
2770 SvUV_set(sv, value);
2774 if (numtype & IS_NUMBER_NOT_INT) {
2775 /* I believe that even if the original PV had decimals,
2776 they are lost beyond the limit of the FP precision.
2777 However, neither is canonical, so both only get p
2778 flags. NWC, 2000/11/25 */
2779 /* Both already have p flags, so do nothing */
2781 const NV nv = SvNVX(sv);
2782 /* XXX should this spot have NAN_COMPARE_BROKEN, too? */
2783 if (SvNVX(sv) < (NV)IV_MAX + 0.5) {
2784 if (SvIVX(sv) == I_V(nv)) {
2787 /* It had no "." so it must be integer. */
2791 /* between IV_MAX and NV(UV_MAX).
2792 Could be slightly > UV_MAX */
2794 if (numtype & IS_NUMBER_NOT_INT) {
2795 /* UV and NV both imprecise. */
2797 const UV nv_as_uv = U_V(nv);
2799 if (value == nv_as_uv && SvUVX(sv) != UV_MAX) {
2808 /* It might be more code efficient to go through the entire logic above
2809 and conditionally set with SvNOKp_on() rather than SvNOK(), but it
2810 gets complex and potentially buggy, so more programmer efficient
2811 to do it this way, by turning off the public flags: */
2813 SvFLAGS(sv) &= ~(SVf_IOK|SVf_NOK);
2814 #endif /* NV_PRESERVES_UV */
2817 if (isGV_with_GP(sv)) {
2818 glob_2number(MUTABLE_GV(sv));
2822 if (!PL_localizing && ckWARN(WARN_UNINITIALIZED))
2824 assert (SvTYPE(sv) >= SVt_NV);
2825 /* Typically the caller expects that sv_any is not NULL now. */
2826 /* XXX Ilya implies that this is a bug in callers that assume this
2827 and ideally should be fixed. */
2831 STORE_NUMERIC_LOCAL_SET_STANDARD();
2832 PerlIO_printf(Perl_debug_log, "0x%"UVxf" 2nv(%" NVgf ")\n",
2833 PTR2UV(sv), SvNVX(sv));
2834 RESTORE_NUMERIC_LOCAL();
2842 Return an SV with the numeric value of the source SV, doing any necessary
2843 reference or overload conversion. The caller is expected to have handled
2850 Perl_sv_2num(pTHX_ SV *const sv)
2852 PERL_ARGS_ASSERT_SV_2NUM;
2857 SV * const tmpsv = AMG_CALLunary(sv, numer_amg);
2858 TAINT_IF(tmpsv && SvTAINTED(tmpsv));
2859 if (tmpsv && (!SvROK(tmpsv) || (SvRV(tmpsv) != SvRV(sv))))
2860 return sv_2num(tmpsv);
2862 return sv_2mortal(newSVuv(PTR2UV(SvRV(sv))));
2865 /* uiv_2buf(): private routine for use by sv_2pv_flags(): print an IV or
2866 * UV as a string towards the end of buf, and return pointers to start and
2869 * We assume that buf is at least TYPE_CHARS(UV) long.
2873 S_uiv_2buf(char *const buf, const IV iv, UV uv, const int is_uv, char **const peob)
2875 char *ptr = buf + TYPE_CHARS(UV);
2876 char * const ebuf = ptr;
2879 PERL_ARGS_ASSERT_UIV_2BUF;
2887 uv = (iv == IV_MIN) ? (UV)iv : (UV)(-iv);
2891 *--ptr = '0' + (char)(uv % 10);
2899 /* Helper for sv_2pv_flags and sv_vcatpvfn_flags. If the NV is an
2900 * infinity or a not-a-number, writes the appropriate strings to the
2901 * buffer, including a zero byte. On success returns the written length,
2902 * excluding the zero byte, on failure (not an infinity, not a nan, or the
2903 * maxlen too small) returns zero.
2905 * XXX for "Inf", "-Inf", and "NaN", we could have three read-only
2906 * shared string constants we point to, instead of generating a new
2907 * string for each instance. */
2909 S_infnan_2pv(NV nv, char* buffer, size_t maxlen, char plus) {
2910 assert(maxlen >= 4);
2911 if (maxlen < 4) /* "Inf\0", "NaN\0" */
2915 if (Perl_isinf(nv)) {
2917 if (maxlen < 5) /* "-Inf\0" */
2926 } else if (Perl_isnan(nv)) {
2930 /* XXX optionally output the payload mantissa bits as
2931 * "(unsigned)" (to match the nan("...") C99 function,
2932 * or maybe as "(0xhhh...)" would make more sense...
2933 * provide a format string so that the user can decide?
2934 * NOTE: would affect the maxlen and assert() logic.*/
2939 assert((s == buffer + 3) || (s == buffer + 4));
2941 return s - buffer - 1; /* -1: excluding the zero byte */
2946 =for apidoc sv_2pv_flags
2948 Returns a pointer to the string value of an SV, and sets *lp to its length.
2949 If flags includes SV_GMAGIC, does an mg_get() first. Coerces sv to a
2950 string if necessary. Normally invoked via the C<SvPV_flags> macro.
2951 C<sv_2pv()> and C<sv_2pv_nomg> usually end up here too.
2957 Perl_sv_2pv_flags(pTHX_ SV *const sv, STRLEN *const lp, const I32 flags)
2961 PERL_ARGS_ASSERT_SV_2PV_FLAGS;
2963 assert (SvTYPE(sv) != SVt_PVAV && SvTYPE(sv) != SVt_PVHV
2964 && SvTYPE(sv) != SVt_PVFM);
2965 if (SvGMAGICAL(sv) && (flags & SV_GMAGIC))
2970 if (flags & SV_SKIP_OVERLOAD)
2972 tmpstr = AMG_CALLunary(sv, string_amg);
2973 TAINT_IF(tmpstr && SvTAINTED(tmpstr));
2974 if (tmpstr && (!SvROK(tmpstr) || (SvRV(tmpstr) != SvRV(sv)))) {
2976 /* char *pv = lp ? SvPV(tmpstr, *lp) : SvPV_nolen(tmpstr);
2980 if ((SvFLAGS(tmpstr) & (SVf_POK)) == SVf_POK) {
2981 if (flags & SV_CONST_RETURN) {
2982 pv = (char *) SvPVX_const(tmpstr);
2984 pv = (flags & SV_MUTABLE_RETURN)
2985 ? SvPVX_mutable(tmpstr) : SvPVX(tmpstr);
2988 *lp = SvCUR(tmpstr);
2990 pv = sv_2pv_flags(tmpstr, lp, flags);
3003 SV *const referent = SvRV(sv);
3007 retval = buffer = savepvn("NULLREF", len);
3008 } else if (SvTYPE(referent) == SVt_REGEXP &&
3009 (!(PL_curcop->cop_hints & HINT_NO_AMAGIC) ||
3010 amagic_is_enabled(string_amg))) {
3011 REGEXP * const re = (REGEXP *)MUTABLE_PTR(referent);
3015 /* If the regex is UTF-8 we want the containing scalar to
3016 have an UTF-8 flag too */
3023 *lp = RX_WRAPLEN(re);
3025 return RX_WRAPPED(re);
3027 const char *const typestr = sv_reftype(referent, 0);
3028 const STRLEN typelen = strlen(typestr);
3029 UV addr = PTR2UV(referent);
3030 const char *stashname = NULL;
3031 STRLEN stashnamelen = 0; /* hush, gcc */
3032 const char *buffer_end;
3034 if (SvOBJECT(referent)) {
3035 const HEK *const name = HvNAME_HEK(SvSTASH(referent));
3038 stashname = HEK_KEY(name);
3039 stashnamelen = HEK_LEN(name);
3041 if (HEK_UTF8(name)) {
3047 stashname = "__ANON__";
3050 len = stashnamelen + 1 /* = */ + typelen + 3 /* (0x */
3051 + 2 * sizeof(UV) + 2 /* )\0 */;
3053 len = typelen + 3 /* (0x */
3054 + 2 * sizeof(UV) + 2 /* )\0 */;
3057 Newx(buffer, len, char);
3058 buffer_end = retval = buffer + len;
3060 /* Working backwards */
3064 *--retval = PL_hexdigit[addr & 15];
3065 } while (addr >>= 4);
3071 memcpy(retval, typestr, typelen);
3075 retval -= stashnamelen;
3076 memcpy(retval, stashname, stashnamelen);
3078 /* retval may not necessarily have reached the start of the
3080 assert (retval >= buffer);
3082 len = buffer_end - retval - 1; /* -1 for that \0 */
3094 if (flags & SV_MUTABLE_RETURN)
3095 return SvPVX_mutable(sv);
3096 if (flags & SV_CONST_RETURN)
3097 return (char *)SvPVX_const(sv);
3102 /* I'm assuming that if both IV and NV are equally valid then
3103 converting the IV is going to be more efficient */
3104 const U32 isUIOK = SvIsUV(sv);
3105 char buf[TYPE_CHARS(UV)];
3109 if (SvTYPE(sv) < SVt_PVIV)
3110 sv_upgrade(sv, SVt_PVIV);
3111 ptr = uiv_2buf(buf, SvIVX(sv), SvUVX(sv), isUIOK, &ebuf);
3113 /* inlined from sv_setpvn */
3114 s = SvGROW_mutable(sv, len + 1);
3115 Move(ptr, s, len, char);
3120 else if (SvNOK(sv)) {
3121 if (SvTYPE(sv) < SVt_PVNV)
3122 sv_upgrade(sv, SVt_PVNV);
3123 if (SvNVX(sv) == 0.0
3124 #if defined(NAN_COMPARE_BROKEN) && defined(Perl_isnan)
3125 && !Perl_isnan(SvNVX(sv))
3128 s = SvGROW_mutable(sv, 2);
3133 STRLEN size = 5; /* "-Inf\0" */
3135 s = SvGROW_mutable(sv, size);
3136 len = S_infnan_2pv(SvNVX(sv), s, size, 0);
3142 /* some Xenix systems wipe out errno here */
3151 5 + /* exponent digits */
3155 s = SvGROW_mutable(sv, size);
3156 #ifndef USE_LOCALE_NUMERIC
3157 SNPRINTF_G(SvNVX(sv), s, SvLEN(sv), NV_DIG);
3163 DECLARATION_FOR_LC_NUMERIC_MANIPULATION;
3164 STORE_LC_NUMERIC_SET_TO_NEEDED();
3168 PL_numeric_radix_sv &&
3169 SvUTF8(PL_numeric_radix_sv);
3170 if (local_radix && SvLEN(PL_numeric_radix_sv) > 1) {
3171 size += SvLEN(PL_numeric_radix_sv) - 1;
3172 s = SvGROW_mutable(sv, size);
3175 SNPRINTF_G(SvNVX(sv), s, SvLEN(sv), NV_DIG);
3177 /* If the radix character is UTF-8, and actually is in the
3178 * output, turn on the UTF-8 flag for the scalar */
3180 instr(s, SvPVX_const(PL_numeric_radix_sv))) {
3184 RESTORE_LC_NUMERIC();
3187 /* We don't call SvPOK_on(), because it may come to
3188 * pass that the locale changes so that the
3189 * stringification we just did is no longer correct. We
3190 * will have to re-stringify every time it is needed */
3197 else if (isGV_with_GP(sv)) {
3198 GV *const gv = MUTABLE_GV(sv);
3199 SV *const buffer = sv_newmortal();
3201 gv_efullname3(buffer, gv, "*");
3203 assert(SvPOK(buffer));
3207 *lp = SvCUR(buffer);
3208 return SvPVX(buffer);
3210 else if (isREGEXP(sv)) {
3211 if (lp) *lp = RX_WRAPLEN((REGEXP *)sv);
3212 return RX_WRAPPED((REGEXP *)sv);
3217 if (flags & SV_UNDEF_RETURNS_NULL)
3219 if (!PL_localizing && ckWARN(WARN_UNINITIALIZED))
3221 /* Typically the caller expects that sv_any is not NULL now. */
3222 if (!SvREADONLY(sv) && SvTYPE(sv) < SVt_PV)
3223 sv_upgrade(sv, SVt_PV);
3228 const STRLEN len = s - SvPVX_const(sv);
3233 DEBUG_c(PerlIO_printf(Perl_debug_log, "0x%"UVxf" 2pv(%s)\n",
3234 PTR2UV(sv),SvPVX_const(sv)));
3235 if (flags & SV_CONST_RETURN)
3236 return (char *)SvPVX_const(sv);
3237 if (flags & SV_MUTABLE_RETURN)
3238 return SvPVX_mutable(sv);
3243 =for apidoc sv_copypv
3245 Copies a stringified representation of the source SV into the
3246 destination SV. Automatically performs any necessary mg_get and
3247 coercion of numeric values into strings. Guaranteed to preserve
3248 UTF8 flag even from overloaded objects. Similar in nature to
3249 sv_2pv[_flags] but operates directly on an SV instead of just the
3250 string. Mostly uses sv_2pv_flags to do its work, except when that
3251 would lose the UTF-8'ness of the PV.
3253 =for apidoc sv_copypv_nomg
3255 Like sv_copypv, but doesn't invoke get magic first.
3257 =for apidoc sv_copypv_flags
3259 Implementation of sv_copypv and sv_copypv_nomg. Calls get magic iff flags
3266 Perl_sv_copypv_flags(pTHX_ SV *const dsv, SV *const ssv, const I32 flags)
3271 PERL_ARGS_ASSERT_SV_COPYPV_FLAGS;
3273 s = SvPV_flags_const(ssv,len,(flags & SV_GMAGIC));
3274 sv_setpvn(dsv,s,len);
3282 =for apidoc sv_2pvbyte
3284 Return a pointer to the byte-encoded representation of the SV, and set *lp
3285 to its length. May cause the SV to be downgraded from UTF-8 as a
3288 Usually accessed via the C<SvPVbyte> macro.
3294 Perl_sv_2pvbyte(pTHX_ SV *sv, STRLEN *const lp)
3296 PERL_ARGS_ASSERT_SV_2PVBYTE;
3299 if (((SvREADONLY(sv) || SvFAKE(sv)) && !SvIsCOW(sv))
3300 || isGV_with_GP(sv) || SvROK(sv)) {
3301 SV *sv2 = sv_newmortal();
3302 sv_copypv_nomg(sv2,sv);
3305 sv_utf8_downgrade(sv,0);
3306 return lp ? SvPV_nomg(sv,*lp) : SvPV_nomg_nolen(sv);
3310 =for apidoc sv_2pvutf8
3312 Return a pointer to the UTF-8-encoded representation of the SV, and set *lp
3313 to its length. May cause the SV to be upgraded to UTF-8 as a side-effect.
3315 Usually accessed via the C<SvPVutf8> macro.
3321 Perl_sv_2pvutf8(pTHX_ SV *sv, STRLEN *const lp)
3323 PERL_ARGS_ASSERT_SV_2PVUTF8;
3325 if (((SvREADONLY(sv) || SvFAKE(sv)) && !SvIsCOW(sv))
3326 || isGV_with_GP(sv) || SvROK(sv))
3327 sv = sv_mortalcopy(sv);
3330 sv_utf8_upgrade_nomg(sv);
3331 return lp ? SvPV_nomg(sv,*lp) : SvPV_nomg_nolen(sv);
3336 =for apidoc sv_2bool
3338 This macro is only used by sv_true() or its macro equivalent, and only if
3339 the latter's argument is neither SvPOK, SvIOK nor SvNOK.
3340 It calls sv_2bool_flags with the SV_GMAGIC flag.
3342 =for apidoc sv_2bool_flags
3344 This function is only used by sv_true() and friends, and only if
3345 the latter's argument is neither SvPOK, SvIOK nor SvNOK. If the flags
3346 contain SV_GMAGIC, then it does an mg_get() first.
3353 Perl_sv_2bool_flags(pTHX_ SV *sv, I32 flags)
3355 PERL_ARGS_ASSERT_SV_2BOOL_FLAGS;
3358 if(flags & SV_GMAGIC) SvGETMAGIC(sv);
3364 SV * const tmpsv = AMG_CALLunary(sv, bool__amg);
3365 if (tmpsv && (!SvROK(tmpsv) || (SvRV(tmpsv) != SvRV(sv)))) {
3368 if(SvGMAGICAL(sv)) {
3370 goto restart; /* call sv_2bool */
3372 /* expanded SvTRUE_common(sv, (flags = 0, goto restart)) */
3373 else if(!SvOK(sv)) {
3376 else if(SvPOK(sv)) {
3377 svb = SvPVXtrue(sv);
3379 else if((SvFLAGS(sv) & (SVf_IOK|SVf_NOK))) {
3380 svb = (SvIOK(sv) && SvIVX(sv) != 0)
3381 || (SvNOK(sv) && SvNVX(sv) != 0.0);
3385 goto restart; /* call sv_2bool_nomg */
3390 return SvRV(sv) != 0;
3394 RX_WRAPLEN(sv) > 1 || (RX_WRAPLEN(sv) && *RX_WRAPPED(sv) != '0');
3395 return SvTRUE_common(sv, isGV_with_GP(sv) ? 1 : 0);
3399 =for apidoc sv_utf8_upgrade
3401 Converts the PV of an SV to its UTF-8-encoded form.
3402 Forces the SV to string form if it is not already.
3403 Will C<mg_get> on C<sv> if appropriate.
3404 Always sets the SvUTF8 flag to avoid future validity checks even
3405 if the whole string is the same in UTF-8 as not.
3406 Returns the number of bytes in the converted string
3408 This is not a general purpose byte encoding to Unicode interface:
3409 use the Encode extension for that.
3411 =for apidoc sv_utf8_upgrade_nomg
3413 Like sv_utf8_upgrade, but doesn't do magic on C<sv>.
3415 =for apidoc sv_utf8_upgrade_flags
3417 Converts the PV of an SV to its UTF-8-encoded form.
3418 Forces the SV to string form if it is not already.
3419 Always sets the SvUTF8 flag to avoid future validity checks even
3420 if all the bytes are invariant in UTF-8.
3421 If C<flags> has C<SV_GMAGIC> bit set,
3422 will C<mg_get> on C<sv> if appropriate, else not.
3424 If C<flags> has SV_FORCE_UTF8_UPGRADE set, this function assumes that the PV
3425 will expand when converted to UTF-8, and skips the extra work of checking for
3426 that. Typically this flag is used by a routine that has already parsed the
3427 string and found such characters, and passes this information on so that the
3428 work doesn't have to be repeated.
3430 Returns the number of bytes in the converted string.
3432 This is not a general purpose byte encoding to Unicode interface:
3433 use the Encode extension for that.
3435 =for apidoc sv_utf8_upgrade_flags_grow
3437 Like sv_utf8_upgrade_flags, but has an additional parameter C<extra>, which is
3438 the number of unused bytes the string of 'sv' is guaranteed to have free after
3439 it upon return. This allows the caller to reserve extra space that it intends
3440 to fill, to avoid extra grows.
3442 C<sv_utf8_upgrade>, C<sv_utf8_upgrade_nomg>, and C<sv_utf8_upgrade_flags>
3443 are implemented in terms of this function.
3445 Returns the number of bytes in the converted string (not including the spares).
3449 (One might think that the calling routine could pass in the position of the
3450 first variant character when it has set SV_FORCE_UTF8_UPGRADE, so it wouldn't
3451 have to be found again. But that is not the case, because typically when the
3452 caller is likely to use this flag, it won't be calling this routine unless it
3453 finds something that won't fit into a byte. Otherwise it tries to not upgrade
3454 and just use bytes. But some things that do fit into a byte are variants in
3455 utf8, and the caller may not have been keeping track of these.)
3457 If the routine itself changes the string, it adds a trailing C<NUL>. Such a
3458 C<NUL> isn't guaranteed due to having other routines do the work in some input
3459 cases, or if the input is already flagged as being in utf8.
3461 The speed of this could perhaps be improved for many cases if someone wanted to
3462 write a fast function that counts the number of variant characters in a string,
3463 especially if it could return the position of the first one.
3468 Perl_sv_utf8_upgrade_flags_grow(pTHX_ SV *const sv, const I32 flags, STRLEN extra)
3470 PERL_ARGS_ASSERT_SV_UTF8_UPGRADE_FLAGS_GROW;
3472 if (sv == &PL_sv_undef)
3474 if (!SvPOK_nog(sv)) {
3476 if (SvREADONLY(sv) && (SvPOKp(sv) || SvIOKp(sv) || SvNOKp(sv))) {
3477 (void) sv_2pv_flags(sv,&len, flags);
3479 if (extra) SvGROW(sv, SvCUR(sv) + extra);
3483 (void) SvPV_force_flags(sv,len,flags & SV_GMAGIC);
3488 if (extra) SvGROW(sv, SvCUR(sv) + extra);
3493 S_sv_uncow(aTHX_ sv, 0);
3496 if (IN_ENCODING && !(flags & SV_UTF8_NO_ENCODING)) {
3497 sv_recode_to_utf8(sv, _get_encoding());
3498 if (extra) SvGROW(sv, SvCUR(sv) + extra);
3502 if (SvCUR(sv) == 0) {
3503 if (extra) SvGROW(sv, extra);
3504 } else { /* Assume Latin-1/EBCDIC */
3505 /* This function could be much more efficient if we
3506 * had a FLAG in SVs to signal if there are any variant
3507 * chars in the PV. Given that there isn't such a flag
3508 * make the loop as fast as possible (although there are certainly ways
3509 * to speed this up, eg. through vectorization) */
3510 U8 * s = (U8 *) SvPVX_const(sv);
3511 U8 * e = (U8 *) SvEND(sv);
3513 STRLEN two_byte_count = 0;
3515 if (flags & SV_FORCE_UTF8_UPGRADE) goto must_be_utf8;
3517 /* See if really will need to convert to utf8. We mustn't rely on our
3518 * incoming SV being well formed and having a trailing '\0', as certain
3519 * code in pp_formline can send us partially built SVs. */
3523 if (NATIVE_BYTE_IS_INVARIANT(ch)) continue;
3525 t--; /* t already incremented; re-point to first variant */
3530 /* utf8 conversion not needed because all are invariants. Mark as
3531 * UTF-8 even if no variant - saves scanning loop */
3533 if (extra) SvGROW(sv, SvCUR(sv) + extra);
3538 /* Here, the string should be converted to utf8, either because of an
3539 * input flag (two_byte_count = 0), or because a character that
3540 * requires 2 bytes was found (two_byte_count = 1). t points either to
3541 * the beginning of the string (if we didn't examine anything), or to
3542 * the first variant. In either case, everything from s to t - 1 will
3543 * occupy only 1 byte each on output.
3545 * There are two main ways to convert. One is to create a new string
3546 * and go through the input starting from the beginning, appending each
3547 * converted value onto the new string as we go along. It's probably
3548 * best to allocate enough space in the string for the worst possible
3549 * case rather than possibly running out of space and having to
3550 * reallocate and then copy what we've done so far. Since everything
3551 * from s to t - 1 is invariant, the destination can be initialized
3552 * with these using a fast memory copy
3554 * The other way is to figure out exactly how big the string should be
3555 * by parsing the entire input. Then you don't have to make it big
3556 * enough to handle the worst possible case, and more importantly, if
3557 * the string you already have is large enough, you don't have to
3558 * allocate a new string, you can copy the last character in the input
3559 * string to the final position(s) that will be occupied by the
3560 * converted string and go backwards, stopping at t, since everything
3561 * before that is invariant.
3563 * There are advantages and disadvantages to each method.
3565 * In the first method, we can allocate a new string, do the memory
3566 * copy from the s to t - 1, and then proceed through the rest of the
3567 * string byte-by-byte.
3569 * In the second method, we proceed through the rest of the input
3570 * string just calculating how big the converted string will be. Then
3571 * there are two cases:
3572 * 1) if the string has enough extra space to handle the converted
3573 * value. We go backwards through the string, converting until we
3574 * get to the position we are at now, and then stop. If this
3575 * position is far enough along in the string, this method is
3576 * faster than the other method. If the memory copy were the same
3577 * speed as the byte-by-byte loop, that position would be about
3578 * half-way, as at the half-way mark, parsing to the end and back
3579 * is one complete string's parse, the same amount as starting
3580 * over and going all the way through. Actually, it would be
3581 * somewhat less than half-way, as it's faster to just count bytes
3582 * than to also copy, and we don't have the overhead of allocating
3583 * a new string, changing the scalar to use it, and freeing the
3584 * existing one. But if the memory copy is fast, the break-even
3585 * point is somewhere after half way. The counting loop could be
3586 * sped up by vectorization, etc, to move the break-even point
3587 * further towards the beginning.
3588 * 2) if the string doesn't have enough space to handle the converted
3589 * value. A new string will have to be allocated, and one might
3590 * as well, given that, start from the beginning doing the first
3591 * method. We've spent extra time parsing the string and in
3592 * exchange all we've gotten is that we know precisely how big to
3593 * make the new one. Perl is more optimized for time than space,
3594 * so this case is a loser.
3595 * So what I've decided to do is not use the 2nd method unless it is
3596 * guaranteed that a new string won't have to be allocated, assuming
3597 * the worst case. I also decided not to put any more conditions on it
3598 * than this, for now. It seems likely that, since the worst case is
3599 * twice as big as the unknown portion of the string (plus 1), we won't
3600 * be guaranteed enough space, causing us to go to the first method,
3601 * unless the string is short, or the first variant character is near
3602 * the end of it. In either of these cases, it seems best to use the
3603 * 2nd method. The only circumstance I can think of where this would
3604 * be really slower is if the string had once had much more data in it
3605 * than it does now, but there is still a substantial amount in it */
3608 STRLEN invariant_head = t - s;
3609 STRLEN size = invariant_head + (e - t) * 2 + 1 + extra;
3610 if (SvLEN(sv) < size) {
3612 /* Here, have decided to allocate a new string */
3617 Newx(dst, size, U8);
3619 /* If no known invariants at the beginning of the input string,
3620 * set so starts from there. Otherwise, can use memory copy to
3621 * get up to where we are now, and then start from here */
3623 if (invariant_head == 0) {
3626 Copy(s, dst, invariant_head, char);
3627 d = dst + invariant_head;
3631 append_utf8_from_native_byte(*t, &d);
3635 SvPV_free(sv); /* No longer using pre-existing string */
3636 SvPV_set(sv, (char*)dst);
3637 SvCUR_set(sv, d - dst);
3638 SvLEN_set(sv, size);
3641 /* Here, have decided to get the exact size of the string.
3642 * Currently this happens only when we know that there is
3643 * guaranteed enough space to fit the converted string, so
3644 * don't have to worry about growing. If two_byte_count is 0,
3645 * then t points to the first byte of the string which hasn't
3646 * been examined yet. Otherwise two_byte_count is 1, and t
3647 * points to the first byte in the string that will expand to
3648 * two. Depending on this, start examining at t or 1 after t.
3651 U8 *d = t + two_byte_count;
3654 /* Count up the remaining bytes that expand to two */
3657 const U8 chr = *d++;
3658 if (! NATIVE_BYTE_IS_INVARIANT(chr)) two_byte_count++;
3661 /* The string will expand by just the number of bytes that
3662 * occupy two positions. But we are one afterwards because of
3663 * the increment just above. This is the place to put the
3664 * trailing NUL, and to set the length before we decrement */
3666 d += two_byte_count;
3667 SvCUR_set(sv, d - s);
3671 /* Having decremented d, it points to the position to put the
3672 * very last byte of the expanded string. Go backwards through
3673 * the string, copying and expanding as we go, stopping when we
3674 * get to the part that is invariant the rest of the way down */
3678 if (NATIVE_BYTE_IS_INVARIANT(*e)) {
3681 *d-- = UTF8_EIGHT_BIT_LO(*e);
3682 *d-- = UTF8_EIGHT_BIT_HI(*e);
3688 if (SvTYPE(sv) >= SVt_PVMG && SvMAGIC(sv)) {
3689 /* Update pos. We do it at the end rather than during
3690 * the upgrade, to avoid slowing down the common case
3691 * (upgrade without pos).
3692 * pos can be stored as either bytes or characters. Since
3693 * this was previously a byte string we can just turn off
3694 * the bytes flag. */
3695 MAGIC * mg = mg_find(sv, PERL_MAGIC_regex_global);
3697 mg->mg_flags &= ~MGf_BYTES;
3699 if ((mg = mg_find(sv, PERL_MAGIC_utf8)))
3700 magic_setutf8(sv,mg); /* clear UTF8 cache */
3705 /* Mark as UTF-8 even if no variant - saves scanning loop */
3711 =for apidoc sv_utf8_downgrade
3713 Attempts to convert the PV of an SV from characters to bytes.
3714 If the PV contains a character that cannot fit
3715 in a byte, this conversion will fail;
3716 in this case, either returns false or, if C<fail_ok> is not
3719 This is not a general purpose Unicode to byte encoding interface:
3720 use the Encode extension for that.
3726 Perl_sv_utf8_downgrade(pTHX_ SV *const sv, const bool fail_ok)
3728 PERL_ARGS_ASSERT_SV_UTF8_DOWNGRADE;
3730 if (SvPOKp(sv) && SvUTF8(sv)) {
3734 int mg_flags = SV_GMAGIC;
3737 S_sv_uncow(aTHX_ sv, 0);
3739 if (SvTYPE(sv) >= SVt_PVMG && SvMAGIC(sv)) {
3741 MAGIC * mg = mg_find(sv, PERL_MAGIC_regex_global);
3742 if (mg && mg->mg_len > 0 && mg->mg_flags & MGf_BYTES) {
3743 mg->mg_len = sv_pos_b2u_flags(sv, mg->mg_len,
3744 SV_GMAGIC|SV_CONST_RETURN);
3745 mg_flags = 0; /* sv_pos_b2u does get magic */
3747 if ((mg = mg_find(sv, PERL_MAGIC_utf8)))
3748 magic_setutf8(sv,mg); /* clear UTF8 cache */
3751 s = (U8 *) SvPV_flags(sv, len, mg_flags);
3753 if (!utf8_to_bytes(s, &len)) {
3758 Perl_croak(aTHX_ "Wide character in %s",
3761 Perl_croak(aTHX_ "Wide character");
3772 =for apidoc sv_utf8_encode
3774 Converts the PV of an SV to UTF-8, but then turns the C<SvUTF8>
3775 flag off so that it looks like octets again.
3781 Perl_sv_utf8_encode(pTHX_ SV *const sv)
3783 PERL_ARGS_ASSERT_SV_UTF8_ENCODE;
3785 if (SvREADONLY(sv)) {
3786 sv_force_normal_flags(sv, 0);
3788 (void) sv_utf8_upgrade(sv);
3793 =for apidoc sv_utf8_decode
3795 If the PV of the SV is an octet sequence in UTF-8
3796 and contains a multiple-byte character, the C<SvUTF8> flag is turned on
3797 so that it looks like a character. If the PV contains only single-byte
3798 characters, the C<SvUTF8> flag stays off.
3799 Scans PV for validity and returns false if the PV is invalid UTF-8.
3805 Perl_sv_utf8_decode(pTHX_ SV *const sv)
3807 PERL_ARGS_ASSERT_SV_UTF8_DECODE;
3810 const U8 *start, *c;
3813 /* The octets may have got themselves encoded - get them back as
3816 if (!sv_utf8_downgrade(sv, TRUE))
3819 /* it is actually just a matter of turning the utf8 flag on, but
3820 * we want to make sure everything inside is valid utf8 first.
3822 c = start = (const U8 *) SvPVX_const(sv);
3823 if (!is_utf8_string(c, SvCUR(sv)))
3825 e = (const U8 *) SvEND(sv);
3828 if (!UTF8_IS_INVARIANT(ch)) {
3833 if (SvTYPE(sv) >= SVt_PVMG && SvMAGIC(sv)) {
3834 /* XXX Is this dead code? XS_utf8_decode calls SvSETMAGIC
3835 after this, clearing pos. Does anything on CPAN
3837 /* adjust pos to the start of a UTF8 char sequence */
3838 MAGIC * mg = mg_find(sv, PERL_MAGIC_regex_global);
3840 I32 pos = mg->mg_len;
3842 for (c = start + pos; c > start; c--) {
3843 if (UTF8_IS_START(*c))
3846 mg->mg_len = c - start;
3849 if ((mg = mg_find(sv, PERL_MAGIC_utf8)))
3850 magic_setutf8(sv,mg); /* clear UTF8 cache */
3857 =for apidoc sv_setsv
3859 Copies the contents of the source SV C<ssv> into the destination SV
3860 C<dsv>. The source SV may be destroyed if it is mortal, so don't use this
3861 function if the source SV needs to be reused. Does not handle 'set' magic on
3862 destination SV. Calls 'get' magic on source SV. Loosely speaking, it
3863 performs a copy-by-value, obliterating any previous content of the
3866 You probably want to use one of the assortment of wrappers, such as
3867 C<SvSetSV>, C<SvSetSV_nosteal>, C<SvSetMagicSV> and
3868 C<SvSetMagicSV_nosteal>.
3870 =for apidoc sv_setsv_flags
3872 Copies the contents of the source SV C<ssv> into the destination SV
3873 C<dsv>. The source SV may be destroyed if it is mortal, so don't use this
3874 function if the source SV needs to be reused. Does not handle 'set' magic.
3875 Loosely speaking, it performs a copy-by-value, obliterating any previous
3876 content of the destination.
3877 If the C<flags> parameter has the C<SV_GMAGIC> bit set, will C<mg_get> on
3878 C<ssv> if appropriate, else not. If the C<flags>
3879 parameter has the C<SV_NOSTEAL> bit set then the
3880 buffers of temps will not be stolen. <sv_setsv>
3881 and C<sv_setsv_nomg> are implemented in terms of this function.
3883 You probably want to use one of the assortment of wrappers, such as
3884 C<SvSetSV>, C<SvSetSV_nosteal>, C<SvSetMagicSV> and
3885 C<SvSetMagicSV_nosteal>.
3887 This is the primary function for copying scalars, and most other
3888 copy-ish functions and macros use this underneath.
3894 S_glob_assign_glob(pTHX_ SV *const dstr, SV *const sstr, const int dtype)
3896 I32 mro_changes = 0; /* 1 = method, 2 = isa, 3 = recursive isa */
3897 HV *old_stash = NULL;
3899 PERL_ARGS_ASSERT_GLOB_ASSIGN_GLOB;
3901 if (dtype != SVt_PVGV && !isGV_with_GP(dstr)) {
3902 const char * const name = GvNAME(sstr);
3903 const STRLEN len = GvNAMELEN(sstr);
3905 if (dtype >= SVt_PV) {
3911 SvUPGRADE(dstr, SVt_PVGV);
3912 (void)SvOK_off(dstr);
3913 isGV_with_GP_on(dstr);
3915 GvSTASH(dstr) = GvSTASH(sstr);
3917 Perl_sv_add_backref(aTHX_ MUTABLE_SV(GvSTASH(dstr)), dstr);
3918 gv_name_set(MUTABLE_GV(dstr), name, len,
3919 GV_ADD | (GvNAMEUTF8(sstr) ? SVf_UTF8 : 0 ));
3920 SvFAKE_on(dstr); /* can coerce to non-glob */
3923 if(GvGP(MUTABLE_GV(sstr))) {
3924 /* If source has method cache entry, clear it */
3926 SvREFCNT_dec(GvCV(sstr));
3927 GvCV_set(sstr, NULL);
3930 /* If source has a real method, then a method is
3933 GvCV((const GV *)sstr) && GvSTASH(dstr) && HvENAME(GvSTASH(dstr))
3939 /* If dest already had a real method, that's a change as well */
3941 !mro_changes && GvGP(MUTABLE_GV(dstr)) && GvCVu((const GV *)dstr)
3942 && GvSTASH(dstr) && HvENAME(GvSTASH(dstr))
3947 /* We don't need to check the name of the destination if it was not a
3948 glob to begin with. */
3949 if(dtype == SVt_PVGV) {
3950 const char * const name = GvNAME((const GV *)dstr);
3953 /* The stash may have been detached from the symbol table, so
3955 && GvSTASH(dstr) && HvENAME(GvSTASH(dstr))
3959 const STRLEN len = GvNAMELEN(dstr);
3960 if ((len > 1 && name[len-2] == ':' && name[len-1] == ':')
3961 || (len == 1 && name[0] == ':')) {
3964 /* Set aside the old stash, so we can reset isa caches on
3966 if((old_stash = GvHV(dstr)))
3967 /* Make sure we do not lose it early. */
3968 SvREFCNT_inc_simple_void_NN(
3969 sv_2mortal((SV *)old_stash)
3974 SvREFCNT_inc_simple_void_NN(sv_2mortal(dstr));
3977 gp_free(MUTABLE_GV(dstr));
3978 GvINTRO_off(dstr); /* one-shot flag */
3979 GvGP_set(dstr, gp_ref(GvGP(sstr)));
3980 if (SvTAINTED(sstr))
3982 if (GvIMPORTED(dstr) != GVf_IMPORTED
3983 && CopSTASH_ne(PL_curcop, GvSTASH(dstr)))
3985 GvIMPORTED_on(dstr);
3988 if(mro_changes == 2) {
3989 if (GvAV((const GV *)sstr)) {
3991 SV * const sref = (SV *)GvAV((const GV *)dstr);
3992 if (SvSMAGICAL(sref) && (mg = mg_find(sref, PERL_MAGIC_isa))) {
3993 if (SvTYPE(mg->mg_obj) != SVt_PVAV) {
3994 AV * const ary = newAV();
3995 av_push(ary, mg->mg_obj); /* takes the refcount */
3996 mg->mg_obj = (SV *)ary;
3998 av_push((AV *)mg->mg_obj, SvREFCNT_inc_simple_NN(dstr));
4000 else sv_magic(sref, dstr, PERL_MAGIC_isa, NULL, 0);
4002 mro_isa_changed_in(GvSTASH(dstr));
4004 else if(mro_changes == 3) {
4005 HV * const stash = GvHV(dstr);
4006 if(old_stash ? (HV *)HvENAME_get(old_stash) : stash)
4012 else if(mro_changes) mro_method_changed_in(GvSTASH(dstr));
4013 if (GvIO(dstr) && dtype == SVt_PVGV) {
4014 DEBUG_o(Perl_deb(aTHX_
4015 "glob_assign_glob clearing PL_stashcache\n"));
4016 /* It's a cache. It will rebuild itself quite happily.
4017 It's a lot of effort to work out exactly which key (or keys)
4018 might be invalidated by the creation of the this file handle.
4020 hv_clear(PL_stashcache);
4026 Perl_gv_setref(pTHX_ SV *const dstr, SV *const sstr)
4028 SV * const sref = SvRV(sstr);
4030 const int intro = GvINTRO(dstr);
4033 const U32 stype = SvTYPE(sref);
4035 PERL_ARGS_ASSERT_GV_SETREF;
4038 GvINTRO_off(dstr); /* one-shot flag */
4039 GvLINE(dstr) = CopLINE(PL_curcop);
4040 GvEGV(dstr) = MUTABLE_GV(dstr);
4045 location = (SV **) &(GvGP(dstr)->gp_cv); /* XXX bypassing GvCV_set */
4046 import_flag = GVf_IMPORTED_CV;
4049 location = (SV **) &GvHV(dstr);
4050 import_flag = GVf_IMPORTED_HV;
4053 location = (SV **) &GvAV(dstr);
4054 import_flag = GVf_IMPORTED_AV;
4057 location = (SV **) &GvIOp(dstr);
4060 location = (SV **) &GvFORM(dstr);
4063 location = &GvSV(dstr);
4064 import_flag = GVf_IMPORTED_SV;
4067 if (stype == SVt_PVCV) {
4068 /*if (GvCVGEN(dstr) && (GvCV(dstr) != (const CV *)sref || GvCVGEN(dstr))) {*/
4069 if (GvCVGEN(dstr)) {
4070 SvREFCNT_dec(GvCV(dstr));
4071 GvCV_set(dstr, NULL);
4072 GvCVGEN(dstr) = 0; /* Switch off cacheness. */
4075 /* SAVEt_GVSLOT takes more room on the savestack and has more
4076 overhead in leave_scope than SAVEt_GENERIC_SV. But for CVs
4077 leave_scope needs access to the GV so it can reset method
4078 caches. We must use SAVEt_GVSLOT whenever the type is
4079 SVt_PVCV, even if the stash is anonymous, as the stash may
4080 gain a name somehow before leave_scope. */
4081 if (stype == SVt_PVCV) {
4082 /* There is no save_pushptrptrptr. Creating it for this
4083 one call site would be overkill. So inline the ss add
4087 SS_ADD_PTR(location);
4088 SS_ADD_PTR(SvREFCNT_inc(*location));
4089 SS_ADD_UV(SAVEt_GVSLOT);
4092 else SAVEGENERICSV(*location);
4095 if (stype == SVt_PVCV && (*location != sref || GvCVGEN(dstr))) {
4096 CV* const cv = MUTABLE_CV(*location);
4098 if (!GvCVGEN((const GV *)dstr) &&
4099 (CvROOT(cv) || CvXSUB(cv)) &&
4100 /* redundant check that avoids creating the extra SV
4101 most of the time: */
4102 (CvCONST(cv) || ckWARN(WARN_REDEFINE)))
4104 SV * const new_const_sv =
4105 CvCONST((const CV *)sref)
4106 ? cv_const_sv((const CV *)sref)
4108 report_redefined_cv(
4109 sv_2mortal(Perl_newSVpvf(aTHX_
4112 HvNAME_HEK(GvSTASH((const GV *)dstr))
4114 HEKfARG(GvENAME_HEK(MUTABLE_GV(dstr)))
4117 CvCONST((const CV *)sref) ? &new_const_sv : NULL
4121 cv_ckproto_len_flags(cv, (const GV *)dstr,
4122 SvPOK(sref) ? CvPROTO(sref) : NULL,
4123 SvPOK(sref) ? CvPROTOLEN(sref) : 0,
4124 SvPOK(sref) ? SvUTF8(sref) : 0);
4126 GvCVGEN(dstr) = 0; /* Switch off cacheness. */
4127 GvASSUMECV_on(dstr);
4128 if(GvSTASH(dstr)) { /* sub foo { 1 } sub bar { 2 } *bar = \&foo */
4129 if (intro && GvREFCNT(dstr) > 1) {
4130 /* temporary remove extra savestack's ref */
4132 gv_method_changed(dstr);
4135 else gv_method_changed(dstr);
4138 *location = SvREFCNT_inc_simple_NN(sref);
4139 if (import_flag && !(GvFLAGS(dstr) & import_flag)
4140 && CopSTASH_ne(PL_curcop, GvSTASH(dstr))) {
4141 GvFLAGS(dstr) |= import_flag;
4143 if (import_flag == GVf_IMPORTED_SV) {
4145 save_aliased_sv((GV *)dstr);
4147 /* Turn off the flag if sref is not referenced elsewhere,
4148 even by weak refs. (SvRMAGICAL is a pessimistic check for
4150 if (SvREFCNT(sref) <= 2 && !SvRMAGICAL(sref))
4151 GvALIASED_SV_off(dstr);
4153 GvALIASED_SV_on(dstr);
4155 if (stype == SVt_PVHV) {
4156 const char * const name = GvNAME((GV*)dstr);
4157 const STRLEN len = GvNAMELEN(dstr);
4160 (len > 1 && name[len-2] == ':' && name[len-1] == ':')
4161 || (len == 1 && name[0] == ':')
4163 && (!dref || HvENAME_get(dref))
4166 (HV *)sref, (HV *)dref,
4172 stype == SVt_PVAV && sref != dref
4173 && strEQ(GvNAME((GV*)dstr), "ISA")
4174 /* The stash may have been detached from the symbol table, so
4175 check its name before doing anything. */
4176 && GvSTASH(dstr) && HvENAME(GvSTASH(dstr))
4179 MAGIC * const omg = dref && SvSMAGICAL(dref)
4180 ? mg_find(dref, PERL_MAGIC_isa)
4182 if (SvSMAGICAL(sref) && (mg = mg_find(sref, PERL_MAGIC_isa))) {
4183 if (SvTYPE(mg->mg_obj) != SVt_PVAV) {
4184 AV * const ary = newAV();
4185 av_push(ary, mg->mg_obj); /* takes the refcount */
4186 mg->mg_obj = (SV *)ary;
4189 if (SvTYPE(omg->mg_obj) == SVt_PVAV) {
4190 SV **svp = AvARRAY((AV *)omg->mg_obj);
4191 I32 items = AvFILLp((AV *)omg->mg_obj) + 1;
4195 SvREFCNT_inc_simple_NN(*svp++)
4201 SvREFCNT_inc_simple_NN(omg->mg_obj)
4205 av_push((AV *)mg->mg_obj,SvREFCNT_inc_simple_NN(dstr));
4210 sref, omg ? omg->mg_obj : dstr, PERL_MAGIC_isa, NULL, 0
4212 mg = mg_find(sref, PERL_MAGIC_isa);
4214 /* Since the *ISA assignment could have affected more than
4215 one stash, don't call mro_isa_changed_in directly, but let
4216 magic_clearisa do it for us, as it already has the logic for
4217 dealing with globs vs arrays of globs. */
4219 Perl_magic_clearisa(aTHX_ NULL, mg);
4221 else if (stype == SVt_PVIO) {
4222 DEBUG_o(Perl_deb(aTHX_ "gv_setref clearing PL_stashcache\n"));
4223 /* It's a cache. It will rebuild itself quite happily.
4224 It's a lot of effort to work out exactly which key (or keys)
4225 might be invalidated by the creation of the this file handle.
4227 hv_clear(PL_stashcache);
4231 if (!intro) SvREFCNT_dec(dref);
4232 if (SvTAINTED(sstr))
4240 #ifdef PERL_DEBUG_READONLY_COW
4241 # include <sys/mman.h>
4243 # ifndef PERL_MEMORY_DEBUG_HEADER_SIZE
4244 # define PERL_MEMORY_DEBUG_HEADER_SIZE 0
4248 Perl_sv_buf_to_ro(pTHX_ SV *sv)
4250 struct perl_memory_debug_header * const header =
4251 (struct perl_memory_debug_header *)(SvPVX(sv)-PERL_MEMORY_DEBUG_HEADER_SIZE);
4252 const MEM_SIZE len = header->size;
4253 PERL_ARGS_ASSERT_SV_BUF_TO_RO;
4254 # ifdef PERL_TRACK_MEMPOOL
4255 if (!header->readonly) header->readonly = 1;
4257 if (mprotect(header, len, PROT_READ))
4258 Perl_warn(aTHX_ "mprotect RW for COW string %p %lu failed with %d",
4259 header, len, errno);
4263 S_sv_buf_to_rw(pTHX_ SV *sv)
4265 struct perl_memory_debug_header * const header =
4266 (struct perl_memory_debug_header *)(SvPVX(sv)-PERL_MEMORY_DEBUG_HEADER_SIZE);
4267 const MEM_SIZE len = header->size;
4268 PERL_ARGS_ASSERT_SV_BUF_TO_RW;
4269 if (mprotect(header, len, PROT_READ|PROT_WRITE))
4270 Perl_warn(aTHX_ "mprotect for COW string %p %lu failed with %d",
4271 header, len, errno);
4272 # ifdef PERL_TRACK_MEMPOOL
4273 header->readonly = 0;
4278 # define sv_buf_to_ro(sv) NOOP
4279 # define sv_buf_to_rw(sv) NOOP
4283 Perl_sv_setsv_flags(pTHX_ SV *dstr, SV* sstr, const I32 flags)
4289 PERL_ARGS_ASSERT_SV_SETSV_FLAGS;
4291 if (UNLIKELY( sstr == dstr ))
4294 if (SvIS_FREED(dstr)) {
4295 Perl_croak(aTHX_ "panic: attempt to copy value %" SVf
4296 " to a freed scalar %p", SVfARG(sstr), (void *)dstr);
4298 SV_CHECK_THINKFIRST_COW_DROP(dstr);
4299 if (UNLIKELY( !sstr ))
4300 sstr = &PL_sv_undef;
4301 if (SvIS_FREED(sstr)) {
4302 Perl_croak(aTHX_ "panic: attempt to copy freed scalar %p to %p",
4303 (void*)sstr, (void*)dstr);
4305 stype = SvTYPE(sstr);
4306 dtype = SvTYPE(dstr);
4308 /* There's a lot of redundancy below but we're going for speed here */
4313 if (LIKELY( dtype != SVt_PVGV && dtype != SVt_PVLV )) {
4314 (void)SvOK_off(dstr);
4322 /* For performance, we inline promoting to type SVt_IV. */
4323 /* We're starting from SVt_NULL, so provided that define is
4324 * actual 0, we don't have to unset any SV type flags
4325 * to promote to SVt_IV. */
4326 STATIC_ASSERT_STMT(SVt_NULL == 0);
4327 SET_SVANY_FOR_BODYLESS_IV(dstr);
4328 SvFLAGS(dstr) |= SVt_IV;
4332 sv_upgrade(dstr, SVt_PVIV);
4336 goto end_of_first_switch;
4338 (void)SvIOK_only(dstr);
4339 SvIV_set(dstr, SvIVX(sstr));
4342 /* SvTAINTED can only be true if the SV has taint magic, which in
4343 turn means that the SV type is PVMG (or greater). This is the
4344 case statement for SVt_IV, so this cannot be true (whatever gcov
4346 assert(!SvTAINTED(sstr));
4351 if (dtype < SVt_PV && dtype != SVt_IV)
4352 sv_upgrade(dstr, SVt_IV);
4356 if (LIKELY( SvNOK(sstr) )) {
4360 sv_upgrade(dstr, SVt_NV);
4364 sv_upgrade(dstr, SVt_PVNV);
4368 goto end_of_first_switch;
4370 SvNV_set(dstr, SvNVX(sstr));
4371 (void)SvNOK_only(dstr);
4372 /* SvTAINTED can only be true if the SV has taint magic, which in
4373 turn means that the SV type is PVMG (or greater). This is the
4374 case statement for SVt_NV, so this cannot be true (whatever gcov
4376 assert(!SvTAINTED(sstr));
4383 sv_upgrade(dstr, SVt_PV);
4386 if (dtype < SVt_PVIV)
4387 sv_upgrade(dstr, SVt_PVIV);
4390 if (dtype < SVt_PVNV)
4391 sv_upgrade(dstr, SVt_PVNV);
4395 const char * const type = sv_reftype(sstr,0);
4397 /* diag_listed_as: Bizarre copy of %s */
4398 Perl_croak(aTHX_ "Bizarre copy of %s in %s", type, OP_DESC(PL_op));
4400 Perl_croak(aTHX_ "Bizarre copy of %s", type);
4402 NOT_REACHED; /* NOTREACHED */
4406 if (dtype < SVt_REGEXP)
4408 if (dtype >= SVt_PV) {
4414 sv_upgrade(dstr, SVt_REGEXP);
4422 if (SvGMAGICAL(sstr) && (flags & SV_GMAGIC)) {
4424 if (SvTYPE(sstr) != stype)
4425 stype = SvTYPE(sstr);
4427 if (isGV_with_GP(sstr) && dtype <= SVt_PVLV) {
4428 glob_assign_glob(dstr, sstr, dtype);
4431 if (stype == SVt_PVLV)
4433 if (isREGEXP(sstr)) goto upgregexp;
4434 SvUPGRADE(dstr, SVt_PVNV);
4437 SvUPGRADE(dstr, (svtype)stype);
4439 end_of_first_switch:
4441 /* dstr may have been upgraded. */
4442 dtype = SvTYPE(dstr);
4443 sflags = SvFLAGS(sstr);
4445 if (UNLIKELY( dtype == SVt_PVCV )) {
4446 /* Assigning to a subroutine sets the prototype. */
4449 const char *const ptr = SvPV_const(sstr, len);
4451 SvGROW(dstr, len + 1);
4452 Copy(ptr, SvPVX(dstr), len + 1, char);
4453 SvCUR_set(dstr, len);
4455 SvFLAGS(dstr) |= sflags & SVf_UTF8;
4456 CvAUTOLOAD_off(dstr);
4461 else if (UNLIKELY(dtype == SVt_PVAV || dtype == SVt_PVHV
4462 || dtype == SVt_PVFM))
4464 const char * const type = sv_reftype(dstr,0);
4466 /* diag_listed_as: Cannot copy to %s */
4467 Perl_croak(aTHX_ "Cannot copy to %s in %s", type, OP_DESC(PL_op));
4469 Perl_croak(aTHX_ "Cannot copy to %s", type);
4470 } else if (sflags & SVf_ROK) {
4471 if (isGV_with_GP(dstr)
4472 && SvTYPE(SvRV(sstr)) == SVt_PVGV && isGV_with_GP(SvRV(sstr))) {
4475 if (GvIMPORTED(dstr) != GVf_IMPORTED
4476 && CopSTASH_ne(PL_curcop, GvSTASH(dstr)))
4478 GvIMPORTED_on(dstr);
4483 glob_assign_glob(dstr, sstr, dtype);
4487 if (dtype >= SVt_PV) {
4488 if (isGV_with_GP(dstr)) {
4489 gv_setref(dstr, sstr);
4492 if (SvPVX_const(dstr)) {
4498 (void)SvOK_off(dstr);
4499 SvRV_set(dstr, SvREFCNT_inc(SvRV(sstr)));
4500 SvFLAGS(dstr) |= sflags & SVf_ROK;
4501 assert(!(sflags & SVp_NOK));
4502 assert(!(sflags & SVp_IOK));
4503 assert(!(sflags & SVf_NOK));
4504 assert(!(sflags & SVf_IOK));
4506 else if (isGV_with_GP(dstr)) {
4507 if (!(sflags & SVf_OK)) {
4508 Perl_ck_warner(aTHX_ packWARN(WARN_MISC),
4509 "Undefined value assigned to typeglob");
4512 GV *gv = gv_fetchsv_nomg(sstr, GV_ADD, SVt_PVGV);
4513 if (dstr != (const SV *)gv) {
4514 const char * const name = GvNAME((const GV *)dstr);
4515 const STRLEN len = GvNAMELEN(dstr);
4516 HV *old_stash = NULL;
4517 bool reset_isa = FALSE;
4518 if ((len > 1 && name[len-2] == ':' && name[len-1] == ':')
4519 || (len == 1 && name[0] == ':')) {
4520 /* Set aside the old stash, so we can reset isa caches
4521 on its subclasses. */
4522 if((old_stash = GvHV(dstr))) {
4523 /* Make sure we do not lose it early. */
4524 SvREFCNT_inc_simple_void_NN(
4525 sv_2mortal((SV *)old_stash)
4532 SvREFCNT_inc_simple_void_NN(sv_2mortal(dstr));
4533 gp_free(MUTABLE_GV(dstr));
4535 GvGP_set(dstr, gp_ref(GvGP(gv)));
4538 HV * const stash = GvHV(dstr);
4540 old_stash ? (HV *)HvENAME_get(old_stash) : stash
4550 else if ((dtype == SVt_REGEXP || dtype == SVt_PVLV)
4551 && (stype == SVt_REGEXP || isREGEXP(sstr))) {
4552 reg_temp_copy((REGEXP*)dstr, (REGEXP*)sstr);
4554 else if (sflags & SVp_POK) {
4555 const STRLEN cur = SvCUR(sstr);
4556 const STRLEN len = SvLEN(sstr);
4559 * We have three basic ways to copy the string:
4565 * Which we choose is based on various factors. The following
4566 * things are listed in order of speed, fastest to slowest:
4568 * - Copying a short string
4569 * - Copy-on-write bookkeeping
4571 * - Copying a long string
4573 * We swipe the string (steal the string buffer) if the SV on the
4574 * rhs is about to be freed anyway (TEMP and refcnt==1). This is a
4575 * big win on long strings. It should be a win on short strings if
4576 * SvPVX_const(dstr) has to be allocated. If not, it should not
4577 * slow things down, as SvPVX_const(sstr) would have been freed
4580 * We also steal the buffer from a PADTMP (operator target) if it
4581 * is ‘long enough’. For short strings, a swipe does not help
4582 * here, as it causes more malloc calls the next time the target
4583 * is used. Benchmarks show that even if SvPVX_const(dstr) has to
4584 * be allocated it is still not worth swiping PADTMPs for short
4585 * strings, as the savings here are small.
4587 * If swiping is not an option, then we see whether it is
4588 * worth using copy-on-write. If the lhs already has a buf-
4589 * fer big enough and the string is short, we skip it and fall back
4590 * to method 3, since memcpy is faster for short strings than the
4591 * later bookkeeping overhead that copy-on-write entails.
4593 * If the rhs is not a copy-on-write string yet, then we also
4594 * consider whether the buffer is too large relative to the string
4595 * it holds. Some operations such as readline allocate a large
4596 * buffer in the expectation of reusing it. But turning such into
4597 * a COW buffer is counter-productive because it increases memory
4598 * usage by making readline allocate a new large buffer the sec-
4599 * ond time round. So, if the buffer is too large, again, we use
4602 * Finally, if there is no buffer on the left, or the buffer is too
4603 * small, then we use copy-on-write and make both SVs share the
4608 /* Whichever path we take through the next code, we want this true,
4609 and doing it now facilitates the COW check. */
4610 (void)SvPOK_only(dstr);
4614 /* slated for free anyway (and not COW)? */
4615 (sflags & (SVs_TEMP|SVf_IsCOW)) == SVs_TEMP
4616 /* or a swipable TARG */
4618 (SVs_PADTMP|SVf_READONLY|SVf_PROTECT|SVf_IsCOW))
4620 /* whose buffer is worth stealing */
4621 && CHECK_COWBUF_THRESHOLD(cur,len)
4624 !(sflags & SVf_OOK) && /* and not involved in OOK hack? */
4625 (!(flags & SV_NOSTEAL)) &&
4626 /* and we're allowed to steal temps */
4627 SvREFCNT(sstr) == 1 && /* and no other references to it? */
4628 len) /* and really is a string */
4629 { /* Passes the swipe test. */
4630 if (SvPVX_const(dstr)) /* we know that dtype >= SVt_PV */
4632 SvPV_set(dstr, SvPVX_mutable(sstr));
4633 SvLEN_set(dstr, SvLEN(sstr));
4634 SvCUR_set(dstr, SvCUR(sstr));
4637 (void)SvOK_off(sstr); /* NOTE: nukes most SvFLAGS on sstr */
4638 SvPV_set(sstr, NULL);
4643 else if (flags & SV_COW_SHARED_HASH_KEYS
4645 #ifdef PERL_OLD_COPY_ON_WRITE
4646 ( sflags & SVf_IsCOW
4647 || ( (sflags & CAN_COW_MASK) == CAN_COW_FLAGS
4648 && (SvFLAGS(dstr) & CAN_COW_MASK) == CAN_COW_FLAGS
4649 && SvTYPE(sstr) >= SVt_PVIV && len
4652 #elif defined(PERL_NEW_COPY_ON_WRITE)
4655 ( (CHECK_COWBUF_THRESHOLD(cur,len) || SvLEN(dstr) < cur+1)
4656 /* If this is a regular (non-hek) COW, only so
4657 many COW "copies" are possible. */
4658 && CowREFCNT(sstr) != SV_COW_REFCNT_MAX ))
4659 : ( (sflags & CAN_COW_MASK) == CAN_COW_FLAGS
4660 && !(SvFLAGS(dstr) & SVf_BREAK)
4661 && CHECK_COW_THRESHOLD(cur,len) && cur+1 < len
4662 && (CHECK_COWBUF_THRESHOLD(cur,len) || SvLEN(dstr) < cur+1)
4666 && !(SvFLAGS(dstr) & SVf_BREAK)
4669 /* Either it's a shared hash key, or it's suitable for
4672 PerlIO_printf(Perl_debug_log, "Copy on write: sstr --> dstr\n");
4677 if (!(sflags & SVf_IsCOW)) {
4679 # ifdef PERL_OLD_COPY_ON_WRITE
4680 /* Make the source SV into a loop of 1.
4681 (about to become 2) */
4682 SV_COW_NEXT_SV_SET(sstr, sstr);
4684 CowREFCNT(sstr) = 0;
4688 if (SvPVX_const(dstr)) { /* we know that dtype >= SVt_PV */
4694 # ifdef PERL_OLD_COPY_ON_WRITE
4695 assert (SvTYPE(dstr) >= SVt_PVIV);
4696 /* SvIsCOW_normal */
4697 /* splice us in between source and next-after-source. */
4698 SV_COW_NEXT_SV_SET(dstr, SV_COW_NEXT_SV(sstr));
4699 SV_COW_NEXT_SV_SET(sstr, dstr);
4701 if (sflags & SVf_IsCOW) {
4706 SvPV_set(dstr, SvPVX_mutable(sstr));
4711 /* SvIsCOW_shared_hash */
4712 DEBUG_C(PerlIO_printf(Perl_debug_log,
4713 "Copy on write: Sharing hash\n"));
4715 assert (SvTYPE(dstr) >= SVt_PV);
4717 HEK_KEY(share_hek_hek(SvSHARED_HEK_FROM_PV(SvPVX_const(sstr)))));
4719 SvLEN_set(dstr, len);
4720 SvCUR_set(dstr, cur);
4723 /* Failed the swipe test, and we cannot do copy-on-write either.
4724 Have to copy the string. */
4725 SvGROW(dstr, cur + 1); /* inlined from sv_setpvn */
4726 Move(SvPVX_const(sstr),SvPVX(dstr),cur,char);
4727 SvCUR_set(dstr, cur);
4728 *SvEND(dstr) = '\0';
4730 if (sflags & SVp_NOK) {
4731 SvNV_set(dstr, SvNVX(sstr));
4733 if (sflags & SVp_IOK) {
4734 SvIV_set(dstr, SvIVX(sstr));
4735 /* Must do this otherwise some other overloaded use of 0x80000000
4736 gets confused. I guess SVpbm_VALID */
4737 if (sflags & SVf_IVisUV)
4740 SvFLAGS(dstr) |= sflags & (SVf_IOK|SVp_IOK|SVf_NOK|SVp_NOK|SVf_UTF8);
4742 const MAGIC * const smg = SvVSTRING_mg(sstr);
4744 sv_magic(dstr, NULL, PERL_MAGIC_vstring,
4745 smg->mg_ptr, smg->mg_len);
4746 SvRMAGICAL_on(dstr);
4750 else if (sflags & (SVp_IOK|SVp_NOK)) {
4751 (void)SvOK_off(dstr);
4752 SvFLAGS(dstr) |= sflags & (SVf_IOK|SVp_IOK|SVf_IVisUV|SVf_NOK|SVp_NOK);
4753 if (sflags & SVp_IOK) {
4754 /* XXXX Do we want to set IsUV for IV(ROK)? Be extra safe... */
4755 SvIV_set(dstr, SvIVX(sstr));
4757 if (sflags & SVp_NOK) {
4758 SvNV_set(dstr, SvNVX(sstr));
4762 if (isGV_with_GP(sstr)) {
4763 gv_efullname3(dstr, MUTABLE_GV(sstr), "*");
4766 (void)SvOK_off(dstr);
4768 if (SvTAINTED(sstr))
4773 =for apidoc sv_setsv_mg
4775 Like C<sv_setsv>, but also handles 'set' magic.
4781 Perl_sv_setsv_mg(pTHX_ SV *const dstr, SV *const sstr)
4783 PERL_ARGS_ASSERT_SV_SETSV_MG;
4785 sv_setsv(dstr,sstr);
4790 # ifdef PERL_OLD_COPY_ON_WRITE
4791 # define SVt_COW SVt_PVIV
4793 # define SVt_COW SVt_PV
4796 Perl_sv_setsv_cow(pTHX_ SV *dstr, SV *sstr)
4798 STRLEN cur = SvCUR(sstr);
4799 STRLEN len = SvLEN(sstr);
4801 #if defined(PERL_DEBUG_READONLY_COW) && defined(PERL_NEW_COPY_ON_WRITE)
4802 const bool already = cBOOL(SvIsCOW(sstr));
4805 PERL_ARGS_ASSERT_SV_SETSV_COW;
4808 PerlIO_printf(Perl_debug_log, "Fast copy on write: %p -> %p\n",
4809 (void*)sstr, (void*)dstr);
4816 if (SvTHINKFIRST(dstr))
4817 sv_force_normal_flags(dstr, SV_COW_DROP_PV);
4818 else if (SvPVX_const(dstr))
4819 Safefree(SvPVX_mutable(dstr));
4823 SvUPGRADE(dstr, SVt_COW);
4825 assert (SvPOK(sstr));
4826 assert (SvPOKp(sstr));
4827 # ifdef PERL_OLD_COPY_ON_WRITE
4828 assert (!SvIOK(sstr));
4829 assert (!SvIOKp(sstr));
4830 assert (!SvNOK(sstr));
4831 assert (!SvNOKp(sstr));
4834 if (SvIsCOW(sstr)) {
4836 if (SvLEN(sstr) == 0) {
4837 /* source is a COW shared hash key. */
4838 DEBUG_C(PerlIO_printf(Perl_debug_log,
4839 "Fast copy on write: Sharing hash\n"));
4840 new_pv = HEK_KEY(share_hek_hek(SvSHARED_HEK_FROM_PV(SvPVX_const(sstr))));
4843 # ifdef PERL_OLD_COPY_ON_WRITE
4844 SV_COW_NEXT_SV_SET(dstr, SV_COW_NEXT_SV(sstr));
4846 assert(SvCUR(sstr)+1 < SvLEN(sstr));
4847 assert(CowREFCNT(sstr) < SV_COW_REFCNT_MAX);
4850 assert ((SvFLAGS(sstr) & CAN_COW_MASK) == CAN_COW_FLAGS);
4851 SvUPGRADE(sstr, SVt_COW);
4853 DEBUG_C(PerlIO_printf(Perl_debug_log,
4854 "Fast copy on write: Converting sstr to COW\n"));
4855 # ifdef PERL_OLD_COPY_ON_WRITE
4856 SV_COW_NEXT_SV_SET(dstr, sstr);
4858 CowREFCNT(sstr) = 0;
4861 # ifdef PERL_OLD_COPY_ON_WRITE
4862 SV_COW_NEXT_SV_SET(sstr, dstr);
4864 # ifdef PERL_DEBUG_READONLY_COW
4865 if (already) sv_buf_to_rw(sstr);
4869 new_pv = SvPVX_mutable(sstr);
4873 SvPV_set(dstr, new_pv);
4874 SvFLAGS(dstr) = (SVt_COW|SVf_POK|SVp_POK|SVf_IsCOW);
4877 SvLEN_set(dstr, len);
4878 SvCUR_set(dstr, cur);
4887 =for apidoc sv_setpvn
4889 Copies a string (possibly containing embedded C<NUL> characters) into an SV.
4890 The C<len> parameter indicates the number of
4891 bytes to be copied. If the C<ptr> argument is NULL the SV will become
4892 undefined. Does not handle 'set' magic. See C<sv_setpvn_mg>.
4898 Perl_sv_setpvn(pTHX_ SV *const sv, const char *const ptr, const STRLEN len)
4902 PERL_ARGS_ASSERT_SV_SETPVN;
4904 SV_CHECK_THINKFIRST_COW_DROP(sv);
4910 /* len is STRLEN which is unsigned, need to copy to signed */
4913 Perl_croak(aTHX_ "panic: sv_setpvn called with negative strlen %"
4916 SvUPGRADE(sv, SVt_PV);
4918 dptr = SvGROW(sv, len + 1);
4919 Move(ptr,dptr,len,char);
4922 (void)SvPOK_only_UTF8(sv); /* validate pointer */
4924 if (SvTYPE(sv) == SVt_PVCV) CvAUTOLOAD_off(sv);
4928 =for apidoc sv_setpvn_mg
4930 Like C<sv_setpvn>, but also handles 'set' magic.
4936 Perl_sv_setpvn_mg(pTHX_ SV *const sv, const char *const ptr, const STRLEN len)
4938 PERL_ARGS_ASSERT_SV_SETPVN_MG;
4940 sv_setpvn(sv,ptr,len);
4945 =for apidoc sv_setpv
4947 Copies a string into an SV. The string must be terminated with a C<NUL>
4949 Does not handle 'set' magic. See C<sv_setpv_mg>.
4955 Perl_sv_setpv(pTHX_ SV *const sv, const char *const ptr)
4959 PERL_ARGS_ASSERT_SV_SETPV;
4961 SV_CHECK_THINKFIRST_COW_DROP(sv);
4967 SvUPGRADE(sv, SVt_PV);
4969 SvGROW(sv, len + 1);
4970 Move(ptr,SvPVX(sv),len+1,char);
4972 (void)SvPOK_only_UTF8(sv); /* validate pointer */
4974 if (SvTYPE(sv) == SVt_PVCV) CvAUTOLOAD_off(sv);
4978 =for apidoc sv_setpv_mg
4980 Like C<sv_setpv>, but also handles 'set' magic.
4986 Perl_sv_setpv_mg(pTHX_ SV *const sv, const char *const ptr)
4988 PERL_ARGS_ASSERT_SV_SETPV_MG;
4995 Perl_sv_sethek(pTHX_ SV *const sv, const HEK *const hek)
4997 PERL_ARGS_ASSERT_SV_SETHEK;
5003 if (HEK_LEN(hek) == HEf_SVKEY) {
5004 sv_setsv(sv, *(SV**)HEK_KEY(hek));
5007 const int flags = HEK_FLAGS(hek);
5008 if (flags & HVhek_WASUTF8) {
5009 STRLEN utf8_len = HEK_LEN(hek);
5010 char *as_utf8 = (char *)bytes_to_utf8((U8*)HEK_KEY(hek), &utf8_len);
5011 sv_usepvn_flags(sv, as_utf8, utf8_len, SV_HAS_TRAILING_NUL);
5014 } else if (flags & HVhek_UNSHARED) {
5015 sv_setpvn(sv, HEK_KEY(hek), HEK_LEN(hek));
5018 else SvUTF8_off(sv);
5022 SV_CHECK_THINKFIRST_COW_DROP(sv);
5023 SvUPGRADE(sv, SVt_PV);
5025 SvPV_set(sv,(char *)HEK_KEY(share_hek_hek(hek)));
5026 SvCUR_set(sv, HEK_LEN(hek));
5032 else SvUTF8_off(sv);
5040 =for apidoc sv_usepvn_flags
5042 Tells an SV to use C<ptr> to find its string value. Normally the
5043 string is stored inside the SV, but sv_usepvn allows the SV to use an
5044 outside string. The C<ptr> should point to memory that was allocated
5045 by L<Newx|perlclib/Memory Management and String Handling>. It must be
5046 the start of a Newx-ed block of memory, and not a pointer to the
5047 middle of it (beware of L<OOK|perlguts/Offsets> and copy-on-write),
5048 and not be from a non-Newx memory allocator like C<malloc>. The
5049 string length, C<len>, must be supplied. By default this function
5050 will C<Renew> (i.e. realloc, move) the memory pointed to by C<ptr>,
5051 so that pointer should not be freed or used by the programmer after
5052 giving it to sv_usepvn, and neither should any pointers from "behind"
5053 that pointer (e.g. ptr + 1) be used.
5055 If C<flags> & SV_SMAGIC is true, will call SvSETMAGIC. If C<flags> &
5056 SV_HAS_TRAILING_NUL is true, then C<ptr[len]> must be C<NUL>, and the realloc
5057 will be skipped (i.e. the buffer is actually at least 1 byte longer than
5058 C<len>, and already meets the requirements for storing in C<SvPVX>).
5064 Perl_sv_usepvn_flags(pTHX_ SV *const sv, char *ptr, const STRLEN len, const U32 flags)
5068 PERL_ARGS_ASSERT_SV_USEPVN_FLAGS;
5070 SV_CHECK_THINKFIRST_COW_DROP(sv);
5071 SvUPGRADE(sv, SVt_PV);
5074 if (flags & SV_SMAGIC)
5078 if (SvPVX_const(sv))
5082 if (flags & SV_HAS_TRAILING_NUL)
5083 assert(ptr[len] == '\0');
5086 allocate = (flags & SV_HAS_TRAILING_NUL)
5088 #ifdef Perl_safesysmalloc_size
5091 PERL_STRLEN_ROUNDUP(len + 1);
5093 if (flags & SV_HAS_TRAILING_NUL) {
5094 /* It's long enough - do nothing.
5095 Specifically Perl_newCONSTSUB is relying on this. */
5098 /* Force a move to shake out bugs in callers. */
5099 char *new_ptr = (char*)safemalloc(allocate);
5100 Copy(ptr, new_ptr, len, char);
5101 PoisonFree(ptr,len,char);
5105 ptr = (char*) saferealloc (ptr, allocate);
5108 #ifdef Perl_safesysmalloc_size
5109 SvLEN_set(sv, Perl_safesysmalloc_size(ptr));
5111 SvLEN_set(sv, allocate);
5115 if (!(flags & SV_HAS_TRAILING_NUL)) {
5118 (void)SvPOK_only_UTF8(sv); /* validate pointer */
5120 if (flags & SV_SMAGIC)
5124 #ifdef PERL_OLD_COPY_ON_WRITE
5125 /* Need to do this *after* making the SV normal, as we need the buffer
5126 pointer to remain valid until after we've copied it. If we let go too early,
5127 another thread could invalidate it by unsharing last of the same hash key
5128 (which it can do by means other than releasing copy-on-write Svs)
5129 or by changing the other copy-on-write SVs in the loop. */
5131 S_sv_release_COW(pTHX_ SV *sv, const char *pvx, SV *after)
5133 PERL_ARGS_ASSERT_SV_RELEASE_COW;
5135 { /* this SV was SvIsCOW_normal(sv) */
5136 /* we need to find the SV pointing to us. */
5137 SV *current = SV_COW_NEXT_SV(after);
5139 if (current == sv) {
5140 /* The SV we point to points back to us (there were only two of us
5142 Hence other SV is no longer copy on write either. */
5144 sv_buf_to_rw(after);
5146 /* We need to follow the pointers around the loop. */
5148 while ((next = SV_COW_NEXT_SV(current)) != sv) {
5151 /* don't loop forever if the structure is bust, and we have
5152 a pointer into a closed loop. */
5153 assert (current != after);
5154 assert (SvPVX_const(current) == pvx);
5156 /* Make the SV before us point to the SV after us. */
5157 SV_COW_NEXT_SV_SET(current, after);
5163 =for apidoc sv_force_normal_flags
5165 Undo various types of fakery on an SV, where fakery means
5166 "more than" a string: if the PV is a shared string, make
5167 a private copy; if we're a ref, stop refing; if we're a glob, downgrade to
5168 an xpvmg; if we're a copy-on-write scalar, this is the on-write time when
5169 we do the copy, and is also used locally; if this is a
5170 vstring, drop the vstring magic. If C<SV_COW_DROP_PV> is set
5171 then a copy-on-write scalar drops its PV buffer (if any) and becomes
5172 SvPOK_off rather than making a copy. (Used where this
5173 scalar is about to be set to some other value.) In addition,
5174 the C<flags> parameter gets passed to C<sv_unref_flags()>
5175 when unreffing. C<sv_force_normal> calls this function
5176 with flags set to 0.
5178 This function is expected to be used to signal to perl that this SV is
5179 about to be written to, and any extra book-keeping needs to be taken care
5180 of. Hence, it croaks on read-only values.
5186 S_sv_uncow(pTHX_ SV * const sv, const U32 flags)
5188 assert(SvIsCOW(sv));
5191 const char * const pvx = SvPVX_const(sv);
5192 const STRLEN len = SvLEN(sv);
5193 const STRLEN cur = SvCUR(sv);
5194 # ifdef PERL_OLD_COPY_ON_WRITE
5195 /* next COW sv in the loop. If len is 0 then this is a shared-hash
5196 key scalar, so we mustn't attempt to call SV_COW_NEXT_SV(), as
5197 we'll fail an assertion. */
5198 SV * const next = len ? SV_COW_NEXT_SV(sv) : 0;
5202 PerlIO_printf(Perl_debug_log,
5203 "Copy on write: Force normal %ld\n",
5208 # ifdef PERL_NEW_COPY_ON_WRITE
5210 /* Must do this first, since the CowREFCNT uses SvPVX and
5211 we need to write to CowREFCNT, or de-RO the whole buffer if we are
5212 the only owner left of the buffer. */
5213 sv_buf_to_rw(sv); /* NOOP if RO-ing not supported */
5215 U8 cowrefcnt = CowREFCNT(sv);
5216 if(cowrefcnt != 0) {
5218 CowREFCNT(sv) = cowrefcnt;
5223 /* Else we are the only owner of the buffer. */
5228 /* This SV doesn't own the buffer, so need to Newx() a new one: */
5233 if (flags & SV_COW_DROP_PV) {
5234 /* OK, so we don't need to copy our buffer. */
5237 SvGROW(sv, cur + 1);
5238 Move(pvx,SvPVX(sv),cur,char);
5243 # ifdef PERL_OLD_COPY_ON_WRITE
5244 sv_release_COW(sv, pvx, next);
5247 unshare_hek(SvSHARED_HEK_FROM_PV(pvx));
5254 const char * const pvx = SvPVX_const(sv);
5255 const STRLEN len = SvCUR(sv);
5259 if (flags & SV_COW_DROP_PV) {
5260 /* OK, so we don't need to copy our buffer. */
5263 SvGROW(sv, len + 1);
5264 Move(pvx,SvPVX(sv),len,char);
5267 unshare_hek(SvSHARED_HEK_FROM_PV(pvx));
5273 Perl_sv_force_normal_flags(pTHX_ SV *const sv, const U32 flags)
5275 PERL_ARGS_ASSERT_SV_FORCE_NORMAL_FLAGS;
5278 Perl_croak_no_modify();
5279 else if (SvIsCOW(sv) && LIKELY(SvTYPE(sv) != SVt_PVHV))
5280 S_sv_uncow(aTHX_ sv, flags);
5282 sv_unref_flags(sv, flags);
5283 else if (SvFAKE(sv) && isGV_with_GP(sv))
5284 sv_unglob(sv, flags);
5285 else if (SvFAKE(sv) && isREGEXP(sv)) {
5286 /* Need to downgrade the REGEXP to a simple(r) scalar. This is analogous
5287 to sv_unglob. We only need it here, so inline it. */
5288 const bool islv = SvTYPE(sv) == SVt_PVLV;
5289 const svtype new_type =
5290 islv ? SVt_NULL : SvMAGIC(sv) || SvSTASH(sv) ? SVt_PVMG : SVt_PV;
5291 SV *const temp = newSV_type(new_type);
5292 regexp *const temp_p = ReANY((REGEXP *)sv);
5294 if (new_type == SVt_PVMG) {
5295 SvMAGIC_set(temp, SvMAGIC(sv));
5296 SvMAGIC_set(sv, NULL);
5297 SvSTASH_set(temp, SvSTASH(sv));
5298 SvSTASH_set(sv, NULL);
5300 if (!islv) SvCUR_set(temp, SvCUR(sv));
5301 /* Remember that SvPVX is in the head, not the body. But
5302 RX_WRAPPED is in the body. */
5303 assert(ReANY((REGEXP *)sv)->mother_re);
5304 /* Their buffer is already owned by someone else. */
5305 if (flags & SV_COW_DROP_PV) {
5306 /* SvLEN is already 0. For SVt_REGEXP, we have a brand new
5307 zeroed body. For SVt_PVLV, it should have been set to 0
5308 before turning into a regexp. */
5309 assert(!SvLEN(islv ? sv : temp));
5310 sv->sv_u.svu_pv = 0;
5313 sv->sv_u.svu_pv = savepvn(RX_WRAPPED((REGEXP *)sv), SvCUR(sv));
5314 SvLEN_set(islv ? sv : temp, SvCUR(sv)+1);
5318 /* Now swap the rest of the bodies. */
5322 SvFLAGS(sv) &= ~SVTYPEMASK;
5323 SvFLAGS(sv) |= new_type;
5324 SvANY(sv) = SvANY(temp);
5327 SvFLAGS(temp) &= ~(SVTYPEMASK);
5328 SvFLAGS(temp) |= SVt_REGEXP|SVf_FAKE;
5329 SvANY(temp) = temp_p;
5330 temp->sv_u.svu_rx = (regexp *)temp_p;
5332 SvREFCNT_dec_NN(temp);
5334 else if (SvVOK(sv)) sv_unmagic(sv, PERL_MAGIC_vstring);
5340 Efficient removal of characters from the beginning of the string buffer.
5341 SvPOK(sv), or at least SvPOKp(sv), must be true and the C<ptr> must be a
5342 pointer to somewhere inside the string buffer. The C<ptr> becomes the first
5343 character of the adjusted string. Uses the "OOK hack". On return, only
5344 SvPOK(sv) and SvPOKp(sv) among the OK flags will be true.
5346 Beware: after this function returns, C<ptr> and SvPVX_const(sv) may no longer
5347 refer to the same chunk of data.
5349 The unfortunate similarity of this function's name to that of Perl's C<chop>
5350 operator is strictly coincidental. This function works from the left;
5351 C<chop> works from the right.
5357 Perl_sv_chop(pTHX_ SV *const sv, const char *const ptr)
5368 PERL_ARGS_ASSERT_SV_CHOP;
5370 if (!ptr || !SvPOKp(sv))
5372 delta = ptr - SvPVX_const(sv);
5374 /* Nothing to do. */
5377 max_delta = SvLEN(sv) ? SvLEN(sv) : SvCUR(sv);
5378 if (delta > max_delta)
5379 Perl_croak(aTHX_ "panic: sv_chop ptr=%p, start=%p, end=%p",
5380 ptr, SvPVX_const(sv), SvPVX_const(sv) + max_delta);
5381 /* SvPVX(sv) may move in SV_CHECK_THINKFIRST(sv), so don't use ptr any more */
5382 SV_CHECK_THINKFIRST(sv);
5383 SvPOK_only_UTF8(sv);
5386 if (!SvLEN(sv)) { /* make copy of shared string */
5387 const char *pvx = SvPVX_const(sv);
5388 const STRLEN len = SvCUR(sv);
5389 SvGROW(sv, len + 1);
5390 Move(pvx,SvPVX(sv),len,char);
5396 SvOOK_offset(sv, old_delta);
5398 SvLEN_set(sv, SvLEN(sv) - delta);
5399 SvCUR_set(sv, SvCUR(sv) - delta);
5400 SvPV_set(sv, SvPVX(sv) + delta);
5402 p = (U8 *)SvPVX_const(sv);
5405 /* how many bytes were evacuated? we will fill them with sentinel
5406 bytes, except for the part holding the new offset of course. */
5409 evacn += (old_delta < 0x100 ? 1 : 1 + sizeof(STRLEN));
5411 assert(evacn <= delta + old_delta);
5415 /* This sets 'delta' to the accumulated value of all deltas so far */
5419 /* If 'delta' fits in a byte, store it just prior to the new beginning of
5420 * the string; otherwise store a 0 byte there and store 'delta' just prior
5421 * to that, using as many bytes as a STRLEN occupies. Thus it overwrites a
5422 * portion of the chopped part of the string */
5423 if (delta < 0x100) {
5427 p -= sizeof(STRLEN);
5428 Copy((U8*)&delta, p, sizeof(STRLEN), U8);
5432 /* Fill the preceding buffer with sentinals to verify that no-one is
5442 =for apidoc sv_catpvn
5444 Concatenates the string onto the end of the string which is in the SV. The
5445 C<len> indicates number of bytes to copy. If the SV has the UTF-8
5446 status set, then the bytes appended should be valid UTF-8.
5447 Handles 'get' magic, but not 'set' magic. See C<sv_catpvn_mg>.
5449 =for apidoc sv_catpvn_flags
5451 Concatenates the string onto the end of the string which is in the SV. The
5452 C<len> indicates number of bytes to copy.
5454 By default, the string appended is assumed to be valid UTF-8 if the SV has
5455 the UTF-8 status set, and a string of bytes otherwise. One can force the
5456 appended string to be interpreted as UTF-8 by supplying the C<SV_CATUTF8>
5457 flag, and as bytes by supplying the C<SV_CATBYTES> flag; the SV or the
5458 string appended will be upgraded to UTF-8 if necessary.
5460 If C<flags> has the C<SV_SMAGIC> bit set, will
5461 C<mg_set> on C<dsv> afterwards if appropriate.
5462 C<sv_catpvn> and C<sv_catpvn_nomg> are implemented
5463 in terms of this function.
5469 Perl_sv_catpvn_flags(pTHX_ SV *const dsv, const char *sstr, const STRLEN slen, const I32 flags)
5472 const char * const dstr = SvPV_force_flags(dsv, dlen, flags);
5474 PERL_ARGS_ASSERT_SV_CATPVN_FLAGS;
5475 assert((flags & (SV_CATBYTES|SV_CATUTF8)) != (SV_CATBYTES|SV_CATUTF8));
5477 if (!(flags & SV_CATBYTES) || !SvUTF8(dsv)) {
5478 if (flags & SV_CATUTF8 && !SvUTF8(dsv)) {
5479 sv_utf8_upgrade_flags_grow(dsv, 0, slen + 1);
5482 else SvGROW(dsv, dlen + slen + 1);
5484 sstr = SvPVX_const(dsv);
5485 Move(sstr, SvPVX(dsv) + dlen, slen, char);
5486 SvCUR_set(dsv, SvCUR(dsv) + slen);
5489 /* We inline bytes_to_utf8, to avoid an extra malloc. */
5490 const char * const send = sstr + slen;
5493 /* Something this code does not account for, which I think is
5494 impossible; it would require the same pv to be treated as
5495 bytes *and* utf8, which would indicate a bug elsewhere. */
5496 assert(sstr != dstr);
5498 SvGROW(dsv, dlen + slen * 2 + 1);
5499 d = (U8 *)SvPVX(dsv) + dlen;
5501 while (sstr < send) {
5502 append_utf8_from_native_byte(*sstr, &d);
5505 SvCUR_set(dsv, d-(const U8 *)SvPVX(dsv));
5508 (void)SvPOK_only_UTF8(dsv); /* validate pointer */
5510 if (flags & SV_SMAGIC)
5515 =for apidoc sv_catsv
5517 Concatenates the string from SV C<ssv> onto the end of the string in SV
5518 C<dsv>. If C<ssv> is null, does nothing; otherwise modifies only C<dsv>.
5519 Handles 'get' magic on both SVs, but no 'set' magic. See C<sv_catsv_mg> and
5522 =for apidoc sv_catsv_flags
5524 Concatenates the string from SV C<ssv> onto the end of the string in SV
5525 C<dsv>. If C<ssv> is null, does nothing; otherwise modifies only C<dsv>.
5526 If C<flags> include C<SV_GMAGIC> bit set, will call C<mg_get> on both SVs if
5527 appropriate. If C<flags> include C<SV_SMAGIC>, C<mg_set> will be called on
5528 the modified SV afterward, if appropriate. C<sv_catsv>, C<sv_catsv_nomg>,
5529 and C<sv_catsv_mg> are implemented in terms of this function.
5534 Perl_sv_catsv_flags(pTHX_ SV *const dsv, SV *const ssv, const I32 flags)
5536 PERL_ARGS_ASSERT_SV_CATSV_FLAGS;
5540 const char *spv = SvPV_flags_const(ssv, slen, flags);
5541 if (flags & SV_GMAGIC)
5543 sv_catpvn_flags(dsv, spv, slen,
5544 DO_UTF8(ssv) ? SV_CATUTF8 : SV_CATBYTES);
5545 if (flags & SV_SMAGIC)
5551 =for apidoc sv_catpv
5553 Concatenates the C<NUL>-terminated string onto the end of the string which is
5555 If the SV has the UTF-8 status set, then the bytes appended should be
5556 valid UTF-8. Handles 'get' magic, but not 'set' magic. See C<sv_catpv_mg>.
5561 Perl_sv_catpv(pTHX_ SV *const sv, const char *ptr)
5567 PERL_ARGS_ASSERT_SV_CATPV;
5571 junk = SvPV_force(sv, tlen);
5573 SvGROW(sv, tlen + len + 1);
5575 ptr = SvPVX_const(sv);
5576 Move(ptr,SvPVX(sv)+tlen,len+1,char);
5577 SvCUR_set(sv, SvCUR(sv) + len);
5578 (void)SvPOK_only_UTF8(sv); /* validate pointer */
5583 =for apidoc sv_catpv_flags
5585 Concatenates the C<NUL>-terminated string onto the end of the string which is
5587 If the SV has the UTF-8 status set, then the bytes appended should
5588 be valid UTF-8. If C<flags> has the C<SV_SMAGIC> bit set, will C<mg_set>
5589 on the modified SV if appropriate.
5595 Perl_sv_catpv_flags(pTHX_ SV *dstr, const char *sstr, const I32 flags)
5597 PERL_ARGS_ASSERT_SV_CATPV_FLAGS;
5598 sv_catpvn_flags(dstr, sstr, strlen(sstr), flags);
5602 =for apidoc sv_catpv_mg
5604 Like C<sv_catpv>, but also handles 'set' magic.
5610 Perl_sv_catpv_mg(pTHX_ SV *const sv, const char *const ptr)
5612 PERL_ARGS_ASSERT_SV_CATPV_MG;
5621 Creates a new SV. A non-zero C<len> parameter indicates the number of
5622 bytes of preallocated string space the SV should have. An extra byte for a
5623 trailing C<NUL> is also reserved. (SvPOK is not set for the SV even if string
5624 space is allocated.) The reference count for the new SV is set to 1.
5626 In 5.9.3, newSV() replaces the older NEWSV() API, and drops the first
5627 parameter, I<x>, a debug aid which allowed callers to identify themselves.
5628 This aid has been superseded by a new build option, PERL_MEM_LOG (see
5629 L<perlhacktips/PERL_MEM_LOG>). The older API is still there for use in XS
5630 modules supporting older perls.
5636 Perl_newSV(pTHX_ const STRLEN len)
5642 sv_grow(sv, len + 1);
5647 =for apidoc sv_magicext
5649 Adds magic to an SV, upgrading it if necessary. Applies the
5650 supplied vtable and returns a pointer to the magic added.
5652 Note that C<sv_magicext> will allow things that C<sv_magic> will not.
5653 In particular, you can add magic to SvREADONLY SVs, and add more than
5654 one instance of the same 'how'.
5656 If C<namlen> is greater than zero then a C<savepvn> I<copy> of C<name> is
5657 stored, if C<namlen> is zero then C<name> is stored as-is and - as another
5658 special case - if C<(name && namlen == HEf_SVKEY)> then C<name> is assumed
5659 to contain an C<SV*> and is stored as-is with its REFCNT incremented.
5661 (This is now used as a subroutine by C<sv_magic>.)
5666 Perl_sv_magicext(pTHX_ SV *const sv, SV *const obj, const int how,
5667 const MGVTBL *const vtable, const char *const name, const I32 namlen)
5671 PERL_ARGS_ASSERT_SV_MAGICEXT;
5673 SvUPGRADE(sv, SVt_PVMG);
5674 Newxz(mg, 1, MAGIC);
5675 mg->mg_moremagic = SvMAGIC(sv);
5676 SvMAGIC_set(sv, mg);
5678 /* Sometimes a magic contains a reference loop, where the sv and
5679 object refer to each other. To prevent a reference loop that
5680 would prevent such objects being freed, we look for such loops
5681 and if we find one we avoid incrementing the object refcount.
5683 Note we cannot do this to avoid self-tie loops as intervening RV must
5684 have its REFCNT incremented to keep it in existence.
5687 if (!obj || obj == sv ||
5688 how == PERL_MAGIC_arylen ||
5689 how == PERL_MAGIC_symtab ||
5690 (SvTYPE(obj) == SVt_PVGV &&
5691 (GvSV(obj) == sv || GvHV(obj) == (const HV *)sv
5692 || GvAV(obj) == (const AV *)sv || GvCV(obj) == (const CV *)sv
5693 || GvIOp(obj) == (const IO *)sv || GvFORM(obj) == (const CV *)sv)))
5698 mg->mg_obj = SvREFCNT_inc_simple(obj);
5699 mg->mg_flags |= MGf_REFCOUNTED;
5702 /* Normal self-ties simply pass a null object, and instead of
5703 using mg_obj directly, use the SvTIED_obj macro to produce a
5704 new RV as needed. For glob "self-ties", we are tieing the PVIO
5705 with an RV obj pointing to the glob containing the PVIO. In
5706 this case, to avoid a reference loop, we need to weaken the
5710 if (how == PERL_MAGIC_tiedscalar && SvTYPE(sv) == SVt_PVIO &&
5711 obj && SvROK(obj) && GvIO(SvRV(obj)) == (const IO *)sv)
5717 mg->mg_len = namlen;
5720 mg->mg_ptr = savepvn(name, namlen);
5721 else if (namlen == HEf_SVKEY) {
5722 /* Yes, this is casting away const. This is only for the case of
5723 HEf_SVKEY. I think we need to document this aberation of the
5724 constness of the API, rather than making name non-const, as
5725 that change propagating outwards a long way. */
5726 mg->mg_ptr = (char*)SvREFCNT_inc_simple_NN((SV *)name);
5728 mg->mg_ptr = (char *) name;
5730 mg->mg_virtual = (MGVTBL *) vtable;
5737 Perl_sv_magicext_mglob(pTHX_ SV *sv)
5739 PERL_ARGS_ASSERT_SV_MAGICEXT_MGLOB;
5740 if (SvTYPE(sv) == SVt_PVLV && LvTYPE(sv) == 'y') {
5741 /* This sv is only a delegate. //g magic must be attached to
5746 #ifdef PERL_OLD_COPY_ON_WRITE
5748 sv_force_normal_flags(sv, 0);
5750 return sv_magicext(sv, NULL, PERL_MAGIC_regex_global,
5751 &PL_vtbl_mglob, 0, 0);
5755 =for apidoc sv_magic
5757 Adds magic to an SV. First upgrades C<sv> to type C<SVt_PVMG> if
5758 necessary, then adds a new magic item of type C<how> to the head of the
5761 See C<sv_magicext> (which C<sv_magic> now calls) for a description of the
5762 handling of the C<name> and C<namlen> arguments.
5764 You need to use C<sv_magicext> to add magic to SvREADONLY SVs and also
5765 to add more than one instance of the same 'how'.
5771 Perl_sv_magic(pTHX_ SV *const sv, SV *const obj, const int how,
5772 const char *const name, const I32 namlen)
5774 const MGVTBL *vtable;
5777 unsigned int vtable_index;
5779 PERL_ARGS_ASSERT_SV_MAGIC;
5781 if (how < 0 || (unsigned)how >= C_ARRAY_LENGTH(PL_magic_data)
5782 || ((flags = PL_magic_data[how]),
5783 (vtable_index = flags & PERL_MAGIC_VTABLE_MASK)
5784 > magic_vtable_max))
5785 Perl_croak(aTHX_ "Don't know how to handle magic of type \\%o", how);
5787 /* PERL_MAGIC_ext is reserved for use by extensions not perl internals.
5788 Useful for attaching extension internal data to perl vars.
5789 Note that multiple extensions may clash if magical scalars
5790 etc holding private data from one are passed to another. */
5792 vtable = (vtable_index == magic_vtable_max)
5793 ? NULL : PL_magic_vtables + vtable_index;
5795 #ifdef PERL_OLD_COPY_ON_WRITE
5797 sv_force_normal_flags(sv, 0);
5799 if (SvREADONLY(sv)) {
5801 !PERL_MAGIC_TYPE_READONLY_ACCEPTABLE(how)
5804 Perl_croak_no_modify();
5807 if (SvMAGICAL(sv) || (how == PERL_MAGIC_taint && SvTYPE(sv) >= SVt_PVMG)) {
5808 if (SvMAGIC(sv) && (mg = mg_find(sv, how))) {
5809 /* sv_magic() refuses to add a magic of the same 'how' as an
5812 if (how == PERL_MAGIC_taint)
5818 /* Force pos to be stored as characters, not bytes. */
5819 if (SvMAGICAL(sv) && DO_UTF8(sv)
5820 && (mg = mg_find(sv, PERL_MAGIC_regex_global))
5822 && mg->mg_flags & MGf_BYTES) {
5823 mg->mg_len = (SSize_t)sv_pos_b2u_flags(sv, (STRLEN)mg->mg_len,
5825 mg->mg_flags &= ~MGf_BYTES;
5828 /* Rest of work is done else where */
5829 mg = sv_magicext(sv,obj,how,vtable,name,namlen);
5832 case PERL_MAGIC_taint:
5835 case PERL_MAGIC_ext:
5836 case PERL_MAGIC_dbfile:
5843 S_sv_unmagicext_flags(pTHX_ SV *const sv, const int type, MGVTBL *vtbl, const U32 flags)
5850 if (SvTYPE(sv) < SVt_PVMG || !SvMAGIC(sv))
5852 mgp = &(((XPVMG*) SvANY(sv))->xmg_u.xmg_magic);
5853 for (mg = *mgp; mg; mg = *mgp) {
5854 const MGVTBL* const virt = mg->mg_virtual;
5855 if (mg->mg_type == type && (!flags || virt == vtbl)) {
5856 *mgp = mg->mg_moremagic;
5857 if (virt && virt->svt_free)
5858 virt->svt_free(aTHX_ sv, mg);
5859 if (mg->mg_ptr && mg->mg_type != PERL_MAGIC_regex_global) {
5861 Safefree(mg->mg_ptr);
5862 else if (mg->mg_len == HEf_SVKEY)
5863 SvREFCNT_dec(MUTABLE_SV(mg->mg_ptr));
5864 else if (mg->mg_type == PERL_MAGIC_utf8)
5865 Safefree(mg->mg_ptr);
5867 if (mg->mg_flags & MGf_REFCOUNTED)
5868 SvREFCNT_dec(mg->mg_obj);
5872 mgp = &mg->mg_moremagic;
5875 if (SvMAGICAL(sv)) /* if we're under save_magic, wait for restore_magic; */
5876 mg_magical(sv); /* else fix the flags now */
5880 SvFLAGS(sv) |= (SvFLAGS(sv) & (SVp_IOK|SVp_NOK|SVp_POK)) >> PRIVSHIFT;
5886 =for apidoc sv_unmagic
5888 Removes all magic of type C<type> from an SV.
5894 Perl_sv_unmagic(pTHX_ SV *const sv, const int type)
5896 PERL_ARGS_ASSERT_SV_UNMAGIC;
5897 return S_sv_unmagicext_flags(aTHX_ sv, type, NULL, 0);
5901 =for apidoc sv_unmagicext
5903 Removes all magic of type C<type> with the specified C<vtbl> from an SV.
5909 Perl_sv_unmagicext(pTHX_ SV *const sv, const int type, MGVTBL *vtbl)
5911 PERL_ARGS_ASSERT_SV_UNMAGICEXT;
5912 return S_sv_unmagicext_flags(aTHX_ sv, type, vtbl, 1);
5916 =for apidoc sv_rvweaken
5918 Weaken a reference: set the C<SvWEAKREF> flag on this RV; give the
5919 referred-to SV C<PERL_MAGIC_backref> magic if it hasn't already; and
5920 push a back-reference to this RV onto the array of backreferences
5921 associated with that magic. If the RV is magical, set magic will be
5922 called after the RV is cleared.
5928 Perl_sv_rvweaken(pTHX_ SV *const sv)
5932 PERL_ARGS_ASSERT_SV_RVWEAKEN;
5934 if (!SvOK(sv)) /* let undefs pass */
5937 Perl_croak(aTHX_ "Can't weaken a nonreference");
5938 else if (SvWEAKREF(sv)) {
5939 Perl_ck_warner(aTHX_ packWARN(WARN_MISC), "Reference is already weak");
5942 else if (SvREADONLY(sv)) croak_no_modify();
5944 Perl_sv_add_backref(aTHX_ tsv, sv);
5946 SvREFCNT_dec_NN(tsv);
5951 =for apidoc sv_get_backrefs
5953 If the sv is the target of a weak reference then it returns the back
5954 references structure associated with the sv; otherwise return NULL.
5956 When returning a non-null result the type of the return is relevant. If it
5957 is an AV then the elements of the AV are the weak reference RVs which
5958 point at this item. If it is any other type then the item itself is the
5961 See also Perl_sv_add_backref(), Perl_sv_del_backref(),
5962 Perl_sv_kill_backrefs()
5968 Perl_sv_get_backrefs(SV *const sv)
5972 PERL_ARGS_ASSERT_SV_GET_BACKREFS;
5974 /* find slot to store array or singleton backref */
5976 if (SvTYPE(sv) == SVt_PVHV) {
5978 struct xpvhv_aux * const iter = HvAUX((HV *)sv);
5979 backrefs = (SV *)iter->xhv_backreferences;
5981 } else if (SvMAGICAL(sv)) {
5982 MAGIC *mg = mg_find(sv, PERL_MAGIC_backref);
5984 backrefs = mg->mg_obj;
5989 /* Give tsv backref magic if it hasn't already got it, then push a
5990 * back-reference to sv onto the array associated with the backref magic.
5992 * As an optimisation, if there's only one backref and it's not an AV,
5993 * store it directly in the HvAUX or mg_obj slot, avoiding the need to
5994 * allocate an AV. (Whether the slot holds an AV tells us whether this is
5998 /* A discussion about the backreferences array and its refcount:
6000 * The AV holding the backreferences is pointed to either as the mg_obj of
6001 * PERL_MAGIC_backref, or in the specific case of a HV, from the
6002 * xhv_backreferences field. The array is created with a refcount
6003 * of 2. This means that if during global destruction the array gets
6004 * picked on before its parent to have its refcount decremented by the
6005 * random zapper, it won't actually be freed, meaning it's still there for
6006 * when its parent gets freed.
6008 * When the parent SV is freed, the extra ref is killed by
6009 * Perl_sv_kill_backrefs. The other ref is killed, in the case of magic,
6010 * by mg_free() / MGf_REFCOUNTED, or for a hash, by Perl_hv_kill_backrefs.
6012 * When a single backref SV is stored directly, it is not reference
6017 Perl_sv_add_backref(pTHX_ SV *const tsv, SV *const sv)
6023 PERL_ARGS_ASSERT_SV_ADD_BACKREF;
6025 /* find slot to store array or singleton backref */
6027 if (SvTYPE(tsv) == SVt_PVHV) {
6028 svp = (SV**)Perl_hv_backreferences_p(aTHX_ MUTABLE_HV(tsv));
6031 mg = mg_find(tsv, PERL_MAGIC_backref);
6033 mg = sv_magicext(tsv, NULL, PERL_MAGIC_backref, &PL_vtbl_backref, NULL, 0);
6034 svp = &(mg->mg_obj);
6037 /* create or retrieve the array */
6039 if ( (!*svp && SvTYPE(sv) == SVt_PVAV)
6040 || (*svp && SvTYPE(*svp) != SVt_PVAV)
6044 mg->mg_flags |= MGf_REFCOUNTED;
6047 SvREFCNT_inc_simple_void_NN(av);
6048 /* av now has a refcnt of 2; see discussion above */
6049 av_extend(av, *svp ? 2 : 1);
6051 /* move single existing backref to the array */
6052 AvARRAY(av)[++AvFILLp(av)] = *svp; /* av_push() */
6057 av = MUTABLE_AV(*svp);
6059 /* optimisation: store single backref directly in HvAUX or mg_obj */
6063 assert(SvTYPE(av) == SVt_PVAV);
6064 if (AvFILLp(av) >= AvMAX(av)) {
6065 av_extend(av, AvFILLp(av)+1);
6068 /* push new backref */
6069 AvARRAY(av)[++AvFILLp(av)] = sv; /* av_push() */
6072 /* delete a back-reference to ourselves from the backref magic associated
6073 * with the SV we point to.
6077 Perl_sv_del_backref(pTHX_ SV *const tsv, SV *const sv)
6081 PERL_ARGS_ASSERT_SV_DEL_BACKREF;
6083 if (SvTYPE(tsv) == SVt_PVHV) {
6085 svp = (SV**)Perl_hv_backreferences_p(aTHX_ MUTABLE_HV(tsv));
6087 else if (SvIS_FREED(tsv) && PL_phase == PERL_PHASE_DESTRUCT) {
6088 /* It's possible for the the last (strong) reference to tsv to have
6089 become freed *before* the last thing holding a weak reference.
6090 If both survive longer than the backreferences array, then when
6091 the referent's reference count drops to 0 and it is freed, it's
6092 not able to chase the backreferences, so they aren't NULLed.
6094 For example, a CV holds a weak reference to its stash. If both the
6095 CV and the stash survive longer than the backreferences array,
6096 and the CV gets picked for the SvBREAK() treatment first,
6097 *and* it turns out that the stash is only being kept alive because
6098 of an our variable in the pad of the CV, then midway during CV
6099 destruction the stash gets freed, but CvSTASH() isn't set to NULL.
6100 It ends up pointing to the freed HV. Hence it's chased in here, and
6101 if this block wasn't here, it would hit the !svp panic just below.
6103 I don't believe that "better" destruction ordering is going to help
6104 here - during global destruction there's always going to be the
6105 chance that something goes out of order. We've tried to make it
6106 foolproof before, and it only resulted in evolutionary pressure on
6107 fools. Which made us look foolish for our hubris. :-(
6113 = SvMAGICAL(tsv) ? mg_find(tsv, PERL_MAGIC_backref) : NULL;
6114 svp = mg ? &(mg->mg_obj) : NULL;
6118 Perl_croak(aTHX_ "panic: del_backref, svp=0");
6120 /* It's possible that sv is being freed recursively part way through the
6121 freeing of tsv. If this happens, the backreferences array of tsv has
6122 already been freed, and so svp will be NULL. If this is the case,
6123 we should not panic. Instead, nothing needs doing, so return. */
6124 if (PL_phase == PERL_PHASE_DESTRUCT && SvREFCNT(tsv) == 0)
6126 Perl_croak(aTHX_ "panic: del_backref, *svp=%p phase=%s refcnt=%" UVuf,
6127 (void*)*svp, PL_phase_names[PL_phase], (UV)SvREFCNT(tsv));
6130 if (SvTYPE(*svp) == SVt_PVAV) {
6134 AV * const av = (AV*)*svp;
6136 assert(!SvIS_FREED(av));
6140 /* for an SV with N weak references to it, if all those
6141 * weak refs are deleted, then sv_del_backref will be called
6142 * N times and O(N^2) compares will be done within the backref
6143 * array. To ameliorate this potential slowness, we:
6144 * 1) make sure this code is as tight as possible;
6145 * 2) when looking for SV, look for it at both the head and tail of the
6146 * array first before searching the rest, since some create/destroy
6147 * patterns will cause the backrefs to be freed in order.
6154 SV **p = &svp[fill];
6155 SV *const topsv = *p;
6162 /* We weren't the last entry.
6163 An unordered list has this property that you
6164 can take the last element off the end to fill
6165 the hole, and it's still an unordered list :-)
6171 break; /* should only be one */
6178 AvFILLp(av) = fill-1;
6180 else if (SvIS_FREED(*svp) && PL_phase == PERL_PHASE_DESTRUCT) {
6181 /* freed AV; skip */
6184 /* optimisation: only a single backref, stored directly */
6186 Perl_croak(aTHX_ "panic: del_backref, *svp=%p, sv=%p",
6187 (void*)*svp, (void*)sv);
6194 Perl_sv_kill_backrefs(pTHX_ SV *const sv, AV *const av)
6200 PERL_ARGS_ASSERT_SV_KILL_BACKREFS;
6205 /* after multiple passes through Perl_sv_clean_all() for a thingy
6206 * that has badly leaked, the backref array may have gotten freed,
6207 * since we only protect it against 1 round of cleanup */
6208 if (SvIS_FREED(av)) {
6209 if (PL_in_clean_all) /* All is fair */
6212 "panic: magic_killbackrefs (freed backref AV/SV)");
6216 is_array = (SvTYPE(av) == SVt_PVAV);
6218 assert(!SvIS_FREED(av));
6221 last = svp + AvFILLp(av);
6224 /* optimisation: only a single backref, stored directly */
6230 while (svp <= last) {
6232 SV *const referrer = *svp;
6233 if (SvWEAKREF(referrer)) {
6234 /* XXX Should we check that it hasn't changed? */
6235 assert(SvROK(referrer));
6236 SvRV_set(referrer, 0);
6238 SvWEAKREF_off(referrer);
6239 SvSETMAGIC(referrer);
6240 } else if (SvTYPE(referrer) == SVt_PVGV ||
6241 SvTYPE(referrer) == SVt_PVLV) {
6242 assert(SvTYPE(sv) == SVt_PVHV); /* stash backref */
6243 /* You lookin' at me? */
6244 assert(GvSTASH(referrer));
6245 assert(GvSTASH(referrer) == (const HV *)sv);
6246 GvSTASH(referrer) = 0;
6247 } else if (SvTYPE(referrer) == SVt_PVCV ||
6248 SvTYPE(referrer) == SVt_PVFM) {
6249 if (SvTYPE(sv) == SVt_PVHV) { /* stash backref */
6250 /* You lookin' at me? */
6251 assert(CvSTASH(referrer));
6252 assert(CvSTASH(referrer) == (const HV *)sv);
6253 SvANY(MUTABLE_CV(referrer))->xcv_stash = 0;
6256 assert(SvTYPE(sv) == SVt_PVGV);
6257 /* You lookin' at me? */
6258 assert(CvGV(referrer));
6259 assert(CvGV(referrer) == (const GV *)sv);
6260 anonymise_cv_maybe(MUTABLE_GV(sv),
6261 MUTABLE_CV(referrer));
6266 "panic: magic_killbackrefs (flags=%"UVxf")",
6267 (UV)SvFLAGS(referrer));
6278 SvREFCNT_dec_NN(av); /* remove extra count added by sv_add_backref() */
6284 =for apidoc sv_insert
6286 Inserts a string at the specified offset/length within the SV. Similar to
6287 the Perl substr() function. Handles get magic.
6289 =for apidoc sv_insert_flags
6291 Same as C<sv_insert>, but the extra C<flags> are passed to the
6292 C<SvPV_force_flags> that applies to C<bigstr>.
6298 Perl_sv_insert_flags(pTHX_ SV *const bigstr, const STRLEN offset, const STRLEN len, const char *const little, const STRLEN littlelen, const U32 flags)
6304 SSize_t i; /* better be sizeof(STRLEN) or bad things happen */
6307 PERL_ARGS_ASSERT_SV_INSERT_FLAGS;
6309 SvPV_force_flags(bigstr, curlen, flags);
6310 (void)SvPOK_only_UTF8(bigstr);
6311 if (offset + len > curlen) {
6312 SvGROW(bigstr, offset+len+1);
6313 Zero(SvPVX(bigstr)+curlen, offset+len-curlen, char);
6314 SvCUR_set(bigstr, offset+len);
6318 i = littlelen - len;
6319 if (i > 0) { /* string might grow */
6320 big = SvGROW(bigstr, SvCUR(bigstr) + i + 1);
6321 mid = big + offset + len;
6322 midend = bigend = big + SvCUR(bigstr);
6325 while (midend > mid) /* shove everything down */
6326 *--bigend = *--midend;
6327 Move(little,big+offset,littlelen,char);
6328 SvCUR_set(bigstr, SvCUR(bigstr) + i);
6333 Move(little,SvPVX(bigstr)+offset,len,char);
6338 big = SvPVX(bigstr);
6341 bigend = big + SvCUR(bigstr);
6343 if (midend > bigend)
6344 Perl_croak(aTHX_ "panic: sv_insert, midend=%p, bigend=%p",
6347 if (mid - big > bigend - midend) { /* faster to shorten from end */
6349 Move(little, mid, littlelen,char);
6352 i = bigend - midend;
6354 Move(midend, mid, i,char);
6358 SvCUR_set(bigstr, mid - big);
6360 else if ((i = mid - big)) { /* faster from front */
6361 midend -= littlelen;
6363 Move(big, midend - i, i, char);
6364 sv_chop(bigstr,midend-i);
6366 Move(little, mid, littlelen,char);
6368 else if (littlelen) {
6369 midend -= littlelen;
6370 sv_chop(bigstr,midend);
6371 Move(little,midend,littlelen,char);
6374 sv_chop(bigstr,midend);
6380 =for apidoc sv_replace
6382 Make the first argument a copy of the second, then delete the original.
6383 The target SV physically takes over ownership of the body of the source SV
6384 and inherits its flags; however, the target keeps any magic it owns,
6385 and any magic in the source is discarded.
6386 Note that this is a rather specialist SV copying operation; most of the
6387 time you'll want to use C<sv_setsv> or one of its many macro front-ends.
6393 Perl_sv_replace(pTHX_ SV *const sv, SV *const nsv)
6395 const U32 refcnt = SvREFCNT(sv);
6397 PERL_ARGS_ASSERT_SV_REPLACE;
6399 SV_CHECK_THINKFIRST_COW_DROP(sv);
6400 if (SvREFCNT(nsv) != 1) {
6401 Perl_croak(aTHX_ "panic: reference miscount on nsv in sv_replace()"
6402 " (%" UVuf " != 1)", (UV) SvREFCNT(nsv));
6404 if (SvMAGICAL(sv)) {
6408 sv_upgrade(nsv, SVt_PVMG);
6409 SvMAGIC_set(nsv, SvMAGIC(sv));
6410 SvFLAGS(nsv) |= SvMAGICAL(sv);
6412 SvMAGIC_set(sv, NULL);
6416 assert(!SvREFCNT(sv));
6417 #ifdef DEBUG_LEAKING_SCALARS
6418 sv->sv_flags = nsv->sv_flags;
6419 sv->sv_any = nsv->sv_any;
6420 sv->sv_refcnt = nsv->sv_refcnt;
6421 sv->sv_u = nsv->sv_u;
6423 StructCopy(nsv,sv,SV);
6425 if(SvTYPE(sv) == SVt_IV) {
6426 SET_SVANY_FOR_BODYLESS_IV(sv);
6430 #ifdef PERL_OLD_COPY_ON_WRITE
6431 if (SvIsCOW_normal(nsv)) {
6432 /* We need to follow the pointers around the loop to make the
6433 previous SV point to sv, rather than nsv. */
6436 while ((next = SV_COW_NEXT_SV(current)) != nsv) {
6439 assert(SvPVX_const(current) == SvPVX_const(nsv));
6441 /* Make the SV before us point to the SV after us. */
6443 PerlIO_printf(Perl_debug_log, "previous is\n");
6445 PerlIO_printf(Perl_debug_log,
6446 "move it from 0x%"UVxf" to 0x%"UVxf"\n",
6447 (UV) SV_COW_NEXT_SV(current), (UV) sv);
6449 SV_COW_NEXT_SV_SET(current, sv);
6452 SvREFCNT(sv) = refcnt;
6453 SvFLAGS(nsv) |= SVTYPEMASK; /* Mark as freed */
6458 /* We're about to free a GV which has a CV that refers back to us.
6459 * If that CV will outlive us, make it anonymous (i.e. fix up its CvGV
6463 S_anonymise_cv_maybe(pTHX_ GV *gv, CV* cv)
6468 PERL_ARGS_ASSERT_ANONYMISE_CV_MAYBE;
6471 assert(SvREFCNT(gv) == 0);
6472 assert(isGV(gv) && isGV_with_GP(gv));
6474 assert(!CvANON(cv));
6475 assert(CvGV(cv) == gv);
6476 assert(!CvNAMED(cv));
6478 /* will the CV shortly be freed by gp_free() ? */
6479 if (GvCV(gv) == cv && GvGP(gv)->gp_refcnt < 2 && SvREFCNT(cv) < 2) {
6480 SvANY(cv)->xcv_gv_u.xcv_gv = NULL;
6484 /* if not, anonymise: */
6485 gvname = (GvSTASH(gv) && HvNAME(GvSTASH(gv)) && HvENAME(GvSTASH(gv)))
6486 ? newSVhek(HvENAME_HEK(GvSTASH(gv)))
6487 : newSVpvn_flags( "__ANON__", 8, 0 );
6488 sv_catpvs(gvname, "::__ANON__");
6489 anongv = gv_fetchsv(gvname, GV_ADDMULTI, SVt_PVCV);
6490 SvREFCNT_dec_NN(gvname);
6494 SvANY(cv)->xcv_gv_u.xcv_gv = MUTABLE_GV(SvREFCNT_inc(anongv));
6499 =for apidoc sv_clear
6501 Clear an SV: call any destructors, free up any memory used by the body,
6502 and free the body itself. The SV's head is I<not> freed, although
6503 its type is set to all 1's so that it won't inadvertently be assumed
6504 to be live during global destruction etc.
6505 This function should only be called when REFCNT is zero. Most of the time
6506 you'll want to call C<sv_free()> (or its macro wrapper C<SvREFCNT_dec>)
6513 Perl_sv_clear(pTHX_ SV *const orig_sv)
6518 const struct body_details *sv_type_details;
6522 STRLEN hash_index = 0; /* initialise to make Coverity et al happy.
6523 Not strictly necessary */
6525 PERL_ARGS_ASSERT_SV_CLEAR;
6527 /* within this loop, sv is the SV currently being freed, and
6528 * iter_sv is the most recent AV or whatever that's being iterated
6529 * over to provide more SVs */
6535 assert(SvREFCNT(sv) == 0);
6536 assert(SvTYPE(sv) != (svtype)SVTYPEMASK);
6538 if (type <= SVt_IV) {
6539 /* See the comment in sv.h about the collusion between this
6540 * early return and the overloading of the NULL slots in the
6544 SvFLAGS(sv) &= SVf_BREAK;
6545 SvFLAGS(sv) |= SVTYPEMASK;
6549 /* objs are always >= MG, but pad names use the SVs_OBJECT flag
6550 for another purpose */
6551 assert(!SvOBJECT(sv) || type >= SVt_PVMG);
6553 if (type >= SVt_PVMG) {
6555 if (!curse(sv, 1)) goto get_next_sv;
6556 type = SvTYPE(sv); /* destructor may have changed it */
6558 /* Free back-references before magic, in case the magic calls
6559 * Perl code that has weak references to sv. */
6560 if (type == SVt_PVHV) {
6561 Perl_hv_kill_backrefs(aTHX_ MUTABLE_HV(sv));
6565 else if (SvMAGIC(sv)) {
6566 /* Free back-references before other types of magic. */
6567 sv_unmagic(sv, PERL_MAGIC_backref);
6573 /* case SVt_INVLIST: */
6576 IoIFP(sv) != PerlIO_stdin() &&
6577 IoIFP(sv) != PerlIO_stdout() &&
6578 IoIFP(sv) != PerlIO_stderr() &&
6579 !(IoFLAGS(sv) & IOf_FAKE_DIRP))
6581 io_close(MUTABLE_IO(sv), NULL, FALSE,
6582 (IoTYPE(sv) == IoTYPE_WRONLY ||
6583 IoTYPE(sv) == IoTYPE_RDWR ||
6584 IoTYPE(sv) == IoTYPE_APPEND));
6586 if (IoDIRP(sv) && !(IoFLAGS(sv) & IOf_FAKE_DIRP))
6587 PerlDir_close(IoDIRP(sv));
6588 IoDIRP(sv) = (DIR*)NULL;
6589 Safefree(IoTOP_NAME(sv));
6590 Safefree(IoFMT_NAME(sv));
6591 Safefree(IoBOTTOM_NAME(sv));
6592 if ((const GV *)sv == PL_statgv)
6596 /* FIXME for plugins */
6598 pregfree2((REGEXP*) sv);
6602 cv_undef(MUTABLE_CV(sv));
6603 /* If we're in a stash, we don't own a reference to it.
6604 * However it does have a back reference to us, which needs to
6606 if ((stash = CvSTASH(sv)))
6607 sv_del_backref(MUTABLE_SV(stash), sv);
6610 if (PL_last_swash_hv == (const HV *)sv) {
6611 PL_last_swash_hv = NULL;
6613 if (HvTOTALKEYS((HV*)sv) > 0) {
6615 /* this statement should match the one at the beginning of
6616 * hv_undef_flags() */
6617 if ( PL_phase != PERL_PHASE_DESTRUCT
6618 && (hek = HvNAME_HEK((HV*)sv)))
6620 if (PL_stashcache) {
6621 DEBUG_o(Perl_deb(aTHX_
6622 "sv_clear clearing PL_stashcache for '%"HEKf
6625 (void)hv_deletehek(PL_stashcache,
6628 hv_name_set((HV*)sv, NULL, 0, 0);
6631 /* save old iter_sv in unused SvSTASH field */
6632 assert(!SvOBJECT(sv));
6633 SvSTASH(sv) = (HV*)iter_sv;
6636 /* save old hash_index in unused SvMAGIC field */
6637 assert(!SvMAGICAL(sv));
6638 assert(!SvMAGIC(sv));
6639 ((XPVMG*) SvANY(sv))->xmg_u.xmg_hash_index = hash_index;
6642 next_sv = Perl_hfree_next_entry(aTHX_ (HV*)sv, &hash_index);
6643 goto get_next_sv; /* process this new sv */
6645 /* free empty hash */
6646 Perl_hv_undef_flags(aTHX_ MUTABLE_HV(sv), HV_NAME_SETALL);
6647 assert(!HvARRAY((HV*)sv));
6651 AV* av = MUTABLE_AV(sv);
6652 if (PL_comppad == av) {
6656 if (AvREAL(av) && AvFILLp(av) > -1) {
6657 next_sv = AvARRAY(av)[AvFILLp(av)--];
6658 /* save old iter_sv in top-most slot of AV,
6659 * and pray that it doesn't get wiped in the meantime */
6660 AvARRAY(av)[AvMAX(av)] = iter_sv;
6662 goto get_next_sv; /* process this new sv */
6664 Safefree(AvALLOC(av));
6669 if (LvTYPE(sv) == 'T') { /* for tie: return HE to pool */
6670 SvREFCNT_dec(HeKEY_sv((HE*)LvTARG(sv)));
6671 HeNEXT((HE*)LvTARG(sv)) = PL_hv_fetch_ent_mh;
6672 PL_hv_fetch_ent_mh = (HE*)LvTARG(sv);
6674 else if (LvTYPE(sv) != 't') /* unless tie: unrefcnted fake SV** */
6675 SvREFCNT_dec(LvTARG(sv));
6676 if (isREGEXP(sv)) goto freeregexp;
6679 if (isGV_with_GP(sv)) {
6680 if(GvCVu((const GV *)sv) && (stash = GvSTASH(MUTABLE_GV(sv)))
6681 && HvENAME_get(stash))
6682 mro_method_changed_in(stash);
6683 gp_free(MUTABLE_GV(sv));
6685 unshare_hek(GvNAME_HEK(sv));
6686 /* If we're in a stash, we don't own a reference to it.
6687 * However it does have a back reference to us, which
6688 * needs to be cleared. */
6689 if (!SvVALID(sv) && (stash = GvSTASH(sv)))
6690 sv_del_backref(MUTABLE_SV(stash), sv);
6692 /* FIXME. There are probably more unreferenced pointers to SVs
6693 * in the interpreter struct that we should check and tidy in
6694 * a similar fashion to this: */
6695 /* See also S_sv_unglob, which does the same thing. */
6696 if ((const GV *)sv == PL_last_in_gv)
6697 PL_last_in_gv = NULL;
6698 else if ((const GV *)sv == PL_statgv)
6700 else if ((const GV *)sv == PL_stderrgv)
6709 /* Don't bother with SvOOK_off(sv); as we're only going to
6713 SvOOK_offset(sv, offset);
6714 SvPV_set(sv, SvPVX_mutable(sv) - offset);
6715 /* Don't even bother with turning off the OOK flag. */
6720 SV * const target = SvRV(sv);
6722 sv_del_backref(target, sv);
6728 else if (SvPVX_const(sv)
6729 && !(SvTYPE(sv) == SVt_PVIO
6730 && !(IoFLAGS(sv) & IOf_FAKE_DIRP)))
6734 PerlIO_printf(Perl_debug_log, "Copy on write: clear\n");
6738 # ifdef PERL_OLD_COPY_ON_WRITE
6739 sv_release_COW(sv, SvPVX_const(sv), SV_COW_NEXT_SV(sv));
6741 if (CowREFCNT(sv)) {
6749 unshare_hek(SvSHARED_HEK_FROM_PV(SvPVX_const(sv)));
6753 # ifdef PERL_OLD_COPY_ON_WRITE
6757 Safefree(SvPVX_mutable(sv));
6761 else if (SvPVX_const(sv) && SvLEN(sv)
6762 && !(SvTYPE(sv) == SVt_PVIO
6763 && !(IoFLAGS(sv) & IOf_FAKE_DIRP)))
6764 Safefree(SvPVX_mutable(sv));
6765 else if (SvPVX_const(sv) && SvIsCOW(sv)) {
6766 unshare_hek(SvSHARED_HEK_FROM_PV(SvPVX_const(sv)));
6776 SvFLAGS(sv) &= SVf_BREAK;
6777 SvFLAGS(sv) |= SVTYPEMASK;
6779 sv_type_details = bodies_by_type + type;
6780 if (sv_type_details->arena) {
6781 del_body(((char *)SvANY(sv) + sv_type_details->offset),
6782 &PL_body_roots[type]);
6784 else if (sv_type_details->body_size) {
6785 safefree(SvANY(sv));
6789 /* caller is responsible for freeing the head of the original sv */
6790 if (sv != orig_sv && !SvREFCNT(sv))
6793 /* grab and free next sv, if any */
6801 else if (!iter_sv) {
6803 } else if (SvTYPE(iter_sv) == SVt_PVAV) {
6804 AV *const av = (AV*)iter_sv;
6805 if (AvFILLp(av) > -1) {
6806 sv = AvARRAY(av)[AvFILLp(av)--];
6808 else { /* no more elements of current AV to free */
6811 /* restore previous value, squirrelled away */
6812 iter_sv = AvARRAY(av)[AvMAX(av)];
6813 Safefree(AvALLOC(av));
6816 } else if (SvTYPE(iter_sv) == SVt_PVHV) {
6817 sv = Perl_hfree_next_entry(aTHX_ (HV*)iter_sv, &hash_index);
6818 if (!sv && !HvTOTALKEYS((HV *)iter_sv)) {
6819 /* no more elements of current HV to free */
6822 /* Restore previous values of iter_sv and hash_index,
6823 * squirrelled away */
6824 assert(!SvOBJECT(sv));
6825 iter_sv = (SV*)SvSTASH(sv);
6826 assert(!SvMAGICAL(sv));
6827 hash_index = ((XPVMG*) SvANY(sv))->xmg_u.xmg_hash_index;
6829 /* perl -DA does not like rubbish in SvMAGIC. */
6833 /* free any remaining detritus from the hash struct */
6834 Perl_hv_undef_flags(aTHX_ MUTABLE_HV(sv), HV_NAME_SETALL);
6835 assert(!HvARRAY((HV*)sv));
6840 /* unrolled SvREFCNT_dec and sv_free2 follows: */
6844 if (!SvREFCNT(sv)) {
6848 if (--(SvREFCNT(sv)))
6852 Perl_ck_warner_d(aTHX_ packWARN(WARN_DEBUGGING),
6853 "Attempt to free temp prematurely: SV 0x%"UVxf
6854 pTHX__FORMAT, PTR2UV(sv) pTHX__VALUE);
6858 if (SvIMMORTAL(sv)) {
6859 /* make sure SvREFCNT(sv)==0 happens very seldom */
6860 SvREFCNT(sv) = SvREFCNT_IMMORTAL;
6869 /* This routine curses the sv itself, not the object referenced by sv. So
6870 sv does not have to be ROK. */
6873 S_curse(pTHX_ SV * const sv, const bool check_refcnt) {
6874 PERL_ARGS_ASSERT_CURSE;
6875 assert(SvOBJECT(sv));
6877 if (PL_defstash && /* Still have a symbol table? */
6883 stash = SvSTASH(sv);
6884 assert(SvTYPE(stash) == SVt_PVHV);
6885 if (HvNAME(stash)) {
6886 CV* destructor = NULL;
6887 assert (SvOOK(stash));
6888 if (!SvOBJECT(stash)) destructor = (CV *)SvSTASH(stash);
6889 if (!destructor || HvMROMETA(stash)->destroy_gen
6890 != PL_sub_generation)
6893 gv_fetchmeth_autoload(stash, "DESTROY", 7, 0);
6894 if (gv) destructor = GvCV(gv);
6895 if (!SvOBJECT(stash))
6898 destructor ? (HV *)destructor : ((HV *)0)+1;
6899 HvAUX(stash)->xhv_mro_meta->destroy_gen =
6903 assert(!destructor || destructor == ((CV *)0)+1
6904 || SvTYPE(destructor) == SVt_PVCV);
6905 if (destructor && destructor != ((CV *)0)+1
6906 /* A constant subroutine can have no side effects, so
6907 don't bother calling it. */
6908 && !CvCONST(destructor)
6909 /* Don't bother calling an empty destructor or one that
6910 returns immediately. */
6911 && (CvISXSUB(destructor)
6912 || (CvSTART(destructor)
6913 && (CvSTART(destructor)->op_next->op_type
6915 && (CvSTART(destructor)->op_next->op_type
6917 || CvSTART(destructor)->op_next->op_next->op_type
6923 SV* const tmpref = newRV(sv);
6924 SvREADONLY_on(tmpref); /* DESTROY() could be naughty */
6926 PUSHSTACKi(PERLSI_DESTROY);
6931 call_sv(MUTABLE_SV(destructor),
6932 G_DISCARD|G_EVAL|G_KEEPERR|G_VOID);
6936 if(SvREFCNT(tmpref) < 2) {
6937 /* tmpref is not kept alive! */
6939 SvRV_set(tmpref, NULL);
6942 SvREFCNT_dec_NN(tmpref);
6945 } while (SvOBJECT(sv) && SvSTASH(sv) != stash);
6948 if (check_refcnt && SvREFCNT(sv)) {
6949 if (PL_in_clean_objs)
6951 "DESTROY created new reference to dead object '%"HEKf"'",
6952 HEKfARG(HvNAME_HEK(stash)));
6953 /* DESTROY gave object new lease on life */
6959 HV * const stash = SvSTASH(sv);
6960 /* Curse before freeing the stash, as freeing the stash could cause
6961 a recursive call into S_curse. */
6962 SvOBJECT_off(sv); /* Curse the object. */
6963 SvSTASH_set(sv,0); /* SvREFCNT_dec may try to read this */
6964 SvREFCNT_dec(stash); /* possibly of changed persuasion */
6970 =for apidoc sv_newref
6972 Increment an SV's reference count. Use the C<SvREFCNT_inc()> wrapper
6979 Perl_sv_newref(pTHX_ SV *const sv)
6981 PERL_UNUSED_CONTEXT;
6990 Decrement an SV's reference count, and if it drops to zero, call
6991 C<sv_clear> to invoke destructors and free up any memory used by
6992 the body; finally, deallocate the SV's head itself.
6993 Normally called via a wrapper macro C<SvREFCNT_dec>.
6999 Perl_sv_free(pTHX_ SV *const sv)
7005 /* Private helper function for SvREFCNT_dec().
7006 * Called with rc set to original SvREFCNT(sv), where rc == 0 or 1 */
7009 Perl_sv_free2(pTHX_ SV *const sv, const U32 rc)
7013 PERL_ARGS_ASSERT_SV_FREE2;
7015 if (LIKELY( rc == 1 )) {
7021 Perl_ck_warner_d(aTHX_ packWARN(WARN_DEBUGGING),
7022 "Attempt to free temp prematurely: SV 0x%"UVxf
7023 pTHX__FORMAT, PTR2UV(sv) pTHX__VALUE);
7027 if (SvIMMORTAL(sv)) {
7028 /* make sure SvREFCNT(sv)==0 happens very seldom */
7029 SvREFCNT(sv) = SvREFCNT_IMMORTAL;
7033 if (! SvREFCNT(sv)) /* may have have been resurrected */
7038 /* handle exceptional cases */
7042 if (SvFLAGS(sv) & SVf_BREAK)
7043 /* this SV's refcnt has been artificially decremented to
7044 * trigger cleanup */
7046 if (PL_in_clean_all) /* All is fair */
7048 if (SvIMMORTAL(sv)) {
7049 /* make sure SvREFCNT(sv)==0 happens very seldom */
7050 SvREFCNT(sv) = SvREFCNT_IMMORTAL;
7053 if (ckWARN_d(WARN_INTERNAL)) {
7054 #ifdef DEBUG_LEAKING_SCALARS_FORK_DUMP
7055 Perl_dump_sv_child(aTHX_ sv);
7057 #ifdef DEBUG_LEAKING_SCALARS
7060 #ifdef DEBUG_LEAKING_SCALARS_ABORT
7061 if (PL_warnhook == PERL_WARNHOOK_FATAL
7062 || ckDEAD(packWARN(WARN_INTERNAL))) {
7063 /* Don't let Perl_warner cause us to escape our fate: */
7067 /* This may not return: */
7068 Perl_warner(aTHX_ packWARN(WARN_INTERNAL),
7069 "Attempt to free unreferenced scalar: SV 0x%"UVxf
7070 pTHX__FORMAT, PTR2UV(sv) pTHX__VALUE);
7073 #ifdef DEBUG_LEAKING_SCALARS_ABORT
7083 Returns the length of the string in the SV. Handles magic and type
7084 coercion and sets the UTF8 flag appropriately. See also C<SvCUR>, which
7085 gives raw access to the xpv_cur slot.
7091 Perl_sv_len(pTHX_ SV *const sv)
7098 (void)SvPV_const(sv, len);
7103 =for apidoc sv_len_utf8
7105 Returns the number of characters in the string in an SV, counting wide
7106 UTF-8 bytes as a single character. Handles magic and type coercion.
7112 * The length is cached in PERL_MAGIC_utf8, in the mg_len field. Also the
7113 * mg_ptr is used, by sv_pos_u2b() and sv_pos_b2u() - see the comments below.
7114 * (Note that the mg_len is not the length of the mg_ptr field.
7115 * This allows the cache to store the character length of the string without
7116 * needing to malloc() extra storage to attach to the mg_ptr.)
7121 Perl_sv_len_utf8(pTHX_ SV *const sv)
7127 return sv_len_utf8_nomg(sv);
7131 Perl_sv_len_utf8_nomg(pTHX_ SV * const sv)
7134 const U8 *s = (U8*)SvPV_nomg_const(sv, len);
7136 PERL_ARGS_ASSERT_SV_LEN_UTF8_NOMG;
7138 if (PL_utf8cache && SvUTF8(sv)) {
7140 MAGIC *mg = SvMAGICAL(sv) ? mg_find(sv, PERL_MAGIC_utf8) : NULL;
7142 if (mg && (mg->mg_len != -1 || mg->mg_ptr)) {
7143 if (mg->mg_len != -1)
7146 /* We can use the offset cache for a headstart.
7147 The longer value is stored in the first pair. */
7148 STRLEN *cache = (STRLEN *) mg->mg_ptr;
7150 ulen = cache[0] + Perl_utf8_length(aTHX_ s + cache[1],
7154 if (PL_utf8cache < 0) {
7155 const STRLEN real = Perl_utf8_length(aTHX_ s, s + len);
7156 assert_uft8_cache_coherent("sv_len_utf8", ulen, real, sv);
7160 ulen = Perl_utf8_length(aTHX_ s, s + len);
7161 utf8_mg_len_cache_update(sv, &mg, ulen);
7165 return SvUTF8(sv) ? Perl_utf8_length(aTHX_ s, s + len) : len;
7168 /* Walk forwards to find the byte corresponding to the passed in UTF-8
7171 S_sv_pos_u2b_forwards(const U8 *const start, const U8 *const send,
7172 STRLEN *const uoffset_p, bool *const at_end)
7174 const U8 *s = start;
7175 STRLEN uoffset = *uoffset_p;
7177 PERL_ARGS_ASSERT_SV_POS_U2B_FORWARDS;
7179 while (s < send && uoffset) {
7186 else if (s > send) {
7188 /* This is the existing behaviour. Possibly it should be a croak, as
7189 it's actually a bounds error */
7192 *uoffset_p -= uoffset;
7196 /* Given the length of the string in both bytes and UTF-8 characters, decide
7197 whether to walk forwards or backwards to find the byte corresponding to
7198 the passed in UTF-8 offset. */
7200 S_sv_pos_u2b_midway(const U8 *const start, const U8 *send,
7201 STRLEN uoffset, const STRLEN uend)
7203 STRLEN backw = uend - uoffset;
7205 PERL_ARGS_ASSERT_SV_POS_U2B_MIDWAY;
7207 if (uoffset < 2 * backw) {
7208 /* The assumption is that going forwards is twice the speed of going
7209 forward (that's where the 2 * backw comes from).
7210 (The real figure of course depends on the UTF-8 data.) */
7211 const U8 *s = start;
7213 while (s < send && uoffset--)
7223 while (UTF8_IS_CONTINUATION(*send))
7226 return send - start;
7229 /* For the string representation of the given scalar, find the byte
7230 corresponding to the passed in UTF-8 offset. uoffset0 and boffset0
7231 give another position in the string, *before* the sought offset, which
7232 (which is always true, as 0, 0 is a valid pair of positions), which should
7233 help reduce the amount of linear searching.
7234 If *mgp is non-NULL, it should point to the UTF-8 cache magic, which
7235 will be used to reduce the amount of linear searching. The cache will be
7236 created if necessary, and the found value offered to it for update. */
7238 S_sv_pos_u2b_cached(pTHX_ SV *const sv, MAGIC **const mgp, const U8 *const start,
7239 const U8 *const send, STRLEN uoffset,
7240 STRLEN uoffset0, STRLEN boffset0)
7242 STRLEN boffset = 0; /* Actually always set, but let's keep gcc happy. */
7244 bool at_end = FALSE;
7246 PERL_ARGS_ASSERT_SV_POS_U2B_CACHED;
7248 assert (uoffset >= uoffset0);
7253 if (!SvREADONLY(sv) && !SvGMAGICAL(sv) && SvPOK(sv)
7255 && (*mgp || (SvTYPE(sv) >= SVt_PVMG &&
7256 (*mgp = mg_find(sv, PERL_MAGIC_utf8))))) {
7257 if ((*mgp)->mg_ptr) {
7258 STRLEN *cache = (STRLEN *) (*mgp)->mg_ptr;
7259 if (cache[0] == uoffset) {
7260 /* An exact match. */
7263 if (cache[2] == uoffset) {
7264 /* An exact match. */
7268 if (cache[0] < uoffset) {
7269 /* The cache already knows part of the way. */
7270 if (cache[0] > uoffset0) {
7271 /* The cache knows more than the passed in pair */
7272 uoffset0 = cache[0];
7273 boffset0 = cache[1];
7275 if ((*mgp)->mg_len != -1) {
7276 /* And we know the end too. */
7278 + sv_pos_u2b_midway(start + boffset0, send,
7280 (*mgp)->mg_len - uoffset0);
7282 uoffset -= uoffset0;
7284 + sv_pos_u2b_forwards(start + boffset0,
7285 send, &uoffset, &at_end);
7286 uoffset += uoffset0;
7289 else if (cache[2] < uoffset) {
7290 /* We're between the two cache entries. */
7291 if (cache[2] > uoffset0) {
7292 /* and the cache knows more than the passed in pair */
7293 uoffset0 = cache[2];
7294 boffset0 = cache[3];
7298 + sv_pos_u2b_midway(start + boffset0,
7301 cache[0] - uoffset0);
7304 + sv_pos_u2b_midway(start + boffset0,
7307 cache[2] - uoffset0);
7311 else if ((*mgp)->mg_len != -1) {
7312 /* If we can take advantage of a passed in offset, do so. */
7313 /* In fact, offset0 is either 0, or less than offset, so don't
7314 need to worry about the other possibility. */
7316 + sv_pos_u2b_midway(start + boffset0, send,
7318 (*mgp)->mg_len - uoffset0);
7323 if (!found || PL_utf8cache < 0) {
7324 STRLEN real_boffset;
7325 uoffset -= uoffset0;
7326 real_boffset = boffset0 + sv_pos_u2b_forwards(start + boffset0,
7327 send, &uoffset, &at_end);
7328 uoffset += uoffset0;
7330 if (found && PL_utf8cache < 0)
7331 assert_uft8_cache_coherent("sv_pos_u2b_cache", boffset,
7333 boffset = real_boffset;
7336 if (PL_utf8cache && !SvGMAGICAL(sv) && SvPOK(sv)) {
7338 utf8_mg_len_cache_update(sv, mgp, uoffset);
7340 utf8_mg_pos_cache_update(sv, mgp, boffset, uoffset, send - start);
7347 =for apidoc sv_pos_u2b_flags
7349 Converts the offset from a count of UTF-8 chars from
7350 the start of the string, to a count of the equivalent number of bytes; if
7351 lenp is non-zero, it does the same to lenp, but this time starting from
7352 the offset, rather than from the start
7353 of the string. Handles type coercion.
7354 I<flags> is passed to C<SvPV_flags>, and usually should be
7355 C<SV_GMAGIC|SV_CONST_RETURN> to handle magic.
7361 * sv_pos_u2b_flags() uses, like sv_pos_b2u(), the mg_ptr of the potential
7362 * PERL_MAGIC_utf8 of the sv to store the mapping between UTF-8 and
7363 * byte offsets. See also the comments of S_utf8_mg_pos_cache_update().
7368 Perl_sv_pos_u2b_flags(pTHX_ SV *const sv, STRLEN uoffset, STRLEN *const lenp,
7375 PERL_ARGS_ASSERT_SV_POS_U2B_FLAGS;
7377 start = (U8*)SvPV_flags(sv, len, flags);
7379 const U8 * const send = start + len;
7381 boffset = sv_pos_u2b_cached(sv, &mg, start, send, uoffset, 0, 0);
7384 && *lenp /* don't bother doing work for 0, as its bytes equivalent
7385 is 0, and *lenp is already set to that. */) {
7386 /* Convert the relative offset to absolute. */
7387 const STRLEN uoffset2 = uoffset + *lenp;
7388 const STRLEN boffset2
7389 = sv_pos_u2b_cached(sv, &mg, start, send, uoffset2,
7390 uoffset, boffset) - boffset;
7404 =for apidoc sv_pos_u2b
7406 Converts the value pointed to by offsetp from a count of UTF-8 chars from
7407 the start of the string, to a count of the equivalent number of bytes; if
7408 lenp is non-zero, it does the same to lenp, but this time starting from
7409 the offset, rather than from the start of the string. Handles magic and
7412 Use C<sv_pos_u2b_flags> in preference, which correctly handles strings longer
7419 * sv_pos_u2b() uses, like sv_pos_b2u(), the mg_ptr of the potential
7420 * PERL_MAGIC_utf8 of the sv to store the mapping between UTF-8 and
7421 * byte offsets. See also the comments of S_utf8_mg_pos_cache_update().
7425 /* This function is subject to size and sign problems */
7428 Perl_sv_pos_u2b(pTHX_ SV *const sv, I32 *const offsetp, I32 *const lenp)
7430 PERL_ARGS_ASSERT_SV_POS_U2B;
7433 STRLEN ulen = (STRLEN)*lenp;
7434 *offsetp = (I32)sv_pos_u2b_flags(sv, (STRLEN)*offsetp, &ulen,
7435 SV_GMAGIC|SV_CONST_RETURN);
7438 *offsetp = (I32)sv_pos_u2b_flags(sv, (STRLEN)*offsetp, NULL,
7439 SV_GMAGIC|SV_CONST_RETURN);
7444 S_utf8_mg_len_cache_update(pTHX_ SV *const sv, MAGIC **const mgp,
7447 PERL_ARGS_ASSERT_UTF8_MG_LEN_CACHE_UPDATE;
7448 if (SvREADONLY(sv) || SvGMAGICAL(sv) || !SvPOK(sv))
7451 if (!*mgp && (SvTYPE(sv) < SVt_PVMG ||
7452 !(*mgp = mg_find(sv, PERL_MAGIC_utf8)))) {
7453 *mgp = sv_magicext(sv, 0, PERL_MAGIC_utf8, &PL_vtbl_utf8, 0, 0);
7457 (*mgp)->mg_len = ulen;
7460 /* Create and update the UTF8 magic offset cache, with the proffered utf8/
7461 byte length pairing. The (byte) length of the total SV is passed in too,
7462 as blen, because for some (more esoteric) SVs, the call to SvPV_const()
7463 may not have updated SvCUR, so we can't rely on reading it directly.
7465 The proffered utf8/byte length pairing isn't used if the cache already has
7466 two pairs, and swapping either for the proffered pair would increase the
7467 RMS of the intervals between known byte offsets.
7469 The cache itself consists of 4 STRLEN values
7470 0: larger UTF-8 offset
7471 1: corresponding byte offset
7472 2: smaller UTF-8 offset
7473 3: corresponding byte offset
7475 Unused cache pairs have the value 0, 0.
7476 Keeping the cache "backwards" means that the invariant of
7477 cache[0] >= cache[2] is maintained even with empty slots, which means that
7478 the code that uses it doesn't need to worry if only 1 entry has actually
7479 been set to non-zero. It also makes the "position beyond the end of the
7480 cache" logic much simpler, as the first slot is always the one to start
7484 S_utf8_mg_pos_cache_update(pTHX_ SV *const sv, MAGIC **const mgp, const STRLEN byte,
7485 const STRLEN utf8, const STRLEN blen)
7489 PERL_ARGS_ASSERT_UTF8_MG_POS_CACHE_UPDATE;
7494 if (!*mgp && (SvTYPE(sv) < SVt_PVMG ||
7495 !(*mgp = mg_find(sv, PERL_MAGIC_utf8)))) {
7496 *mgp = sv_magicext(sv, 0, PERL_MAGIC_utf8, (MGVTBL*)&PL_vtbl_utf8, 0,
7498 (*mgp)->mg_len = -1;
7502 if (!(cache = (STRLEN *)(*mgp)->mg_ptr)) {
7503 Newxz(cache, PERL_MAGIC_UTF8_CACHESIZE * 2, STRLEN);
7504 (*mgp)->mg_ptr = (char *) cache;
7508 if (PL_utf8cache < 0 && SvPOKp(sv)) {
7509 /* SvPOKp() because, if sv is a reference, then SvPVX() is actually
7510 a pointer. Note that we no longer cache utf8 offsets on refer-
7511 ences, but this check is still a good idea, for robustness. */
7512 const U8 *start = (const U8 *) SvPVX_const(sv);
7513 const STRLEN realutf8 = utf8_length(start, start + byte);
7515 assert_uft8_cache_coherent("utf8_mg_pos_cache_update", utf8, realutf8,
7519 /* Cache is held with the later position first, to simplify the code
7520 that deals with unbounded ends. */
7522 ASSERT_UTF8_CACHE(cache);
7523 if (cache[1] == 0) {
7524 /* Cache is totally empty */
7527 } else if (cache[3] == 0) {
7528 if (byte > cache[1]) {
7529 /* New one is larger, so goes first. */
7530 cache[2] = cache[0];
7531 cache[3] = cache[1];
7539 /* float casts necessary? XXX */
7540 #define THREEWAY_SQUARE(a,b,c,d) \
7541 ((float)((d) - (c))) * ((float)((d) - (c))) \
7542 + ((float)((c) - (b))) * ((float)((c) - (b))) \
7543 + ((float)((b) - (a))) * ((float)((b) - (a)))
7545 /* Cache has 2 slots in use, and we know three potential pairs.
7546 Keep the two that give the lowest RMS distance. Do the
7547 calculation in bytes simply because we always know the byte
7548 length. squareroot has the same ordering as the positive value,
7549 so don't bother with the actual square root. */
7550 if (byte > cache[1]) {
7551 /* New position is after the existing pair of pairs. */
7552 const float keep_earlier
7553 = THREEWAY_SQUARE(0, cache[3], byte, blen);
7554 const float keep_later
7555 = THREEWAY_SQUARE(0, cache[1], byte, blen);
7557 if (keep_later < keep_earlier) {
7558 cache[2] = cache[0];
7559 cache[3] = cache[1];
7565 const float keep_later = THREEWAY_SQUARE(0, byte, cache[1], blen);
7566 float b, c, keep_earlier;
7567 if (byte > cache[3]) {
7568 /* New position is between the existing pair of pairs. */
7569 b = (float)cache[3];
7572 /* New position is before the existing pair of pairs. */
7574 c = (float)cache[3];
7576 keep_earlier = THREEWAY_SQUARE(0, b, c, blen);
7577 if (byte > cache[3]) {
7578 if (keep_later < keep_earlier) {
7588 if (! (keep_later < keep_earlier)) {
7589 cache[0] = cache[2];
7590 cache[1] = cache[3];
7597 ASSERT_UTF8_CACHE(cache);
7600 /* We already know all of the way, now we may be able to walk back. The same
7601 assumption is made as in S_sv_pos_u2b_midway(), namely that walking
7602 backward is half the speed of walking forward. */
7604 S_sv_pos_b2u_midway(pTHX_ const U8 *const s, const U8 *const target,
7605 const U8 *end, STRLEN endu)
7607 const STRLEN forw = target - s;
7608 STRLEN backw = end - target;
7610 PERL_ARGS_ASSERT_SV_POS_B2U_MIDWAY;
7612 if (forw < 2 * backw) {
7613 return utf8_length(s, target);
7616 while (end > target) {
7618 while (UTF8_IS_CONTINUATION(*end)) {
7627 =for apidoc sv_pos_b2u_flags
7629 Converts the offset from a count of bytes from the start of the string, to
7630 a count of the equivalent number of UTF-8 chars. Handles type coercion.
7631 I<flags> is passed to C<SvPV_flags>, and usually should be
7632 C<SV_GMAGIC|SV_CONST_RETURN> to handle magic.
7638 * sv_pos_b2u_flags() uses, like sv_pos_u2b_flags(), the mg_ptr of the
7639 * potential PERL_MAGIC_utf8 of the sv to store the mapping between UTF-8
7644 Perl_sv_pos_b2u_flags(pTHX_ SV *const sv, STRLEN const offset, U32 flags)
7647 STRLEN len = 0; /* Actually always set, but let's keep gcc happy. */
7653 PERL_ARGS_ASSERT_SV_POS_B2U_FLAGS;
7655 s = (const U8*)SvPV_flags(sv, blen, flags);
7658 Perl_croak(aTHX_ "panic: sv_pos_b2u: bad byte offset, blen=%"UVuf
7659 ", byte=%"UVuf, (UV)blen, (UV)offset);
7665 && SvTYPE(sv) >= SVt_PVMG
7666 && (mg = mg_find(sv, PERL_MAGIC_utf8)))
7669 STRLEN * const cache = (STRLEN *) mg->mg_ptr;
7670 if (cache[1] == offset) {
7671 /* An exact match. */
7674 if (cache[3] == offset) {
7675 /* An exact match. */
7679 if (cache[1] < offset) {
7680 /* We already know part of the way. */
7681 if (mg->mg_len != -1) {
7682 /* Actually, we know the end too. */
7684 + S_sv_pos_b2u_midway(aTHX_ s + cache[1], send,
7685 s + blen, mg->mg_len - cache[0]);
7687 len = cache[0] + utf8_length(s + cache[1], send);
7690 else if (cache[3] < offset) {
7691 /* We're between the two cached pairs, so we do the calculation
7692 offset by the byte/utf-8 positions for the earlier pair,
7693 then add the utf-8 characters from the string start to
7695 len = S_sv_pos_b2u_midway(aTHX_ s + cache[3], send,
7696 s + cache[1], cache[0] - cache[2])
7700 else { /* cache[3] > offset */
7701 len = S_sv_pos_b2u_midway(aTHX_ s, send, s + cache[3],
7705 ASSERT_UTF8_CACHE(cache);
7707 } else if (mg->mg_len != -1) {
7708 len = S_sv_pos_b2u_midway(aTHX_ s, send, s + blen, mg->mg_len);
7712 if (!found || PL_utf8cache < 0) {
7713 const STRLEN real_len = utf8_length(s, send);
7715 if (found && PL_utf8cache < 0)
7716 assert_uft8_cache_coherent("sv_pos_b2u", len, real_len, sv);
7722 utf8_mg_len_cache_update(sv, &mg, len);
7724 utf8_mg_pos_cache_update(sv, &mg, offset, len, blen);
7731 =for apidoc sv_pos_b2u
7733 Converts the value pointed to by offsetp from a count of bytes from the
7734 start of the string, to a count of the equivalent number of UTF-8 chars.
7735 Handles magic and type coercion.
7737 Use C<sv_pos_b2u_flags> in preference, which correctly handles strings
7744 * sv_pos_b2u() uses, like sv_pos_u2b(), the mg_ptr of the potential
7745 * PERL_MAGIC_utf8 of the sv to store the mapping between UTF-8 and
7750 Perl_sv_pos_b2u(pTHX_ SV *const sv, I32 *const offsetp)
7752 PERL_ARGS_ASSERT_SV_POS_B2U;
7757 *offsetp = (I32)sv_pos_b2u_flags(sv, (STRLEN)*offsetp,
7758 SV_GMAGIC|SV_CONST_RETURN);
7762 S_assert_uft8_cache_coherent(pTHX_ const char *const func, STRLEN from_cache,
7763 STRLEN real, SV *const sv)
7765 PERL_ARGS_ASSERT_ASSERT_UFT8_CACHE_COHERENT;
7767 /* As this is debugging only code, save space by keeping this test here,
7768 rather than inlining it in all the callers. */
7769 if (from_cache == real)
7772 /* Need to turn the assertions off otherwise we may recurse infinitely
7773 while printing error messages. */
7774 SAVEI8(PL_utf8cache);
7776 Perl_croak(aTHX_ "panic: %s cache %"UVuf" real %"UVuf" for %"SVf,
7777 func, (UV) from_cache, (UV) real, SVfARG(sv));
7783 Returns a boolean indicating whether the strings in the two SVs are
7784 identical. Is UTF-8 and 'use bytes' aware, handles get magic, and will
7785 coerce its args to strings if necessary.
7787 =for apidoc sv_eq_flags
7789 Returns a boolean indicating whether the strings in the two SVs are
7790 identical. Is UTF-8 and 'use bytes' aware and coerces its args to strings
7791 if necessary. If the flags include SV_GMAGIC, it handles get-magic, too.
7797 Perl_sv_eq_flags(pTHX_ SV *sv1, SV *sv2, const U32 flags)
7804 SV* svrecode = NULL;
7811 /* if pv1 and pv2 are the same, second SvPV_const call may
7812 * invalidate pv1 (if we are handling magic), so we may need to
7814 if (sv1 == sv2 && flags & SV_GMAGIC
7815 && (SvTHINKFIRST(sv1) || SvGMAGICAL(sv1))) {
7816 pv1 = SvPV_const(sv1, cur1);
7817 sv1 = newSVpvn_flags(pv1, cur1, SVs_TEMP | SvUTF8(sv2));
7819 pv1 = SvPV_flags_const(sv1, cur1, flags);
7827 pv2 = SvPV_flags_const(sv2, cur2, flags);
7829 if (cur1 && cur2 && SvUTF8(sv1) != SvUTF8(sv2) && !IN_BYTES) {
7830 /* Differing utf8ness.
7831 * Do not UTF8size the comparands as a side-effect. */
7834 svrecode = newSVpvn(pv2, cur2);
7835 sv_recode_to_utf8(svrecode, _get_encoding());
7836 pv2 = SvPV_const(svrecode, cur2);
7839 svrecode = newSVpvn(pv1, cur1);
7840 sv_recode_to_utf8(svrecode, _get_encoding());
7841 pv1 = SvPV_const(svrecode, cur1);
7843 /* Now both are in UTF-8. */
7845 SvREFCNT_dec_NN(svrecode);
7851 /* sv1 is the UTF-8 one */
7852 return bytes_cmp_utf8((const U8*)pv2, cur2,
7853 (const U8*)pv1, cur1) == 0;
7856 /* sv2 is the UTF-8 one */
7857 return bytes_cmp_utf8((const U8*)pv1, cur1,
7858 (const U8*)pv2, cur2) == 0;
7864 eq = (pv1 == pv2) || memEQ(pv1, pv2, cur1);
7866 SvREFCNT_dec(svrecode);
7874 Compares the strings in two SVs. Returns -1, 0, or 1 indicating whether the
7875 string in C<sv1> is less than, equal to, or greater than the string in
7876 C<sv2>. Is UTF-8 and 'use bytes' aware, handles get magic, and will
7877 coerce its args to strings if necessary. See also C<sv_cmp_locale>.
7879 =for apidoc sv_cmp_flags
7881 Compares the strings in two SVs. Returns -1, 0, or 1 indicating whether the
7882 string in C<sv1> is less than, equal to, or greater than the string in
7883 C<sv2>. Is UTF-8 and 'use bytes' aware and will coerce its args to strings
7884 if necessary. If the flags include SV_GMAGIC, it handles get magic. See
7885 also C<sv_cmp_locale_flags>.
7891 Perl_sv_cmp(pTHX_ SV *const sv1, SV *const sv2)
7893 return sv_cmp_flags(sv1, sv2, SV_GMAGIC);
7897 Perl_sv_cmp_flags(pTHX_ SV *const sv1, SV *const sv2,
7901 const char *pv1, *pv2;
7903 SV *svrecode = NULL;
7910 pv1 = SvPV_flags_const(sv1, cur1, flags);
7917 pv2 = SvPV_flags_const(sv2, cur2, flags);
7919 if (cur1 && cur2 && SvUTF8(sv1) != SvUTF8(sv2) && !IN_BYTES) {
7920 /* Differing utf8ness.
7921 * Do not UTF8size the comparands as a side-effect. */
7924 svrecode = newSVpvn(pv2, cur2);
7925 sv_recode_to_utf8(svrecode, _get_encoding());
7926 pv2 = SvPV_const(svrecode, cur2);
7929 const int retval = -bytes_cmp_utf8((const U8*)pv2, cur2,
7930 (const U8*)pv1, cur1);
7931 return retval ? retval < 0 ? -1 : +1 : 0;
7936 svrecode = newSVpvn(pv1, cur1);
7937 sv_recode_to_utf8(svrecode, _get_encoding());
7938 pv1 = SvPV_const(svrecode, cur1);
7941 const int retval = bytes_cmp_utf8((const U8*)pv1, cur1,
7942 (const U8*)pv2, cur2);
7943 return retval ? retval < 0 ? -1 : +1 : 0;
7949 cmp = cur2 ? -1 : 0;
7953 const I32 retval = memcmp((const void*)pv1, (const void*)pv2, cur1 < cur2 ? cur1 : cur2);
7956 cmp = retval < 0 ? -1 : 1;
7957 } else if (cur1 == cur2) {
7960 cmp = cur1 < cur2 ? -1 : 1;
7964 SvREFCNT_dec(svrecode);
7970 =for apidoc sv_cmp_locale
7972 Compares the strings in two SVs in a locale-aware manner. Is UTF-8 and
7973 'use bytes' aware, handles get magic, and will coerce its args to strings
7974 if necessary. See also C<sv_cmp>.
7976 =for apidoc sv_cmp_locale_flags
7978 Compares the strings in two SVs in a locale-aware manner. Is UTF-8 and
7979 'use bytes' aware and will coerce its args to strings if necessary. If the
7980 flags contain SV_GMAGIC, it handles get magic. See also C<sv_cmp_flags>.
7986 Perl_sv_cmp_locale(pTHX_ SV *const sv1, SV *const sv2)
7988 return sv_cmp_locale_flags(sv1, sv2, SV_GMAGIC);
7992 Perl_sv_cmp_locale_flags(pTHX_ SV *const sv1, SV *const sv2,
7995 #ifdef USE_LOCALE_COLLATE
8001 if (PL_collation_standard)
8005 pv1 = sv1 ? sv_collxfrm_flags(sv1, &len1, flags) : (char *) NULL;
8007 pv2 = sv2 ? sv_collxfrm_flags(sv2, &len2, flags) : (char *) NULL;
8009 if (!pv1 || !len1) {
8020 retval = memcmp((void*)pv1, (void*)pv2, len1 < len2 ? len1 : len2);
8023 return retval < 0 ? -1 : 1;
8026 * When the result of collation is equality, that doesn't mean
8027 * that there are no differences -- some locales exclude some
8028 * characters from consideration. So to avoid false equalities,
8029 * we use the raw string as a tiebreaker.
8036 PERL_UNUSED_ARG(flags);
8037 #endif /* USE_LOCALE_COLLATE */
8039 return sv_cmp(sv1, sv2);
8043 #ifdef USE_LOCALE_COLLATE
8046 =for apidoc sv_collxfrm
8048 This calls C<sv_collxfrm_flags> with the SV_GMAGIC flag. See
8049 C<sv_collxfrm_flags>.
8051 =for apidoc sv_collxfrm_flags
8053 Add Collate Transform magic to an SV if it doesn't already have it. If the
8054 flags contain SV_GMAGIC, it handles get-magic.
8056 Any scalar variable may carry PERL_MAGIC_collxfrm magic that contains the
8057 scalar data of the variable, but transformed to such a format that a normal
8058 memory comparison can be used to compare the data according to the locale
8065 Perl_sv_collxfrm_flags(pTHX_ SV *const sv, STRLEN *const nxp, const I32 flags)
8069 PERL_ARGS_ASSERT_SV_COLLXFRM_FLAGS;
8071 mg = SvMAGICAL(sv) ? mg_find(sv, PERL_MAGIC_collxfrm) : (MAGIC *) NULL;
8072 if (!mg || !mg->mg_ptr || *(U32*)mg->mg_ptr != PL_collation_ix) {
8078 Safefree(mg->mg_ptr);
8079 s = SvPV_flags_const(sv, len, flags);
8080 if ((xf = mem_collxfrm(s, len, &xlen))) {
8082 #ifdef PERL_OLD_COPY_ON_WRITE
8084 sv_force_normal_flags(sv, 0);
8086 mg = sv_magicext(sv, 0, PERL_MAGIC_collxfrm, &PL_vtbl_collxfrm,
8100 if (mg && mg->mg_ptr) {
8102 return mg->mg_ptr + sizeof(PL_collation_ix);
8110 #endif /* USE_LOCALE_COLLATE */
8113 S_sv_gets_append_to_utf8(pTHX_ SV *const sv, PerlIO *const fp, I32 append)
8115 SV * const tsv = newSV(0);
8118 sv_gets(tsv, fp, 0);
8119 sv_utf8_upgrade_nomg(tsv);
8120 SvCUR_set(sv,append);
8123 return (SvCUR(sv) - append) ? SvPVX(sv) : NULL;
8127 S_sv_gets_read_record(pTHX_ SV *const sv, PerlIO *const fp, I32 append)
8130 const STRLEN recsize = SvUV(SvRV(PL_rs)); /* RsRECORD() guarantees > 0. */
8131 /* Grab the size of the record we're getting */
8132 char *buffer = SvGROW(sv, (STRLEN)(recsize + append + 1)) + append;
8139 /* With a true, record-oriented file on VMS, we need to use read directly
8140 * to ensure that we respect RMS record boundaries. The user is responsible
8141 * for providing a PL_rs value that corresponds to the FAB$W_MRS (maximum
8142 * record size) field. N.B. This is likely to produce invalid results on
8143 * varying-width character data when a record ends mid-character.
8145 fd = PerlIO_fileno(fp);
8147 && PerlLIO_fstat(fd, &st) == 0
8148 && (st.st_fab_rfm == FAB$C_VAR
8149 || st.st_fab_rfm == FAB$C_VFC
8150 || st.st_fab_rfm == FAB$C_FIX)) {
8152 bytesread = PerlLIO_read(fd, buffer, recsize);
8154 else /* in-memory file from PerlIO::Scalar
8155 * or not a record-oriented file
8159 bytesread = PerlIO_read(fp, buffer, recsize);
8161 /* At this point, the logic in sv_get() means that sv will
8162 be treated as utf-8 if the handle is utf8.
8164 if (PerlIO_isutf8(fp) && bytesread > 0) {
8165 char *bend = buffer + bytesread;
8166 char *bufp = buffer;
8167 size_t charcount = 0;
8168 bool charstart = TRUE;
8171 while (charcount < recsize) {
8172 /* count accumulated characters */
8173 while (bufp < bend) {
8175 skip = UTF8SKIP(bufp);
8177 if (bufp + skip > bend) {
8178 /* partial at the end */
8189 if (charcount < recsize) {
8191 STRLEN bufp_offset = bufp - buffer;
8192 SSize_t morebytesread;
8194 /* originally I read enough to fill any incomplete
8195 character and the first byte of the next
8196 character if needed, but if there's many
8197 multi-byte encoded characters we're going to be
8198 making a read call for every character beyond
8199 the original read size.
8201 So instead, read the rest of the character if
8202 any, and enough bytes to match at least the
8203 start bytes for each character we're going to
8207 readsize = recsize - charcount;
8209 readsize = skip - (bend - bufp) + recsize - charcount - 1;
8210 buffer = SvGROW(sv, append + bytesread + readsize + 1) + append;
8211 bend = buffer + bytesread;
8212 morebytesread = PerlIO_read(fp, bend, readsize);
8213 if (morebytesread <= 0) {
8214 /* we're done, if we still have incomplete
8215 characters the check code in sv_gets() will
8218 I'd originally considered doing
8219 PerlIO_ungetc() on all but the lead
8220 character of the incomplete character, but
8221 read() doesn't do that, so I don't.
8226 /* prepare to scan some more */
8227 bytesread += morebytesread;
8228 bend = buffer + bytesread;
8229 bufp = buffer + bufp_offset;
8237 SvCUR_set(sv, bytesread + append);
8238 buffer[bytesread] = '\0';
8239 return (SvCUR(sv) - append) ? SvPVX(sv) : NULL;
8245 Get a line from the filehandle and store it into the SV, optionally
8246 appending to the currently-stored string. If C<append> is not 0, the
8247 line is appended to the SV instead of overwriting it. C<append> should
8248 be set to the byte offset that the appended string should start at
8249 in the SV (typically, C<SvCUR(sv)> is a suitable choice).
8255 Perl_sv_gets(pTHX_ SV *const sv, PerlIO *const fp, I32 append)
8265 PERL_ARGS_ASSERT_SV_GETS;
8267 if (SvTHINKFIRST(sv))
8268 sv_force_normal_flags(sv, append ? 0 : SV_COW_DROP_PV);
8269 /* XXX. If you make this PVIV, then copy on write can copy scalars read
8271 However, perlbench says it's slower, because the existing swipe code
8272 is faster than copy on write.
8273 Swings and roundabouts. */
8274 SvUPGRADE(sv, SVt_PV);
8277 /* line is going to be appended to the existing buffer in the sv */
8278 if (PerlIO_isutf8(fp)) {
8280 sv_utf8_upgrade_nomg(sv);
8281 sv_pos_u2b(sv,&append,0);
8283 } else if (SvUTF8(sv)) {
8284 return S_sv_gets_append_to_utf8(aTHX_ sv, fp, append);
8290 /* not appending - "clear" the string by setting SvCUR to 0,
8291 * the pv is still avaiable. */
8294 if (PerlIO_isutf8(fp))
8297 if (IN_PERL_COMPILETIME) {
8298 /* we always read code in line mode */
8302 else if (RsSNARF(PL_rs)) {
8303 /* If it is a regular disk file use size from stat() as estimate
8304 of amount we are going to read -- may result in mallocing
8305 more memory than we really need if the layers below reduce
8306 the size we read (e.g. CRLF or a gzip layer).
8309 if (!PerlLIO_fstat(PerlIO_fileno(fp), &st) && S_ISREG(st.st_mode)) {
8310 const Off_t offset = PerlIO_tell(fp);
8311 if (offset != (Off_t) -1 && st.st_size + append > offset) {
8312 #ifdef PERL_NEW_COPY_ON_WRITE
8313 /* Add an extra byte for the sake of copy-on-write's
8314 * buffer reference count. */
8315 (void) SvGROW(sv, (STRLEN)((st.st_size - offset) + append + 2));
8317 (void) SvGROW(sv, (STRLEN)((st.st_size - offset) + append + 1));
8324 else if (RsRECORD(PL_rs)) {
8325 return S_sv_gets_read_record(aTHX_ sv, fp, append);
8327 else if (RsPARA(PL_rs)) {
8333 /* Get $/ i.e. PL_rs into same encoding as stream wants */
8334 if (PerlIO_isutf8(fp)) {
8335 rsptr = SvPVutf8(PL_rs, rslen);
8338 if (SvUTF8(PL_rs)) {
8339 if (!sv_utf8_downgrade(PL_rs, TRUE)) {
8340 Perl_croak(aTHX_ "Wide character in $/");
8343 /* extract the raw pointer to the record separator */
8344 rsptr = SvPV_const(PL_rs, rslen);
8348 /* rslast is the last character in the record separator
8349 * note we don't use rslast except when rslen is true, so the
8350 * null assign is a placeholder. */
8351 rslast = rslen ? rsptr[rslen - 1] : '\0';
8353 if (rspara) { /* have to do this both before and after */
8354 do { /* to make sure file boundaries work right */
8357 i = PerlIO_getc(fp);
8361 PerlIO_ungetc(fp,i);
8367 /* See if we know enough about I/O mechanism to cheat it ! */
8369 /* This used to be #ifdef test - it is made run-time test for ease
8370 of abstracting out stdio interface. One call should be cheap
8371 enough here - and may even be a macro allowing compile
8375 if (PerlIO_fast_gets(fp)) {
8377 * We can do buffer based IO operations on this filehandle.
8379 * This means we can bypass a lot of subcalls and process
8380 * the buffer directly, it also means we know the upper bound
8381 * on the amount of data we might read of the current buffer
8382 * into our sv. Knowing this allows us to preallocate the pv
8383 * to be able to hold that maximum, which allows us to simplify
8384 * a lot of logic. */
8387 * We're going to steal some values from the stdio struct
8388 * and put EVERYTHING in the innermost loop into registers.
8390 STDCHAR *ptr; /* pointer into fp's read-ahead buffer */
8391 STRLEN bpx; /* length of the data in the target sv
8392 used to fix pointers after a SvGROW */
8393 I32 shortbuffered; /* If the pv buffer is shorter than the amount
8394 of data left in the read-ahead buffer.
8395 If 0 then the pv buffer can hold the full
8396 amount left, otherwise this is the amount it
8399 #if defined(__VMS) && defined(PERLIO_IS_STDIO)
8400 /* An ungetc()d char is handled separately from the regular
8401 * buffer, so we getc() it back out and stuff it in the buffer.
8403 i = PerlIO_getc(fp);
8404 if (i == EOF) return 0;
8405 *(--((*fp)->_ptr)) = (unsigned char) i;
8409 /* Here is some breathtakingly efficient cheating */
8411 /* When you read the following logic resist the urge to think
8412 * of record separators that are 1 byte long. They are an
8413 * uninteresting special (simple) case.
8415 * Instead think of record separators which are at least 2 bytes
8416 * long, and keep in mind that we need to deal with such
8417 * separators when they cross a read-ahead buffer boundary.
8419 * Also consider that we need to gracefully deal with separators
8420 * that may be longer than a single read ahead buffer.
8422 * Lastly do not forget we want to copy the delimiter as well. We
8423 * are copying all data in the file _up_to_and_including_ the separator
8426 * Now that you have all that in mind here is what is happening below:
8428 * 1. When we first enter the loop we do some memory book keeping to see
8429 * how much free space there is in the target SV. (This sub assumes that
8430 * it is operating on the same SV most of the time via $_ and that it is
8431 * going to be able to reuse the same pv buffer each call.) If there is
8432 * "enough" room then we set "shortbuffered" to how much space there is
8433 * and start reading forward.
8435 * 2. When we scan forward we copy from the read-ahead buffer to the target
8436 * SV's pv buffer. While we go we watch for the end of the read-ahead buffer,
8437 * and the end of the of pv, as well as for the "rslast", which is the last
8438 * char of the separator.
8440 * 3. When scanning forward if we see rslast then we jump backwards in *pv*
8441 * (which has a "complete" record up to the point we saw rslast) and check
8442 * it to see if it matches the separator. If it does we are done. If it doesn't
8443 * we continue on with the scan/copy.
8445 * 4. If we run out of read-ahead buffer (cnt goes to 0) then we have to get
8446 * the IO system to read the next buffer. We do this by doing a getc(), which
8447 * returns a single char read (or EOF), and prefills the buffer, and also
8448 * allows us to find out how full the buffer is. We use this information to
8449 * SvGROW() the sv to the size remaining in the buffer, after which we copy
8450 * the returned single char into the target sv, and then go back into scan
8453 * 5. If we run out of write-buffer then we SvGROW() it by the size of the
8454 * remaining space in the read-buffer.
8456 * Note that this code despite its twisty-turny nature is pretty darn slick.
8457 * It manages single byte separators, multi-byte cross boundary separators,
8458 * and cross-read-buffer separators cleanly and efficiently at the cost
8459 * of potentially greatly overallocating the target SV.
8465 /* get the number of bytes remaining in the read-ahead buffer
8466 * on first call on a given fp this will return 0.*/
8467 cnt = PerlIO_get_cnt(fp);
8469 /* make sure we have the room */
8470 if ((I32)(SvLEN(sv) - append) <= cnt + 1) {
8471 /* Not room for all of it
8472 if we are looking for a separator and room for some
8474 if (rslen && cnt > 80 && (I32)SvLEN(sv) > append) {
8475 /* just process what we have room for */
8476 shortbuffered = cnt - SvLEN(sv) + append + 1;
8477 cnt -= shortbuffered;
8480 /* ensure that the target sv has enough room to hold
8481 * the rest of the read-ahead buffer */
8483 /* remember that cnt can be negative */
8484 SvGROW(sv, (STRLEN)(append + (cnt <= 0 ? 2 : (cnt + 1))));
8488 /* we have enough room to hold the full buffer, lets scream */
8492 /* extract the pointer to sv's string buffer, offset by append as necessary */
8493 bp = (STDCHAR*)SvPVX_const(sv) + append; /* move these two too to registers */
8494 /* extract the point to the read-ahead buffer */
8495 ptr = (STDCHAR*)PerlIO_get_ptr(fp);
8497 /* some trace debug output */
8498 DEBUG_P(PerlIO_printf(Perl_debug_log,
8499 "Screamer: entering, ptr=%"UVuf", cnt=%ld\n",PTR2UV(ptr),(long)cnt));
8500 DEBUG_P(PerlIO_printf(Perl_debug_log,
8501 "Screamer: entering: PerlIO * thinks ptr=%"UVuf", cnt=%"IVdf", base=%"
8503 PTR2UV(PerlIO_get_ptr(fp)), (IV)PerlIO_get_cnt(fp),
8504 PTR2UV(PerlIO_has_base(fp) ? PerlIO_get_base(fp) : 0)));
8508 /* if there is stuff left in the read-ahead buffer */
8510 /* if there is a separator */
8512 /* loop until we hit the end of the read-ahead buffer */
8513 while (cnt > 0) { /* this | eat */
8514 /* scan forward copying and searching for rslast as we go */
8516 if ((*bp++ = *ptr++) == rslast) /* really | dust */
8517 goto thats_all_folks; /* screams | sed :-) */
8521 /* no separator, slurp the full buffer */
8522 Copy(ptr, bp, cnt, char); /* this | eat */
8523 bp += cnt; /* screams | dust */
8524 ptr += cnt; /* louder | sed :-) */
8526 assert (!shortbuffered);
8527 goto cannot_be_shortbuffered;
8531 if (shortbuffered) { /* oh well, must extend */
8532 /* we didnt have enough room to fit the line into the target buffer
8533 * so we must extend the target buffer and keep going */
8534 cnt = shortbuffered;
8536 bpx = bp - (STDCHAR*)SvPVX_const(sv); /* box up before relocation */
8538 /* extned the target sv's buffer so it can hold the full read-ahead buffer */
8539 SvGROW(sv, SvLEN(sv) + append + cnt + 2);
8540 bp = (STDCHAR*)SvPVX_const(sv) + bpx; /* unbox after relocation */
8544 cannot_be_shortbuffered:
8545 /* we need to refill the read-ahead buffer if possible */
8547 DEBUG_P(PerlIO_printf(Perl_debug_log,
8548 "Screamer: going to getc, ptr=%"UVuf", cnt=%"IVdf"\n",
8549 PTR2UV(ptr),(IV)cnt));
8550 PerlIO_set_ptrcnt(fp, (STDCHAR*)ptr, cnt); /* deregisterize cnt and ptr */
8552 DEBUG_Pv(PerlIO_printf(Perl_debug_log,
8553 "Screamer: pre: FILE * thinks ptr=%"UVuf", cnt=%"IVdf", base=%"UVuf"\n",
8554 PTR2UV(PerlIO_get_ptr(fp)), (IV)PerlIO_get_cnt(fp),
8555 PTR2UV(PerlIO_has_base (fp) ? PerlIO_get_base(fp) : 0)));
8558 call PerlIO_getc() to let it prefill the lookahead buffer
8560 This used to call 'filbuf' in stdio form, but as that behaves like
8561 getc when cnt <= 0 we use PerlIO_getc here to avoid introducing
8562 another abstraction.
8564 Note we have to deal with the char in 'i' if we are not at EOF
8566 i = PerlIO_getc(fp); /* get more characters */
8568 DEBUG_Pv(PerlIO_printf(Perl_debug_log,
8569 "Screamer: post: FILE * thinks ptr=%"UVuf", cnt=%"IVdf", base=%"UVuf"\n",
8570 PTR2UV(PerlIO_get_ptr(fp)), (IV)PerlIO_get_cnt(fp),
8571 PTR2UV(PerlIO_has_base (fp) ? PerlIO_get_base(fp) : 0)));
8573 /* find out how much is left in the read-ahead buffer, and rextract its pointer */
8574 cnt = PerlIO_get_cnt(fp);
8575 ptr = (STDCHAR*)PerlIO_get_ptr(fp); /* reregisterize cnt and ptr */
8576 DEBUG_P(PerlIO_printf(Perl_debug_log,
8577 "Screamer: after getc, ptr=%"UVuf", cnt=%"IVdf"\n",
8578 PTR2UV(ptr),(IV)cnt));
8580 if (i == EOF) /* all done for ever? */
8581 goto thats_really_all_folks;
8583 /* make sure we have enough space in the target sv */
8584 bpx = bp - (STDCHAR*)SvPVX_const(sv); /* box up before relocation */
8586 SvGROW(sv, bpx + cnt + 2);
8587 bp = (STDCHAR*)SvPVX_const(sv) + bpx; /* unbox after relocation */
8589 /* copy of the char we got from getc() */
8590 *bp++ = (STDCHAR)i; /* store character from PerlIO_getc */
8592 /* make sure we deal with the i being the last character of a separator */
8593 if (rslen && (STDCHAR)i == rslast) /* all done for now? */
8594 goto thats_all_folks;
8598 /* check if we have actually found the separator - only really applies
8600 if ((rslen > 1 && (STRLEN)(bp - (STDCHAR*)SvPVX_const(sv)) < rslen) ||
8601 memNE((char*)bp - rslen, rsptr, rslen))
8602 goto screamer; /* go back to the fray */
8603 thats_really_all_folks:
8605 cnt += shortbuffered;
8606 DEBUG_P(PerlIO_printf(Perl_debug_log,
8607 "Screamer: quitting, ptr=%"UVuf", cnt=%"IVdf"\n",PTR2UV(ptr),(IV)cnt));
8608 PerlIO_set_ptrcnt(fp, (STDCHAR*)ptr, cnt); /* put these back or we're in trouble */
8609 DEBUG_P(PerlIO_printf(Perl_debug_log,
8610 "Screamer: end: FILE * thinks ptr=%"UVuf", cnt=%"IVdf", base=%"UVuf
8612 PTR2UV(PerlIO_get_ptr(fp)), (IV)PerlIO_get_cnt(fp),
8613 PTR2UV(PerlIO_has_base (fp) ? PerlIO_get_base(fp) : 0)));
8615 SvCUR_set(sv, bp - (STDCHAR*)SvPVX_const(sv)); /* set length */
8616 DEBUG_P(PerlIO_printf(Perl_debug_log,
8617 "Screamer: done, len=%ld, string=|%.*s|\n",
8618 (long)SvCUR(sv),(int)SvCUR(sv),SvPVX_const(sv)));
8622 /*The big, slow, and stupid way. */
8623 #ifdef USE_HEAP_INSTEAD_OF_STACK /* Even slower way. */
8624 STDCHAR *buf = NULL;
8625 Newx(buf, 8192, STDCHAR);
8633 const STDCHAR * const bpe = buf + sizeof(buf);
8635 while ((i = PerlIO_getc(fp)) != EOF && (*bp++ = (STDCHAR)i) != rslast && bp < bpe)
8636 ; /* keep reading */
8640 cnt = PerlIO_read(fp,(char*)buf, sizeof(buf));
8641 /* Accommodate broken VAXC compiler, which applies U8 cast to
8642 * both args of ?: operator, causing EOF to change into 255
8645 i = (U8)buf[cnt - 1];
8651 cnt = 0; /* we do need to re-set the sv even when cnt <= 0 */
8653 sv_catpvn_nomg(sv, (char *) buf, cnt);
8655 sv_setpvn(sv, (char *) buf, cnt); /* "nomg" is implied */
8657 if (i != EOF && /* joy */
8659 SvCUR(sv) < rslen ||
8660 memNE(SvPVX_const(sv) + SvCUR(sv) - rslen, rsptr, rslen)))
8664 * If we're reading from a TTY and we get a short read,
8665 * indicating that the user hit his EOF character, we need
8666 * to notice it now, because if we try to read from the TTY
8667 * again, the EOF condition will disappear.
8669 * The comparison of cnt to sizeof(buf) is an optimization
8670 * that prevents unnecessary calls to feof().
8674 if (!(cnt < (I32)sizeof(buf) && PerlIO_eof(fp)))
8678 #ifdef USE_HEAP_INSTEAD_OF_STACK
8683 if (rspara) { /* have to do this both before and after */
8684 while (i != EOF) { /* to make sure file boundaries work right */
8685 i = PerlIO_getc(fp);
8687 PerlIO_ungetc(fp,i);
8693 return (SvCUR(sv) - append) ? SvPVX(sv) : NULL;
8699 Auto-increment of the value in the SV, doing string to numeric conversion
8700 if necessary. Handles 'get' magic and operator overloading.
8706 Perl_sv_inc(pTHX_ SV *const sv)
8715 =for apidoc sv_inc_nomg
8717 Auto-increment of the value in the SV, doing string to numeric conversion
8718 if necessary. Handles operator overloading. Skips handling 'get' magic.
8724 Perl_sv_inc_nomg(pTHX_ SV *const sv)
8731 if (SvTHINKFIRST(sv)) {
8732 if (SvREADONLY(sv)) {
8733 Perl_croak_no_modify();
8737 if (SvAMAGIC(sv) && AMG_CALLunary(sv, inc_amg))
8739 i = PTR2IV(SvRV(sv));
8743 else sv_force_normal_flags(sv, 0);
8745 flags = SvFLAGS(sv);
8746 if ((flags & (SVp_NOK|SVp_IOK)) == SVp_NOK) {
8747 /* It's (privately or publicly) a float, but not tested as an
8748 integer, so test it to see. */
8750 flags = SvFLAGS(sv);
8752 if ((flags & SVf_IOK) || ((flags & (SVp_IOK | SVp_NOK)) == SVp_IOK)) {
8753 /* It's publicly an integer, or privately an integer-not-float */
8754 #ifdef PERL_PRESERVE_IVUV
8758 if (SvUVX(sv) == UV_MAX)
8759 sv_setnv(sv, UV_MAX_P1);
8761 (void)SvIOK_only_UV(sv);
8762 SvUV_set(sv, SvUVX(sv) + 1);
8764 if (SvIVX(sv) == IV_MAX)
8765 sv_setuv(sv, (UV)IV_MAX + 1);
8767 (void)SvIOK_only(sv);
8768 SvIV_set(sv, SvIVX(sv) + 1);
8773 if (flags & SVp_NOK) {
8774 const NV was = SvNVX(sv);
8775 if (LIKELY(!Perl_isinfnan(was)) &&
8776 NV_OVERFLOWS_INTEGERS_AT &&
8777 was >= NV_OVERFLOWS_INTEGERS_AT) {
8778 /* diag_listed_as: Lost precision when %s %f by 1 */
8779 Perl_ck_warner(aTHX_ packWARN(WARN_IMPRECISION),
8780 "Lost precision when incrementing %" NVff " by 1",
8783 (void)SvNOK_only(sv);
8784 SvNV_set(sv, was + 1.0);
8788 if (!(flags & SVp_POK) || !*SvPVX_const(sv)) {
8789 if ((flags & SVTYPEMASK) < SVt_PVIV)
8790 sv_upgrade(sv, ((flags & SVTYPEMASK) > SVt_IV ? SVt_PVIV : SVt_IV));
8791 (void)SvIOK_only(sv);
8796 while (isALPHA(*d)) d++;
8797 while (isDIGIT(*d)) d++;
8798 if (d < SvEND(sv)) {
8799 const int numtype = grok_number_flags(SvPVX_const(sv), SvCUR(sv), NULL, PERL_SCAN_TRAILING);
8800 #ifdef PERL_PRESERVE_IVUV
8801 /* Got to punt this as an integer if needs be, but we don't issue
8802 warnings. Probably ought to make the sv_iv_please() that does
8803 the conversion if possible, and silently. */
8804 if (numtype && !(numtype & IS_NUMBER_INFINITY)) {
8805 /* Need to try really hard to see if it's an integer.
8806 9.22337203685478e+18 is an integer.
8807 but "9.22337203685478e+18" + 0 is UV=9223372036854779904
8808 so $a="9.22337203685478e+18"; $a+0; $a++
8809 needs to be the same as $a="9.22337203685478e+18"; $a++
8816 /* sv_2iv *should* have made this an NV */
8817 if (flags & SVp_NOK) {
8818 (void)SvNOK_only(sv);
8819 SvNV_set(sv, SvNVX(sv) + 1.0);
8822 /* I don't think we can get here. Maybe I should assert this
8823 And if we do get here I suspect that sv_setnv will croak. NWC
8825 DEBUG_c(PerlIO_printf(Perl_debug_log,"sv_inc punt failed to convert '%s' to IOK or NOKp, UV=0x%"UVxf" NV=%"NVgf"\n",
8826 SvPVX_const(sv), SvIVX(sv), SvNVX(sv)));
8828 #endif /* PERL_PRESERVE_IVUV */
8829 if (!numtype && ckWARN(WARN_NUMERIC))
8830 not_incrementable(sv);
8831 sv_setnv(sv,Atof(SvPVX_const(sv)) + 1.0);
8835 while (d >= SvPVX_const(sv)) {
8843 /* MKS: The original code here died if letters weren't consecutive.
8844 * at least it didn't have to worry about non-C locales. The
8845 * new code assumes that ('z'-'a')==('Z'-'A'), letters are
8846 * arranged in order (although not consecutively) and that only
8847 * [A-Za-z] are accepted by isALPHA in the C locale.
8849 if (isALPHA_FOLD_NE(*d, 'z')) {
8850 do { ++*d; } while (!isALPHA(*d));
8853 *(d--) -= 'z' - 'a';
8858 *(d--) -= 'z' - 'a' + 1;
8862 /* oh,oh, the number grew */
8863 SvGROW(sv, SvCUR(sv) + 2);
8864 SvCUR_set(sv, SvCUR(sv) + 1);
8865 for (d = SvPVX(sv) + SvCUR(sv); d > SvPVX_const(sv); d--)
8876 Auto-decrement of the value in the SV, doing string to numeric conversion
8877 if necessary. Handles 'get' magic and operator overloading.
8883 Perl_sv_dec(pTHX_ SV *const sv)
8892 =for apidoc sv_dec_nomg
8894 Auto-decrement of the value in the SV, doing string to numeric conversion
8895 if necessary. Handles operator overloading. Skips handling 'get' magic.
8901 Perl_sv_dec_nomg(pTHX_ SV *const sv)
8907 if (SvTHINKFIRST(sv)) {
8908 if (SvREADONLY(sv)) {
8909 Perl_croak_no_modify();
8913 if (SvAMAGIC(sv) && AMG_CALLunary(sv, dec_amg))
8915 i = PTR2IV(SvRV(sv));
8919 else sv_force_normal_flags(sv, 0);
8921 /* Unlike sv_inc we don't have to worry about string-never-numbers
8922 and keeping them magic. But we mustn't warn on punting */
8923 flags = SvFLAGS(sv);
8924 if ((flags & SVf_IOK) || ((flags & (SVp_IOK | SVp_NOK)) == SVp_IOK)) {
8925 /* It's publicly an integer, or privately an integer-not-float */
8926 #ifdef PERL_PRESERVE_IVUV
8930 if (SvUVX(sv) == 0) {
8931 (void)SvIOK_only(sv);
8935 (void)SvIOK_only_UV(sv);
8936 SvUV_set(sv, SvUVX(sv) - 1);
8939 if (SvIVX(sv) == IV_MIN) {
8940 sv_setnv(sv, (NV)IV_MIN);
8944 (void)SvIOK_only(sv);
8945 SvIV_set(sv, SvIVX(sv) - 1);
8950 if (flags & SVp_NOK) {
8953 const NV was = SvNVX(sv);
8954 if (LIKELY(!Perl_isinfnan(was)) &&
8955 NV_OVERFLOWS_INTEGERS_AT &&
8956 was <= -NV_OVERFLOWS_INTEGERS_AT) {
8957 /* diag_listed_as: Lost precision when %s %f by 1 */
8958 Perl_ck_warner(aTHX_ packWARN(WARN_IMPRECISION),
8959 "Lost precision when decrementing %" NVff " by 1",
8962 (void)SvNOK_only(sv);
8963 SvNV_set(sv, was - 1.0);
8967 if (!(flags & SVp_POK)) {
8968 if ((flags & SVTYPEMASK) < SVt_PVIV)
8969 sv_upgrade(sv, ((flags & SVTYPEMASK) > SVt_IV) ? SVt_PVIV : SVt_IV);
8971 (void)SvIOK_only(sv);
8974 #ifdef PERL_PRESERVE_IVUV
8976 const int numtype = grok_number(SvPVX_const(sv), SvCUR(sv), NULL);
8977 if (numtype && !(numtype & IS_NUMBER_INFINITY)) {
8978 /* Need to try really hard to see if it's an integer.
8979 9.22337203685478e+18 is an integer.
8980 but "9.22337203685478e+18" + 0 is UV=9223372036854779904
8981 so $a="9.22337203685478e+18"; $a+0; $a--
8982 needs to be the same as $a="9.22337203685478e+18"; $a--
8989 /* sv_2iv *should* have made this an NV */
8990 if (flags & SVp_NOK) {
8991 (void)SvNOK_only(sv);
8992 SvNV_set(sv, SvNVX(sv) - 1.0);
8995 /* I don't think we can get here. Maybe I should assert this
8996 And if we do get here I suspect that sv_setnv will croak. NWC
8998 DEBUG_c(PerlIO_printf(Perl_debug_log,"sv_dec punt failed to convert '%s' to IOK or NOKp, UV=0x%"UVxf" NV=%"NVgf"\n",
8999 SvPVX_const(sv), SvIVX(sv), SvNVX(sv)));
9002 #endif /* PERL_PRESERVE_IVUV */
9003 sv_setnv(sv,Atof(SvPVX_const(sv)) - 1.0); /* punt */
9006 /* this define is used to eliminate a chunk of duplicated but shared logic
9007 * it has the suffix __SV_C to signal that it isnt API, and isnt meant to be
9008 * used anywhere but here - yves
9010 #define PUSH_EXTEND_MORTAL__SV_C(AnSv) \
9012 SSize_t ix = ++PL_tmps_ix; \
9013 if (UNLIKELY(ix >= PL_tmps_max)) \
9014 ix = tmps_grow_p(ix); \
9015 PL_tmps_stack[ix] = (AnSv); \
9019 =for apidoc sv_mortalcopy
9021 Creates a new SV which is a copy of the original SV (using C<sv_setsv>).
9022 The new SV is marked as mortal. It will be destroyed "soon", either by an
9023 explicit call to FREETMPS, or by an implicit call at places such as
9024 statement boundaries. See also C<sv_newmortal> and C<sv_2mortal>.
9029 /* Make a string that will exist for the duration of the expression
9030 * evaluation. Actually, it may have to last longer than that, but
9031 * hopefully we won't free it until it has been assigned to a
9032 * permanent location. */
9035 Perl_sv_mortalcopy_flags(pTHX_ SV *const oldstr, U32 flags)
9039 if (flags & SV_GMAGIC)
9040 SvGETMAGIC(oldstr); /* before new_SV, in case it dies */
9042 sv_setsv_flags(sv,oldstr,flags & ~SV_GMAGIC);
9043 PUSH_EXTEND_MORTAL__SV_C(sv);
9049 =for apidoc sv_newmortal
9051 Creates a new null SV which is mortal. The reference count of the SV is
9052 set to 1. It will be destroyed "soon", either by an explicit call to
9053 FREETMPS, or by an implicit call at places such as statement boundaries.
9054 See also C<sv_mortalcopy> and C<sv_2mortal>.
9060 Perl_sv_newmortal(pTHX)
9065 SvFLAGS(sv) = SVs_TEMP;
9066 PUSH_EXTEND_MORTAL__SV_C(sv);
9072 =for apidoc newSVpvn_flags
9074 Creates a new SV and copies a string (which may contain C<NUL> (C<\0>)
9075 characters) into it. The reference count for the
9076 SV is set to 1. Note that if C<len> is zero, Perl will create a zero length
9077 string. You are responsible for ensuring that the source string is at least
9078 C<len> bytes long. If the C<s> argument is NULL the new SV will be undefined.
9079 Currently the only flag bits accepted are C<SVf_UTF8> and C<SVs_TEMP>.
9080 If C<SVs_TEMP> is set, then C<sv_2mortal()> is called on the result before
9081 returning. If C<SVf_UTF8> is set, C<s>
9082 is considered to be in UTF-8 and the
9083 C<SVf_UTF8> flag will be set on the new SV.
9084 C<newSVpvn_utf8()> is a convenience wrapper for this function, defined as
9086 #define newSVpvn_utf8(s, len, u) \
9087 newSVpvn_flags((s), (len), (u) ? SVf_UTF8 : 0)
9093 Perl_newSVpvn_flags(pTHX_ const char *const s, const STRLEN len, const U32 flags)
9097 /* All the flags we don't support must be zero.
9098 And we're new code so I'm going to assert this from the start. */
9099 assert(!(flags & ~(SVf_UTF8|SVs_TEMP)));
9101 sv_setpvn(sv,s,len);
9103 /* This code used to do a sv_2mortal(), however we now unroll the call to
9104 * sv_2mortal() and do what it does ourselves here. Since we have asserted
9105 * that flags can only have the SVf_UTF8 and/or SVs_TEMP flags set above we
9106 * can use it to enable the sv flags directly (bypassing SvTEMP_on), which
9107 * in turn means we dont need to mask out the SVf_UTF8 flag below, which
9108 * means that we eliminate quite a few steps than it looks - Yves
9109 * (explaining patch by gfx) */
9111 SvFLAGS(sv) |= flags;
9113 if(flags & SVs_TEMP){
9114 PUSH_EXTEND_MORTAL__SV_C(sv);
9121 =for apidoc sv_2mortal
9123 Marks an existing SV as mortal. The SV will be destroyed "soon", either
9124 by an explicit call to FREETMPS, or by an implicit call at places such as
9125 statement boundaries. SvTEMP() is turned on which means that the SV's
9126 string buffer can be "stolen" if this SV is copied. See also C<sv_newmortal>
9127 and C<sv_mortalcopy>.
9133 Perl_sv_2mortal(pTHX_ SV *const sv)
9140 PUSH_EXTEND_MORTAL__SV_C(sv);
9148 Creates a new SV and copies a string (which may contain C<NUL> (C<\0>)
9149 characters) into it. The reference count for the
9150 SV is set to 1. If C<len> is zero, Perl will compute the length using
9151 strlen(), (which means if you use this option, that C<s> can't have embedded
9152 C<NUL> characters and has to have a terminating C<NUL> byte).
9154 For efficiency, consider using C<newSVpvn> instead.
9160 Perl_newSVpv(pTHX_ const char *const s, const STRLEN len)
9165 sv_setpvn(sv, s, len || s == NULL ? len : strlen(s));
9170 =for apidoc newSVpvn
9172 Creates a new SV and copies a string into it, which may contain C<NUL> characters
9173 (C<\0>) and other binary data. The reference count for the SV is set to 1.
9174 Note that if C<len> is zero, Perl will create a zero length (Perl) string. You
9175 are responsible for ensuring that the source buffer is at least
9176 C<len> bytes long. If the C<buffer> argument is NULL the new SV will be
9183 Perl_newSVpvn(pTHX_ const char *const buffer, const STRLEN len)
9187 sv_setpvn(sv,buffer,len);
9192 =for apidoc newSVhek
9194 Creates a new SV from the hash key structure. It will generate scalars that
9195 point to the shared string table where possible. Returns a new (undefined)
9196 SV if the hek is NULL.
9202 Perl_newSVhek(pTHX_ const HEK *const hek)
9211 if (HEK_LEN(hek) == HEf_SVKEY) {
9212 return newSVsv(*(SV**)HEK_KEY(hek));
9214 const int flags = HEK_FLAGS(hek);
9215 if (flags & HVhek_WASUTF8) {
9217 Andreas would like keys he put in as utf8 to come back as utf8
9219 STRLEN utf8_len = HEK_LEN(hek);
9220 SV * const sv = newSV_type(SVt_PV);
9221 char *as_utf8 = (char *)bytes_to_utf8 ((U8*)HEK_KEY(hek), &utf8_len);
9222 /* bytes_to_utf8() allocates a new string, which we can repurpose: */
9223 sv_usepvn_flags(sv, as_utf8, utf8_len, SV_HAS_TRAILING_NUL);
9226 } else if (flags & HVhek_UNSHARED) {
9227 /* A hash that isn't using shared hash keys has to have
9228 the flag in every key so that we know not to try to call
9229 share_hek_hek on it. */
9231 SV * const sv = newSVpvn (HEK_KEY(hek), HEK_LEN(hek));
9236 /* This will be overwhelminly the most common case. */
9238 /* Inline most of newSVpvn_share(), because share_hek_hek() is far
9239 more efficient than sharepvn(). */
9243 sv_upgrade(sv, SVt_PV);
9244 SvPV_set(sv, (char *)HEK_KEY(share_hek_hek(hek)));
9245 SvCUR_set(sv, HEK_LEN(hek));
9257 =for apidoc newSVpvn_share
9259 Creates a new SV with its SvPVX_const pointing to a shared string in the string
9260 table. If the string does not already exist in the table, it is
9261 created first. Turns on the SvIsCOW flag (or READONLY
9262 and FAKE in 5.16 and earlier). If the C<hash> parameter
9263 is non-zero, that value is used; otherwise the hash is computed.
9264 The string's hash can later be retrieved from the SV
9265 with the C<SvSHARED_HASH()> macro. The idea here is
9266 that as the string table is used for shared hash keys these strings will have
9267 SvPVX_const == HeKEY and hash lookup will avoid string compare.
9273 Perl_newSVpvn_share(pTHX_ const char *src, I32 len, U32 hash)
9277 bool is_utf8 = FALSE;
9278 const char *const orig_src = src;
9281 STRLEN tmplen = -len;
9283 /* See the note in hv.c:hv_fetch() --jhi */
9284 src = (char*)bytes_from_utf8((const U8*)src, &tmplen, &is_utf8);
9288 PERL_HASH(hash, src, len);
9290 /* The logic for this is inlined in S_mro_get_linear_isa_dfs(), so if it
9291 changes here, update it there too. */
9292 sv_upgrade(sv, SVt_PV);
9293 SvPV_set(sv, sharepvn(src, is_utf8?-len:len, hash));
9300 if (src != orig_src)
9306 =for apidoc newSVpv_share
9308 Like C<newSVpvn_share>, but takes a C<NUL>-terminated string instead of a
9315 Perl_newSVpv_share(pTHX_ const char *src, U32 hash)
9317 return newSVpvn_share(src, strlen(src), hash);
9320 #if defined(PERL_IMPLICIT_CONTEXT)
9322 /* pTHX_ magic can't cope with varargs, so this is a no-context
9323 * version of the main function, (which may itself be aliased to us).
9324 * Don't access this version directly.
9328 Perl_newSVpvf_nocontext(const char *const pat, ...)
9334 PERL_ARGS_ASSERT_NEWSVPVF_NOCONTEXT;
9336 va_start(args, pat);
9337 sv = vnewSVpvf(pat, &args);
9344 =for apidoc newSVpvf
9346 Creates a new SV and initializes it with the string formatted like
9353 Perl_newSVpvf(pTHX_ const char *const pat, ...)
9358 PERL_ARGS_ASSERT_NEWSVPVF;
9360 va_start(args, pat);
9361 sv = vnewSVpvf(pat, &args);
9366 /* backend for newSVpvf() and newSVpvf_nocontext() */
9369 Perl_vnewSVpvf(pTHX_ const char *const pat, va_list *const args)
9373 PERL_ARGS_ASSERT_VNEWSVPVF;
9376 sv_vsetpvfn(sv, pat, strlen(pat), args, NULL, 0, NULL);
9383 Creates a new SV and copies a floating point value into it.
9384 The reference count for the SV is set to 1.
9390 Perl_newSVnv(pTHX_ const NV n)
9402 Creates a new SV and copies an integer into it. The reference count for the
9409 Perl_newSViv(pTHX_ const IV i)
9415 /* Inlining ONLY the small relevant subset of sv_setiv here
9416 * for performance. Makes a significant difference. */
9418 /* We're starting from SVt_FIRST, so provided that's
9419 * actual 0, we don't have to unset any SV type flags
9420 * to promote to SVt_IV. */
9421 STATIC_ASSERT_STMT(SVt_FIRST == 0);
9423 SET_SVANY_FOR_BODYLESS_IV(sv);
9424 SvFLAGS(sv) |= SVt_IV;
9436 Creates a new SV and copies an unsigned integer into it.
9437 The reference count for the SV is set to 1.
9443 Perl_newSVuv(pTHX_ const UV u)
9447 /* Inlining ONLY the small relevant subset of sv_setuv here
9448 * for performance. Makes a significant difference. */
9450 /* Using ivs is more efficient than using uvs - see sv_setuv */
9451 if (u <= (UV)IV_MAX) {
9452 return newSViv((IV)u);
9457 /* We're starting from SVt_FIRST, so provided that's
9458 * actual 0, we don't have to unset any SV type flags
9459 * to promote to SVt_IV. */
9460 STATIC_ASSERT_STMT(SVt_FIRST == 0);
9462 SET_SVANY_FOR_BODYLESS_IV(sv);
9463 SvFLAGS(sv) |= SVt_IV;
9465 (void)SvIsUV_on(sv);
9474 =for apidoc newSV_type
9476 Creates a new SV, of the type specified. The reference count for the new SV
9483 Perl_newSV_type(pTHX_ const svtype type)
9488 ASSUME(SvTYPE(sv) == SVt_FIRST);
9489 if(type != SVt_FIRST)
9490 sv_upgrade(sv, type);
9495 =for apidoc newRV_noinc
9497 Creates an RV wrapper for an SV. The reference count for the original
9498 SV is B<not> incremented.
9504 Perl_newRV_noinc(pTHX_ SV *const tmpRef)
9508 PERL_ARGS_ASSERT_NEWRV_NOINC;
9512 /* We're starting from SVt_FIRST, so provided that's
9513 * actual 0, we don't have to unset any SV type flags
9514 * to promote to SVt_IV. */
9515 STATIC_ASSERT_STMT(SVt_FIRST == 0);
9517 SET_SVANY_FOR_BODYLESS_IV(sv);
9518 SvFLAGS(sv) |= SVt_IV;
9523 SvRV_set(sv, tmpRef);
9528 /* newRV_inc is the official function name to use now.
9529 * newRV_inc is in fact #defined to newRV in sv.h
9533 Perl_newRV(pTHX_ SV *const sv)
9535 PERL_ARGS_ASSERT_NEWRV;
9537 return newRV_noinc(SvREFCNT_inc_simple_NN(sv));
9543 Creates a new SV which is an exact duplicate of the original SV.
9550 Perl_newSVsv(pTHX_ SV *const old)
9556 if (SvTYPE(old) == (svtype)SVTYPEMASK) {
9557 Perl_ck_warner_d(aTHX_ packWARN(WARN_INTERNAL), "semi-panic: attempt to dup freed string");
9560 /* Do this here, otherwise we leak the new SV if this croaks. */
9563 /* SV_NOSTEAL prevents TEMP buffers being, well, stolen, and saves games
9564 with SvTEMP_off and SvTEMP_on round a call to sv_setsv. */
9565 sv_setsv_flags(sv, old, SV_NOSTEAL);
9570 =for apidoc sv_reset
9572 Underlying implementation for the C<reset> Perl function.
9573 Note that the perl-level function is vaguely deprecated.
9579 Perl_sv_reset(pTHX_ const char *s, HV *const stash)
9581 PERL_ARGS_ASSERT_SV_RESET;
9583 sv_resetpvn(*s ? s : NULL, strlen(s), stash);
9587 Perl_sv_resetpvn(pTHX_ const char *s, STRLEN len, HV * const stash)
9589 char todo[PERL_UCHAR_MAX+1];
9592 if (!stash || SvTYPE(stash) != SVt_PVHV)
9595 if (!s) { /* reset ?? searches */
9596 MAGIC * const mg = mg_find((const SV *)stash, PERL_MAGIC_symtab);
9598 const U32 count = mg->mg_len / sizeof(PMOP**);
9599 PMOP **pmp = (PMOP**) mg->mg_ptr;
9600 PMOP *const *const end = pmp + count;
9604 SvREADONLY_off(PL_regex_pad[(*pmp)->op_pmoffset]);
9606 (*pmp)->op_pmflags &= ~PMf_USED;
9614 /* reset variables */
9616 if (!HvARRAY(stash))
9619 Zero(todo, 256, char);
9623 I32 i = (unsigned char)*s;
9627 max = (unsigned char)*s++;
9628 for ( ; i <= max; i++) {
9631 for (i = 0; i <= (I32) HvMAX(stash); i++) {
9633 for (entry = HvARRAY(stash)[i];
9635 entry = HeNEXT(entry))
9640 if (!todo[(U8)*HeKEY(entry)])
9642 gv = MUTABLE_GV(HeVAL(entry));
9644 if (sv && !SvREADONLY(sv)) {
9645 SV_CHECK_THINKFIRST_COW_DROP(sv);
9646 if (!isGV(sv)) SvOK_off(sv);
9651 if (GvHV(gv) && !HvNAME_get(GvHV(gv))) {
9662 Using various gambits, try to get an IO from an SV: the IO slot if its a
9663 GV; or the recursive result if we're an RV; or the IO slot of the symbol
9664 named after the PV if we're a string.
9666 'Get' magic is ignored on the sv passed in, but will be called on
9667 C<SvRV(sv)> if sv is an RV.
9673 Perl_sv_2io(pTHX_ SV *const sv)
9678 PERL_ARGS_ASSERT_SV_2IO;
9680 switch (SvTYPE(sv)) {
9682 io = MUTABLE_IO(sv);
9686 if (isGV_with_GP(sv)) {
9687 gv = MUTABLE_GV(sv);
9690 Perl_croak(aTHX_ "Bad filehandle: %"HEKf,
9691 HEKfARG(GvNAME_HEK(gv)));
9697 Perl_croak(aTHX_ PL_no_usym, "filehandle");
9699 SvGETMAGIC(SvRV(sv));
9700 return sv_2io(SvRV(sv));
9702 gv = gv_fetchsv_nomg(sv, 0, SVt_PVIO);
9709 if (SvGMAGICAL(sv)) {
9710 newsv = sv_newmortal();
9711 sv_setsv_nomg(newsv, sv);
9713 Perl_croak(aTHX_ "Bad filehandle: %"SVf, SVfARG(newsv));
9723 Using various gambits, try to get a CV from an SV; in addition, try if
9724 possible to set C<*st> and C<*gvp> to the stash and GV associated with it.
9725 The flags in C<lref> are passed to gv_fetchsv.
9731 Perl_sv_2cv(pTHX_ SV *sv, HV **const st, GV **const gvp, const I32 lref)
9736 PERL_ARGS_ASSERT_SV_2CV;
9743 switch (SvTYPE(sv)) {
9747 return MUTABLE_CV(sv);
9757 sv = amagic_deref_call(sv, to_cv_amg);
9760 if (SvTYPE(sv) == SVt_PVCV) {
9761 cv = MUTABLE_CV(sv);
9766 else if(SvGETMAGIC(sv), isGV_with_GP(sv))
9767 gv = MUTABLE_GV(sv);
9769 Perl_croak(aTHX_ "Not a subroutine reference");
9771 else if (isGV_with_GP(sv)) {
9772 gv = MUTABLE_GV(sv);
9775 gv = gv_fetchsv_nomg(sv, lref, SVt_PVCV);
9782 /* Some flags to gv_fetchsv mean don't really create the GV */
9783 if (!isGV_with_GP(gv)) {
9788 if (lref & ~GV_ADDMG && !GvCVu(gv)) {
9789 /* XXX this is probably not what they think they're getting.
9790 * It has the same effect as "sub name;", i.e. just a forward
9801 Returns true if the SV has a true value by Perl's rules.
9802 Use the C<SvTRUE> macro instead, which may call C<sv_true()> or may
9803 instead use an in-line version.
9809 Perl_sv_true(pTHX_ SV *const sv)
9814 const XPV* const tXpv = (XPV*)SvANY(sv);
9816 (tXpv->xpv_cur > 1 ||
9817 (tXpv->xpv_cur && *sv->sv_u.svu_pv != '0')))
9824 return SvIVX(sv) != 0;
9827 return SvNVX(sv) != 0.0;
9829 return sv_2bool(sv);
9835 =for apidoc sv_pvn_force
9837 Get a sensible string out of the SV somehow.
9838 A private implementation of the C<SvPV_force> macro for compilers which
9839 can't cope with complex macro expressions. Always use the macro instead.
9841 =for apidoc sv_pvn_force_flags
9843 Get a sensible string out of the SV somehow.
9844 If C<flags> has C<SV_GMAGIC> bit set, will C<mg_get> on C<sv> if
9845 appropriate, else not. C<sv_pvn_force> and C<sv_pvn_force_nomg> are
9846 implemented in terms of this function.
9847 You normally want to use the various wrapper macros instead: see
9848 C<SvPV_force> and C<SvPV_force_nomg>
9854 Perl_sv_pvn_force_flags(pTHX_ SV *const sv, STRLEN *const lp, const I32 flags)
9856 PERL_ARGS_ASSERT_SV_PVN_FORCE_FLAGS;
9858 if (flags & SV_GMAGIC) SvGETMAGIC(sv);
9859 if (SvTHINKFIRST(sv) && (!SvROK(sv) || SvREADONLY(sv)))
9860 sv_force_normal_flags(sv, 0);
9870 if (SvTYPE(sv) > SVt_PVLV
9871 || isGV_with_GP(sv))
9872 /* diag_listed_as: Can't coerce %s to %s in %s */
9873 Perl_croak(aTHX_ "Can't coerce %s to string in %s", sv_reftype(sv,0),
9875 s = sv_2pv_flags(sv, &len, flags &~ SV_GMAGIC);
9882 if (SvTYPE(sv) < SVt_PV ||
9883 s != SvPVX_const(sv)) { /* Almost, but not quite, sv_setpvn() */
9886 SvUPGRADE(sv, SVt_PV); /* Never FALSE */
9887 SvGROW(sv, len + 1);
9888 Move(s,SvPVX(sv),len,char);
9890 SvPVX(sv)[len] = '\0';
9893 SvPOK_on(sv); /* validate pointer */
9895 DEBUG_c(PerlIO_printf(Perl_debug_log, "0x%"UVxf" 2pv(%s)\n",
9896 PTR2UV(sv),SvPVX_const(sv)));
9899 (void)SvPOK_only_UTF8(sv);
9900 return SvPVX_mutable(sv);
9904 =for apidoc sv_pvbyten_force
9906 The backend for the C<SvPVbytex_force> macro. Always use the macro
9913 Perl_sv_pvbyten_force(pTHX_ SV *const sv, STRLEN *const lp)
9915 PERL_ARGS_ASSERT_SV_PVBYTEN_FORCE;
9917 sv_pvn_force(sv,lp);
9918 sv_utf8_downgrade(sv,0);
9924 =for apidoc sv_pvutf8n_force
9926 The backend for the C<SvPVutf8x_force> macro. Always use the macro
9933 Perl_sv_pvutf8n_force(pTHX_ SV *const sv, STRLEN *const lp)
9935 PERL_ARGS_ASSERT_SV_PVUTF8N_FORCE;
9938 sv_utf8_upgrade_nomg(sv);
9944 =for apidoc sv_reftype
9946 Returns a string describing what the SV is a reference to.
9952 Perl_sv_reftype(pTHX_ const SV *const sv, const int ob)
9954 PERL_ARGS_ASSERT_SV_REFTYPE;
9955 if (ob && SvOBJECT(sv)) {
9956 return SvPV_nolen_const(sv_ref(NULL, sv, ob));
9959 /* WARNING - There is code, for instance in mg.c, that assumes that
9960 * the only reason that sv_reftype(sv,0) would return a string starting
9961 * with 'L' or 'S' is that it is a LVALUE or a SCALAR.
9962 * Yes this a dodgy way to do type checking, but it saves practically reimplementing
9963 * this routine inside other subs, and it saves time.
9964 * Do not change this assumption without searching for "dodgy type check" in
9967 switch (SvTYPE(sv)) {
9982 case SVt_PVLV: return (char *) (SvROK(sv) ? "REF"
9983 /* tied lvalues should appear to be
9984 * scalars for backwards compatibility */
9985 : (isALPHA_FOLD_EQ(LvTYPE(sv), 't'))
9986 ? "SCALAR" : "LVALUE");
9987 case SVt_PVAV: return "ARRAY";
9988 case SVt_PVHV: return "HASH";
9989 case SVt_PVCV: return "CODE";
9990 case SVt_PVGV: return (char *) (isGV_with_GP(sv)
9991 ? "GLOB" : "SCALAR");
9992 case SVt_PVFM: return "FORMAT";
9993 case SVt_PVIO: return "IO";
9994 case SVt_INVLIST: return "INVLIST";
9995 case SVt_REGEXP: return "REGEXP";
9996 default: return "UNKNOWN";
10004 Returns a SV describing what the SV passed in is a reference to.
10010 Perl_sv_ref(pTHX_ SV *dst, const SV *const sv, const int ob)
10012 PERL_ARGS_ASSERT_SV_REF;
10015 dst = sv_newmortal();
10017 if (ob && SvOBJECT(sv)) {
10018 HvNAME_get(SvSTASH(sv))
10019 ? sv_sethek(dst, HvNAME_HEK(SvSTASH(sv)))
10020 : sv_setpvn(dst, "__ANON__", 8);
10023 const char * reftype = sv_reftype(sv, 0);
10024 sv_setpv(dst, reftype);
10030 =for apidoc sv_isobject
10032 Returns a boolean indicating whether the SV is an RV pointing to a blessed
10033 object. If the SV is not an RV, or if the object is not blessed, then this
10040 Perl_sv_isobject(pTHX_ SV *sv)
10056 Returns a boolean indicating whether the SV is blessed into the specified
10057 class. This does not check for subtypes; use C<sv_derived_from> to verify
10058 an inheritance relationship.
10064 Perl_sv_isa(pTHX_ SV *sv, const char *const name)
10066 const char *hvname;
10068 PERL_ARGS_ASSERT_SV_ISA;
10078 hvname = HvNAME_get(SvSTASH(sv));
10082 return strEQ(hvname, name);
10086 =for apidoc newSVrv
10088 Creates a new SV for the existing RV, C<rv>, to point to. If C<rv> is not an
10089 RV then it will be upgraded to one. If C<classname> is non-null then the new
10090 SV will be blessed in the specified package. The new SV is returned and its
10091 reference count is 1. The reference count 1 is owned by C<rv>.
10097 Perl_newSVrv(pTHX_ SV *const rv, const char *const classname)
10101 PERL_ARGS_ASSERT_NEWSVRV;
10105 SV_CHECK_THINKFIRST_COW_DROP(rv);
10107 if (UNLIKELY( SvTYPE(rv) >= SVt_PVMG )) {
10108 const U32 refcnt = SvREFCNT(rv);
10112 SvREFCNT(rv) = refcnt;
10114 sv_upgrade(rv, SVt_IV);
10115 } else if (SvROK(rv)) {
10116 SvREFCNT_dec(SvRV(rv));
10118 prepare_SV_for_RV(rv);
10126 HV* const stash = gv_stashpv(classname, GV_ADD);
10127 (void)sv_bless(rv, stash);
10133 Perl_newSVavdefelem(pTHX_ AV *av, SSize_t ix, bool extendible)
10135 SV * const lv = newSV_type(SVt_PVLV);
10136 PERL_ARGS_ASSERT_NEWSVAVDEFELEM;
10138 sv_magic(lv, NULL, PERL_MAGIC_defelem, NULL, 0);
10139 LvTARG(lv) = SvREFCNT_inc_simple_NN(av);
10140 LvSTARGOFF(lv) = ix;
10141 LvTARGLEN(lv) = extendible ? 1 : (STRLEN)UV_MAX;
10146 =for apidoc sv_setref_pv
10148 Copies a pointer into a new SV, optionally blessing the SV. The C<rv>
10149 argument will be upgraded to an RV. That RV will be modified to point to
10150 the new SV. If the C<pv> argument is NULL then C<PL_sv_undef> will be placed
10151 into the SV. The C<classname> argument indicates the package for the
10152 blessing. Set C<classname> to C<NULL> to avoid the blessing. The new SV
10153 will have a reference count of 1, and the RV will be returned.
10155 Do not use with other Perl types such as HV, AV, SV, CV, because those
10156 objects will become corrupted by the pointer copy process.
10158 Note that C<sv_setref_pvn> copies the string while this copies the pointer.
10164 Perl_sv_setref_pv(pTHX_ SV *const rv, const char *const classname, void *const pv)
10166 PERL_ARGS_ASSERT_SV_SETREF_PV;
10169 sv_setsv(rv, &PL_sv_undef);
10173 sv_setiv(newSVrv(rv,classname), PTR2IV(pv));
10178 =for apidoc sv_setref_iv
10180 Copies an integer into a new SV, optionally blessing the SV. The C<rv>
10181 argument will be upgraded to an RV. That RV will be modified to point to
10182 the new SV. The C<classname> argument indicates the package for the
10183 blessing. Set C<classname> to C<NULL> to avoid the blessing. The new SV
10184 will have a reference count of 1, and the RV will be returned.
10190 Perl_sv_setref_iv(pTHX_ SV *const rv, const char *const classname, const IV iv)
10192 PERL_ARGS_ASSERT_SV_SETREF_IV;
10194 sv_setiv(newSVrv(rv,classname), iv);
10199 =for apidoc sv_setref_uv
10201 Copies an unsigned integer into a new SV, optionally blessing the SV. The C<rv>
10202 argument will be upgraded to an RV. That RV will be modified to point to
10203 the new SV. The C<classname> argument indicates the package for the
10204 blessing. Set C<classname> to C<NULL> to avoid the blessing. The new SV
10205 will have a reference count of 1, and the RV will be returned.
10211 Perl_sv_setref_uv(pTHX_ SV *const rv, const char *const classname, const UV uv)
10213 PERL_ARGS_ASSERT_SV_SETREF_UV;
10215 sv_setuv(newSVrv(rv,classname), uv);
10220 =for apidoc sv_setref_nv
10222 Copies a double into a new SV, optionally blessing the SV. The C<rv>
10223 argument will be upgraded to an RV. That RV will be modified to point to
10224 the new SV. The C<classname> argument indicates the package for the
10225 blessing. Set C<classname> to C<NULL> to avoid the blessing. The new SV
10226 will have a reference count of 1, and the RV will be returned.
10232 Perl_sv_setref_nv(pTHX_ SV *const rv, const char *const classname, const NV nv)
10234 PERL_ARGS_ASSERT_SV_SETREF_NV;
10236 sv_setnv(newSVrv(rv,classname), nv);
10241 =for apidoc sv_setref_pvn
10243 Copies a string into a new SV, optionally blessing the SV. The length of the
10244 string must be specified with C<n>. The C<rv> argument will be upgraded to
10245 an RV. That RV will be modified to point to the new SV. The C<classname>
10246 argument indicates the package for the blessing. Set C<classname> to
10247 C<NULL> to avoid the blessing. The new SV will have a reference count
10248 of 1, and the RV will be returned.
10250 Note that C<sv_setref_pv> copies the pointer while this copies the string.
10256 Perl_sv_setref_pvn(pTHX_ SV *const rv, const char *const classname,
10257 const char *const pv, const STRLEN n)
10259 PERL_ARGS_ASSERT_SV_SETREF_PVN;
10261 sv_setpvn(newSVrv(rv,classname), pv, n);
10266 =for apidoc sv_bless
10268 Blesses an SV into a specified package. The SV must be an RV. The package
10269 must be designated by its stash (see C<gv_stashpv()>). The reference count
10270 of the SV is unaffected.
10276 Perl_sv_bless(pTHX_ SV *const sv, HV *const stash)
10279 HV *oldstash = NULL;
10281 PERL_ARGS_ASSERT_SV_BLESS;
10285 Perl_croak(aTHX_ "Can't bless non-reference value");
10287 if (SvFLAGS(tmpRef) & (SVs_OBJECT|SVf_READONLY|SVf_PROTECT)) {
10288 if (SvREADONLY(tmpRef))
10289 Perl_croak_no_modify();
10290 if (SvOBJECT(tmpRef)) {
10291 oldstash = SvSTASH(tmpRef);
10294 SvOBJECT_on(tmpRef);
10295 SvUPGRADE(tmpRef, SVt_PVMG);
10296 SvSTASH_set(tmpRef, MUTABLE_HV(SvREFCNT_inc_simple(stash)));
10297 SvREFCNT_dec(oldstash);
10299 if(SvSMAGICAL(tmpRef))
10300 if(mg_find(tmpRef, PERL_MAGIC_ext) || mg_find(tmpRef, PERL_MAGIC_uvar))
10308 /* Downgrades a PVGV to a PVMG. If it's actually a PVLV, we leave the type
10309 * as it is after unglobbing it.
10312 PERL_STATIC_INLINE void
10313 S_sv_unglob(pTHX_ SV *const sv, U32 flags)
10317 SV * const temp = flags & SV_COW_DROP_PV ? NULL : sv_newmortal();
10319 PERL_ARGS_ASSERT_SV_UNGLOB;
10321 assert(SvTYPE(sv) == SVt_PVGV || SvTYPE(sv) == SVt_PVLV);
10323 if (!(flags & SV_COW_DROP_PV))
10324 gv_efullname3(temp, MUTABLE_GV(sv), "*");
10326 SvREFCNT_inc_simple_void_NN(sv_2mortal(sv));
10328 if(GvCVu((const GV *)sv) && (stash = GvSTASH(MUTABLE_GV(sv)))
10329 && HvNAME_get(stash))
10330 mro_method_changed_in(stash);
10331 gp_free(MUTABLE_GV(sv));
10334 sv_del_backref(MUTABLE_SV(GvSTASH(sv)), sv);
10335 GvSTASH(sv) = NULL;
10338 if (GvNAME_HEK(sv)) {
10339 unshare_hek(GvNAME_HEK(sv));
10341 isGV_with_GP_off(sv);
10343 if(SvTYPE(sv) == SVt_PVGV) {
10344 /* need to keep SvANY(sv) in the right arena */
10345 xpvmg = new_XPVMG();
10346 StructCopy(SvANY(sv), xpvmg, XPVMG);
10347 del_XPVGV(SvANY(sv));
10350 SvFLAGS(sv) &= ~SVTYPEMASK;
10351 SvFLAGS(sv) |= SVt_PVMG;
10354 /* Intentionally not calling any local SET magic, as this isn't so much a
10355 set operation as merely an internal storage change. */
10356 if (flags & SV_COW_DROP_PV) SvOK_off(sv);
10357 else sv_setsv_flags(sv, temp, 0);
10359 if ((const GV *)sv == PL_last_in_gv)
10360 PL_last_in_gv = NULL;
10361 else if ((const GV *)sv == PL_statgv)
10366 =for apidoc sv_unref_flags
10368 Unsets the RV status of the SV, and decrements the reference count of
10369 whatever was being referenced by the RV. This can almost be thought of
10370 as a reversal of C<newSVrv>. The C<cflags> argument can contain
10371 C<SV_IMMEDIATE_UNREF> to force the reference count to be decremented
10372 (otherwise the decrementing is conditional on the reference count being
10373 different from one or the reference being a readonly SV).
10380 Perl_sv_unref_flags(pTHX_ SV *const ref, const U32 flags)
10382 SV* const target = SvRV(ref);
10384 PERL_ARGS_ASSERT_SV_UNREF_FLAGS;
10386 if (SvWEAKREF(ref)) {
10387 sv_del_backref(target, ref);
10388 SvWEAKREF_off(ref);
10389 SvRV_set(ref, NULL);
10392 SvRV_set(ref, NULL);
10394 /* You can't have a || SvREADONLY(target) here, as $a = $$a, where $a was
10395 assigned to as BEGIN {$a = \"Foo"} will fail. */
10396 if (SvREFCNT(target) != 1 || (flags & SV_IMMEDIATE_UNREF))
10397 SvREFCNT_dec_NN(target);
10398 else /* XXX Hack, but hard to make $a=$a->[1] work otherwise */
10399 sv_2mortal(target); /* Schedule for freeing later */
10403 =for apidoc sv_untaint
10405 Untaint an SV. Use C<SvTAINTED_off> instead.
10411 Perl_sv_untaint(pTHX_ SV *const sv)
10413 PERL_ARGS_ASSERT_SV_UNTAINT;
10414 PERL_UNUSED_CONTEXT;
10416 if (SvTYPE(sv) >= SVt_PVMG && SvMAGIC(sv)) {
10417 MAGIC * const mg = mg_find(sv, PERL_MAGIC_taint);
10424 =for apidoc sv_tainted
10426 Test an SV for taintedness. Use C<SvTAINTED> instead.
10432 Perl_sv_tainted(pTHX_ SV *const sv)
10434 PERL_ARGS_ASSERT_SV_TAINTED;
10435 PERL_UNUSED_CONTEXT;
10437 if (SvTYPE(sv) >= SVt_PVMG && SvMAGIC(sv)) {
10438 const MAGIC * const mg = mg_find(sv, PERL_MAGIC_taint);
10439 if (mg && (mg->mg_len & 1) )
10446 =for apidoc sv_setpviv
10448 Copies an integer into the given SV, also updating its string value.
10449 Does not handle 'set' magic. See C<sv_setpviv_mg>.
10455 Perl_sv_setpviv(pTHX_ SV *const sv, const IV iv)
10457 char buf[TYPE_CHARS(UV)];
10459 char * const ptr = uiv_2buf(buf, iv, 0, 0, &ebuf);
10461 PERL_ARGS_ASSERT_SV_SETPVIV;
10463 sv_setpvn(sv, ptr, ebuf - ptr);
10467 =for apidoc sv_setpviv_mg
10469 Like C<sv_setpviv>, but also handles 'set' magic.
10475 Perl_sv_setpviv_mg(pTHX_ SV *const sv, const IV iv)
10477 PERL_ARGS_ASSERT_SV_SETPVIV_MG;
10479 sv_setpviv(sv, iv);
10483 #if defined(PERL_IMPLICIT_CONTEXT)
10485 /* pTHX_ magic can't cope with varargs, so this is a no-context
10486 * version of the main function, (which may itself be aliased to us).
10487 * Don't access this version directly.
10491 Perl_sv_setpvf_nocontext(SV *const sv, const char *const pat, ...)
10496 PERL_ARGS_ASSERT_SV_SETPVF_NOCONTEXT;
10498 va_start(args, pat);
10499 sv_vsetpvf(sv, pat, &args);
10503 /* pTHX_ magic can't cope with varargs, so this is a no-context
10504 * version of the main function, (which may itself be aliased to us).
10505 * Don't access this version directly.
10509 Perl_sv_setpvf_mg_nocontext(SV *const sv, const char *const pat, ...)
10514 PERL_ARGS_ASSERT_SV_SETPVF_MG_NOCONTEXT;
10516 va_start(args, pat);
10517 sv_vsetpvf_mg(sv, pat, &args);
10523 =for apidoc sv_setpvf
10525 Works like C<sv_catpvf> but copies the text into the SV instead of
10526 appending it. Does not handle 'set' magic. See C<sv_setpvf_mg>.
10532 Perl_sv_setpvf(pTHX_ SV *const sv, const char *const pat, ...)
10536 PERL_ARGS_ASSERT_SV_SETPVF;
10538 va_start(args, pat);
10539 sv_vsetpvf(sv, pat, &args);
10544 =for apidoc sv_vsetpvf
10546 Works like C<sv_vcatpvf> but copies the text into the SV instead of
10547 appending it. Does not handle 'set' magic. See C<sv_vsetpvf_mg>.
10549 Usually used via its frontend C<sv_setpvf>.
10555 Perl_sv_vsetpvf(pTHX_ SV *const sv, const char *const pat, va_list *const args)
10557 PERL_ARGS_ASSERT_SV_VSETPVF;
10559 sv_vsetpvfn(sv, pat, strlen(pat), args, NULL, 0, NULL);
10563 =for apidoc sv_setpvf_mg
10565 Like C<sv_setpvf>, but also handles 'set' magic.
10571 Perl_sv_setpvf_mg(pTHX_ SV *const sv, const char *const pat, ...)
10575 PERL_ARGS_ASSERT_SV_SETPVF_MG;
10577 va_start(args, pat);
10578 sv_vsetpvf_mg(sv, pat, &args);
10583 =for apidoc sv_vsetpvf_mg
10585 Like C<sv_vsetpvf>, but also handles 'set' magic.
10587 Usually used via its frontend C<sv_setpvf_mg>.
10593 Perl_sv_vsetpvf_mg(pTHX_ SV *const sv, const char *const pat, va_list *const args)
10595 PERL_ARGS_ASSERT_SV_VSETPVF_MG;
10597 sv_vsetpvfn(sv, pat, strlen(pat), args, NULL, 0, NULL);
10601 #if defined(PERL_IMPLICIT_CONTEXT)
10603 /* pTHX_ magic can't cope with varargs, so this is a no-context
10604 * version of the main function, (which may itself be aliased to us).
10605 * Don't access this version directly.
10609 Perl_sv_catpvf_nocontext(SV *const sv, const char *const pat, ...)
10614 PERL_ARGS_ASSERT_SV_CATPVF_NOCONTEXT;
10616 va_start(args, pat);
10617 sv_vcatpvfn_flags(sv, pat, strlen(pat), &args, NULL, 0, NULL, SV_GMAGIC|SV_SMAGIC);
10621 /* pTHX_ magic can't cope with varargs, so this is a no-context
10622 * version of the main function, (which may itself be aliased to us).
10623 * Don't access this version directly.
10627 Perl_sv_catpvf_mg_nocontext(SV *const sv, const char *const pat, ...)
10632 PERL_ARGS_ASSERT_SV_CATPVF_MG_NOCONTEXT;
10634 va_start(args, pat);
10635 sv_vcatpvfn_flags(sv, pat, strlen(pat), &args, NULL, 0, NULL, SV_GMAGIC|SV_SMAGIC);
10642 =for apidoc sv_catpvf
10644 Processes its arguments like C<sprintf> and appends the formatted
10645 output to an SV. If the appended data contains "wide" characters
10646 (including, but not limited to, SVs with a UTF-8 PV formatted with %s,
10647 and characters >255 formatted with %c), the original SV might get
10648 upgraded to UTF-8. Handles 'get' magic, but not 'set' magic. See
10649 C<sv_catpvf_mg>. If the original SV was UTF-8, the pattern should be
10650 valid UTF-8; if the original SV was bytes, the pattern should be too.
10655 Perl_sv_catpvf(pTHX_ SV *const sv, const char *const pat, ...)
10659 PERL_ARGS_ASSERT_SV_CATPVF;
10661 va_start(args, pat);
10662 sv_vcatpvfn_flags(sv, pat, strlen(pat), &args, NULL, 0, NULL, SV_GMAGIC|SV_SMAGIC);
10667 =for apidoc sv_vcatpvf
10669 Processes its arguments like C<vsprintf> and appends the formatted output
10670 to an SV. Does not handle 'set' magic. See C<sv_vcatpvf_mg>.
10672 Usually used via its frontend C<sv_catpvf>.
10678 Perl_sv_vcatpvf(pTHX_ SV *const sv, const char *const pat, va_list *const args)
10680 PERL_ARGS_ASSERT_SV_VCATPVF;
10682 sv_vcatpvfn_flags(sv, pat, strlen(pat), args, NULL, 0, NULL, SV_GMAGIC|SV_SMAGIC);
10686 =for apidoc sv_catpvf_mg
10688 Like C<sv_catpvf>, but also handles 'set' magic.
10694 Perl_sv_catpvf_mg(pTHX_ SV *const sv, const char *const pat, ...)
10698 PERL_ARGS_ASSERT_SV_CATPVF_MG;
10700 va_start(args, pat);
10701 sv_vcatpvfn_flags(sv, pat, strlen(pat), &args, NULL, 0, NULL, SV_GMAGIC|SV_SMAGIC);
10707 =for apidoc sv_vcatpvf_mg
10709 Like C<sv_vcatpvf>, but also handles 'set' magic.
10711 Usually used via its frontend C<sv_catpvf_mg>.
10717 Perl_sv_vcatpvf_mg(pTHX_ SV *const sv, const char *const pat, va_list *const args)
10719 PERL_ARGS_ASSERT_SV_VCATPVF_MG;
10721 sv_vcatpvfn(sv, pat, strlen(pat), args, NULL, 0, NULL);
10726 =for apidoc sv_vsetpvfn
10728 Works like C<sv_vcatpvfn> but copies the text into the SV instead of
10731 Usually used via one of its frontends C<sv_vsetpvf> and C<sv_vsetpvf_mg>.
10737 Perl_sv_vsetpvfn(pTHX_ SV *const sv, const char *const pat, const STRLEN patlen,
10738 va_list *const args, SV **const svargs, const I32 svmax, bool *const maybe_tainted)
10740 PERL_ARGS_ASSERT_SV_VSETPVFN;
10743 sv_vcatpvfn_flags(sv, pat, patlen, args, svargs, svmax, maybe_tainted, 0);
10748 * Warn of missing argument to sprintf, and then return a defined value
10749 * to avoid inappropriate "use of uninit" warnings [perl #71000].
10752 S_vcatpvfn_missing_argument(pTHX) {
10753 if (ckWARN(WARN_MISSING)) {
10754 Perl_warner(aTHX_ packWARN(WARN_MISSING), "Missing argument in %s",
10755 PL_op ? OP_DESC(PL_op) : "sv_vcatpvfn()");
10762 S_expect_number(pTHX_ char **const pattern)
10766 PERL_ARGS_ASSERT_EXPECT_NUMBER;
10768 switch (**pattern) {
10769 case '1': case '2': case '3':
10770 case '4': case '5': case '6':
10771 case '7': case '8': case '9':
10772 var = *(*pattern)++ - '0';
10773 while (isDIGIT(**pattern)) {
10774 const I32 tmp = var * 10 + (*(*pattern)++ - '0');
10776 Perl_croak(aTHX_ "Integer overflow in format string for %s", (PL_op ? OP_DESC(PL_op) : "sv_vcatpvfn"));
10784 S_F0convert(NV nv, char *const endbuf, STRLEN *const len)
10786 const int neg = nv < 0;
10789 PERL_ARGS_ASSERT_F0CONVERT;
10791 if (UNLIKELY(Perl_isinfnan(nv))) {
10792 STRLEN n = S_infnan_2pv(nv, endbuf - *len, *len, 0);
10802 if (uv & 1 && uv == nv)
10803 uv--; /* Round to even */
10805 const unsigned dig = uv % 10;
10807 } while (uv /= 10);
10818 =for apidoc sv_vcatpvfn
10820 =for apidoc sv_vcatpvfn_flags
10822 Processes its arguments like C<vsprintf> and appends the formatted output
10823 to an SV. Uses an array of SVs if the C style variable argument list is
10824 missing (NULL). When running with taint checks enabled, indicates via
10825 C<maybe_tainted> if results are untrustworthy (often due to the use of
10828 If called as C<sv_vcatpvfn> or flags include C<SV_GMAGIC>, calls get magic.
10830 Usually used via one of its frontends C<sv_vcatpvf> and C<sv_vcatpvf_mg>.
10835 #define VECTORIZE_ARGS vecsv = va_arg(*args, SV*);\
10836 vecstr = (U8*)SvPV_const(vecsv,veclen);\
10837 vec_utf8 = DO_UTF8(vecsv);
10839 /* XXX maybe_tainted is never assigned to, so the doc above is lying. */
10842 Perl_sv_vcatpvfn(pTHX_ SV *const sv, const char *const pat, const STRLEN patlen,
10843 va_list *const args, SV **const svargs, const I32 svmax, bool *const maybe_tainted)
10845 PERL_ARGS_ASSERT_SV_VCATPVFN;
10847 sv_vcatpvfn_flags(sv, pat, patlen, args, svargs, svmax, maybe_tainted, SV_GMAGIC|SV_SMAGIC);
10850 #ifdef LONGDOUBLE_DOUBLEDOUBLE
10851 /* The first double can be as large as 2**1023, or '1' x '0' x 1023.
10852 * The second double can be as small as 2**-1074, or '0' x 1073 . '1'.
10853 * The sum of them can be '1' . '0' x 2096 . '1', with implied radix point
10854 * after the first 1023 zero bits.
10856 * XXX The 2098 is quite large (262.25 bytes) and therefore some sort
10857 * of dynamically growing buffer might be better, start at just 16 bytes
10858 * (for example) and grow only when necessary. Or maybe just by looking
10859 * at the exponents of the two doubles? */
10860 # define DOUBLEDOUBLE_MAXBITS 2098
10863 /* vhex will contain the values (0..15) of the hex digits ("nybbles"
10864 * of 4 bits); 1 for the implicit 1, and the mantissa bits, four bits
10865 * per xdigit. For the double-double case, this can be rather many.
10866 * The non-double-double-long-double overshoots since all bits of NV
10867 * are not mantissa bits, there are also exponent bits. */
10868 #ifdef LONGDOUBLE_DOUBLEDOUBLE
10869 # define VHEX_SIZE (1+DOUBLEDOUBLE_MAXBITS/4)
10871 # define VHEX_SIZE (1+(NVSIZE * 8)/4)
10874 /* If we do not have a known long double format, (including not using
10875 * long doubles, or long doubles being equal to doubles) then we will
10876 * fall back to the ldexp/frexp route, with which we can retrieve at
10877 * most as many bits as our widest unsigned integer type is. We try
10878 * to get a 64-bit unsigned integer even if we are not using a 64-bit UV.
10880 * (If you want to test the case of UVSIZE == 4, NVSIZE == 8,
10881 * set the MANTISSATYPE to int and the MANTISSASIZE to 4.)
10883 #if defined(HAS_QUAD) && defined(Uquad_t)
10884 # define MANTISSATYPE Uquad_t
10885 # define MANTISSASIZE 8
10887 # define MANTISSATYPE UV
10888 # define MANTISSASIZE UVSIZE
10891 #if defined(DOUBLE_LITTLE_ENDIAN) || defined(LONGDOUBLE_LITTLE_ENDIAN)
10892 # define HEXTRACT_LITTLE_ENDIAN
10893 #elif defined(DOUBLE_BIG_ENDIAN) || defined(LONGDOUBLE_BIG_ENDIAN)
10894 # define HEXTRACT_BIG_ENDIAN
10896 # define HEXTRACT_MIX_ENDIAN
10899 /* S_hextract() is a helper for Perl_sv_vcatpvfn_flags, for extracting
10900 * the hexadecimal values (for %a/%A). The nv is the NV where the value
10901 * are being extracted from (either directly from the long double in-memory
10902 * presentation, or from the uquad computed via frexp+ldexp). frexp also
10903 * is used to update the exponent. vhex is the pointer to the beginning
10904 * of the output buffer (of VHEX_SIZE).
10906 * The tricky part is that S_hextract() needs to be called twice:
10907 * the first time with vend as NULL, and the second time with vend as
10908 * the pointer returned by the first call. What happens is that on
10909 * the first round the output size is computed, and the intended
10910 * extraction sanity checked. On the second round the actual output
10911 * (the extraction of the hexadecimal values) takes place.
10912 * Sanity failures cause fatal failures during both rounds. */
10914 S_hextract(pTHX_ const NV nv, int* exponent, U8* vhex, U8* vend)
10918 int ixmin = 0, ixmax = 0;
10920 /* XXX Inf/NaN/denormal handling in the HEXTRACT_IMPLICIT_BIT,
10921 * and elsewhere. */
10923 /* These macros are just to reduce typos, they have multiple
10924 * repetitions below, but usually only one (or sometimes two)
10925 * of them is really being used. */
10926 /* HEXTRACT_OUTPUT() extracts the high nybble first. */
10927 #define HEXTRACT_OUTPUT_HI(ix) (*v++ = nvp[ix] >> 4)
10928 #define HEXTRACT_OUTPUT_LO(ix) (*v++ = nvp[ix] & 0xF)
10929 #define HEXTRACT_OUTPUT(ix) \
10931 HEXTRACT_OUTPUT_HI(ix); HEXTRACT_OUTPUT_LO(ix); \
10933 #define HEXTRACT_COUNT(ix, c) \
10935 v += c; if (ix < ixmin) ixmin = ix; else if (ix > ixmax) ixmax = ix; \
10937 #define HEXTRACT_BYTE(ix) \
10939 if (vend) HEXTRACT_OUTPUT(ix); else HEXTRACT_COUNT(ix, 2); \
10941 #define HEXTRACT_LO_NYBBLE(ix) \
10943 if (vend) HEXTRACT_OUTPUT_LO(ix); else HEXTRACT_COUNT(ix, 1); \
10945 /* HEXTRACT_TOP_NYBBLE is just convenience disguise,
10946 * to make it look less odd when the top bits of a NV
10947 * are extracted using HEXTRACT_LO_NYBBLE: the highest
10948 * order bits can be in the "low nybble" of a byte. */
10949 #define HEXTRACT_TOP_NYBBLE(ix) HEXTRACT_LO_NYBBLE(ix)
10950 #define HEXTRACT_BYTES_LE(a, b) \
10951 for (ix = a; ix >= b; ix--) { HEXTRACT_BYTE(ix); }
10952 #define HEXTRACT_BYTES_BE(a, b) \
10953 for (ix = a; ix <= b; ix++) { HEXTRACT_BYTE(ix); }
10954 #define HEXTRACT_IMPLICIT_BIT(nv) \
10956 if (vend) *v++ = ((nv) == 0.0) ? 0 : 1; else v++; \
10959 /* Most formats do. Those which don't should undef this. */
10960 #define HEXTRACT_HAS_IMPLICIT_BIT
10961 /* Many formats do. Those which don't should undef this. */
10962 #define HEXTRACT_HAS_TOP_NYBBLE
10964 /* HEXTRACTSIZE is the maximum number of xdigits. */
10965 #if defined(USE_LONG_DOUBLE) && defined(LONGDOUBLE_DOUBLEDOUBLE)
10966 # define HEXTRACTSIZE (DOUBLEDOUBLE_MAXBITS/4)
10968 # define HEXTRACTSIZE 2 * NVSIZE
10971 const U8* vmaxend = vhex + HEXTRACTSIZE;
10972 PERL_UNUSED_VAR(ix); /* might happen */
10973 (void)Perl_frexp(PERL_ABS(nv), exponent);
10974 if (vend && (vend <= vhex || vend > vmaxend))
10975 Perl_croak(aTHX_ "Hexadecimal float: internal error");
10977 /* First check if using long doubles. */
10978 #if defined(USE_LONG_DOUBLE) && (NVSIZE > DOUBLESIZE)
10979 # if LONG_DOUBLEKIND == LONG_DOUBLE_IS_IEEE_754_128_BIT_LITTLE_ENDIAN
10980 /* Used in e.g. VMS and HP-UX IA-64, e.g. -0.1L:
10981 * 9a 99 99 99 99 99 99 99 99 99 99 99 99 99 fb 3f */
10982 /* The bytes 13..0 are the mantissa/fraction,
10983 * the 15,14 are the sign+exponent. */
10984 const U8* nvp = (const U8*)(&nv);
10985 HEXTRACT_IMPLICIT_BIT(nv);
10986 # undef HEXTRACT_HAS_TOP_NYBBLE
10987 HEXTRACT_BYTES_LE(13, 0);
10988 # elif LONG_DOUBLEKIND == LONG_DOUBLE_IS_IEEE_754_128_BIT_BIG_ENDIAN
10989 /* Used in e.g. Solaris Sparc and HP-UX PA-RISC, e.g. -0.1L:
10990 * bf fb 99 99 99 99 99 99 99 99 99 99 99 99 99 9a */
10991 /* The bytes 2..15 are the mantissa/fraction,
10992 * the 0,1 are the sign+exponent. */
10993 const U8* nvp = (const U8*)(&nv);
10994 HEXTRACT_IMPLICIT_BIT(nv);
10995 # undef HEXTRACT_HAS_TOP_NYBBLE
10996 HEXTRACT_BYTES_BE(2, 15);
10997 # elif LONG_DOUBLEKIND == LONG_DOUBLE_IS_X86_80_BIT_LITTLE_ENDIAN
10998 /* x86 80-bit "extended precision", 64 bits of mantissa / fraction /
10999 * significand, 15 bits of exponent, 1 bit of sign. NVSIZE can
11000 * be either 12 (ILP32, Solaris x86) or 16 (LP64, Linux and OS X),
11001 * meaning that 2 or 6 bytes are empty padding. */
11002 /* The bytes 7..0 are the mantissa/fraction */
11003 const U8* nvp = (const U8*)(&nv);
11004 # undef HEXTRACT_HAS_IMPLICIT_BIT
11005 # undef HEXTRACT_HAS_TOP_NYBBLE
11006 HEXTRACT_BYTES_LE(7, 0);
11007 # elif LONG_DOUBLEKIND == LONG_DOUBLE_IS_X86_80_BIT_BIG_ENDIAN
11008 /* Does this format ever happen? (Wikipedia says the Motorola
11009 * 6888x math coprocessors used format _like_ this but padded
11010 * to 96 bits with 16 unused bits between the exponent and the
11012 const U8* nvp = (const U8*)(&nv);
11013 # undef HEXTRACT_HAS_IMPLICIT_BIT
11014 # undef HEXTRACT_HAS_TOP_NYBBLE
11015 HEXTRACT_BYTES_BE(0, 7);
11017 # define HEXTRACT_FALLBACK
11018 /* Double-double format: two doubles next to each other.
11019 * The first double is the high-order one, exactly like
11020 * it would be for a "lone" double. The second double
11021 * is shifted down using the exponent so that that there
11022 * are no common bits. The tricky part is that the value
11023 * of the double-double is the SUM of the two doubles and
11024 * the second one can be also NEGATIVE.
11026 * Because of this tricky construction the bytewise extraction we
11027 * use for the other long double formats doesn't work, we must
11028 * extract the values bit by bit.
11030 * The little-endian double-double is used .. somewhere?
11032 * The big endian double-double is used in e.g. PPC/Power (AIX)
11035 * The mantissa bits are in two separate stretches, e.g. for -0.1L:
11036 * 9a 99 99 99 99 99 59 bc 9a 99 99 99 99 99 b9 3f (LE)
11037 * 3f b9 99 99 99 99 99 9a bc 59 99 99 99 99 99 9a (BE)
11040 #else /* #if defined(USE_LONG_DOUBLE) && (NVSIZE > DOUBLESIZE) */
11041 /* Using normal doubles, not long doubles.
11043 * We generate 4-bit xdigits (nybble/nibble) instead of 8-bit
11044 * bytes, since we might need to handle printf precision, and
11045 * also need to insert the radix. */
11047 # ifdef HEXTRACT_LITTLE_ENDIAN
11048 /* 0 1 2 3 4 5 6 7 (MSB = 7, LSB = 0, 6+7 = exponent+sign) */
11049 const U8* nvp = (const U8*)(&nv);
11050 HEXTRACT_IMPLICIT_BIT(nv);
11051 HEXTRACT_TOP_NYBBLE(6);
11052 HEXTRACT_BYTES_LE(5, 0);
11053 # elif defined(HEXTRACT_BIG_ENDIAN)
11054 /* 7 6 5 4 3 2 1 0 (MSB = 7, LSB = 0, 6+7 = exponent+sign) */
11055 const U8* nvp = (const U8*)(&nv);
11056 HEXTRACT_IMPLICIT_BIT(nv);
11057 HEXTRACT_TOP_NYBBLE(1);
11058 HEXTRACT_BYTES_BE(2, 7);
11059 # elif DOUBLEKIND == DOUBLE_IS_IEEE_754_64_BIT_MIXED_ENDIAN_LE_BE
11060 /* 4 5 6 7 0 1 2 3 (MSB = 7, LSB = 0, 6:7 = nybble:exponent:sign) */
11061 const U8* nvp = (const U8*)(&nv);
11062 HEXTRACT_IMPLICIT_BIT(nv);
11063 HEXTRACT_TOP_NYBBLE(2); /* 6 */
11064 HEXTRACT_BYTE(1); /* 5 */
11065 HEXTRACT_BYTE(0); /* 4 */
11066 HEXTRACT_BYTE(7); /* 3 */
11067 HEXTRACT_BYTE(6); /* 2 */
11068 HEXTRACT_BYTE(5); /* 1 */
11069 HEXTRACT_BYTE(4); /* 0 */
11070 # elif DOUBLEKIND == DOUBLE_IS_IEEE_754_64_BIT_MIXED_ENDIAN_BE_LE
11071 /* 3 2 1 0 7 6 5 4 (MSB = 7, LSB = 0, 7:6 = sign:exponent:nybble) */
11072 const U8* nvp = (const U8*)(&nv);
11073 HEXTRACT_IMPLICIT_BIT(nv);
11074 HEXTRACT_TOP_NYBBLE(5); /* 6 */
11075 HEXTRACT_BYTE(6); /* 5 */
11076 HEXTRACT_BYTE(7); /* 4 */
11077 HEXTRACT_BYTE(0); /* 3 */
11078 HEXTRACT_BYTE(1); /* 2 */
11079 HEXTRACT_BYTE(2); /* 1 */
11080 HEXTRACT_BYTE(3); /* 0 */
11082 # define HEXTRACT_FALLBACK
11085 # define HEXTRACT_FALLBACK
11087 #endif /* #if defined(USE_LONG_DOUBLE) && (NVSIZE > DOUBLESIZE) #else */
11088 # ifdef HEXTRACT_FALLBACK
11089 # undef HEXTRACT_HAS_TOP_NYBBLE /* Meaningless, but consistent. */
11090 /* The fallback is used for the double-double format, and
11091 * for unknown long double formats, and for unknown double
11092 * formats, or in general unknown NV formats. */
11093 if (nv == (NV)0.0) {
11101 NV d = nv < 0 ? -nv : nv;
11103 U8 ha = 0x0; /* hexvalue accumulator */
11104 U8 hd = 0x8; /* hexvalue digit */
11106 /* Shift d and e (and update exponent) so that e <= d < 2*e,
11107 * this is essentially manual frexp(). Multiplying by 0.5 and
11108 * doubling should be lossless in binary floating point. */
11118 while (d >= e + e) {
11122 /* Now e <= d < 2*e */
11124 /* First extract the leading hexdigit (the implicit bit). */
11140 /* Then extract the remaining hexdigits. */
11141 while (d > (NV)0.0) {
11147 /* Output or count in groups of four bits,
11148 * that is, when the hexdigit is down to one. */
11153 /* Reset the hexvalue. */
11162 /* Flush possible pending hexvalue. */
11172 /* Croak for various reasons: if the output pointer escaped the
11173 * output buffer, if the extraction index escaped the extraction
11174 * buffer, or if the ending output pointer didn't match the
11175 * previously computed value. */
11176 if (v <= vhex || v - vhex >= VHEX_SIZE ||
11177 /* For double-double the ixmin and ixmax stay at zero,
11178 * which is convenient since the HEXTRACTSIZE is tricky
11179 * for double-double. */
11180 ixmin < 0 || ixmax >= NVSIZE ||
11181 (vend && v != vend))
11182 Perl_croak(aTHX_ "Hexadecimal float: internal error");
11187 Perl_sv_vcatpvfn_flags(pTHX_ SV *const sv, const char *const pat, const STRLEN patlen,
11188 va_list *const args, SV **const svargs, const I32 svmax, bool *const maybe_tainted,
11193 const char *patend;
11196 static const char nullstr[] = "(null)";
11198 bool has_utf8 = DO_UTF8(sv); /* has the result utf8? */
11199 const bool pat_utf8 = has_utf8; /* the pattern is in utf8? */
11201 /* Times 4: a decimal digit takes more than 3 binary digits.
11202 * NV_DIG: mantissa takes than many decimal digits.
11203 * Plus 32: Playing safe. */
11204 char ebuf[IV_DIG * 4 + NV_DIG + 32];
11205 bool no_redundant_warning = FALSE; /* did we use any explicit format parameter index? */
11206 bool hexfp = FALSE; /* hexadecimal floating point? */
11208 DECLARATION_FOR_LC_NUMERIC_MANIPULATION;
11210 PERL_ARGS_ASSERT_SV_VCATPVFN_FLAGS;
11211 PERL_UNUSED_ARG(maybe_tainted);
11213 if (flags & SV_GMAGIC)
11216 /* no matter what, this is a string now */
11217 (void)SvPV_force_nomg(sv, origlen);
11219 /* special-case "", "%s", and "%-p" (SVf - see below) */
11221 if (svmax && ckWARN(WARN_REDUNDANT))
11222 Perl_warner(aTHX_ packWARN(WARN_REDUNDANT), "Redundant argument in %s",
11223 PL_op ? OP_DESC(PL_op) : "sv_vcatpvfn()");
11226 if (patlen == 2 && pat[0] == '%' && pat[1] == 's') {
11227 if (svmax > 1 && ckWARN(WARN_REDUNDANT))
11228 Perl_warner(aTHX_ packWARN(WARN_REDUNDANT), "Redundant argument in %s",
11229 PL_op ? OP_DESC(PL_op) : "sv_vcatpvfn()");
11232 const char * const s = va_arg(*args, char*);
11233 sv_catpv_nomg(sv, s ? s : nullstr);
11235 else if (svix < svmax) {
11236 /* we want get magic on the source but not the target. sv_catsv can't do that, though */
11237 SvGETMAGIC(*svargs);
11238 sv_catsv_nomg(sv, *svargs);
11241 S_vcatpvfn_missing_argument(aTHX);
11244 if (args && patlen == 3 && pat[0] == '%' &&
11245 pat[1] == '-' && pat[2] == 'p') {
11246 if (svmax > 1 && ckWARN(WARN_REDUNDANT))
11247 Perl_warner(aTHX_ packWARN(WARN_REDUNDANT), "Redundant argument in %s",
11248 PL_op ? OP_DESC(PL_op) : "sv_vcatpvfn()");
11249 argsv = MUTABLE_SV(va_arg(*args, void*));
11250 sv_catsv_nomg(sv, argsv);
11254 #if !defined(USE_LONG_DOUBLE) && !defined(USE_QUADMATH)
11255 /* special-case "%.<number>[gf]" */
11256 if ( !args && patlen <= 5 && pat[0] == '%' && pat[1] == '.'
11257 && (pat[patlen-1] == 'g' || pat[patlen-1] == 'f') ) {
11258 unsigned digits = 0;
11262 while (*pp >= '0' && *pp <= '9')
11263 digits = 10 * digits + (*pp++ - '0');
11265 /* XXX: Why do this `svix < svmax` test? Couldn't we just
11266 format the first argument and WARN_REDUNDANT if svmax > 1?
11267 Munged by Nicholas Clark in v5.13.0-209-g95ea86d */
11268 if (pp - pat == (int)patlen - 1 && svix < svmax) {
11269 const NV nv = SvNV(*svargs);
11270 if (LIKELY(!Perl_isinfnan(nv))) {
11272 /* Add check for digits != 0 because it seems that some
11273 gconverts are buggy in this case, and we don't yet have
11274 a Configure test for this. */
11275 if (digits && digits < sizeof(ebuf) - NV_DIG - 10) {
11276 /* 0, point, slack */
11277 STORE_LC_NUMERIC_SET_TO_NEEDED();
11278 SNPRINTF_G(nv, ebuf, size, digits);
11279 sv_catpv_nomg(sv, ebuf);
11280 if (*ebuf) /* May return an empty string for digits==0 */
11283 } else if (!digits) {
11286 if ((p = F0convert(nv, ebuf + sizeof ebuf, &l))) {
11287 sv_catpvn_nomg(sv, p, l);
11294 #endif /* !USE_LONG_DOUBLE */
11296 if (!args && svix < svmax && DO_UTF8(*svargs))
11299 patend = (char*)pat + patlen;
11300 for (p = (char*)pat; p < patend; p = q) {
11303 bool vectorize = FALSE;
11304 bool vectorarg = FALSE;
11305 bool vec_utf8 = FALSE;
11311 bool has_precis = FALSE;
11313 const I32 osvix = svix;
11314 bool is_utf8 = FALSE; /* is this item utf8? */
11315 #ifdef HAS_LDBL_SPRINTF_BUG
11316 /* This is to try to fix a bug with irix/nonstop-ux/powerux and
11317 with sfio - Allen <allens@cpan.org> */
11318 bool fix_ldbl_sprintf_bug = FALSE;
11322 U8 utf8buf[UTF8_MAXBYTES+1];
11323 STRLEN esignlen = 0;
11325 const char *eptr = NULL;
11326 const char *fmtstart;
11329 const U8 *vecstr = NULL;
11336 /* We need a long double target in case HAS_LONG_DOUBLE,
11337 * even without USE_LONG_DOUBLE, so that we can printf with
11338 * long double formats, even without NV being long double.
11339 * But we call the target 'fv' instead of 'nv', since most of
11340 * the time it is not (most compilers these days recognize
11341 * "long double", even if only as a synonym for "double").
11343 #if defined(HAS_LONG_DOUBLE) && LONG_DOUBLESIZE > DOUBLESIZE && \
11344 defined(PERL_PRIgldbl) && !defined(USE_QUADMATH)
11346 # ifdef Perl_isfinitel
11347 # define FV_ISFINITE(x) Perl_isfinitel(x)
11349 # define FV_GF PERL_PRIgldbl
11350 # if defined(__VMS) && defined(__ia64) && defined(__IEEE_FLOAT)
11351 /* Work around breakage in OTS$CVT_FLOAT_T_X */
11352 # define NV_TO_FV(nv,fv) STMT_START { \
11354 fv = Perl_isnan(_dv) ? LDBL_QNAN : _dv; \
11357 # define NV_TO_FV(nv,fv) (fv)=(nv)
11361 # define FV_GF NVgf
11362 # define NV_TO_FV(nv,fv) (fv)=(nv)
11364 #ifndef FV_ISFINITE
11365 # define FV_ISFINITE(x) Perl_isfinite((NV)(x))
11371 const char *dotstr = ".";
11372 STRLEN dotstrlen = 1;
11373 I32 efix = 0; /* explicit format parameter index */
11374 I32 ewix = 0; /* explicit width index */
11375 I32 epix = 0; /* explicit precision index */
11376 I32 evix = 0; /* explicit vector index */
11377 bool asterisk = FALSE;
11378 bool infnan = FALSE;
11380 /* echo everything up to the next format specification */
11381 for (q = p; q < patend && *q != '%'; ++q) ;
11383 if (has_utf8 && !pat_utf8)
11384 sv_catpvn_nomg_utf8_upgrade(sv, p, q - p, nsv);
11386 sv_catpvn_nomg(sv, p, q - p);
11395 We allow format specification elements in this order:
11396 \d+\$ explicit format parameter index
11398 v|\*(\d+\$)?v vector with optional (optionally specified) arg
11399 0 flag (as above): repeated to allow "v02"
11400 \d+|\*(\d+\$)? width using optional (optionally specified) arg
11401 \.(\d*|\*(\d+\$)?) precision using optional (optionally specified) arg
11403 [%bcdefginopsuxDFOUX] format (mandatory)
11408 As of perl5.9.3, printf format checking is on by default.
11409 Internally, perl uses %p formats to provide an escape to
11410 some extended formatting. This block deals with those
11411 extensions: if it does not match, (char*)q is reset and
11412 the normal format processing code is used.
11414 Currently defined extensions are:
11415 %p include pointer address (standard)
11416 %-p (SVf) include an SV (previously %_)
11417 %-<num>p include an SV with precision <num>
11419 %3p include a HEK with precision of 256
11420 %4p char* preceded by utf8 flag and length
11421 %<num>p (where num is 1 or > 4) reserved for future
11424 Robin Barker 2005-07-14 (but modified since)
11426 %1p (VDf) removed. RMB 2007-10-19
11433 else if (strnEQ(q, UTF8f, sizeof(UTF8f)-1)) { /* UTF8f */
11434 /* The argument has already gone through cBOOL, so the cast
11436 is_utf8 = (bool)va_arg(*args, int);
11437 elen = va_arg(*args, UV);
11438 if ((IV)elen < 0) {
11439 /* check if utf8 length is larger than 0 when cast to IV */
11440 assert( (IV)elen >= 0 ); /* in DEBUGGING build we want to crash */
11441 elen= 0; /* otherwise we want to treat this as an empty string */
11443 eptr = va_arg(*args, char *);
11444 q += sizeof(UTF8f)-1;
11447 n = expect_number(&q);
11449 if (sv) { /* SVf */
11454 argsv = MUTABLE_SV(va_arg(*args, void*));
11455 eptr = SvPV_const(argsv, elen);
11456 if (DO_UTF8(argsv))
11460 else if (n==2 || n==3) { /* HEKf */
11461 HEK * const hek = va_arg(*args, HEK *);
11462 eptr = HEK_KEY(hek);
11463 elen = HEK_LEN(hek);
11464 if (HEK_UTF8(hek)) is_utf8 = TRUE;
11465 if (n==3) precis = 256, has_precis = TRUE;
11469 Perl_ck_warner_d(aTHX_ packWARN(WARN_INTERNAL),
11470 "internal %%<num>p might conflict with future printf extensions");
11476 if ( (width = expect_number(&q)) ) {
11480 if (!no_redundant_warning)
11481 /* I've forgotten if it's a better
11482 micro-optimization to always set this or to
11483 only set it if it's unset */
11484 no_redundant_warning = TRUE;
11496 if (plus == '+' && *q == ' ') /* '+' over ' ' */
11525 if ( (ewix = expect_number(&q)) )
11534 if ((vectorarg = asterisk)) {
11547 width = expect_number(&q);
11550 if (vectorize && vectorarg) {
11551 /* vectorizing, but not with the default "." */
11553 vecsv = va_arg(*args, SV*);
11555 vecsv = (evix > 0 && evix <= svmax)
11556 ? svargs[evix-1] : S_vcatpvfn_missing_argument(aTHX);
11558 vecsv = svix < svmax
11559 ? svargs[svix++] : S_vcatpvfn_missing_argument(aTHX);
11561 dotstr = SvPV_const(vecsv, dotstrlen);
11562 /* Keep the DO_UTF8 test *after* the SvPV call, else things go
11563 bad with tied or overloaded values that return UTF8. */
11564 if (DO_UTF8(vecsv))
11566 else if (has_utf8) {
11567 vecsv = sv_mortalcopy(vecsv);
11568 sv_utf8_upgrade(vecsv);
11569 dotstr = SvPV_const(vecsv, dotstrlen);
11576 i = va_arg(*args, int);
11578 i = (ewix ? ewix <= svmax : svix < svmax) ?
11579 SvIVx(svargs[ewix ? ewix-1 : svix++]) : 0;
11581 width = (i < 0) ? -i : i;
11591 if ( ((epix = expect_number(&q))) && (*q++ != '$') )
11593 /* XXX: todo, support specified precision parameter */
11597 i = va_arg(*args, int);
11599 i = (ewix ? ewix <= svmax : svix < svmax)
11600 ? SvIVx(svargs[ewix ? ewix-1 : svix++]) : 0;
11602 has_precis = !(i < 0);
11606 while (isDIGIT(*q))
11607 precis = precis * 10 + (*q++ - '0');
11616 else if (efix ? (efix > 0 && efix <= svmax) : svix < svmax) {
11617 vecsv = svargs[efix ? efix-1 : svix++];
11618 vecstr = (U8*)SvPV_const(vecsv,veclen);
11619 vec_utf8 = DO_UTF8(vecsv);
11621 /* if this is a version object, we need to convert
11622 * back into v-string notation and then let the
11623 * vectorize happen normally
11625 if (sv_isobject(vecsv) && sv_derived_from(vecsv, "version")) {
11626 if ( hv_exists(MUTABLE_HV(SvRV(vecsv)), "alpha", 5 ) ) {
11627 Perl_ck_warner_d(aTHX_ packWARN(WARN_PRINTF),
11628 "vector argument not supported with alpha versions");
11631 vecsv = sv_newmortal();
11632 scan_vstring((char *)vecstr, (char *)vecstr + veclen,
11634 vecstr = (U8*)SvPV_const(vecsv, veclen);
11635 vec_utf8 = DO_UTF8(vecsv);
11649 case 'I': /* Ix, I32x, and I64x */
11650 # ifdef USE_64_BIT_INT
11651 if (q[1] == '6' && q[2] == '4') {
11657 if (q[1] == '3' && q[2] == '2') {
11661 # ifdef USE_64_BIT_INT
11667 #if (IVSIZE >= 8 || defined(HAS_LONG_DOUBLE)) || \
11668 (IVSIZE == 4 && !defined(HAS_LONG_DOUBLE))
11671 # ifdef USE_QUADMATH
11684 #if (IVSIZE >= 8 || defined(HAS_LONG_DOUBLE)) || \
11685 (IVSIZE == 4 && !defined(HAS_LONG_DOUBLE))
11686 if (*q == 'l') { /* lld, llf */
11695 if (*++q == 'h') { /* hhd, hhu */
11724 if (!vectorize && !args) {
11726 const I32 i = efix-1;
11727 argsv = (i >= 0 && i < svmax)
11728 ? svargs[i] : S_vcatpvfn_missing_argument(aTHX);
11730 argsv = (svix >= 0 && svix < svmax)
11731 ? svargs[svix++] : S_vcatpvfn_missing_argument(aTHX);
11735 if (argsv && strchr("BbcDdiOopuUXx",*q)) {
11736 /* XXX va_arg(*args) case? need peek, use va_copy? */
11738 if (UNLIKELY(SvAMAGIC(argsv)))
11739 argsv = sv_2num(argsv);
11740 infnan = UNLIKELY(isinfnansv(argsv));
11743 switch (c = *q++) {
11751 Perl_croak(aTHX_ "Cannot printf %"NVgf" with '%c'",
11752 /* no va_arg() case */
11753 SvNV_nomg(argsv), (int)c);
11754 uv = (args) ? va_arg(*args, int) : SvIV_nomg(argsv);
11756 (!UVCHR_IS_INVARIANT(uv) && SvUTF8(sv)))
11758 eptr = (char*)utf8buf;
11759 elen = uvchr_to_utf8((U8*)eptr, uv) - utf8buf;
11773 eptr = va_arg(*args, char*);
11775 elen = strlen(eptr);
11777 eptr = (char *)nullstr;
11778 elen = sizeof nullstr - 1;
11782 eptr = SvPV_const(argsv, elen);
11783 if (DO_UTF8(argsv)) {
11784 STRLEN old_precis = precis;
11785 if (has_precis && precis < elen) {
11786 STRLEN ulen = sv_or_pv_len_utf8(argsv, eptr, elen);
11787 STRLEN p = precis > ulen ? ulen : precis;
11788 precis = sv_or_pv_pos_u2b(argsv, eptr, p, 0);
11789 /* sticks at end */
11791 if (width) { /* fudge width (can't fudge elen) */
11792 if (has_precis && precis < elen)
11793 width += precis - old_precis;
11796 elen - sv_or_pv_len_utf8(argsv,eptr,elen);
11803 if (has_precis && precis < elen)
11811 goto floating_point;
11813 if (alt || vectorize)
11815 uv = PTR2UV(args ? va_arg(*args, void*) : argsv);
11829 goto floating_point;
11836 uv = utf8n_to_uvchr(vecstr, veclen, &ulen,
11845 esignbuf[esignlen++] = plus;
11849 case 'c': iv = (char)va_arg(*args, int); break;
11850 case 'h': iv = (short)va_arg(*args, int); break;
11851 case 'l': iv = va_arg(*args, long); break;
11852 case 'V': iv = va_arg(*args, IV); break;
11853 case 'z': iv = va_arg(*args, SSize_t); break;
11854 #ifdef HAS_PTRDIFF_T
11855 case 't': iv = va_arg(*args, ptrdiff_t); break;
11857 default: iv = va_arg(*args, int); break;
11859 case 'j': iv = va_arg(*args, intmax_t); break;
11863 iv = va_arg(*args, Quad_t); break;
11870 IV tiv = SvIV_nomg(argsv); /* work around GCC bug #13488 */
11872 case 'c': iv = (char)tiv; break;
11873 case 'h': iv = (short)tiv; break;
11874 case 'l': iv = (long)tiv; break;
11876 default: iv = tiv; break;
11879 iv = (Quad_t)tiv; break;
11885 if ( !vectorize ) /* we already set uv above */
11890 esignbuf[esignlen++] = plus;
11893 uv = (iv == IV_MIN) ? (UV)iv : (UV)(-iv);
11894 esignbuf[esignlen++] = '-';
11933 goto floating_point;
11941 uv = utf8n_to_uvchr(vecstr, veclen, &ulen,
11952 case 'c': uv = (unsigned char)va_arg(*args, unsigned); break;
11953 case 'h': uv = (unsigned short)va_arg(*args, unsigned); break;
11954 case 'l': uv = va_arg(*args, unsigned long); break;
11955 case 'V': uv = va_arg(*args, UV); break;
11956 case 'z': uv = va_arg(*args, Size_t); break;
11957 #ifdef HAS_PTRDIFF_T
11958 case 't': uv = va_arg(*args, ptrdiff_t); break; /* will sign extend, but there is no uptrdiff_t, so oh well */
11961 case 'j': uv = va_arg(*args, uintmax_t); break;
11963 default: uv = va_arg(*args, unsigned); break;
11966 uv = va_arg(*args, Uquad_t); break;
11973 UV tuv = SvUV_nomg(argsv); /* work around GCC bug #13488 */
11975 case 'c': uv = (unsigned char)tuv; break;
11976 case 'h': uv = (unsigned short)tuv; break;
11977 case 'l': uv = (unsigned long)tuv; break;
11979 default: uv = tuv; break;
11982 uv = (Uquad_t)tuv; break;
11991 char *ptr = ebuf + sizeof ebuf;
11992 bool tempalt = uv ? alt : FALSE; /* Vectors can't change alt */
11998 p = (char *)((c == 'X') ? PL_hexdigit + 16 : PL_hexdigit);
12002 } while (uv >>= 4);
12004 esignbuf[esignlen++] = '0';
12005 esignbuf[esignlen++] = c; /* 'x' or 'X' */
12011 *--ptr = '0' + dig;
12012 } while (uv >>= 3);
12013 if (alt && *ptr != '0')
12019 *--ptr = '0' + dig;
12020 } while (uv >>= 1);
12022 esignbuf[esignlen++] = '0';
12023 esignbuf[esignlen++] = c;
12026 default: /* it had better be ten or less */
12029 *--ptr = '0' + dig;
12030 } while (uv /= base);
12033 elen = (ebuf + sizeof ebuf) - ptr;
12037 zeros = precis - elen;
12038 else if (precis == 0 && elen == 1 && *eptr == '0'
12039 && !(base == 8 && alt)) /* "%#.0o" prints "0" */
12042 /* a precision nullifies the 0 flag. */
12049 /* FLOATING POINT */
12054 c = 'f'; /* maybe %F isn't supported here */
12056 case 'e': case 'E':
12058 case 'g': case 'G':
12059 case 'a': case 'A':
12063 /* This is evil, but floating point is even more evil */
12065 /* for SV-style calling, we can only get NV
12066 for C-style calling, we assume %f is double;
12067 for simplicity we allow any of %Lf, %llf, %qf for long double
12071 #if defined(USE_LONG_DOUBLE) || defined(USE_QUADMATH)
12075 /* [perl #20339] - we should accept and ignore %lf rather than die */
12079 #if defined(USE_LONG_DOUBLE) || defined(USE_QUADMATH)
12080 intsize = args ? 0 : 'q';
12084 #if defined(HAS_LONG_DOUBLE)
12097 /* Now we need (long double) if intsize == 'q', else (double). */
12099 /* Note: do not pull NVs off the va_list with va_arg()
12100 * (pull doubles instead) because if you have a build
12101 * with long doubles, you would always be pulling long
12102 * doubles, which would badly break anyone using only
12103 * doubles (i.e. the majority of builds). In other
12104 * words, you cannot mix doubles and long doubles.
12105 * The only case where you can pull off long doubles
12106 * is when the format specifier explicitly asks so with
12108 #ifdef USE_QUADMATH
12109 fv = intsize == 'q' ?
12110 va_arg(*args, NV) : va_arg(*args, double);
12112 #elif LONG_DOUBLESIZE > DOUBLESIZE
12113 if (intsize == 'q') {
12114 fv = va_arg(*args, long double);
12117 nv = va_arg(*args, double);
12121 nv = va_arg(*args, double);
12127 if (!infnan) SvGETMAGIC(argsv);
12128 nv = SvNV_nomg(argsv);
12133 /* frexp() (or frexpl) has some unspecified behaviour for
12134 * nan/inf/-inf, so let's avoid calling that on non-finites. */
12135 if (isALPHA_FOLD_NE(c, 'e') && FV_ISFINITE(fv)) {
12137 (void)Perl_frexp((NV)fv, &i);
12138 if (i == PERL_INT_MIN)
12139 Perl_die(aTHX_ "panic: frexp: %"FV_GF, fv);
12140 /* Do not set hexfp earlier since we want to printf
12141 * Inf/NaN for Inf/NaN, not their hexfp. */
12142 hexfp = isALPHA_FOLD_EQ(c, 'a');
12143 if (UNLIKELY(hexfp)) {
12144 /* This seriously overshoots in most cases, but
12145 * better the undershooting. Firstly, all bytes
12146 * of the NV are not mantissa, some of them are
12147 * exponent. Secondly, for the reasonably common
12148 * long doubles case, the "80-bit extended", two
12149 * or six bytes of the NV are unused. */
12151 (fv < 0) ? 1 : 0 + /* possible unary minus */
12153 1 + /* the very unlikely carry */
12156 2 * NVSIZE + /* 2 hexdigits for each byte */
12158 6 + /* exponent: sign, plus up to 16383 (quad fp) */
12160 #ifdef LONGDOUBLE_DOUBLEDOUBLE
12161 /* However, for the "double double", we need more.
12162 * Since each double has their own exponent, the
12163 * doubles may float (haha) rather far from each
12164 * other, and the number of required bits is much
12165 * larger, up to total of DOUBLEDOUBLE_MAXBITS bits.
12166 * See the definition of DOUBLEDOUBLE_MAXBITS.
12168 * Need 2 hexdigits for each byte. */
12169 need += (DOUBLEDOUBLE_MAXBITS/8 + 1) * 2;
12170 /* the size for the exponent already added */
12172 #ifdef USE_LOCALE_NUMERIC
12173 STORE_LC_NUMERIC_SET_TO_NEEDED();
12174 if (PL_numeric_radix_sv && IN_LC(LC_NUMERIC))
12175 need += SvLEN(PL_numeric_radix_sv);
12176 RESTORE_LC_NUMERIC();
12180 need = BIT_DIGITS(i);
12181 } /* if i < 0, the number of digits is hard to predict. */
12183 need += has_precis ? precis : 6; /* known default */
12188 #ifdef HAS_LDBL_SPRINTF_BUG
12189 /* This is to try to fix a bug with irix/nonstop-ux/powerux and
12190 with sfio - Allen <allens@cpan.org> */
12193 # define MY_DBL_MAX DBL_MAX
12194 # else /* XXX guessing! HUGE_VAL may be defined as infinity, so not using */
12195 # if DOUBLESIZE >= 8
12196 # define MY_DBL_MAX 1.7976931348623157E+308L
12198 # define MY_DBL_MAX 3.40282347E+38L
12202 # ifdef HAS_LDBL_SPRINTF_BUG_LESS1 /* only between -1L & 1L - Allen */
12203 # define MY_DBL_MAX_BUG 1L
12205 # define MY_DBL_MAX_BUG MY_DBL_MAX
12209 # define MY_DBL_MIN DBL_MIN
12210 # else /* XXX guessing! -Allen */
12211 # if DOUBLESIZE >= 8
12212 # define MY_DBL_MIN 2.2250738585072014E-308L
12214 # define MY_DBL_MIN 1.17549435E-38L
12218 if ((intsize == 'q') && (c == 'f') &&
12219 ((fv < MY_DBL_MAX_BUG) && (fv > -MY_DBL_MAX_BUG)) &&
12220 (need < DBL_DIG)) {
12221 /* it's going to be short enough that
12222 * long double precision is not needed */
12224 if ((fv <= 0L) && (fv >= -0L))
12225 fix_ldbl_sprintf_bug = TRUE; /* 0 is 0 - easiest */
12227 /* would use Perl_fp_class as a double-check but not
12228 * functional on IRIX - see perl.h comments */
12230 if ((fv >= MY_DBL_MIN) || (fv <= -MY_DBL_MIN)) {
12231 /* It's within the range that a double can represent */
12232 #if defined(DBL_MAX) && !defined(DBL_MIN)
12233 if ((fv >= ((long double)1/DBL_MAX)) ||
12234 (fv <= (-(long double)1/DBL_MAX)))
12236 fix_ldbl_sprintf_bug = TRUE;
12239 if (fix_ldbl_sprintf_bug == TRUE) {
12249 # undef MY_DBL_MAX_BUG
12252 #endif /* HAS_LDBL_SPRINTF_BUG */
12254 need += 20; /* fudge factor */
12255 if (PL_efloatsize < need) {
12256 Safefree(PL_efloatbuf);
12257 PL_efloatsize = need + 20; /* more fudge */
12258 Newx(PL_efloatbuf, PL_efloatsize, char);
12259 PL_efloatbuf[0] = '\0';
12262 if ( !(width || left || plus || alt) && fill != '0'
12263 && has_precis && intsize != 'q' /* Shortcuts */
12264 && LIKELY(!Perl_isinfnan((NV)fv)) ) {
12265 /* See earlier comment about buggy Gconvert when digits,
12267 if ( c == 'g' && precis ) {
12268 STORE_LC_NUMERIC_SET_TO_NEEDED();
12269 SNPRINTF_G(fv, PL_efloatbuf, PL_efloatsize, precis);
12270 /* May return an empty string for digits==0 */
12271 if (*PL_efloatbuf) {
12272 elen = strlen(PL_efloatbuf);
12273 goto float_converted;
12275 } else if ( c == 'f' && !precis ) {
12276 if ((eptr = F0convert(nv, ebuf + sizeof ebuf, &elen)))
12281 if (UNLIKELY(hexfp)) {
12282 /* Hexadecimal floating point. */
12283 char* p = PL_efloatbuf;
12284 U8 vhex[VHEX_SIZE];
12285 U8* v = vhex; /* working pointer to vhex */
12286 U8* vend; /* pointer to one beyond last digit of vhex */
12287 U8* vfnz = NULL; /* first non-zero */
12288 const bool lower = (c == 'a');
12289 /* At output the values of vhex (up to vend) will
12290 * be mapped through the xdig to get the actual
12291 * human-readable xdigits. */
12292 const char* xdig = PL_hexdigit;
12293 int zerotail = 0; /* how many extra zeros to append */
12294 int exponent = 0; /* exponent of the floating point input */
12296 /* XXX: denormals, NaN, Inf.
12298 * For example with denormals, (assuming the vanilla
12299 * 64-bit double): the exponent is zero. 1xp-1074 is
12300 * the smallest denormal and the smallest double, it
12301 * should be output as 0x0.0000000000001p-1022 to
12302 * match its internal structure. */
12304 vend = S_hextract(aTHX_ nv, &exponent, vhex, NULL);
12305 S_hextract(aTHX_ nv, &exponent, vhex, vend);
12307 #if NVSIZE > DOUBLESIZE
12308 # ifdef HEXTRACT_HAS_IMPLICIT_BIT
12309 /* In this case there is an implicit bit,
12310 * and therefore the exponent is shifted shift by one. */
12313 /* In this case there is no implicit bit,
12314 * and the exponent is shifted by the first xdigit. */
12329 xdig += 16; /* Use uppercase hex. */
12332 /* Find the first non-zero xdigit. */
12333 for (v = vhex; v < vend; v++) {
12341 U8* vlnz = NULL; /* The last non-zero. */
12343 /* Find the last non-zero xdigit. */
12344 for (v = vend - 1; v >= vhex; v--) {
12351 #if NVSIZE == DOUBLESIZE
12357 if ((SSize_t)(precis + 1) < vend - vhex) {
12360 v = vhex + precis + 1;
12361 /* Round away from zero: if the tail
12362 * beyond the precis xdigits is equal to
12363 * or greater than 0x8000... */
12365 if (!round && *v == 0x8) {
12366 for (v++; v < vend; v++) {
12374 for (v = vhex + precis; v >= vhex; v--) {
12381 /* If the carry goes all the way to
12382 * the front, we need to output
12383 * a single '1'. This goes against
12384 * the "xdigit and then radix"
12385 * but since this is "cannot happen"
12386 * category, that is probably good. */
12391 /* The new effective "last non zero". */
12392 vlnz = vhex + precis;
12395 zerotail = precis - (vlnz - vhex);
12402 /* The radix is always output after the first
12403 * non-zero xdigit, or if alt. */
12404 if (vfnz < vlnz || alt) {
12405 #ifndef USE_LOCALE_NUMERIC
12408 STORE_LC_NUMERIC_SET_TO_NEEDED();
12409 if (PL_numeric_radix_sv && IN_LC(LC_NUMERIC)) {
12411 const char* r = SvPV(PL_numeric_radix_sv, n);
12412 Copy(r, p, n, char);
12418 RESTORE_LC_NUMERIC();
12433 elen = p - PL_efloatbuf;
12434 elen += my_snprintf(p, PL_efloatsize - elen,
12435 "%c%+d", lower ? 'p' : 'P',
12438 if (elen < width) {
12440 /* Pad the back with spaces. */
12441 memset(PL_efloatbuf + elen, ' ', width - elen);
12443 else if (fill == '0') {
12444 /* Insert the zeros between the "0x" and
12445 * the digits, otherwise we end up with
12447 STRLEN nzero = width - elen;
12448 char* zerox = PL_efloatbuf + 2;
12449 Move(zerox, zerox + nzero, elen - 2, char);
12450 memset(zerox, fill, nzero);
12453 /* Move it to the right. */
12454 Move(PL_efloatbuf, PL_efloatbuf + width - elen,
12456 /* Pad the front with spaces. */
12457 memset(PL_efloatbuf, ' ', width - elen);
12463 elen = S_infnan_2pv(nv, PL_efloatbuf, PL_efloatsize, plus);
12465 /* Not affecting infnan output: precision, alt, fill. */
12466 if (elen < width) {
12468 /* Pack the back with spaces. */
12469 memset(PL_efloatbuf + elen, ' ', width - elen);
12471 /* Move it to the right. */
12472 Move(PL_efloatbuf, PL_efloatbuf + width - elen,
12474 /* Pad the front with spaces. */
12475 memset(PL_efloatbuf, ' ', width - elen);
12483 char *ptr = ebuf + sizeof ebuf;
12486 #if defined(USE_QUADMATH)
12487 if (intsize == 'q') {
12491 /* FIXME: what to do if HAS_LONG_DOUBLE but not PERL_PRIfldbl? */
12492 #elif defined(HAS_LONG_DOUBLE) && defined(PERL_PRIfldbl)
12493 /* Note that this is HAS_LONG_DOUBLE and PERL_PRIfldbl,
12494 * not USE_LONG_DOUBLE and NVff. In other words,
12495 * this needs to work without USE_LONG_DOUBLE. */
12496 if (intsize == 'q') {
12497 /* Copy the one or more characters in a long double
12498 * format before the 'base' ([efgEFG]) character to
12499 * the format string. */
12500 static char const ldblf[] = PERL_PRIfldbl;
12501 char const *p = ldblf + sizeof(ldblf) - 3;
12502 while (p >= ldblf) { *--ptr = *p--; }
12507 do { *--ptr = '0' + (base % 10); } while (base /= 10);
12512 do { *--ptr = '0' + (base % 10); } while (base /= 10);
12524 /* No taint. Otherwise we are in the strange situation
12525 * where printf() taints but print($float) doesn't.
12528 STORE_LC_NUMERIC_SET_TO_NEEDED();
12530 /* hopefully the above makes ptr a very constrained format
12531 * that is safe to use, even though it's not literal */
12532 GCC_DIAG_IGNORE(-Wformat-nonliteral);
12533 #ifdef USE_QUADMATH
12535 const char* qfmt = quadmath_format_single(ptr);
12537 Perl_croak_nocontext("panic: quadmath invalid format \"%s\"", ptr);
12538 elen = quadmath_snprintf(PL_efloatbuf, PL_efloatsize,
12540 if ((IV)elen == -1)
12541 Perl_croak_nocontext("panic: quadmath_snprintf failed, format \"%s|'", qfmt);
12545 #elif defined(HAS_LONG_DOUBLE)
12546 elen = ((intsize == 'q')
12547 ? my_snprintf(PL_efloatbuf, PL_efloatsize, ptr, fv)
12548 : my_snprintf(PL_efloatbuf, PL_efloatsize, ptr, (double)fv));
12550 elen = my_sprintf(PL_efloatbuf, ptr, fv);
12556 eptr = PL_efloatbuf;
12557 assert((IV)elen > 0); /* here zero elen is bad */
12559 #ifdef USE_LOCALE_NUMERIC
12560 /* If the decimal point character in the string is UTF-8, make the
12562 if (PL_numeric_radix_sv && SvUTF8(PL_numeric_radix_sv)
12563 && instr(eptr, SvPVX_const(PL_numeric_radix_sv)))
12576 i = SvCUR(sv) - origlen;
12579 case 'c': *(va_arg(*args, char*)) = i; break;
12580 case 'h': *(va_arg(*args, short*)) = i; break;
12581 default: *(va_arg(*args, int*)) = i; break;
12582 case 'l': *(va_arg(*args, long*)) = i; break;
12583 case 'V': *(va_arg(*args, IV*)) = i; break;
12584 case 'z': *(va_arg(*args, SSize_t*)) = i; break;
12585 #ifdef HAS_PTRDIFF_T
12586 case 't': *(va_arg(*args, ptrdiff_t*)) = i; break;
12589 case 'j': *(va_arg(*args, intmax_t*)) = i; break;
12593 *(va_arg(*args, Quad_t*)) = i; break;
12600 sv_setuv_mg(argsv, has_utf8 ? (UV)sv_len_utf8(sv) : (UV)i);
12601 continue; /* not "break" */
12608 && (PL_op->op_type == OP_PRTF || PL_op->op_type == OP_SPRINTF)
12609 && ckWARN(WARN_PRINTF))
12611 SV * const msg = sv_newmortal();
12612 Perl_sv_setpvf(aTHX_ msg, "Invalid conversion in %sprintf: ",
12613 (PL_op->op_type == OP_PRTF) ? "" : "s");
12614 if (fmtstart < patend) {
12615 const char * const fmtend = q < patend ? q : patend;
12617 sv_catpvs(msg, "\"%");
12618 for (f = fmtstart; f < fmtend; f++) {
12620 sv_catpvn_nomg(msg, f, 1);
12622 Perl_sv_catpvf(aTHX_ msg,
12623 "\\%03"UVof, (UV)*f & 0xFF);
12626 sv_catpvs(msg, "\"");
12628 sv_catpvs(msg, "end of string");
12630 Perl_warner(aTHX_ packWARN(WARN_PRINTF), "%"SVf, SVfARG(msg)); /* yes, this is reentrant */
12633 /* output mangled stuff ... */
12639 /* ... right here, because formatting flags should not apply */
12640 SvGROW(sv, SvCUR(sv) + elen + 1);
12642 Copy(eptr, p, elen, char);
12645 SvCUR_set(sv, p - SvPVX_const(sv));
12647 continue; /* not "break" */
12650 if (is_utf8 != has_utf8) {
12653 sv_utf8_upgrade(sv);
12656 const STRLEN old_elen = elen;
12657 SV * const nsv = newSVpvn_flags(eptr, elen, SVs_TEMP);
12658 sv_utf8_upgrade(nsv);
12659 eptr = SvPVX_const(nsv);
12662 if (width) { /* fudge width (can't fudge elen) */
12663 width += elen - old_elen;
12669 assert((IV)elen >= 0); /* here zero elen is fine */
12670 have = esignlen + zeros + elen;
12672 croak_memory_wrap();
12674 need = (have > width ? have : width);
12677 if (need >= (((STRLEN)~0) - SvCUR(sv) - dotstrlen - 1))
12678 croak_memory_wrap();
12679 SvGROW(sv, SvCUR(sv) + need + dotstrlen + 1);
12681 if (esignlen && fill == '0') {
12683 for (i = 0; i < (int)esignlen; i++)
12684 *p++ = esignbuf[i];
12686 if (gap && !left) {
12687 memset(p, fill, gap);
12690 if (esignlen && fill != '0') {
12692 for (i = 0; i < (int)esignlen; i++)
12693 *p++ = esignbuf[i];
12697 for (i = zeros; i; i--)
12701 Copy(eptr, p, elen, char);
12705 memset(p, ' ', gap);
12710 Copy(dotstr, p, dotstrlen, char);
12714 vectorize = FALSE; /* done iterating over vecstr */
12721 SvCUR_set(sv, p - SvPVX_const(sv));
12728 /* Now that we've consumed all our printf format arguments (svix)
12729 * do we have things left on the stack that we didn't use?
12731 if (!no_redundant_warning && svmax >= svix + 1 && ckWARN(WARN_REDUNDANT)) {
12732 Perl_warner(aTHX_ packWARN(WARN_REDUNDANT), "Redundant argument in %s",
12733 PL_op ? OP_DESC(PL_op) : "sv_vcatpvfn()");
12738 RESTORE_LC_NUMERIC(); /* Done outside loop, so don't have to save/restore
12742 /* =========================================================================
12744 =head1 Cloning an interpreter
12748 All the macros and functions in this section are for the private use of
12749 the main function, perl_clone().
12751 The foo_dup() functions make an exact copy of an existing foo thingy.
12752 During the course of a cloning, a hash table is used to map old addresses
12753 to new addresses. The table is created and manipulated with the
12754 ptr_table_* functions.
12756 * =========================================================================*/
12759 #if defined(USE_ITHREADS)
12761 /* XXX Remove this so it doesn't have to go thru the macro and return for nothing */
12762 #ifndef GpREFCNT_inc
12763 # define GpREFCNT_inc(gp) ((gp) ? (++(gp)->gp_refcnt, (gp)) : (GP*)NULL)
12767 /* Certain cases in Perl_ss_dup have been merged, by relying on the fact
12768 that currently av_dup, gv_dup and hv_dup are the same as sv_dup.
12769 If this changes, please unmerge ss_dup.
12770 Likewise, sv_dup_inc_multiple() relies on this fact. */
12771 #define sv_dup_inc_NN(s,t) SvREFCNT_inc_NN(sv_dup_inc(s,t))
12772 #define av_dup(s,t) MUTABLE_AV(sv_dup((const SV *)s,t))
12773 #define av_dup_inc(s,t) MUTABLE_AV(sv_dup_inc((const SV *)s,t))
12774 #define hv_dup(s,t) MUTABLE_HV(sv_dup((const SV *)s,t))
12775 #define hv_dup_inc(s,t) MUTABLE_HV(sv_dup_inc((const SV *)s,t))
12776 #define cv_dup(s,t) MUTABLE_CV(sv_dup((const SV *)s,t))
12777 #define cv_dup_inc(s,t) MUTABLE_CV(sv_dup_inc((const SV *)s,t))
12778 #define io_dup(s,t) MUTABLE_IO(sv_dup((const SV *)s,t))
12779 #define io_dup_inc(s,t) MUTABLE_IO(sv_dup_inc((const SV *)s,t))
12780 #define gv_dup(s,t) MUTABLE_GV(sv_dup((const SV *)s,t))
12781 #define gv_dup_inc(s,t) MUTABLE_GV(sv_dup_inc((const SV *)s,t))
12782 #define SAVEPV(p) ((p) ? savepv(p) : NULL)
12783 #define SAVEPVN(p,n) ((p) ? savepvn(p,n) : NULL)
12785 /* clone a parser */
12788 Perl_parser_dup(pTHX_ const yy_parser *const proto, CLONE_PARAMS *const param)
12792 PERL_ARGS_ASSERT_PARSER_DUP;
12797 /* look for it in the table first */
12798 parser = (yy_parser *)ptr_table_fetch(PL_ptr_table, proto);
12802 /* create anew and remember what it is */
12803 Newxz(parser, 1, yy_parser);
12804 ptr_table_store(PL_ptr_table, proto, parser);
12806 /* XXX these not yet duped */
12807 parser->old_parser = NULL;
12808 parser->stack = NULL;
12810 parser->stack_size = 0;
12811 /* XXX parser->stack->state = 0; */
12813 /* XXX eventually, just Copy() most of the parser struct ? */
12815 parser->lex_brackets = proto->lex_brackets;
12816 parser->lex_casemods = proto->lex_casemods;
12817 parser->lex_brackstack = savepvn(proto->lex_brackstack,
12818 (proto->lex_brackets < 120 ? 120 : proto->lex_brackets));
12819 parser->lex_casestack = savepvn(proto->lex_casestack,
12820 (proto->lex_casemods < 12 ? 12 : proto->lex_casemods));
12821 parser->lex_defer = proto->lex_defer;
12822 parser->lex_dojoin = proto->lex_dojoin;
12823 parser->lex_formbrack = proto->lex_formbrack;
12824 parser->lex_inpat = proto->lex_inpat;
12825 parser->lex_inwhat = proto->lex_inwhat;
12826 parser->lex_op = proto->lex_op;
12827 parser->lex_repl = sv_dup_inc(proto->lex_repl, param);
12828 parser->lex_starts = proto->lex_starts;
12829 parser->lex_stuff = sv_dup_inc(proto->lex_stuff, param);
12830 parser->multi_close = proto->multi_close;
12831 parser->multi_open = proto->multi_open;
12832 parser->multi_start = proto->multi_start;
12833 parser->multi_end = proto->multi_end;
12834 parser->preambled = proto->preambled;
12835 parser->sublex_info = proto->sublex_info; /* XXX not quite right */
12836 parser->linestr = sv_dup_inc(proto->linestr, param);
12837 parser->expect = proto->expect;
12838 parser->copline = proto->copline;
12839 parser->last_lop_op = proto->last_lop_op;
12840 parser->lex_state = proto->lex_state;
12841 parser->rsfp = fp_dup(proto->rsfp, '<', param);
12842 /* rsfp_filters entries have fake IoDIRP() */
12843 parser->rsfp_filters= av_dup_inc(proto->rsfp_filters, param);
12844 parser->in_my = proto->in_my;
12845 parser->in_my_stash = hv_dup(proto->in_my_stash, param);
12846 parser->error_count = proto->error_count;
12849 parser->linestr = sv_dup_inc(proto->linestr, param);
12852 char * const ols = SvPVX(proto->linestr);
12853 char * const ls = SvPVX(parser->linestr);
12855 parser->bufptr = ls + (proto->bufptr >= ols ?
12856 proto->bufptr - ols : 0);
12857 parser->oldbufptr = ls + (proto->oldbufptr >= ols ?
12858 proto->oldbufptr - ols : 0);
12859 parser->oldoldbufptr= ls + (proto->oldoldbufptr >= ols ?
12860 proto->oldoldbufptr - ols : 0);
12861 parser->linestart = ls + (proto->linestart >= ols ?
12862 proto->linestart - ols : 0);
12863 parser->last_uni = ls + (proto->last_uni >= ols ?
12864 proto->last_uni - ols : 0);
12865 parser->last_lop = ls + (proto->last_lop >= ols ?
12866 proto->last_lop - ols : 0);
12868 parser->bufend = ls + SvCUR(parser->linestr);
12871 Copy(proto->tokenbuf, parser->tokenbuf, 256, char);
12874 Copy(proto->nextval, parser->nextval, 5, YYSTYPE);
12875 Copy(proto->nexttype, parser->nexttype, 5, I32);
12876 parser->nexttoke = proto->nexttoke;
12878 /* XXX should clone saved_curcop here, but we aren't passed
12879 * proto_perl; so do it in perl_clone_using instead */
12885 /* duplicate a file handle */
12888 Perl_fp_dup(pTHX_ PerlIO *const fp, const char type, CLONE_PARAMS *const param)
12892 PERL_ARGS_ASSERT_FP_DUP;
12893 PERL_UNUSED_ARG(type);
12896 return (PerlIO*)NULL;
12898 /* look for it in the table first */
12899 ret = (PerlIO*)ptr_table_fetch(PL_ptr_table, fp);
12903 /* create anew and remember what it is */
12904 ret = PerlIO_fdupopen(aTHX_ fp, param, PERLIO_DUP_CLONE);
12905 ptr_table_store(PL_ptr_table, fp, ret);
12909 /* duplicate a directory handle */
12912 Perl_dirp_dup(pTHX_ DIR *const dp, CLONE_PARAMS *const param)
12916 #if defined(HAS_FCHDIR) && defined(HAS_TELLDIR) && defined(HAS_SEEKDIR)
12918 const Direntry_t *dirent;
12919 char smallbuf[256];
12925 PERL_UNUSED_CONTEXT;
12926 PERL_ARGS_ASSERT_DIRP_DUP;
12931 /* look for it in the table first */
12932 ret = (DIR*)ptr_table_fetch(PL_ptr_table, dp);
12936 #if defined(HAS_FCHDIR) && defined(HAS_TELLDIR) && defined(HAS_SEEKDIR)
12938 PERL_UNUSED_ARG(param);
12942 /* open the current directory (so we can switch back) */
12943 if (!(pwd = PerlDir_open("."))) return (DIR *)NULL;
12945 /* chdir to our dir handle and open the present working directory */
12946 if (fchdir(my_dirfd(dp)) < 0 || !(ret = PerlDir_open("."))) {
12947 PerlDir_close(pwd);
12948 return (DIR *)NULL;
12950 /* Now we should have two dir handles pointing to the same dir. */
12952 /* Be nice to the calling code and chdir back to where we were. */
12953 /* XXX If this fails, then what? */
12954 PERL_UNUSED_RESULT(fchdir(my_dirfd(pwd)));
12956 /* We have no need of the pwd handle any more. */
12957 PerlDir_close(pwd);
12960 # define d_namlen(d) (d)->d_namlen
12962 # define d_namlen(d) strlen((d)->d_name)
12964 /* Iterate once through dp, to get the file name at the current posi-
12965 tion. Then step back. */
12966 pos = PerlDir_tell(dp);
12967 if ((dirent = PerlDir_read(dp))) {
12968 len = d_namlen(dirent);
12969 if (len <= sizeof smallbuf) name = smallbuf;
12970 else Newx(name, len, char);
12971 Move(dirent->d_name, name, len, char);
12973 PerlDir_seek(dp, pos);
12975 /* Iterate through the new dir handle, till we find a file with the
12977 if (!dirent) /* just before the end */
12979 pos = PerlDir_tell(ret);
12980 if (PerlDir_read(ret)) continue; /* not there yet */
12981 PerlDir_seek(ret, pos); /* step back */
12985 const long pos0 = PerlDir_tell(ret);
12987 pos = PerlDir_tell(ret);
12988 if ((dirent = PerlDir_read(ret))) {
12989 if (len == (STRLEN)d_namlen(dirent)
12990 && memEQ(name, dirent->d_name, len)) {
12992 PerlDir_seek(ret, pos); /* step back */
12995 /* else we are not there yet; keep iterating */
12997 else { /* This is not meant to happen. The best we can do is
12998 reset the iterator to the beginning. */
12999 PerlDir_seek(ret, pos0);
13006 if (name && name != smallbuf)
13011 ret = win32_dirp_dup(dp, param);
13014 /* pop it in the pointer table */
13016 ptr_table_store(PL_ptr_table, dp, ret);
13021 /* duplicate a typeglob */
13024 Perl_gp_dup(pTHX_ GP *const gp, CLONE_PARAMS *const param)
13028 PERL_ARGS_ASSERT_GP_DUP;
13032 /* look for it in the table first */
13033 ret = (GP*)ptr_table_fetch(PL_ptr_table, gp);
13037 /* create anew and remember what it is */
13039 ptr_table_store(PL_ptr_table, gp, ret);
13042 /* ret->gp_refcnt must be 0 before any other dups are called. We're relying
13043 on Newxz() to do this for us. */
13044 ret->gp_sv = sv_dup_inc(gp->gp_sv, param);
13045 ret->gp_io = io_dup_inc(gp->gp_io, param);
13046 ret->gp_form = cv_dup_inc(gp->gp_form, param);
13047 ret->gp_av = av_dup_inc(gp->gp_av, param);
13048 ret->gp_hv = hv_dup_inc(gp->gp_hv, param);
13049 ret->gp_egv = gv_dup(gp->gp_egv, param);/* GvEGV is not refcounted */
13050 ret->gp_cv = cv_dup_inc(gp->gp_cv, param);
13051 ret->gp_cvgen = gp->gp_cvgen;
13052 ret->gp_line = gp->gp_line;
13053 ret->gp_file_hek = hek_dup(gp->gp_file_hek, param);
13057 /* duplicate a chain of magic */
13060 Perl_mg_dup(pTHX_ MAGIC *mg, CLONE_PARAMS *const param)
13062 MAGIC *mgret = NULL;
13063 MAGIC **mgprev_p = &mgret;
13065 PERL_ARGS_ASSERT_MG_DUP;
13067 for (; mg; mg = mg->mg_moremagic) {
13070 if ((param->flags & CLONEf_JOIN_IN)
13071 && mg->mg_type == PERL_MAGIC_backref)
13072 /* when joining, we let the individual SVs add themselves to
13073 * backref as needed. */
13076 Newx(nmg, 1, MAGIC);
13078 mgprev_p = &(nmg->mg_moremagic);
13080 /* There was a comment "XXX copy dynamic vtable?" but as we don't have
13081 dynamic vtables, I'm not sure why Sarathy wrote it. The comment dates
13082 from the original commit adding Perl_mg_dup() - revision 4538.
13083 Similarly there is the annotation "XXX random ptr?" next to the
13084 assignment to nmg->mg_ptr. */
13087 /* FIXME for plugins
13088 if (nmg->mg_type == PERL_MAGIC_qr) {
13089 nmg->mg_obj = MUTABLE_SV(CALLREGDUPE((REGEXP*)nmg->mg_obj, param));
13093 nmg->mg_obj = (nmg->mg_flags & MGf_REFCOUNTED)
13094 ? nmg->mg_type == PERL_MAGIC_backref
13095 /* The backref AV has its reference
13096 * count deliberately bumped by 1 */
13097 ? SvREFCNT_inc(av_dup_inc((const AV *)
13098 nmg->mg_obj, param))
13099 : sv_dup_inc(nmg->mg_obj, param)
13100 : sv_dup(nmg->mg_obj, param);
13102 if (nmg->mg_ptr && nmg->mg_type != PERL_MAGIC_regex_global) {
13103 if (nmg->mg_len > 0) {
13104 nmg->mg_ptr = SAVEPVN(nmg->mg_ptr, nmg->mg_len);
13105 if (nmg->mg_type == PERL_MAGIC_overload_table &&
13106 AMT_AMAGIC((AMT*)nmg->mg_ptr))
13108 AMT * const namtp = (AMT*)nmg->mg_ptr;
13109 sv_dup_inc_multiple((SV**)(namtp->table),
13110 (SV**)(namtp->table), NofAMmeth, param);
13113 else if (nmg->mg_len == HEf_SVKEY)
13114 nmg->mg_ptr = (char*)sv_dup_inc((const SV *)nmg->mg_ptr, param);
13116 if ((nmg->mg_flags & MGf_DUP) && nmg->mg_virtual && nmg->mg_virtual->svt_dup) {
13117 nmg->mg_virtual->svt_dup(aTHX_ nmg, param);
13123 #endif /* USE_ITHREADS */
13125 struct ptr_tbl_arena {
13126 struct ptr_tbl_arena *next;
13127 struct ptr_tbl_ent array[1023/3]; /* as ptr_tbl_ent has 3 pointers. */
13130 /* create a new pointer-mapping table */
13133 Perl_ptr_table_new(pTHX)
13136 PERL_UNUSED_CONTEXT;
13138 Newx(tbl, 1, PTR_TBL_t);
13139 tbl->tbl_max = 511;
13140 tbl->tbl_items = 0;
13141 tbl->tbl_arena = NULL;
13142 tbl->tbl_arena_next = NULL;
13143 tbl->tbl_arena_end = NULL;
13144 Newxz(tbl->tbl_ary, tbl->tbl_max + 1, PTR_TBL_ENT_t*);
13148 #define PTR_TABLE_HASH(ptr) \
13149 ((PTR2UV(ptr) >> 3) ^ (PTR2UV(ptr) >> (3 + 7)) ^ (PTR2UV(ptr) >> (3 + 17)))
13151 /* map an existing pointer using a table */
13153 STATIC PTR_TBL_ENT_t *
13154 S_ptr_table_find(PTR_TBL_t *const tbl, const void *const sv)
13156 PTR_TBL_ENT_t *tblent;
13157 const UV hash = PTR_TABLE_HASH(sv);
13159 PERL_ARGS_ASSERT_PTR_TABLE_FIND;
13161 tblent = tbl->tbl_ary[hash & tbl->tbl_max];
13162 for (; tblent; tblent = tblent->next) {
13163 if (tblent->oldval == sv)
13170 Perl_ptr_table_fetch(pTHX_ PTR_TBL_t *const tbl, const void *const sv)
13172 PTR_TBL_ENT_t const *const tblent = ptr_table_find(tbl, sv);
13174 PERL_ARGS_ASSERT_PTR_TABLE_FETCH;
13175 PERL_UNUSED_CONTEXT;
13177 return tblent ? tblent->newval : NULL;
13180 /* add a new entry to a pointer-mapping table 'tbl'. In hash terms, 'oldsv' is
13181 * the key; 'newsv' is the value. The names "old" and "new" are specific to
13182 * the core's typical use of ptr_tables in thread cloning. */
13185 Perl_ptr_table_store(pTHX_ PTR_TBL_t *const tbl, const void *const oldsv, void *const newsv)
13187 PTR_TBL_ENT_t *tblent = ptr_table_find(tbl, oldsv);
13189 PERL_ARGS_ASSERT_PTR_TABLE_STORE;
13190 PERL_UNUSED_CONTEXT;
13193 tblent->newval = newsv;
13195 const UV entry = PTR_TABLE_HASH(oldsv) & tbl->tbl_max;
13197 if (tbl->tbl_arena_next == tbl->tbl_arena_end) {
13198 struct ptr_tbl_arena *new_arena;
13200 Newx(new_arena, 1, struct ptr_tbl_arena);
13201 new_arena->next = tbl->tbl_arena;
13202 tbl->tbl_arena = new_arena;
13203 tbl->tbl_arena_next = new_arena->array;
13204 tbl->tbl_arena_end = C_ARRAY_END(new_arena->array);
13207 tblent = tbl->tbl_arena_next++;
13209 tblent->oldval = oldsv;
13210 tblent->newval = newsv;
13211 tblent->next = tbl->tbl_ary[entry];
13212 tbl->tbl_ary[entry] = tblent;
13214 if (tblent->next && tbl->tbl_items > tbl->tbl_max)
13215 ptr_table_split(tbl);
13219 /* double the hash bucket size of an existing ptr table */
13222 Perl_ptr_table_split(pTHX_ PTR_TBL_t *const tbl)
13224 PTR_TBL_ENT_t **ary = tbl->tbl_ary;
13225 const UV oldsize = tbl->tbl_max + 1;
13226 UV newsize = oldsize * 2;
13229 PERL_ARGS_ASSERT_PTR_TABLE_SPLIT;
13230 PERL_UNUSED_CONTEXT;
13232 Renew(ary, newsize, PTR_TBL_ENT_t*);
13233 Zero(&ary[oldsize], newsize-oldsize, PTR_TBL_ENT_t*);
13234 tbl->tbl_max = --newsize;
13235 tbl->tbl_ary = ary;
13236 for (i=0; i < oldsize; i++, ary++) {
13237 PTR_TBL_ENT_t **entp = ary;
13238 PTR_TBL_ENT_t *ent = *ary;
13239 PTR_TBL_ENT_t **curentp;
13242 curentp = ary + oldsize;
13244 if ((newsize & PTR_TABLE_HASH(ent->oldval)) != i) {
13246 ent->next = *curentp;
13256 /* remove all the entries from a ptr table */
13257 /* Deprecated - will be removed post 5.14 */
13260 Perl_ptr_table_clear(pTHX_ PTR_TBL_t *const tbl)
13262 PERL_UNUSED_CONTEXT;
13263 if (tbl && tbl->tbl_items) {
13264 struct ptr_tbl_arena *arena = tbl->tbl_arena;
13266 Zero(tbl->tbl_ary, tbl->tbl_max + 1, struct ptr_tbl_ent **);
13269 struct ptr_tbl_arena *next = arena->next;
13275 tbl->tbl_items = 0;
13276 tbl->tbl_arena = NULL;
13277 tbl->tbl_arena_next = NULL;
13278 tbl->tbl_arena_end = NULL;
13282 /* clear and free a ptr table */
13285 Perl_ptr_table_free(pTHX_ PTR_TBL_t *const tbl)
13287 struct ptr_tbl_arena *arena;
13289 PERL_UNUSED_CONTEXT;
13295 arena = tbl->tbl_arena;
13298 struct ptr_tbl_arena *next = arena->next;
13304 Safefree(tbl->tbl_ary);
13308 #if defined(USE_ITHREADS)
13311 Perl_rvpv_dup(pTHX_ SV *const dstr, const SV *const sstr, CLONE_PARAMS *const param)
13313 PERL_ARGS_ASSERT_RVPV_DUP;
13315 assert(!isREGEXP(sstr));
13317 if (SvWEAKREF(sstr)) {
13318 SvRV_set(dstr, sv_dup(SvRV_const(sstr), param));
13319 if (param->flags & CLONEf_JOIN_IN) {
13320 /* if joining, we add any back references individually rather
13321 * than copying the whole backref array */
13322 Perl_sv_add_backref(aTHX_ SvRV(dstr), dstr);
13326 SvRV_set(dstr, sv_dup_inc(SvRV_const(sstr), param));
13328 else if (SvPVX_const(sstr)) {
13329 /* Has something there */
13331 /* Normal PV - clone whole allocated space */
13332 SvPV_set(dstr, SAVEPVN(SvPVX_const(sstr), SvLEN(sstr)-1));
13333 /* sstr may not be that normal, but actually copy on write.
13334 But we are a true, independent SV, so: */
13338 /* Special case - not normally malloced for some reason */
13339 if (isGV_with_GP(sstr)) {
13340 /* Don't need to do anything here. */
13342 else if ((SvIsCOW(sstr))) {
13343 /* A "shared" PV - clone it as "shared" PV */
13345 HEK_KEY(hek_dup(SvSHARED_HEK_FROM_PV(SvPVX_const(sstr)),
13349 /* Some other special case - random pointer */
13350 SvPV_set(dstr, (char *) SvPVX_const(sstr));
13355 /* Copy the NULL */
13356 SvPV_set(dstr, NULL);
13360 /* duplicate a list of SVs. source and dest may point to the same memory. */
13362 S_sv_dup_inc_multiple(pTHX_ SV *const *source, SV **dest,
13363 SSize_t items, CLONE_PARAMS *const param)
13365 PERL_ARGS_ASSERT_SV_DUP_INC_MULTIPLE;
13367 while (items-- > 0) {
13368 *dest++ = sv_dup_inc(*source++, param);
13374 /* duplicate an SV of any type (including AV, HV etc) */
13377 S_sv_dup_common(pTHX_ const SV *const sstr, CLONE_PARAMS *const param)
13382 PERL_ARGS_ASSERT_SV_DUP_COMMON;
13384 if (SvTYPE(sstr) == (svtype)SVTYPEMASK) {
13385 #ifdef DEBUG_LEAKING_SCALARS_ABORT
13390 /* look for it in the table first */
13391 dstr = MUTABLE_SV(ptr_table_fetch(PL_ptr_table, sstr));
13395 if(param->flags & CLONEf_JOIN_IN) {
13396 /** We are joining here so we don't want do clone
13397 something that is bad **/
13398 if (SvTYPE(sstr) == SVt_PVHV) {
13399 const HEK * const hvname = HvNAME_HEK(sstr);
13401 /** don't clone stashes if they already exist **/
13402 dstr = MUTABLE_SV(gv_stashpvn(HEK_KEY(hvname), HEK_LEN(hvname),
13403 HEK_UTF8(hvname) ? SVf_UTF8 : 0));
13404 ptr_table_store(PL_ptr_table, sstr, dstr);
13408 else if (SvTYPE(sstr) == SVt_PVGV && !SvFAKE(sstr)) {
13409 HV *stash = GvSTASH(sstr);
13410 const HEK * hvname;
13411 if (stash && (hvname = HvNAME_HEK(stash))) {
13412 /** don't clone GVs if they already exist **/
13414 stash = gv_stashpvn(HEK_KEY(hvname), HEK_LEN(hvname),
13415 HEK_UTF8(hvname) ? SVf_UTF8 : 0);
13417 stash, GvNAME(sstr),
13423 if (svp && *svp && SvTYPE(*svp) == SVt_PVGV) {
13424 ptr_table_store(PL_ptr_table, sstr, *svp);
13431 /* create anew and remember what it is */
13434 #ifdef DEBUG_LEAKING_SCALARS
13435 dstr->sv_debug_optype = sstr->sv_debug_optype;
13436 dstr->sv_debug_line = sstr->sv_debug_line;
13437 dstr->sv_debug_inpad = sstr->sv_debug_inpad;
13438 dstr->sv_debug_parent = (SV*)sstr;
13439 FREE_SV_DEBUG_FILE(dstr);
13440 dstr->sv_debug_file = savesharedpv(sstr->sv_debug_file);
13443 ptr_table_store(PL_ptr_table, sstr, dstr);
13446 SvFLAGS(dstr) = SvFLAGS(sstr);
13447 SvFLAGS(dstr) &= ~SVf_OOK; /* don't propagate OOK hack */
13448 SvREFCNT(dstr) = 0; /* must be before any other dups! */
13451 if (SvANY(sstr) && PL_watch_pvx && SvPVX_const(sstr) == PL_watch_pvx)
13452 PerlIO_printf(Perl_debug_log, "watch at %p hit, found string \"%s\"\n",
13453 (void*)PL_watch_pvx, SvPVX_const(sstr));
13456 /* don't clone objects whose class has asked us not to */
13458 && ! (SvFLAGS(SvSTASH(sstr)) & SVphv_CLONEABLE))
13464 switch (SvTYPE(sstr)) {
13466 SvANY(dstr) = NULL;
13469 SET_SVANY_FOR_BODYLESS_IV(dstr);
13471 Perl_rvpv_dup(aTHX_ dstr, sstr, param);
13473 SvIV_set(dstr, SvIVX(sstr));
13477 #if NVSIZE <= IVSIZE
13478 SET_SVANY_FOR_BODYLESS_NV(dstr);
13480 SvANY(dstr) = new_XNV();
13482 SvNV_set(dstr, SvNVX(sstr));
13486 /* These are all the types that need complex bodies allocating. */
13488 const svtype sv_type = SvTYPE(sstr);
13489 const struct body_details *const sv_type_details
13490 = bodies_by_type + sv_type;
13494 Perl_croak(aTHX_ "Bizarre SvTYPE [%" IVdf "]", (IV)SvTYPE(sstr));
13510 assert(sv_type_details->body_size);
13511 if (sv_type_details->arena) {
13512 new_body_inline(new_body, sv_type);
13514 = (void*)((char*)new_body - sv_type_details->offset);
13516 new_body = new_NOARENA(sv_type_details);
13520 SvANY(dstr) = new_body;
13523 Copy(((char*)SvANY(sstr)) + sv_type_details->offset,
13524 ((char*)SvANY(dstr)) + sv_type_details->offset,
13525 sv_type_details->copy, char);
13527 Copy(((char*)SvANY(sstr)),
13528 ((char*)SvANY(dstr)),
13529 sv_type_details->body_size + sv_type_details->offset, char);
13532 if (sv_type != SVt_PVAV && sv_type != SVt_PVHV
13533 && !isGV_with_GP(dstr)
13535 && !(sv_type == SVt_PVIO && !(IoFLAGS(dstr) & IOf_FAKE_DIRP)))
13536 Perl_rvpv_dup(aTHX_ dstr, sstr, param);
13538 /* The Copy above means that all the source (unduplicated) pointers
13539 are now in the destination. We can check the flags and the
13540 pointers in either, but it's possible that there's less cache
13541 missing by always going for the destination.
13542 FIXME - instrument and check that assumption */
13543 if (sv_type >= SVt_PVMG) {
13545 SvMAGIC_set(dstr, mg_dup(SvMAGIC(dstr), param));
13546 if (SvOBJECT(dstr) && SvSTASH(dstr))
13547 SvSTASH_set(dstr, hv_dup_inc(SvSTASH(dstr), param));
13548 else SvSTASH_set(dstr, 0); /* don't copy DESTROY cache */
13551 /* The cast silences a GCC warning about unhandled types. */
13552 switch ((int)sv_type) {
13563 /* FIXME for plugins */
13564 dstr->sv_u.svu_rx = ((REGEXP *)dstr)->sv_any;
13565 re_dup_guts((REGEXP*) sstr, (REGEXP*) dstr, param);
13568 /* XXX LvTARGOFF sometimes holds PMOP* when DEBUGGING */
13569 if (LvTYPE(dstr) == 't') /* for tie: unrefcnted fake (SV**) */
13570 LvTARG(dstr) = dstr;
13571 else if (LvTYPE(dstr) == 'T') /* for tie: fake HE */
13572 LvTARG(dstr) = MUTABLE_SV(he_dup((HE*)LvTARG(dstr), 0, param));
13574 LvTARG(dstr) = sv_dup_inc(LvTARG(dstr), param);
13575 if (isREGEXP(sstr)) goto duprex;
13577 /* non-GP case already handled above */
13578 if(isGV_with_GP(sstr)) {
13579 GvNAME_HEK(dstr) = hek_dup(GvNAME_HEK(dstr), param);
13580 /* Don't call sv_add_backref here as it's going to be
13581 created as part of the magic cloning of the symbol
13582 table--unless this is during a join and the stash
13583 is not actually being cloned. */
13584 /* Danger Will Robinson - GvGP(dstr) isn't initialised
13585 at the point of this comment. */
13586 GvSTASH(dstr) = hv_dup(GvSTASH(dstr), param);
13587 if (param->flags & CLONEf_JOIN_IN)
13588 Perl_sv_add_backref(aTHX_ MUTABLE_SV(GvSTASH(dstr)), dstr);
13589 GvGP_set(dstr, gp_dup(GvGP(sstr), param));
13590 (void)GpREFCNT_inc(GvGP(dstr));
13594 /* PL_parser->rsfp_filters entries have fake IoDIRP() */
13595 if(IoFLAGS(dstr) & IOf_FAKE_DIRP) {
13596 /* I have no idea why fake dirp (rsfps)
13597 should be treated differently but otherwise
13598 we end up with leaks -- sky*/
13599 IoTOP_GV(dstr) = gv_dup_inc(IoTOP_GV(dstr), param);
13600 IoFMT_GV(dstr) = gv_dup_inc(IoFMT_GV(dstr), param);
13601 IoBOTTOM_GV(dstr) = gv_dup_inc(IoBOTTOM_GV(dstr), param);
13603 IoTOP_GV(dstr) = gv_dup(IoTOP_GV(dstr), param);
13604 IoFMT_GV(dstr) = gv_dup(IoFMT_GV(dstr), param);
13605 IoBOTTOM_GV(dstr) = gv_dup(IoBOTTOM_GV(dstr), param);
13606 if (IoDIRP(dstr)) {
13607 IoDIRP(dstr) = dirp_dup(IoDIRP(dstr), param);
13610 /* IoDIRP(dstr) is already a copy of IoDIRP(sstr) */
13612 IoIFP(dstr) = fp_dup(IoIFP(sstr), IoTYPE(dstr), param);
13614 if (IoOFP(dstr) == IoIFP(sstr))
13615 IoOFP(dstr) = IoIFP(dstr);
13617 IoOFP(dstr) = fp_dup(IoOFP(dstr), IoTYPE(dstr), param);
13618 IoTOP_NAME(dstr) = SAVEPV(IoTOP_NAME(dstr));
13619 IoFMT_NAME(dstr) = SAVEPV(IoFMT_NAME(dstr));
13620 IoBOTTOM_NAME(dstr) = SAVEPV(IoBOTTOM_NAME(dstr));
13623 /* avoid cloning an empty array */
13624 if (AvARRAY((const AV *)sstr) && AvFILLp((const AV *)sstr) >= 0) {
13625 SV **dst_ary, **src_ary;
13626 SSize_t items = AvFILLp((const AV *)sstr) + 1;
13628 src_ary = AvARRAY((const AV *)sstr);
13629 Newxz(dst_ary, AvMAX((const AV *)sstr)+1, SV*);
13630 ptr_table_store(PL_ptr_table, src_ary, dst_ary);
13631 AvARRAY(MUTABLE_AV(dstr)) = dst_ary;
13632 AvALLOC((const AV *)dstr) = dst_ary;
13633 if (AvREAL((const AV *)sstr)) {
13634 dst_ary = sv_dup_inc_multiple(src_ary, dst_ary, items,
13638 while (items-- > 0)
13639 *dst_ary++ = sv_dup(*src_ary++, param);
13641 items = AvMAX((const AV *)sstr) - AvFILLp((const AV *)sstr);
13642 while (items-- > 0) {
13647 AvARRAY(MUTABLE_AV(dstr)) = NULL;
13648 AvALLOC((const AV *)dstr) = (SV**)NULL;
13649 AvMAX( (const AV *)dstr) = -1;
13650 AvFILLp((const AV *)dstr) = -1;
13654 if (HvARRAY((const HV *)sstr)) {
13656 const bool sharekeys = !!HvSHAREKEYS(sstr);
13657 XPVHV * const dxhv = (XPVHV*)SvANY(dstr);
13658 XPVHV * const sxhv = (XPVHV*)SvANY(sstr);
13660 Newx(darray, PERL_HV_ARRAY_ALLOC_BYTES(dxhv->xhv_max+1)
13661 + (SvOOK(sstr) ? sizeof(struct xpvhv_aux) : 0),
13663 HvARRAY(dstr) = (HE**)darray;
13664 while (i <= sxhv->xhv_max) {
13665 const HE * const source = HvARRAY(sstr)[i];
13666 HvARRAY(dstr)[i] = source
13667 ? he_dup(source, sharekeys, param) : 0;
13671 const struct xpvhv_aux * const saux = HvAUX(sstr);
13672 struct xpvhv_aux * const daux = HvAUX(dstr);
13673 /* This flag isn't copied. */
13676 if (saux->xhv_name_count) {
13677 HEK ** const sname = saux->xhv_name_u.xhvnameu_names;
13679 = saux->xhv_name_count < 0
13680 ? -saux->xhv_name_count
13681 : saux->xhv_name_count;
13682 HEK **shekp = sname + count;
13684 Newx(daux->xhv_name_u.xhvnameu_names, count, HEK *);
13685 dhekp = daux->xhv_name_u.xhvnameu_names + count;
13686 while (shekp-- > sname) {
13688 *dhekp = hek_dup(*shekp, param);
13692 daux->xhv_name_u.xhvnameu_name
13693 = hek_dup(saux->xhv_name_u.xhvnameu_name,
13696 daux->xhv_name_count = saux->xhv_name_count;
13698 daux->xhv_fill_lazy = saux->xhv_fill_lazy;
13699 daux->xhv_aux_flags = saux->xhv_aux_flags;
13700 #ifdef PERL_HASH_RANDOMIZE_KEYS
13701 daux->xhv_rand = saux->xhv_rand;
13702 daux->xhv_last_rand = saux->xhv_last_rand;
13704 daux->xhv_riter = saux->xhv_riter;
13705 daux->xhv_eiter = saux->xhv_eiter
13706 ? he_dup(saux->xhv_eiter,
13707 cBOOL(HvSHAREKEYS(sstr)), param) : 0;
13708 /* backref array needs refcnt=2; see sv_add_backref */
13709 daux->xhv_backreferences =
13710 (param->flags & CLONEf_JOIN_IN)
13711 /* when joining, we let the individual GVs and
13712 * CVs add themselves to backref as
13713 * needed. This avoids pulling in stuff
13714 * that isn't required, and simplifies the
13715 * case where stashes aren't cloned back
13716 * if they already exist in the parent
13719 : saux->xhv_backreferences
13720 ? (SvTYPE(saux->xhv_backreferences) == SVt_PVAV)
13721 ? MUTABLE_AV(SvREFCNT_inc(
13722 sv_dup_inc((const SV *)
13723 saux->xhv_backreferences, param)))
13724 : MUTABLE_AV(sv_dup((const SV *)
13725 saux->xhv_backreferences, param))
13728 daux->xhv_mro_meta = saux->xhv_mro_meta
13729 ? mro_meta_dup(saux->xhv_mro_meta, param)
13732 /* Record stashes for possible cloning in Perl_clone(). */
13734 av_push(param->stashes, dstr);
13738 HvARRAY(MUTABLE_HV(dstr)) = NULL;
13741 if (!(param->flags & CLONEf_COPY_STACKS)) {
13746 /* NOTE: not refcounted */
13747 SvANY(MUTABLE_CV(dstr))->xcv_stash =
13748 hv_dup(CvSTASH(dstr), param);
13749 if ((param->flags & CLONEf_JOIN_IN) && CvSTASH(dstr))
13750 Perl_sv_add_backref(aTHX_ MUTABLE_SV(CvSTASH(dstr)), dstr);
13751 if (!CvISXSUB(dstr)) {
13753 CvROOT(dstr) = OpREFCNT_inc(CvROOT(dstr));
13755 CvSLABBED_off(dstr);
13756 } else if (CvCONST(dstr)) {
13757 CvXSUBANY(dstr).any_ptr =
13758 sv_dup_inc((const SV *)CvXSUBANY(dstr).any_ptr, param);
13760 assert(!CvSLABBED(dstr));
13761 if (CvDYNFILE(dstr)) CvFILE(dstr) = SAVEPV(CvFILE(dstr));
13763 SvANY((CV *)dstr)->xcv_gv_u.xcv_hek =
13764 hek_dup(CvNAME_HEK((CV *)sstr), param);
13765 /* don't dup if copying back - CvGV isn't refcounted, so the
13766 * duped GV may never be freed. A bit of a hack! DAPM */
13768 SvANY(MUTABLE_CV(dstr))->xcv_gv_u.xcv_gv =
13770 ? gv_dup_inc(CvGV(sstr), param)
13771 : (param->flags & CLONEf_JOIN_IN)
13773 : gv_dup(CvGV(sstr), param);
13775 if (!CvISXSUB(sstr)) {
13776 PADLIST * padlist = CvPADLIST(sstr);
13778 padlist = padlist_dup(padlist, param);
13779 CvPADLIST_set(dstr, padlist);
13781 /* unthreaded perl can't sv_dup so we dont support unthreaded's CvHSCXT */
13782 PoisonPADLIST(dstr);
13785 CvWEAKOUTSIDE(sstr)
13786 ? cv_dup( CvOUTSIDE(dstr), param)
13787 : cv_dup_inc(CvOUTSIDE(dstr), param);
13797 Perl_sv_dup_inc(pTHX_ const SV *const sstr, CLONE_PARAMS *const param)
13799 PERL_ARGS_ASSERT_SV_DUP_INC;
13800 return sstr ? SvREFCNT_inc(sv_dup_common(sstr, param)) : NULL;
13804 Perl_sv_dup(pTHX_ const SV *const sstr, CLONE_PARAMS *const param)
13806 SV *dstr = sstr ? sv_dup_common(sstr, param) : NULL;
13807 PERL_ARGS_ASSERT_SV_DUP;
13809 /* Track every SV that (at least initially) had a reference count of 0.
13810 We need to do this by holding an actual reference to it in this array.
13811 If we attempt to cheat, turn AvREAL_off(), and store only pointers
13812 (akin to the stashes hash, and the perl stack), we come unstuck if
13813 a weak reference (or other SV legitimately SvREFCNT() == 0 for this
13814 thread) is manipulated in a CLONE method, because CLONE runs before the
13815 unreferenced array is walked to find SVs still with SvREFCNT() == 0
13816 (and fix things up by giving each a reference via the temps stack).
13817 Instead, during CLONE, if the 0-referenced SV has SvREFCNT_inc() and
13818 then SvREFCNT_dec(), it will be cleaned up (and added to the free list)
13819 before the walk of unreferenced happens and a reference to that is SV
13820 added to the temps stack. At which point we have the same SV considered
13821 to be in use, and free to be re-used. Not good.
13823 if (dstr && !(param->flags & CLONEf_COPY_STACKS) && !SvREFCNT(dstr)) {
13824 assert(param->unreferenced);
13825 av_push(param->unreferenced, SvREFCNT_inc(dstr));
13831 /* duplicate a context */
13834 Perl_cx_dup(pTHX_ PERL_CONTEXT *cxs, I32 ix, I32 max, CLONE_PARAMS* param)
13836 PERL_CONTEXT *ncxs;
13838 PERL_ARGS_ASSERT_CX_DUP;
13841 return (PERL_CONTEXT*)NULL;
13843 /* look for it in the table first */
13844 ncxs = (PERL_CONTEXT*)ptr_table_fetch(PL_ptr_table, cxs);
13848 /* create anew and remember what it is */
13849 Newx(ncxs, max + 1, PERL_CONTEXT);
13850 ptr_table_store(PL_ptr_table, cxs, ncxs);
13851 Copy(cxs, ncxs, max + 1, PERL_CONTEXT);
13854 PERL_CONTEXT * const ncx = &ncxs[ix];
13855 if (CxTYPE(ncx) == CXt_SUBST) {
13856 Perl_croak(aTHX_ "Cloning substitution context is unimplemented");
13859 ncx->blk_oldcop = (COP*)any_dup(ncx->blk_oldcop, param->proto_perl);
13860 switch (CxTYPE(ncx)) {
13862 ncx->blk_sub.cv = (ncx->blk_sub.olddepth == 0
13863 ? cv_dup_inc(ncx->blk_sub.cv, param)
13864 : cv_dup(ncx->blk_sub.cv,param));
13865 if(CxHASARGS(ncx)){
13866 ncx->blk_sub.argarray = av_dup_inc(ncx->blk_sub.argarray,param);
13867 ncx->blk_sub.savearray = av_dup_inc(ncx->blk_sub.savearray,param);
13869 ncx->blk_sub.argarray = NULL;
13870 ncx->blk_sub.savearray = NULL;
13872 ncx->blk_sub.oldcomppad = (PAD*)ptr_table_fetch(PL_ptr_table,
13873 ncx->blk_sub.oldcomppad);
13876 ncx->blk_eval.old_namesv = sv_dup_inc(ncx->blk_eval.old_namesv,
13878 ncx->blk_eval.cur_text = sv_dup(ncx->blk_eval.cur_text, param);
13879 ncx->blk_eval.cv = cv_dup(ncx->blk_eval.cv, param);
13881 case CXt_LOOP_LAZYSV:
13882 ncx->blk_loop.state_u.lazysv.end
13883 = sv_dup_inc(ncx->blk_loop.state_u.lazysv.end, param);
13884 /* Fallthrough: duplicate lazysv.cur by using the ary.ary
13885 duplication code instead.
13886 We are taking advantage of (1) av_dup_inc and sv_dup_inc
13887 actually being the same function, and (2) order
13888 equivalence of the two unions.
13889 We can assert the later [but only at run time :-(] */
13890 assert ((void *) &ncx->blk_loop.state_u.ary.ary ==
13891 (void *) &ncx->blk_loop.state_u.lazysv.cur);
13894 ncx->blk_loop.state_u.ary.ary
13895 = av_dup_inc(ncx->blk_loop.state_u.ary.ary, param);
13897 case CXt_LOOP_LAZYIV:
13898 case CXt_LOOP_PLAIN:
13899 /* code common to all CXt_LOOP_* types */
13900 if (CxPADLOOP(ncx)) {
13901 ncx->blk_loop.itervar_u.oldcomppad
13902 = (PAD*)ptr_table_fetch(PL_ptr_table,
13903 ncx->blk_loop.itervar_u.oldcomppad);
13905 ncx->blk_loop.itervar_u.gv
13906 = gv_dup((const GV *)ncx->blk_loop.itervar_u.gv,
13911 ncx->blk_format.cv = cv_dup(ncx->blk_format.cv, param);
13912 ncx->blk_format.gv = gv_dup(ncx->blk_format.gv, param);
13913 ncx->blk_format.dfoutgv = gv_dup_inc(ncx->blk_format.dfoutgv,
13928 /* duplicate a stack info structure */
13931 Perl_si_dup(pTHX_ PERL_SI *si, CLONE_PARAMS* param)
13935 PERL_ARGS_ASSERT_SI_DUP;
13938 return (PERL_SI*)NULL;
13940 /* look for it in the table first */
13941 nsi = (PERL_SI*)ptr_table_fetch(PL_ptr_table, si);
13945 /* create anew and remember what it is */
13946 Newxz(nsi, 1, PERL_SI);
13947 ptr_table_store(PL_ptr_table, si, nsi);
13949 nsi->si_stack = av_dup_inc(si->si_stack, param);
13950 nsi->si_cxix = si->si_cxix;
13951 nsi->si_cxmax = si->si_cxmax;
13952 nsi->si_cxstack = cx_dup(si->si_cxstack, si->si_cxix, si->si_cxmax, param);
13953 nsi->si_type = si->si_type;
13954 nsi->si_prev = si_dup(si->si_prev, param);
13955 nsi->si_next = si_dup(si->si_next, param);
13956 nsi->si_markoff = si->si_markoff;
13961 #define POPINT(ss,ix) ((ss)[--(ix)].any_i32)
13962 #define TOPINT(ss,ix) ((ss)[ix].any_i32)
13963 #define POPLONG(ss,ix) ((ss)[--(ix)].any_long)
13964 #define TOPLONG(ss,ix) ((ss)[ix].any_long)
13965 #define POPIV(ss,ix) ((ss)[--(ix)].any_iv)
13966 #define TOPIV(ss,ix) ((ss)[ix].any_iv)
13967 #define POPUV(ss,ix) ((ss)[--(ix)].any_uv)
13968 #define TOPUV(ss,ix) ((ss)[ix].any_uv)
13969 #define POPBOOL(ss,ix) ((ss)[--(ix)].any_bool)
13970 #define TOPBOOL(ss,ix) ((ss)[ix].any_bool)
13971 #define POPPTR(ss,ix) ((ss)[--(ix)].any_ptr)
13972 #define TOPPTR(ss,ix) ((ss)[ix].any_ptr)
13973 #define POPDPTR(ss,ix) ((ss)[--(ix)].any_dptr)
13974 #define TOPDPTR(ss,ix) ((ss)[ix].any_dptr)
13975 #define POPDXPTR(ss,ix) ((ss)[--(ix)].any_dxptr)
13976 #define TOPDXPTR(ss,ix) ((ss)[ix].any_dxptr)
13979 #define pv_dup_inc(p) SAVEPV(p)
13980 #define pv_dup(p) SAVEPV(p)
13981 #define svp_dup_inc(p,pp) any_dup(p,pp)
13983 /* map any object to the new equivent - either something in the
13984 * ptr table, or something in the interpreter structure
13988 Perl_any_dup(pTHX_ void *v, const PerlInterpreter *proto_perl)
13992 PERL_ARGS_ASSERT_ANY_DUP;
13995 return (void*)NULL;
13997 /* look for it in the table first */
13998 ret = ptr_table_fetch(PL_ptr_table, v);
14002 /* see if it is part of the interpreter structure */
14003 if (v >= (void*)proto_perl && v < (void*)(proto_perl+1))
14004 ret = (void*)(((char*)aTHX) + (((char*)v) - (char*)proto_perl));
14012 /* duplicate the save stack */
14015 Perl_ss_dup(pTHX_ PerlInterpreter *proto_perl, CLONE_PARAMS* param)
14018 ANY * const ss = proto_perl->Isavestack;
14019 const I32 max = proto_perl->Isavestack_max;
14020 I32 ix = proto_perl->Isavestack_ix;
14033 void (*dptr) (void*);
14034 void (*dxptr) (pTHX_ void*);
14036 PERL_ARGS_ASSERT_SS_DUP;
14038 Newxz(nss, max, ANY);
14041 const UV uv = POPUV(ss,ix);
14042 const U8 type = (U8)uv & SAVE_MASK;
14044 TOPUV(nss,ix) = uv;
14046 case SAVEt_CLEARSV:
14047 case SAVEt_CLEARPADRANGE:
14049 case SAVEt_HELEM: /* hash element */
14050 case SAVEt_SV: /* scalar reference */
14051 sv = (const SV *)POPPTR(ss,ix);
14052 TOPPTR(nss,ix) = SvREFCNT_inc(sv_dup_inc(sv, param));
14054 case SAVEt_ITEM: /* normal string */
14055 case SAVEt_GVSV: /* scalar slot in GV */
14056 sv = (const SV *)POPPTR(ss,ix);
14057 TOPPTR(nss,ix) = sv_dup_inc(sv, param);
14058 if (type == SAVEt_SV)
14062 case SAVEt_MORTALIZESV:
14063 case SAVEt_READONLY_OFF:
14064 sv = (const SV *)POPPTR(ss,ix);
14065 TOPPTR(nss,ix) = sv_dup_inc(sv, param);
14067 case SAVEt_FREEPADNAME:
14068 ptr = POPPTR(ss,ix);
14069 TOPPTR(nss,ix) = padname_dup((PADNAME *)ptr, param);
14070 PadnameREFCNT((PADNAME *)TOPPTR(nss,ix))++;
14072 case SAVEt_SHARED_PVREF: /* char* in shared space */
14073 c = (char*)POPPTR(ss,ix);
14074 TOPPTR(nss,ix) = savesharedpv(c);
14075 ptr = POPPTR(ss,ix);
14076 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14078 case SAVEt_GENERIC_SVREF: /* generic sv */
14079 case SAVEt_SVREF: /* scalar reference */
14080 sv = (const SV *)POPPTR(ss,ix);
14081 TOPPTR(nss,ix) = sv_dup_inc(sv, param);
14082 if (type == SAVEt_SVREF)
14083 SvREFCNT_inc_simple_void((SV *)TOPPTR(nss,ix));
14084 ptr = POPPTR(ss,ix);
14085 TOPPTR(nss,ix) = svp_dup_inc((SV**)ptr, proto_perl);/* XXXXX */
14087 case SAVEt_GVSLOT: /* any slot in GV */
14088 sv = (const SV *)POPPTR(ss,ix);
14089 TOPPTR(nss,ix) = sv_dup_inc(sv, param);
14090 ptr = POPPTR(ss,ix);
14091 TOPPTR(nss,ix) = svp_dup_inc((SV**)ptr, proto_perl);/* XXXXX */
14092 sv = (const SV *)POPPTR(ss,ix);
14093 TOPPTR(nss,ix) = sv_dup_inc(sv, param);
14095 case SAVEt_HV: /* hash reference */
14096 case SAVEt_AV: /* array reference */
14097 sv = (const SV *) POPPTR(ss,ix);
14098 TOPPTR(nss,ix) = sv_dup_inc(sv, param);
14100 case SAVEt_COMPPAD:
14102 sv = (const SV *) POPPTR(ss,ix);
14103 TOPPTR(nss,ix) = sv_dup(sv, param);
14105 case SAVEt_INT: /* int reference */
14106 ptr = POPPTR(ss,ix);
14107 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14108 intval = (int)POPINT(ss,ix);
14109 TOPINT(nss,ix) = intval;
14111 case SAVEt_LONG: /* long reference */
14112 ptr = POPPTR(ss,ix);
14113 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14114 longval = (long)POPLONG(ss,ix);
14115 TOPLONG(nss,ix) = longval;
14117 case SAVEt_I32: /* I32 reference */
14118 ptr = POPPTR(ss,ix);
14119 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14121 TOPINT(nss,ix) = i;
14123 case SAVEt_IV: /* IV reference */
14124 case SAVEt_STRLEN: /* STRLEN/size_t ref */
14125 ptr = POPPTR(ss,ix);
14126 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14128 TOPIV(nss,ix) = iv;
14130 case SAVEt_HPTR: /* HV* reference */
14131 case SAVEt_APTR: /* AV* reference */
14132 case SAVEt_SPTR: /* SV* reference */
14133 ptr = POPPTR(ss,ix);
14134 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14135 sv = (const SV *)POPPTR(ss,ix);
14136 TOPPTR(nss,ix) = sv_dup(sv, param);
14138 case SAVEt_VPTR: /* random* reference */
14139 ptr = POPPTR(ss,ix);
14140 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14142 case SAVEt_INT_SMALL:
14143 case SAVEt_I32_SMALL:
14144 case SAVEt_I16: /* I16 reference */
14145 case SAVEt_I8: /* I8 reference */
14147 ptr = POPPTR(ss,ix);
14148 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14150 case SAVEt_GENERIC_PVREF: /* generic char* */
14151 case SAVEt_PPTR: /* char* reference */
14152 ptr = POPPTR(ss,ix);
14153 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14154 c = (char*)POPPTR(ss,ix);
14155 TOPPTR(nss,ix) = pv_dup(c);
14157 case SAVEt_GP: /* scalar reference */
14158 gp = (GP*)POPPTR(ss,ix);
14159 TOPPTR(nss,ix) = gp = gp_dup(gp, param);
14160 (void)GpREFCNT_inc(gp);
14161 gv = (const GV *)POPPTR(ss,ix);
14162 TOPPTR(nss,ix) = gv_dup_inc(gv, param);
14165 ptr = POPPTR(ss,ix);
14166 if (ptr && (((OP*)ptr)->op_private & OPpREFCOUNTED)) {
14167 /* these are assumed to be refcounted properly */
14169 switch (((OP*)ptr)->op_type) {
14171 case OP_LEAVESUBLV:
14175 case OP_LEAVEWRITE:
14176 TOPPTR(nss,ix) = ptr;
14179 (void) OpREFCNT_inc(o);
14183 TOPPTR(nss,ix) = NULL;
14188 TOPPTR(nss,ix) = NULL;
14190 case SAVEt_FREECOPHH:
14191 ptr = POPPTR(ss,ix);
14192 TOPPTR(nss,ix) = cophh_copy((COPHH *)ptr);
14194 case SAVEt_ADELETE:
14195 av = (const AV *)POPPTR(ss,ix);
14196 TOPPTR(nss,ix) = av_dup_inc(av, param);
14198 TOPINT(nss,ix) = i;
14201 hv = (const HV *)POPPTR(ss,ix);
14202 TOPPTR(nss,ix) = hv_dup_inc(hv, param);
14204 TOPINT(nss,ix) = i;
14207 c = (char*)POPPTR(ss,ix);
14208 TOPPTR(nss,ix) = pv_dup_inc(c);
14210 case SAVEt_STACK_POS: /* Position on Perl stack */
14212 TOPINT(nss,ix) = i;
14214 case SAVEt_DESTRUCTOR:
14215 ptr = POPPTR(ss,ix);
14216 TOPPTR(nss,ix) = any_dup(ptr, proto_perl); /* XXX quite arbitrary */
14217 dptr = POPDPTR(ss,ix);
14218 TOPDPTR(nss,ix) = DPTR2FPTR(void (*)(void*),
14219 any_dup(FPTR2DPTR(void *, dptr),
14222 case SAVEt_DESTRUCTOR_X:
14223 ptr = POPPTR(ss,ix);
14224 TOPPTR(nss,ix) = any_dup(ptr, proto_perl); /* XXX quite arbitrary */
14225 dxptr = POPDXPTR(ss,ix);
14226 TOPDXPTR(nss,ix) = DPTR2FPTR(void (*)(pTHX_ void*),
14227 any_dup(FPTR2DPTR(void *, dxptr),
14230 case SAVEt_REGCONTEXT:
14232 ix -= uv >> SAVE_TIGHT_SHIFT;
14234 case SAVEt_AELEM: /* array element */
14235 sv = (const SV *)POPPTR(ss,ix);
14236 TOPPTR(nss,ix) = SvREFCNT_inc(sv_dup_inc(sv, param));
14238 TOPINT(nss,ix) = i;
14239 av = (const AV *)POPPTR(ss,ix);
14240 TOPPTR(nss,ix) = av_dup_inc(av, param);
14243 ptr = POPPTR(ss,ix);
14244 TOPPTR(nss,ix) = ptr;
14247 ptr = POPPTR(ss,ix);
14248 ptr = cophh_copy((COPHH*)ptr);
14249 TOPPTR(nss,ix) = ptr;
14251 TOPINT(nss,ix) = i;
14252 if (i & HINT_LOCALIZE_HH) {
14253 hv = (const HV *)POPPTR(ss,ix);
14254 TOPPTR(nss,ix) = hv_dup_inc(hv, param);
14257 case SAVEt_PADSV_AND_MORTALIZE:
14258 longval = (long)POPLONG(ss,ix);
14259 TOPLONG(nss,ix) = longval;
14260 ptr = POPPTR(ss,ix);
14261 TOPPTR(nss,ix) = any_dup(ptr, proto_perl);
14262 sv = (const SV *)POPPTR(ss,ix);
14263 TOPPTR(nss,ix) = sv_dup_inc(sv, param);
14265 case SAVEt_SET_SVFLAGS:
14267 TOPINT(nss,ix) = i;
14269 TOPINT(nss,ix) = i;
14270 sv = (const SV *)POPPTR(ss,ix);
14271 TOPPTR(nss,ix) = sv_dup(sv, param);
14273 case SAVEt_COMPILE_WARNINGS:
14274 ptr = POPPTR(ss,ix);
14275 TOPPTR(nss,ix) = DUP_WARNINGS((STRLEN*)ptr);
14278 ptr = POPPTR(ss,ix);
14279 TOPPTR(nss,ix) = parser_dup((const yy_parser*)ptr, param);
14281 case SAVEt_GP_ALIASED_SV: {
14282 GP * gp_ptr = (GP *)POPPTR(ss,ix);
14283 GP * new_gp_ptr = gp_dup(gp_ptr, param);
14284 TOPPTR(nss,ix) = new_gp_ptr;
14285 new_gp_ptr->gp_refcnt++;
14290 "panic: ss_dup inconsistency (%"IVdf")", (IV) type);
14298 /* if sv is a stash, call $class->CLONE_SKIP(), and set the SVphv_CLONEABLE
14299 * flag to the result. This is done for each stash before cloning starts,
14300 * so we know which stashes want their objects cloned */
14303 do_mark_cloneable_stash(pTHX_ SV *const sv)
14305 const HEK * const hvname = HvNAME_HEK((const HV *)sv);
14307 GV* const cloner = gv_fetchmethod_autoload(MUTABLE_HV(sv), "CLONE_SKIP", 0);
14308 SvFLAGS(sv) |= SVphv_CLONEABLE; /* clone objects by default */
14309 if (cloner && GvCV(cloner)) {
14316 mXPUSHs(newSVhek(hvname));
14318 call_sv(MUTABLE_SV(GvCV(cloner)), G_SCALAR);
14325 SvFLAGS(sv) &= ~SVphv_CLONEABLE;
14333 =for apidoc perl_clone
14335 Create and return a new interpreter by cloning the current one.
14337 perl_clone takes these flags as parameters:
14339 CLONEf_COPY_STACKS - is used to, well, copy the stacks also,
14340 without it we only clone the data and zero the stacks,
14341 with it we copy the stacks and the new perl interpreter is
14342 ready to run at the exact same point as the previous one.
14343 The pseudo-fork code uses COPY_STACKS while the
14344 threads->create doesn't.
14346 CLONEf_KEEP_PTR_TABLE -
14347 perl_clone keeps a ptr_table with the pointer of the old
14348 variable as a key and the new variable as a value,
14349 this allows it to check if something has been cloned and not
14350 clone it again but rather just use the value and increase the
14351 refcount. If KEEP_PTR_TABLE is not set then perl_clone will kill
14352 the ptr_table using the function
14353 C<ptr_table_free(PL_ptr_table); PL_ptr_table = NULL;>,
14354 reason to keep it around is if you want to dup some of your own
14355 variable who are outside the graph perl scans, example of this
14356 code is in threads.xs create.
14358 CLONEf_CLONE_HOST -
14359 This is a win32 thing, it is ignored on unix, it tells perls
14360 win32host code (which is c++) to clone itself, this is needed on
14361 win32 if you want to run two threads at the same time,
14362 if you just want to do some stuff in a separate perl interpreter
14363 and then throw it away and return to the original one,
14364 you don't need to do anything.
14369 /* XXX the above needs expanding by someone who actually understands it ! */
14370 EXTERN_C PerlInterpreter *
14371 perl_clone_host(PerlInterpreter* proto_perl, UV flags);
14374 perl_clone(PerlInterpreter *proto_perl, UV flags)
14377 #ifdef PERL_IMPLICIT_SYS
14379 PERL_ARGS_ASSERT_PERL_CLONE;
14381 /* perlhost.h so we need to call into it
14382 to clone the host, CPerlHost should have a c interface, sky */
14384 if (flags & CLONEf_CLONE_HOST) {
14385 return perl_clone_host(proto_perl,flags);
14387 return perl_clone_using(proto_perl, flags,
14389 proto_perl->IMemShared,
14390 proto_perl->IMemParse,
14392 proto_perl->IStdIO,
14396 proto_perl->IProc);
14400 perl_clone_using(PerlInterpreter *proto_perl, UV flags,
14401 struct IPerlMem* ipM, struct IPerlMem* ipMS,
14402 struct IPerlMem* ipMP, struct IPerlEnv* ipE,
14403 struct IPerlStdIO* ipStd, struct IPerlLIO* ipLIO,
14404 struct IPerlDir* ipD, struct IPerlSock* ipS,
14405 struct IPerlProc* ipP)
14407 /* XXX many of the string copies here can be optimized if they're
14408 * constants; they need to be allocated as common memory and just
14409 * their pointers copied. */
14412 CLONE_PARAMS clone_params;
14413 CLONE_PARAMS* const param = &clone_params;
14415 PerlInterpreter * const my_perl = (PerlInterpreter*)(*ipM->pMalloc)(ipM, sizeof(PerlInterpreter));
14417 PERL_ARGS_ASSERT_PERL_CLONE_USING;
14418 #else /* !PERL_IMPLICIT_SYS */
14420 CLONE_PARAMS clone_params;
14421 CLONE_PARAMS* param = &clone_params;
14422 PerlInterpreter * const my_perl = (PerlInterpreter*)PerlMem_malloc(sizeof(PerlInterpreter));
14424 PERL_ARGS_ASSERT_PERL_CLONE;
14425 #endif /* PERL_IMPLICIT_SYS */
14427 /* for each stash, determine whether its objects should be cloned */
14428 S_visit(proto_perl, do_mark_cloneable_stash, SVt_PVHV, SVTYPEMASK);
14429 PERL_SET_THX(my_perl);
14432 PoisonNew(my_perl, 1, PerlInterpreter);
14435 PL_defstash = NULL; /* may be used by perl malloc() */
14438 PL_scopestack_name = 0;
14440 PL_savestack_ix = 0;
14441 PL_savestack_max = -1;
14442 PL_sig_pending = 0;
14444 Zero(&PL_debug_pad, 1, struct perl_debug_pad);
14445 Zero(&PL_padname_undef, 1, PADNAME);
14446 Zero(&PL_padname_const, 1, PADNAME);
14447 # ifdef DEBUG_LEAKING_SCALARS
14448 PL_sv_serial = (((UV)my_perl >> 2) & 0xfff) * 1000000;
14450 #else /* !DEBUGGING */
14451 Zero(my_perl, 1, PerlInterpreter);
14452 #endif /* DEBUGGING */
14454 #ifdef PERL_IMPLICIT_SYS
14455 /* host pointers */
14457 PL_MemShared = ipMS;
14458 PL_MemParse = ipMP;
14465 #endif /* PERL_IMPLICIT_SYS */
14468 param->flags = flags;
14469 /* Nothing in the core code uses this, but we make it available to
14470 extensions (using mg_dup). */
14471 param->proto_perl = proto_perl;
14472 /* Likely nothing will use this, but it is initialised to be consistent
14473 with Perl_clone_params_new(). */
14474 param->new_perl = my_perl;
14475 param->unreferenced = NULL;
14478 INIT_TRACK_MEMPOOL(my_perl->Imemory_debug_header, my_perl);
14480 PL_body_arenas = NULL;
14481 Zero(&PL_body_roots, 1, PL_body_roots);
14485 PL_sv_arenaroot = NULL;
14487 PL_debug = proto_perl->Idebug;
14489 /* dbargs array probably holds garbage */
14492 PL_compiling = proto_perl->Icompiling;
14494 /* pseudo environmental stuff */
14495 PL_origargc = proto_perl->Iorigargc;
14496 PL_origargv = proto_perl->Iorigargv;
14498 #ifndef NO_TAINT_SUPPORT
14499 /* Set tainting stuff before PerlIO_debug can possibly get called */
14500 PL_tainting = proto_perl->Itainting;
14501 PL_taint_warn = proto_perl->Itaint_warn;
14503 PL_tainting = FALSE;
14504 PL_taint_warn = FALSE;
14507 PL_minus_c = proto_perl->Iminus_c;
14509 PL_localpatches = proto_perl->Ilocalpatches;
14510 PL_splitstr = proto_perl->Isplitstr;
14511 PL_minus_n = proto_perl->Iminus_n;
14512 PL_minus_p = proto_perl->Iminus_p;
14513 PL_minus_l = proto_perl->Iminus_l;
14514 PL_minus_a = proto_perl->Iminus_a;
14515 PL_minus_E = proto_perl->Iminus_E;
14516 PL_minus_F = proto_perl->Iminus_F;
14517 PL_doswitches = proto_perl->Idoswitches;
14518 PL_dowarn = proto_perl->Idowarn;
14519 PL_sawalias = proto_perl->Isawalias;
14520 #ifdef PERL_SAWAMPERSAND
14521 PL_sawampersand = proto_perl->Isawampersand;
14523 PL_unsafe = proto_perl->Iunsafe;
14524 PL_perldb = proto_perl->Iperldb;
14525 PL_perl_destruct_level = proto_perl->Iperl_destruct_level;
14526 PL_exit_flags = proto_perl->Iexit_flags;
14528 /* XXX time(&PL_basetime) when asked for? */
14529 PL_basetime = proto_perl->Ibasetime;
14531 PL_maxsysfd = proto_perl->Imaxsysfd;
14532 PL_statusvalue = proto_perl->Istatusvalue;
14534 PL_statusvalue_vms = proto_perl->Istatusvalue_vms;
14536 PL_statusvalue_posix = proto_perl->Istatusvalue_posix;
14539 /* RE engine related */
14540 PL_regmatch_slab = NULL;
14541 PL_reg_curpm = NULL;
14543 PL_sub_generation = proto_perl->Isub_generation;
14545 /* funky return mechanisms */
14546 PL_forkprocess = proto_perl->Iforkprocess;
14548 /* internal state */
14549 PL_maxo = proto_perl->Imaxo;
14551 PL_main_start = proto_perl->Imain_start;
14552 PL_eval_root = proto_perl->Ieval_root;
14553 PL_eval_start = proto_perl->Ieval_start;
14555 PL_filemode = proto_perl->Ifilemode;
14556 PL_lastfd = proto_perl->Ilastfd;
14557 PL_oldname = proto_perl->Ioldname; /* XXX not quite right */
14560 PL_gensym = proto_perl->Igensym;
14562 PL_laststatval = proto_perl->Ilaststatval;
14563 PL_laststype = proto_perl->Ilaststype;
14566 PL_profiledata = NULL;
14568 PL_generation = proto_perl->Igeneration;
14570 PL_in_clean_objs = proto_perl->Iin_clean_objs;
14571 PL_in_clean_all = proto_perl->Iin_clean_all;
14573 PL_delaymagic_uid = proto_perl->Idelaymagic_uid;
14574 PL_delaymagic_euid = proto_perl->Idelaymagic_euid;
14575 PL_delaymagic_gid = proto_perl->Idelaymagic_gid;
14576 PL_delaymagic_egid = proto_perl->Idelaymagic_egid;
14577 PL_nomemok = proto_perl->Inomemok;
14578 PL_an = proto_perl->Ian;
14579 PL_evalseq = proto_perl->Ievalseq;
14580 PL_origenviron = proto_perl->Iorigenviron; /* XXX not quite right */
14581 PL_origalen = proto_perl->Iorigalen;
14583 PL_sighandlerp = proto_perl->Isighandlerp;
14585 PL_runops = proto_perl->Irunops;
14587 PL_subline = proto_perl->Isubline;
14589 PL_cv_has_eval = proto_perl->Icv_has_eval;
14592 PL_cryptseen = proto_perl->Icryptseen;
14595 #ifdef USE_LOCALE_COLLATE
14596 PL_collation_ix = proto_perl->Icollation_ix;
14597 PL_collation_standard = proto_perl->Icollation_standard;
14598 PL_collxfrm_base = proto_perl->Icollxfrm_base;
14599 PL_collxfrm_mult = proto_perl->Icollxfrm_mult;
14600 #endif /* USE_LOCALE_COLLATE */
14602 #ifdef USE_LOCALE_NUMERIC
14603 PL_numeric_standard = proto_perl->Inumeric_standard;
14604 PL_numeric_local = proto_perl->Inumeric_local;
14605 #endif /* !USE_LOCALE_NUMERIC */
14607 /* Did the locale setup indicate UTF-8? */
14608 PL_utf8locale = proto_perl->Iutf8locale;
14609 PL_in_utf8_CTYPE_locale = proto_perl->Iin_utf8_CTYPE_locale;
14610 /* Unicode features (see perlrun/-C) */
14611 PL_unicode = proto_perl->Iunicode;
14613 /* Pre-5.8 signals control */
14614 PL_signals = proto_perl->Isignals;
14616 /* times() ticks per second */
14617 PL_clocktick = proto_perl->Iclocktick;
14619 /* Recursion stopper for PerlIO_find_layer */
14620 PL_in_load_module = proto_perl->Iin_load_module;
14622 /* sort() routine */
14623 PL_sort_RealCmp = proto_perl->Isort_RealCmp;
14625 /* Not really needed/useful since the reenrant_retint is "volatile",
14626 * but do it for consistency's sake. */
14627 PL_reentrant_retint = proto_perl->Ireentrant_retint;
14629 /* Hooks to shared SVs and locks. */
14630 PL_sharehook = proto_perl->Isharehook;
14631 PL_lockhook = proto_perl->Ilockhook;
14632 PL_unlockhook = proto_perl->Iunlockhook;
14633 PL_threadhook = proto_perl->Ithreadhook;
14634 PL_destroyhook = proto_perl->Idestroyhook;
14635 PL_signalhook = proto_perl->Isignalhook;
14637 PL_globhook = proto_perl->Iglobhook;
14640 PL_last_swash_hv = NULL; /* reinits on demand */
14641 PL_last_swash_klen = 0;
14642 PL_last_swash_key[0]= '\0';
14643 PL_last_swash_tmps = (U8*)NULL;
14644 PL_last_swash_slen = 0;
14646 PL_srand_called = proto_perl->Isrand_called;
14647 Copy(&(proto_perl->Irandom_state), &PL_random_state, 1, PL_RANDOM_STATE_TYPE);
14649 if (flags & CLONEf_COPY_STACKS) {
14650 /* next allocation will be PL_tmps_stack[PL_tmps_ix+1] */
14651 PL_tmps_ix = proto_perl->Itmps_ix;
14652 PL_tmps_max = proto_perl->Itmps_max;
14653 PL_tmps_floor = proto_perl->Itmps_floor;
14655 /* next push_scope()/ENTER sets PL_scopestack[PL_scopestack_ix]
14656 * NOTE: unlike the others! */
14657 PL_scopestack_ix = proto_perl->Iscopestack_ix;
14658 PL_scopestack_max = proto_perl->Iscopestack_max;
14660 /* next SSPUSHFOO() sets PL_savestack[PL_savestack_ix]
14661 * NOTE: unlike the others! */
14662 PL_savestack_ix = proto_perl->Isavestack_ix;
14663 PL_savestack_max = proto_perl->Isavestack_max;
14666 PL_start_env = proto_perl->Istart_env; /* XXXXXX */
14667 PL_top_env = &PL_start_env;
14669 PL_op = proto_perl->Iop;
14672 PL_Xpv = (XPV*)NULL;
14673 my_perl->Ina = proto_perl->Ina;
14675 PL_statbuf = proto_perl->Istatbuf;
14676 PL_statcache = proto_perl->Istatcache;
14678 #ifndef NO_TAINT_SUPPORT
14679 PL_tainted = proto_perl->Itainted;
14681 PL_tainted = FALSE;
14683 PL_curpm = proto_perl->Icurpm; /* XXX No PMOP ref count */
14685 PL_chopset = proto_perl->Ichopset; /* XXX never deallocated */
14687 PL_restartjmpenv = proto_perl->Irestartjmpenv;
14688 PL_restartop = proto_perl->Irestartop;
14689 PL_in_eval = proto_perl->Iin_eval;
14690 PL_delaymagic = proto_perl->Idelaymagic;
14691 PL_phase = proto_perl->Iphase;
14692 PL_localizing = proto_perl->Ilocalizing;
14694 PL_hv_fetch_ent_mh = NULL;
14695 PL_modcount = proto_perl->Imodcount;
14696 PL_lastgotoprobe = NULL;
14697 PL_dumpindent = proto_perl->Idumpindent;
14699 PL_efloatbuf = NULL; /* reinits on demand */
14700 PL_efloatsize = 0; /* reinits on demand */
14704 PL_colorset = 0; /* reinits PL_colors[] */
14705 /*PL_colors[6] = {0,0,0,0,0,0};*/
14707 /* Pluggable optimizer */
14708 PL_peepp = proto_perl->Ipeepp;
14709 PL_rpeepp = proto_perl->Irpeepp;
14710 /* op_free() hook */
14711 PL_opfreehook = proto_perl->Iopfreehook;
14713 #ifdef USE_REENTRANT_API
14714 /* XXX: things like -Dm will segfault here in perlio, but doing
14715 * PERL_SET_CONTEXT(proto_perl);
14716 * breaks too many other things
14718 Perl_reentrant_init(aTHX);
14721 /* create SV map for pointer relocation */
14722 PL_ptr_table = ptr_table_new();
14724 /* initialize these special pointers as early as possible */
14726 ptr_table_store(PL_ptr_table, &proto_perl->Isv_undef, &PL_sv_undef);
14727 ptr_table_store(PL_ptr_table, &proto_perl->Isv_no, &PL_sv_no);
14728 ptr_table_store(PL_ptr_table, &proto_perl->Isv_yes, &PL_sv_yes);
14729 ptr_table_store(PL_ptr_table, &proto_perl->Ipadname_const,
14730 &PL_padname_const);
14732 /* create (a non-shared!) shared string table */
14733 PL_strtab = newHV();
14734 HvSHAREKEYS_off(PL_strtab);
14735 hv_ksplit(PL_strtab, HvTOTALKEYS(proto_perl->Istrtab));
14736 ptr_table_store(PL_ptr_table, proto_perl->Istrtab, PL_strtab);
14738 Zero(PL_sv_consts, SV_CONSTS_COUNT, SV*);
14740 /* This PV will be free'd special way so must set it same way op.c does */
14741 PL_compiling.cop_file = savesharedpv(PL_compiling.cop_file);
14742 ptr_table_store(PL_ptr_table, proto_perl->Icompiling.cop_file, PL_compiling.cop_file);
14744 ptr_table_store(PL_ptr_table, &proto_perl->Icompiling, &PL_compiling);
14745 PL_compiling.cop_warnings = DUP_WARNINGS(PL_compiling.cop_warnings);
14746 CopHINTHASH_set(&PL_compiling, cophh_copy(CopHINTHASH_get(&PL_compiling)));
14747 PL_curcop = (COP*)any_dup(proto_perl->Icurcop, proto_perl);
14749 param->stashes = newAV(); /* Setup array of objects to call clone on */
14750 /* This makes no difference to the implementation, as it always pushes
14751 and shifts pointers to other SVs without changing their reference
14752 count, with the array becoming empty before it is freed. However, it
14753 makes it conceptually clear what is going on, and will avoid some
14754 work inside av.c, filling slots between AvFILL() and AvMAX() with
14755 &PL_sv_undef, and SvREFCNT_dec()ing those. */
14756 AvREAL_off(param->stashes);
14758 if (!(flags & CLONEf_COPY_STACKS)) {
14759 param->unreferenced = newAV();
14762 #ifdef PERLIO_LAYERS
14763 /* Clone PerlIO tables as soon as we can handle general xx_dup() */
14764 PerlIO_clone(aTHX_ proto_perl, param);
14767 PL_envgv = gv_dup_inc(proto_perl->Ienvgv, param);
14768 PL_incgv = gv_dup_inc(proto_perl->Iincgv, param);
14769 PL_hintgv = gv_dup_inc(proto_perl->Ihintgv, param);
14770 PL_origfilename = SAVEPV(proto_perl->Iorigfilename);
14771 PL_xsubfilename = proto_perl->Ixsubfilename;
14772 PL_diehook = sv_dup_inc(proto_perl->Idiehook, param);
14773 PL_warnhook = sv_dup_inc(proto_perl->Iwarnhook, param);
14776 PL_patchlevel = sv_dup_inc(proto_perl->Ipatchlevel, param);
14777 PL_inplace = SAVEPV(proto_perl->Iinplace);
14778 PL_e_script = sv_dup_inc(proto_perl->Ie_script, param);
14780 /* magical thingies */
14782 PL_encoding = sv_dup(proto_perl->Iencoding, param);
14783 PL_lex_encoding = sv_dup(proto_perl->Ilex_encoding, param);
14785 sv_setpvs(PERL_DEBUG_PAD(0), ""); /* For regex debugging. */
14786 sv_setpvs(PERL_DEBUG_PAD(1), ""); /* ext/re needs these */
14787 sv_setpvs(PERL_DEBUG_PAD(2), ""); /* even without DEBUGGING. */
14790 /* Clone the regex array */
14791 /* ORANGE FIXME for plugins, probably in the SV dup code.
14792 newSViv(PTR2IV(CALLREGDUPE(
14793 INT2PTR(REGEXP *, SvIVX(regex)), param))))
14795 PL_regex_padav = av_dup_inc(proto_perl->Iregex_padav, param);
14796 PL_regex_pad = AvARRAY(PL_regex_padav);
14798 PL_stashpadmax = proto_perl->Istashpadmax;
14799 PL_stashpadix = proto_perl->Istashpadix ;
14800 Newx(PL_stashpad, PL_stashpadmax, HV *);
14803 for (; o < PL_stashpadmax; ++o)
14804 PL_stashpad[o] = hv_dup(proto_perl->Istashpad[o], param);
14807 /* shortcuts to various I/O objects */
14808 PL_ofsgv = gv_dup_inc(proto_perl->Iofsgv, param);
14809 PL_stdingv = gv_dup(proto_perl->Istdingv, param);
14810 PL_stderrgv = gv_dup(proto_perl->Istderrgv, param);
14811 PL_defgv = gv_dup(proto_perl->Idefgv, param);
14812 PL_argvgv = gv_dup_inc(proto_perl->Iargvgv, param);
14813 PL_argvoutgv = gv_dup(proto_perl->Iargvoutgv, param);
14814 PL_argvout_stack = av_dup_inc(proto_perl->Iargvout_stack, param);
14816 /* shortcuts to regexp stuff */
14817 PL_replgv = gv_dup_inc(proto_perl->Ireplgv, param);
14819 /* shortcuts to misc objects */
14820 PL_errgv = gv_dup(proto_perl->Ierrgv, param);
14822 /* shortcuts to debugging objects */
14823 PL_DBgv = gv_dup_inc(proto_perl->IDBgv, param);
14824 PL_DBline = gv_dup_inc(proto_perl->IDBline, param);
14825 PL_DBsub = gv_dup_inc(proto_perl->IDBsub, param);
14826 PL_DBsingle = sv_dup(proto_perl->IDBsingle, param);
14827 PL_DBtrace = sv_dup(proto_perl->IDBtrace, param);
14828 PL_DBsignal = sv_dup(proto_perl->IDBsignal, param);
14829 Copy(proto_perl->IDBcontrol, PL_DBcontrol, DBVARMG_COUNT, IV);
14831 /* symbol tables */
14832 PL_defstash = hv_dup_inc(proto_perl->Idefstash, param);
14833 PL_curstash = hv_dup_inc(proto_perl->Icurstash, param);
14834 PL_debstash = hv_dup(proto_perl->Idebstash, param);
14835 PL_globalstash = hv_dup(proto_perl->Iglobalstash, param);
14836 PL_curstname = sv_dup_inc(proto_perl->Icurstname, param);
14838 PL_beginav = av_dup_inc(proto_perl->Ibeginav, param);
14839 PL_beginav_save = av_dup_inc(proto_perl->Ibeginav_save, param);
14840 PL_checkav_save = av_dup_inc(proto_perl->Icheckav_save, param);
14841 PL_unitcheckav = av_dup_inc(proto_perl->Iunitcheckav, param);
14842 PL_unitcheckav_save = av_dup_inc(proto_perl->Iunitcheckav_save, param);
14843 PL_endav = av_dup_inc(proto_perl->Iendav, param);
14844 PL_checkav = av_dup_inc(proto_perl->Icheckav, param);
14845 PL_initav = av_dup_inc(proto_perl->Iinitav, param);
14846 PL_savebegin = proto_perl->Isavebegin;
14848 PL_isarev = hv_dup_inc(proto_perl->Iisarev, param);
14850 /* subprocess state */
14851 PL_fdpid = av_dup_inc(proto_perl->Ifdpid, param);
14853 if (proto_perl->Iop_mask)
14854 PL_op_mask = SAVEPVN(proto_perl->Iop_mask, PL_maxo);
14857 /* PL_asserting = proto_perl->Iasserting; */
14859 /* current interpreter roots */
14860 PL_main_cv = cv_dup_inc(proto_perl->Imain_cv, param);
14862 PL_main_root = OpREFCNT_inc(proto_perl->Imain_root);
14865 /* runtime control stuff */
14866 PL_curcopdb = (COP*)any_dup(proto_perl->Icurcopdb, proto_perl);
14868 PL_preambleav = av_dup_inc(proto_perl->Ipreambleav, param);
14870 PL_ors_sv = sv_dup_inc(proto_perl->Iors_sv, param);
14872 /* interpreter atexit processing */
14873 PL_exitlistlen = proto_perl->Iexitlistlen;
14874 if (PL_exitlistlen) {
14875 Newx(PL_exitlist, PL_exitlistlen, PerlExitListEntry);
14876 Copy(proto_perl->Iexitlist, PL_exitlist, PL_exitlistlen, PerlExitListEntry);
14879 PL_exitlist = (PerlExitListEntry*)NULL;
14881 PL_my_cxt_size = proto_perl->Imy_cxt_size;
14882 if (PL_my_cxt_size) {
14883 Newx(PL_my_cxt_list, PL_my_cxt_size, void *);
14884 Copy(proto_perl->Imy_cxt_list, PL_my_cxt_list, PL_my_cxt_size, void *);
14885 #ifdef PERL_GLOBAL_STRUCT_PRIVATE
14886 Newx(PL_my_cxt_keys, PL_my_cxt_size, const char *);
14887 Copy(proto_perl->Imy_cxt_keys, PL_my_cxt_keys, PL_my_cxt_size, char *);
14891 PL_my_cxt_list = (void**)NULL;
14892 #ifdef PERL_GLOBAL_STRUCT_PRIVATE
14893 PL_my_cxt_keys = (const char**)NULL;
14896 PL_modglobal = hv_dup_inc(proto_perl->Imodglobal, param);
14897 PL_custom_op_names = hv_dup_inc(proto_perl->Icustom_op_names,param);
14898 PL_custom_op_descs = hv_dup_inc(proto_perl->Icustom_op_descs,param);
14899 PL_custom_ops = hv_dup_inc(proto_perl->Icustom_ops, param);
14901 PL_compcv = cv_dup(proto_perl->Icompcv, param);
14903 PAD_CLONE_VARS(proto_perl, param);
14905 #ifdef HAVE_INTERP_INTERN
14906 sys_intern_dup(&proto_perl->Isys_intern, &PL_sys_intern);
14909 PL_DBcv = cv_dup(proto_perl->IDBcv, param);
14911 #ifdef PERL_USES_PL_PIDSTATUS
14912 PL_pidstatus = newHV(); /* XXX flag for cloning? */
14914 PL_osname = SAVEPV(proto_perl->Iosname);
14915 PL_parser = parser_dup(proto_perl->Iparser, param);
14917 /* XXX this only works if the saved cop has already been cloned */
14918 if (proto_perl->Iparser) {
14919 PL_parser->saved_curcop = (COP*)any_dup(
14920 proto_perl->Iparser->saved_curcop,
14924 PL_subname = sv_dup_inc(proto_perl->Isubname, param);
14926 #ifdef USE_LOCALE_CTYPE
14927 /* Should we warn if uses locale? */
14928 PL_warn_locale = sv_dup_inc(proto_perl->Iwarn_locale, param);
14931 #ifdef USE_LOCALE_COLLATE
14932 PL_collation_name = SAVEPV(proto_perl->Icollation_name);
14933 #endif /* USE_LOCALE_COLLATE */
14935 #ifdef USE_LOCALE_NUMERIC
14936 PL_numeric_name = SAVEPV(proto_perl->Inumeric_name);
14937 PL_numeric_radix_sv = sv_dup_inc(proto_perl->Inumeric_radix_sv, param);
14938 #endif /* !USE_LOCALE_NUMERIC */
14940 /* Unicode inversion lists */
14941 PL_Latin1 = sv_dup_inc(proto_perl->ILatin1, param);
14942 PL_UpperLatin1 = sv_dup_inc(proto_perl->IUpperLatin1, param);
14943 PL_AboveLatin1 = sv_dup_inc(proto_perl->IAboveLatin1, param);
14944 PL_InBitmap = sv_dup_inc(proto_perl->IInBitmap, param);
14946 PL_NonL1NonFinalFold = sv_dup_inc(proto_perl->INonL1NonFinalFold, param);
14947 PL_HasMultiCharFold = sv_dup_inc(proto_perl->IHasMultiCharFold, param);
14949 /* utf8 character class swashes */
14950 for (i = 0; i < POSIX_SWASH_COUNT; i++) {
14951 PL_utf8_swash_ptrs[i] = sv_dup_inc(proto_perl->Iutf8_swash_ptrs[i], param);
14953 for (i = 0; i < POSIX_CC_COUNT; i++) {
14954 PL_XPosix_ptrs[i] = sv_dup_inc(proto_perl->IXPosix_ptrs[i], param);
14956 PL_GCB_invlist = sv_dup_inc(proto_perl->IGCB_invlist, param);
14957 PL_SB_invlist = sv_dup_inc(proto_perl->ISB_invlist, param);
14958 PL_WB_invlist = sv_dup_inc(proto_perl->IWB_invlist, param);
14959 PL_utf8_mark = sv_dup_inc(proto_perl->Iutf8_mark, param);
14960 PL_utf8_toupper = sv_dup_inc(proto_perl->Iutf8_toupper, param);
14961 PL_utf8_totitle = sv_dup_inc(proto_perl->Iutf8_totitle, param);
14962 PL_utf8_tolower = sv_dup_inc(proto_perl->Iutf8_tolower, param);
14963 PL_utf8_tofold = sv_dup_inc(proto_perl->Iutf8_tofold, param);
14964 PL_utf8_idstart = sv_dup_inc(proto_perl->Iutf8_idstart, param);
14965 PL_utf8_xidstart = sv_dup_inc(proto_perl->Iutf8_xidstart, param);
14966 PL_utf8_perl_idstart = sv_dup_inc(proto_perl->Iutf8_perl_idstart, param);
14967 PL_utf8_perl_idcont = sv_dup_inc(proto_perl->Iutf8_perl_idcont, param);
14968 PL_utf8_idcont = sv_dup_inc(proto_perl->Iutf8_idcont, param);
14969 PL_utf8_xidcont = sv_dup_inc(proto_perl->Iutf8_xidcont, param);
14970 PL_utf8_foldable = sv_dup_inc(proto_perl->Iutf8_foldable, param);
14971 PL_utf8_charname_begin = sv_dup_inc(proto_perl->Iutf8_charname_begin, param);
14972 PL_utf8_charname_continue = sv_dup_inc(proto_perl->Iutf8_charname_continue, param);
14974 if (proto_perl->Ipsig_pend) {
14975 Newxz(PL_psig_pend, SIG_SIZE, int);
14978 PL_psig_pend = (int*)NULL;
14981 if (proto_perl->Ipsig_name) {
14982 Newx(PL_psig_name, 2 * SIG_SIZE, SV*);
14983 sv_dup_inc_multiple(proto_perl->Ipsig_name, PL_psig_name, 2 * SIG_SIZE,
14985 PL_psig_ptr = PL_psig_name + SIG_SIZE;
14988 PL_psig_ptr = (SV**)NULL;
14989 PL_psig_name = (SV**)NULL;
14992 if (flags & CLONEf_COPY_STACKS) {
14993 Newx(PL_tmps_stack, PL_tmps_max, SV*);
14994 sv_dup_inc_multiple(proto_perl->Itmps_stack, PL_tmps_stack,
14995 PL_tmps_ix+1, param);
14997 /* next PUSHMARK() sets *(PL_markstack_ptr+1) */
14998 i = proto_perl->Imarkstack_max - proto_perl->Imarkstack;
14999 Newxz(PL_markstack, i, I32);
15000 PL_markstack_max = PL_markstack + (proto_perl->Imarkstack_max
15001 - proto_perl->Imarkstack);
15002 PL_markstack_ptr = PL_markstack + (proto_perl->Imarkstack_ptr
15003 - proto_perl->Imarkstack);
15004 Copy(proto_perl->Imarkstack, PL_markstack,
15005 PL_markstack_ptr - PL_markstack + 1, I32);
15007 /* next push_scope()/ENTER sets PL_scopestack[PL_scopestack_ix]
15008 * NOTE: unlike the others! */
15009 Newxz(PL_scopestack, PL_scopestack_max, I32);
15010 Copy(proto_perl->Iscopestack, PL_scopestack, PL_scopestack_ix, I32);
15013 Newxz(PL_scopestack_name, PL_scopestack_max, const char *);
15014 Copy(proto_perl->Iscopestack_name, PL_scopestack_name, PL_scopestack_ix, const char *);
15016 /* reset stack AV to correct length before its duped via
15017 * PL_curstackinfo */
15018 AvFILLp(proto_perl->Icurstack) =
15019 proto_perl->Istack_sp - proto_perl->Istack_base;
15021 /* NOTE: si_dup() looks at PL_markstack */
15022 PL_curstackinfo = si_dup(proto_perl->Icurstackinfo, param);
15024 /* PL_curstack = PL_curstackinfo->si_stack; */
15025 PL_curstack = av_dup(proto_perl->Icurstack, param);
15026 PL_mainstack = av_dup(proto_perl->Imainstack, param);
15028 /* next PUSHs() etc. set *(PL_stack_sp+1) */
15029 PL_stack_base = AvARRAY(PL_curstack);
15030 PL_stack_sp = PL_stack_base + (proto_perl->Istack_sp
15031 - proto_perl->Istack_base);
15032 PL_stack_max = PL_stack_base + AvMAX(PL_curstack);
15034 /*Newxz(PL_savestack, PL_savestack_max, ANY);*/
15035 PL_savestack = ss_dup(proto_perl, param);
15039 ENTER; /* perl_destruct() wants to LEAVE; */
15042 PL_statgv = gv_dup(proto_perl->Istatgv, param);
15043 PL_statname = sv_dup_inc(proto_perl->Istatname, param);
15045 PL_rs = sv_dup_inc(proto_perl->Irs, param);
15046 PL_last_in_gv = gv_dup(proto_perl->Ilast_in_gv, param);
15047 PL_defoutgv = gv_dup_inc(proto_perl->Idefoutgv, param);
15048 PL_toptarget = sv_dup_inc(proto_perl->Itoptarget, param);
15049 PL_bodytarget = sv_dup_inc(proto_perl->Ibodytarget, param);
15050 PL_formtarget = sv_dup(proto_perl->Iformtarget, param);
15052 PL_errors = sv_dup_inc(proto_perl->Ierrors, param);
15054 PL_sortcop = (OP*)any_dup(proto_perl->Isortcop, proto_perl);
15055 PL_firstgv = gv_dup_inc(proto_perl->Ifirstgv, param);
15056 PL_secondgv = gv_dup_inc(proto_perl->Isecondgv, param);
15058 PL_stashcache = newHV();
15060 PL_watchaddr = (char **) ptr_table_fetch(PL_ptr_table,
15061 proto_perl->Iwatchaddr);
15062 PL_watchok = PL_watchaddr ? * PL_watchaddr : NULL;
15063 if (PL_debug && PL_watchaddr) {
15064 PerlIO_printf(Perl_debug_log,
15065 "WATCHING: %"UVxf" cloned as %"UVxf" with value %"UVxf"\n",
15066 PTR2UV(proto_perl->Iwatchaddr), PTR2UV(PL_watchaddr),
15067 PTR2UV(PL_watchok));
15070 PL_registered_mros = hv_dup_inc(proto_perl->Iregistered_mros, param);
15071 PL_blockhooks = av_dup_inc(proto_perl->Iblockhooks, param);
15072 PL_utf8_foldclosures = hv_dup_inc(proto_perl->Iutf8_foldclosures, param);
15074 /* Call the ->CLONE method, if it exists, for each of the stashes
15075 identified by sv_dup() above.
15077 while(av_tindex(param->stashes) != -1) {
15078 HV* const stash = MUTABLE_HV(av_shift(param->stashes));
15079 GV* const cloner = gv_fetchmethod_autoload(stash, "CLONE", 0);
15080 if (cloner && GvCV(cloner)) {
15085 mXPUSHs(newSVhek(HvNAME_HEK(stash)));
15087 call_sv(MUTABLE_SV(GvCV(cloner)), G_DISCARD);
15093 if (!(flags & CLONEf_KEEP_PTR_TABLE)) {
15094 ptr_table_free(PL_ptr_table);
15095 PL_ptr_table = NULL;
15098 if (!(flags & CLONEf_COPY_STACKS)) {
15099 unreferenced_to_tmp_stack(param->unreferenced);
15102 SvREFCNT_dec(param->stashes);
15104 /* orphaned? eg threads->new inside BEGIN or use */
15105 if (PL_compcv && ! SvREFCNT(PL_compcv)) {
15106 SvREFCNT_inc_simple_void(PL_compcv);
15107 SAVEFREESV(PL_compcv);
15114 S_unreferenced_to_tmp_stack(pTHX_ AV *const unreferenced)
15116 PERL_ARGS_ASSERT_UNREFERENCED_TO_TMP_STACK;
15118 if (AvFILLp(unreferenced) > -1) {
15119 SV **svp = AvARRAY(unreferenced);
15120 SV **const last = svp + AvFILLp(unreferenced);
15124 if (SvREFCNT(*svp) == 1)
15126 } while (++svp <= last);
15128 EXTEND_MORTAL(count);
15129 svp = AvARRAY(unreferenced);
15132 if (SvREFCNT(*svp) == 1) {
15133 /* Our reference is the only one to this SV. This means that
15134 in this thread, the scalar effectively has a 0 reference.
15135 That doesn't work (cleanup never happens), so donate our
15136 reference to it onto the save stack. */
15137 PL_tmps_stack[++PL_tmps_ix] = *svp;
15139 /* As an optimisation, because we are already walking the
15140 entire array, instead of above doing either
15141 SvREFCNT_inc(*svp) or *svp = &PL_sv_undef, we can instead
15142 release our reference to the scalar, so that at the end of
15143 the array owns zero references to the scalars it happens to
15144 point to. We are effectively converting the array from
15145 AvREAL() on to AvREAL() off. This saves the av_clear()
15146 (triggered by the SvREFCNT_dec(unreferenced) below) from
15147 walking the array a second time. */
15148 SvREFCNT_dec(*svp);
15151 } while (++svp <= last);
15152 AvREAL_off(unreferenced);
15154 SvREFCNT_dec_NN(unreferenced);
15158 Perl_clone_params_del(CLONE_PARAMS *param)
15160 /* This seemingly funky ordering keeps the build with PERL_GLOBAL_STRUCT
15162 PerlInterpreter *const to = param->new_perl;
15164 PerlInterpreter *const was = PERL_GET_THX;
15166 PERL_ARGS_ASSERT_CLONE_PARAMS_DEL;
15172 SvREFCNT_dec(param->stashes);
15173 if (param->unreferenced)
15174 unreferenced_to_tmp_stack(param->unreferenced);
15184 Perl_clone_params_new(PerlInterpreter *const from, PerlInterpreter *const to)
15187 /* Need to play this game, as newAV() can call safesysmalloc(), and that
15188 does a dTHX; to get the context from thread local storage.
15189 FIXME - under PERL_CORE Newx(), Safefree() and friends should expand to
15190 a version that passes in my_perl. */
15191 PerlInterpreter *const was = PERL_GET_THX;
15192 CLONE_PARAMS *param;
15194 PERL_ARGS_ASSERT_CLONE_PARAMS_NEW;
15200 /* Given that we've set the context, we can do this unshared. */
15201 Newx(param, 1, CLONE_PARAMS);
15204 param->proto_perl = from;
15205 param->new_perl = to;
15206 param->stashes = (AV *)Perl_newSV_type(to, SVt_PVAV);
15207 AvREAL_off(param->stashes);
15208 param->unreferenced = (AV *)Perl_newSV_type(to, SVt_PVAV);
15216 #endif /* USE_ITHREADS */
15219 Perl_init_constants(pTHX)
15221 SvREFCNT(&PL_sv_undef) = SvREFCNT_IMMORTAL;
15222 SvFLAGS(&PL_sv_undef) = SVf_READONLY|SVf_PROTECT|SVt_NULL;
15223 SvANY(&PL_sv_undef) = NULL;
15225 SvANY(&PL_sv_no) = new_XPVNV();
15226 SvREFCNT(&PL_sv_no) = SvREFCNT_IMMORTAL;
15227 SvFLAGS(&PL_sv_no) = SVt_PVNV|SVf_READONLY|SVf_PROTECT
15228 |SVp_IOK|SVf_IOK|SVp_NOK|SVf_NOK
15231 SvANY(&PL_sv_yes) = new_XPVNV();
15232 SvREFCNT(&PL_sv_yes) = SvREFCNT_IMMORTAL;
15233 SvFLAGS(&PL_sv_yes) = SVt_PVNV|SVf_READONLY|SVf_PROTECT
15234 |SVp_IOK|SVf_IOK|SVp_NOK|SVf_NOK
15237 SvPV_set(&PL_sv_no, (char*)PL_No);
15238 SvCUR_set(&PL_sv_no, 0);
15239 SvLEN_set(&PL_sv_no, 0);
15240 SvIV_set(&PL_sv_no, 0);
15241 SvNV_set(&PL_sv_no, 0);
15243 SvPV_set(&PL_sv_yes, (char*)PL_Yes);
15244 SvCUR_set(&PL_sv_yes, 1);
15245 SvLEN_set(&PL_sv_yes, 0);
15246 SvIV_set(&PL_sv_yes, 1);
15247 SvNV_set(&PL_sv_yes, 1);
15249 PadnamePV(&PL_padname_const) = (char *)PL_No;
15253 =head1 Unicode Support
15255 =for apidoc sv_recode_to_utf8
15257 The encoding is assumed to be an Encode object, on entry the PV
15258 of the sv is assumed to be octets in that encoding, and the sv
15259 will be converted into Unicode (and UTF-8).
15261 If the sv already is UTF-8 (or if it is not POK), or if the encoding
15262 is not a reference, nothing is done to the sv. If the encoding is not
15263 an C<Encode::XS> Encoding object, bad things will happen.
15264 (See F<lib/encoding.pm> and L<Encode>.)
15266 The PV of the sv is returned.
15271 Perl_sv_recode_to_utf8(pTHX_ SV *sv, SV *encoding)
15273 PERL_ARGS_ASSERT_SV_RECODE_TO_UTF8;
15275 if (SvPOK(sv) && !SvUTF8(sv) && !IN_BYTES && SvROK(encoding)) {
15284 if (SvPADTMP(nsv)) {
15285 nsv = sv_newmortal();
15286 SvSetSV_nosteal(nsv, sv);
15295 Passing sv_yes is wrong - it needs to be or'ed set of constants
15296 for Encode::XS, while UTf-8 decode (currently) assumes a true value means
15297 remove converted chars from source.
15299 Both will default the value - let them.
15301 XPUSHs(&PL_sv_yes);
15304 call_method("decode", G_SCALAR);
15308 s = SvPV_const(uni, len);
15309 if (s != SvPVX_const(sv)) {
15310 SvGROW(sv, len + 1);
15311 Move(s, SvPVX(sv), len + 1, char);
15312 SvCUR_set(sv, len);
15317 if (SvTYPE(sv) >= SVt_PVMG && SvMAGIC(sv)) {
15318 /* clear pos and any utf8 cache */
15319 MAGIC * mg = mg_find(sv, PERL_MAGIC_regex_global);
15322 if ((mg = mg_find(sv, PERL_MAGIC_utf8)))
15323 magic_setutf8(sv,mg); /* clear UTF8 cache */
15328 return SvPOKp(sv) ? SvPVX(sv) : NULL;
15332 =for apidoc sv_cat_decode
15334 The encoding is assumed to be an Encode object, the PV of the ssv is
15335 assumed to be octets in that encoding and decoding the input starts
15336 from the position which (PV + *offset) pointed to. The dsv will be
15337 concatenated the decoded UTF-8 string from ssv. Decoding will terminate
15338 when the string tstr appears in decoding output or the input ends on
15339 the PV of the ssv. The value which the offset points will be modified
15340 to the last input position on the ssv.
15342 Returns TRUE if the terminator was found, else returns FALSE.
15347 Perl_sv_cat_decode(pTHX_ SV *dsv, SV *encoding,
15348 SV *ssv, int *offset, char *tstr, int tlen)
15352 PERL_ARGS_ASSERT_SV_CAT_DECODE;
15354 if (SvPOK(ssv) && SvPOK(dsv) && SvROK(encoding)) {
15365 offsv = newSViv(*offset);
15367 mPUSHp(tstr, tlen);
15369 call_method("cat_decode", G_SCALAR);
15371 ret = SvTRUE(TOPs);
15372 *offset = SvIV(offsv);
15378 Perl_croak(aTHX_ "Invalid argument to sv_cat_decode");
15383 /* ---------------------------------------------------------------------
15385 * support functions for report_uninit()
15388 /* the maxiumum size of array or hash where we will scan looking
15389 * for the undefined element that triggered the warning */
15391 #define FUV_MAX_SEARCH_SIZE 1000
15393 /* Look for an entry in the hash whose value has the same SV as val;
15394 * If so, return a mortal copy of the key. */
15397 S_find_hash_subscript(pTHX_ const HV *const hv, const SV *const val)
15403 PERL_ARGS_ASSERT_FIND_HASH_SUBSCRIPT;
15405 if (!hv || SvMAGICAL(hv) || !HvARRAY(hv) ||
15406 (HvTOTALKEYS(hv) > FUV_MAX_SEARCH_SIZE))
15409 array = HvARRAY(hv);
15411 for (i=HvMAX(hv); i>=0; i--) {
15413 for (entry = array[i]; entry; entry = HeNEXT(entry)) {
15414 if (HeVAL(entry) != val)
15416 if ( HeVAL(entry) == &PL_sv_undef ||
15417 HeVAL(entry) == &PL_sv_placeholder)
15421 if (HeKLEN(entry) == HEf_SVKEY)
15422 return sv_mortalcopy(HeKEY_sv(entry));
15423 return sv_2mortal(newSVhek(HeKEY_hek(entry)));
15429 /* Look for an entry in the array whose value has the same SV as val;
15430 * If so, return the index, otherwise return -1. */
15433 S_find_array_subscript(pTHX_ const AV *const av, const SV *const val)
15435 PERL_ARGS_ASSERT_FIND_ARRAY_SUBSCRIPT;
15437 if (!av || SvMAGICAL(av) || !AvARRAY(av) ||
15438 (AvFILLp(av) > FUV_MAX_SEARCH_SIZE))
15441 if (val != &PL_sv_undef) {
15442 SV ** const svp = AvARRAY(av);
15445 for (i=AvFILLp(av); i>=0; i--)
15452 /* varname(): return the name of a variable, optionally with a subscript.
15453 * If gv is non-zero, use the name of that global, along with gvtype (one
15454 * of "$", "@", "%"); otherwise use the name of the lexical at pad offset
15455 * targ. Depending on the value of the subscript_type flag, return:
15458 #define FUV_SUBSCRIPT_NONE 1 /* "@foo" */
15459 #define FUV_SUBSCRIPT_ARRAY 2 /* "$foo[aindex]" */
15460 #define FUV_SUBSCRIPT_HASH 3 /* "$foo{keyname}" */
15461 #define FUV_SUBSCRIPT_WITHIN 4 /* "within @foo" */
15464 Perl_varname(pTHX_ const GV *const gv, const char gvtype, PADOFFSET targ,
15465 const SV *const keyname, I32 aindex, int subscript_type)
15468 SV * const name = sv_newmortal();
15469 if (gv && isGV(gv)) {
15471 buffer[0] = gvtype;
15474 /* as gv_fullname4(), but add literal '^' for $^FOO names */
15476 gv_fullname4(name, gv, buffer, 0);
15478 if ((unsigned int)SvPVX(name)[1] <= 26) {
15480 buffer[1] = SvPVX(name)[1] + 'A' - 1;
15482 /* Swap the 1 unprintable control character for the 2 byte pretty
15483 version - ie substr($name, 1, 1) = $buffer; */
15484 sv_insert(name, 1, 1, buffer, 2);
15488 CV * const cv = gv ? ((CV *)gv) : find_runcv(NULL);
15491 assert(!cv || SvTYPE(cv) == SVt_PVCV || SvTYPE(cv) == SVt_PVFM);
15493 if (!cv || !CvPADLIST(cv))
15495 sv = padnamelist_fetch(PadlistNAMES(CvPADLIST(cv)), targ);
15496 sv_setpvn(name, PadnamePV(sv), PadnameLEN(sv));
15500 if (subscript_type == FUV_SUBSCRIPT_HASH) {
15501 SV * const sv = newSV(0);
15502 *SvPVX(name) = '$';
15503 Perl_sv_catpvf(aTHX_ name, "{%s}",
15504 pv_pretty(sv, SvPVX_const(keyname), SvCUR(keyname), 32, NULL, NULL,
15505 PERL_PV_PRETTY_DUMP | PERL_PV_ESCAPE_UNI_DETECT ));
15506 SvREFCNT_dec_NN(sv);
15508 else if (subscript_type == FUV_SUBSCRIPT_ARRAY) {
15509 *SvPVX(name) = '$';
15510 Perl_sv_catpvf(aTHX_ name, "[%"IVdf"]", (IV)aindex);
15512 else if (subscript_type == FUV_SUBSCRIPT_WITHIN) {
15513 /* We know that name has no magic, so can use 0 instead of SV_GMAGIC */
15514 Perl_sv_insert_flags(aTHX_ name, 0, 0, STR_WITH_LEN("within "), 0);
15522 =for apidoc find_uninit_var
15524 Find the name of the undefined variable (if any) that caused the operator
15525 to issue a "Use of uninitialized value" warning.
15526 If match is true, only return a name if its value matches uninit_sv.
15527 So roughly speaking, if a unary operator (such as OP_COS) generates a
15528 warning, then following the direct child of the op may yield an
15529 OP_PADSV or OP_GV that gives the name of the undefined variable. On the
15530 other hand, with OP_ADD there are two branches to follow, so we only print
15531 the variable name if we get an exact match.
15532 desc_p points to a string pointer holding the description of the op.
15533 This may be updated if needed.
15535 The name is returned as a mortal SV.
15537 Assumes that PL_op is the op that originally triggered the error, and that
15538 PL_comppad/PL_curpad points to the currently executing pad.
15544 S_find_uninit_var(pTHX_ const OP *const obase, const SV *const uninit_sv,
15545 bool match, const char **desc_p)
15550 const OP *o, *o2, *kid;
15552 PERL_ARGS_ASSERT_FIND_UNINIT_VAR;
15554 if (!obase || (match && (!uninit_sv || uninit_sv == &PL_sv_undef ||
15555 uninit_sv == &PL_sv_placeholder)))
15558 switch (obase->op_type) {
15565 const bool pad = ( obase->op_type == OP_PADAV
15566 || obase->op_type == OP_PADHV
15567 || obase->op_type == OP_PADRANGE
15570 const bool hash = ( obase->op_type == OP_PADHV
15571 || obase->op_type == OP_RV2HV
15572 || (obase->op_type == OP_PADRANGE
15573 && SvTYPE(PAD_SVl(obase->op_targ)) == SVt_PVHV)
15577 int subscript_type = FUV_SUBSCRIPT_WITHIN;
15579 if (pad) { /* @lex, %lex */
15580 sv = PAD_SVl(obase->op_targ);
15584 if (cUNOPx(obase)->op_first->op_type == OP_GV) {
15585 /* @global, %global */
15586 gv = cGVOPx_gv(cUNOPx(obase)->op_first);
15589 sv = hash ? MUTABLE_SV(GvHV(gv)): MUTABLE_SV(GvAV(gv));
15591 else if (obase == PL_op) /* @{expr}, %{expr} */
15592 return find_uninit_var(cUNOPx(obase)->op_first,
15593 uninit_sv, match, desc_p);
15594 else /* @{expr}, %{expr} as a sub-expression */
15598 /* attempt to find a match within the aggregate */
15600 keysv = find_hash_subscript((const HV*)sv, uninit_sv);
15602 subscript_type = FUV_SUBSCRIPT_HASH;
15605 index = find_array_subscript((const AV *)sv, uninit_sv);
15607 subscript_type = FUV_SUBSCRIPT_ARRAY;
15610 if (match && subscript_type == FUV_SUBSCRIPT_WITHIN)
15613 return varname(gv, (char)(hash ? '%' : '@'), obase->op_targ,
15614 keysv, index, subscript_type);
15618 if (cUNOPx(obase)->op_first->op_type == OP_GV) {
15620 gv = cGVOPx_gv(cUNOPx(obase)->op_first);
15621 if (!gv || !GvSTASH(gv))
15623 if (match && (GvSV(gv) != uninit_sv))
15625 return varname(gv, '$', 0, NULL, 0, FUV_SUBSCRIPT_NONE);
15628 return find_uninit_var(cUNOPx(obase)->op_first, uninit_sv, 1, desc_p);
15631 if (match && PAD_SVl(obase->op_targ) != uninit_sv)
15633 return varname(NULL, '$', obase->op_targ,
15634 NULL, 0, FUV_SUBSCRIPT_NONE);
15637 gv = cGVOPx_gv(obase);
15638 if (!gv || (match && GvSV(gv) != uninit_sv) || !GvSTASH(gv))
15640 return varname(gv, '$', 0, NULL, 0, FUV_SUBSCRIPT_NONE);
15642 case OP_AELEMFAST_LEX:
15645 AV *av = MUTABLE_AV(PAD_SV(obase->op_targ));
15646 if (!av || SvRMAGICAL(av))
15648 svp = av_fetch(av, (I8)obase->op_private, FALSE);
15649 if (!svp || *svp != uninit_sv)
15652 return varname(NULL, '$', obase->op_targ,
15653 NULL, (I8)obase->op_private, FUV_SUBSCRIPT_ARRAY);
15656 gv = cGVOPx_gv(obase);
15661 AV *const av = GvAV(gv);
15662 if (!av || SvRMAGICAL(av))
15664 svp = av_fetch(av, (I8)obase->op_private, FALSE);
15665 if (!svp || *svp != uninit_sv)
15668 return varname(gv, '$', 0,
15669 NULL, (I8)obase->op_private, FUV_SUBSCRIPT_ARRAY);
15671 NOT_REACHED; /* NOTREACHED */
15674 o = cUNOPx(obase)->op_first;
15675 if (!o || o->op_type != OP_NULL ||
15676 ! (o->op_targ == OP_AELEM || o->op_targ == OP_HELEM))
15678 return find_uninit_var(cBINOPo->op_last, uninit_sv, match, desc_p);
15683 bool negate = FALSE;
15685 if (PL_op == obase)
15686 /* $a[uninit_expr] or $h{uninit_expr} */
15687 return find_uninit_var(cBINOPx(obase)->op_last,
15688 uninit_sv, match, desc_p);
15691 o = cBINOPx(obase)->op_first;
15692 kid = cBINOPx(obase)->op_last;
15694 /* get the av or hv, and optionally the gv */
15696 if (o->op_type == OP_PADAV || o->op_type == OP_PADHV) {
15697 sv = PAD_SV(o->op_targ);
15699 else if ((o->op_type == OP_RV2AV || o->op_type == OP_RV2HV)
15700 && cUNOPo->op_first->op_type == OP_GV)
15702 gv = cGVOPx_gv(cUNOPo->op_first);
15706 == OP_RV2HV ? MUTABLE_SV(GvHV(gv)) : MUTABLE_SV(GvAV(gv));
15711 if (kid && kid->op_type == OP_NEGATE) {
15713 kid = cUNOPx(kid)->op_first;
15716 if (kid && kid->op_type == OP_CONST && SvOK(cSVOPx_sv(kid))) {
15717 /* index is constant */
15720 kidsv = newSVpvs_flags("-", SVs_TEMP);
15721 sv_catsv(kidsv, cSVOPx_sv(kid));
15724 kidsv = cSVOPx_sv(kid);
15728 if (obase->op_type == OP_HELEM) {
15729 HE* he = hv_fetch_ent(MUTABLE_HV(sv), kidsv, 0, 0);
15730 if (!he || HeVAL(he) != uninit_sv)
15734 SV * const opsv = cSVOPx_sv(kid);
15735 const IV opsviv = SvIV(opsv);
15736 SV * const * const svp = av_fetch(MUTABLE_AV(sv),
15737 negate ? - opsviv : opsviv,
15739 if (!svp || *svp != uninit_sv)
15743 if (obase->op_type == OP_HELEM)
15744 return varname(gv, '%', o->op_targ,
15745 kidsv, 0, FUV_SUBSCRIPT_HASH);
15747 return varname(gv, '@', o->op_targ, NULL,
15748 negate ? - SvIV(cSVOPx_sv(kid)) : SvIV(cSVOPx_sv(kid)),
15749 FUV_SUBSCRIPT_ARRAY);
15752 /* index is an expression;
15753 * attempt to find a match within the aggregate */
15754 if (obase->op_type == OP_HELEM) {
15755 SV * const keysv = find_hash_subscript((const HV*)sv, uninit_sv);
15757 return varname(gv, '%', o->op_targ,
15758 keysv, 0, FUV_SUBSCRIPT_HASH);
15762 = find_array_subscript((const AV *)sv, uninit_sv);
15764 return varname(gv, '@', o->op_targ,
15765 NULL, index, FUV_SUBSCRIPT_ARRAY);
15770 (char)((o->op_type == OP_PADAV || o->op_type == OP_RV2AV)
15772 o->op_targ, NULL, 0, FUV_SUBSCRIPT_WITHIN);
15774 NOT_REACHED; /* NOTREACHED */
15777 case OP_MULTIDEREF: {
15778 /* If we were executing OP_MULTIDEREF when the undef warning
15779 * triggered, then it must be one of the index values within
15780 * that triggered it. If not, then the only possibility is that
15781 * the value retrieved by the last aggregate lookup might be the
15782 * culprit. For the former, we set PL_multideref_pc each time before
15783 * using an index, so work though the item list until we reach
15784 * that point. For the latter, just work through the entire item
15785 * list; the last aggregate retrieved will be the candidate.
15788 /* the named aggregate, if any */
15789 PADOFFSET agg_targ = 0;
15791 /* the last-seen index */
15793 PADOFFSET index_targ;
15795 IV index_const_iv = 0; /* init for spurious compiler warn */
15796 SV *index_const_sv;
15797 int depth = 0; /* how many array/hash lookups we've done */
15799 UNOP_AUX_item *items = cUNOP_AUXx(obase)->op_aux;
15800 UNOP_AUX_item *last = NULL;
15801 UV actions = items->uv;
15804 if (PL_op == obase) {
15805 last = PL_multideref_pc;
15806 assert(last >= items && last <= items + items[-1].uv);
15813 switch (actions & MDEREF_ACTION_MASK) {
15815 case MDEREF_reload:
15816 actions = (++items)->uv;
15819 case MDEREF_HV_padhv_helem: /* $lex{...} */
15822 case MDEREF_AV_padav_aelem: /* $lex[...] */
15823 agg_targ = (++items)->pad_offset;
15827 case MDEREF_HV_gvhv_helem: /* $pkg{...} */
15830 case MDEREF_AV_gvav_aelem: /* $pkg[...] */
15832 agg_gv = (GV*)UNOP_AUX_item_sv(++items);
15833 assert(isGV_with_GP(agg_gv));
15836 case MDEREF_HV_gvsv_vivify_rv2hv_helem: /* $pkg->{...} */
15837 case MDEREF_HV_padsv_vivify_rv2hv_helem: /* $lex->{...} */
15840 case MDEREF_HV_pop_rv2hv_helem: /* expr->{...} */
15841 case MDEREF_HV_vivify_rv2hv_helem: /* vivify, ->{...} */
15847 case MDEREF_AV_gvsv_vivify_rv2av_aelem: /* $pkg->[...] */
15848 case MDEREF_AV_padsv_vivify_rv2av_aelem: /* $lex->[...] */
15851 case MDEREF_AV_pop_rv2av_aelem: /* expr->[...] */
15852 case MDEREF_AV_vivify_rv2av_aelem: /* vivify, ->[...] */
15859 index_const_sv = NULL;
15861 index_type = (actions & MDEREF_INDEX_MASK);
15862 switch (index_type) {
15863 case MDEREF_INDEX_none:
15865 case MDEREF_INDEX_const:
15867 index_const_sv = UNOP_AUX_item_sv(++items)
15869 index_const_iv = (++items)->iv;
15871 case MDEREF_INDEX_padsv:
15872 index_targ = (++items)->pad_offset;
15874 case MDEREF_INDEX_gvsv:
15875 index_gv = (GV*)UNOP_AUX_item_sv(++items);
15876 assert(isGV_with_GP(index_gv));
15880 if (index_type != MDEREF_INDEX_none)
15883 if ( index_type == MDEREF_INDEX_none
15884 || (actions & MDEREF_FLAG_last)
15885 || (last && items == last)
15889 actions >>= MDEREF_SHIFT;
15892 if (PL_op == obase) {
15893 /* index was undef */
15895 *desc_p = ( (actions & MDEREF_FLAG_last)
15896 && (obase->op_private
15897 & (OPpMULTIDEREF_EXISTS|OPpMULTIDEREF_DELETE)))
15899 (obase->op_private & OPpMULTIDEREF_EXISTS)
15902 : is_hv ? "hash element" : "array element";
15903 assert(index_type != MDEREF_INDEX_none);
15905 return varname(index_gv, '$', 0, NULL, 0, FUV_SUBSCRIPT_NONE);
15907 return varname(NULL, '$', index_targ,
15908 NULL, 0, FUV_SUBSCRIPT_NONE);
15909 assert(is_hv); /* AV index is an IV and can't be undef */
15910 /* can a const HV index ever be undef? */
15914 /* the SV returned by pp_multideref() was undef, if anything was */
15920 sv = PAD_SV(agg_targ);
15922 sv = is_hv ? MUTABLE_SV(GvHV(agg_gv)) : MUTABLE_SV(GvAV(agg_gv));
15926 if (index_type == MDEREF_INDEX_const) {
15931 HE* he = hv_fetch_ent(MUTABLE_HV(sv), index_const_sv, 0, 0);
15932 if (!he || HeVAL(he) != uninit_sv)
15936 SV * const * const svp =
15937 av_fetch(MUTABLE_AV(sv), index_const_iv, FALSE);
15938 if (!svp || *svp != uninit_sv)
15943 ? varname(agg_gv, '%', agg_targ,
15944 index_const_sv, 0, FUV_SUBSCRIPT_HASH)
15945 : varname(agg_gv, '@', agg_targ,
15946 NULL, index_const_iv, FUV_SUBSCRIPT_ARRAY);
15949 /* index is an var */
15951 SV * const keysv = find_hash_subscript((const HV*)sv, uninit_sv);
15953 return varname(agg_gv, '%', agg_targ,
15954 keysv, 0, FUV_SUBSCRIPT_HASH);
15958 = find_array_subscript((const AV *)sv, uninit_sv);
15960 return varname(agg_gv, '@', agg_targ,
15961 NULL, index, FUV_SUBSCRIPT_ARRAY);
15965 return varname(agg_gv,
15967 agg_targ, NULL, 0, FUV_SUBSCRIPT_WITHIN);
15969 NOT_REACHED; /* NOTREACHED */
15973 /* only examine RHS */
15974 return find_uninit_var(cBINOPx(obase)->op_first, uninit_sv,
15978 o = cUNOPx(obase)->op_first;
15979 if ( o->op_type == OP_PUSHMARK
15980 || (o->op_type == OP_NULL && o->op_targ == OP_PUSHMARK)
15984 if (!OpHAS_SIBLING(o)) {
15985 /* one-arg version of open is highly magical */
15987 if (o->op_type == OP_GV) { /* open FOO; */
15989 if (match && GvSV(gv) != uninit_sv)
15991 return varname(gv, '$', 0,
15992 NULL, 0, FUV_SUBSCRIPT_NONE);
15994 /* other possibilities not handled are:
15995 * open $x; or open my $x; should return '${*$x}'
15996 * open expr; should return '$'.expr ideally
16002 /* ops where $_ may be an implicit arg */
16007 if ( !(obase->op_flags & OPf_STACKED)) {
16008 if (uninit_sv == DEFSV)
16009 return newSVpvs_flags("$_", SVs_TEMP);
16010 else if (obase->op_targ
16011 && uninit_sv == PAD_SVl(obase->op_targ))
16012 return varname(NULL, '$', obase->op_targ, NULL, 0,
16013 FUV_SUBSCRIPT_NONE);
16020 match = 1; /* print etc can return undef on defined args */
16021 /* skip filehandle as it can't produce 'undef' warning */
16022 o = cUNOPx(obase)->op_first;
16023 if ((obase->op_flags & OPf_STACKED)
16025 ( o->op_type == OP_PUSHMARK
16026 || (o->op_type == OP_NULL && o->op_targ == OP_PUSHMARK)))
16027 o = OpSIBLING(OpSIBLING(o));
16031 case OP_ENTEREVAL: /* could be eval $undef or $x='$undef'; eval $x */
16032 case OP_CUSTOM: /* XS or custom code could trigger random warnings */
16034 /* the following ops are capable of returning PL_sv_undef even for
16035 * defined arg(s) */
16054 case OP_GETPEERNAME:
16102 case OP_SMARTMATCH:
16111 /* XXX tmp hack: these two may call an XS sub, and currently
16112 XS subs don't have a SUB entry on the context stack, so CV and
16113 pad determination goes wrong, and BAD things happen. So, just
16114 don't try to determine the value under those circumstances.
16115 Need a better fix at dome point. DAPM 11/2007 */
16121 GV * const gv = gv_fetchpvs(".", GV_NOTQUAL, SVt_PV);
16122 if (gv && GvSV(gv) == uninit_sv)
16123 return newSVpvs_flags("$.", SVs_TEMP);
16128 /* def-ness of rval pos() is independent of the def-ness of its arg */
16129 if ( !(obase->op_flags & OPf_MOD))
16134 if (SvROK(PL_rs) && uninit_sv == SvRV(PL_rs))
16135 return newSVpvs_flags("${$/}", SVs_TEMP);
16140 if (!(obase->op_flags & OPf_KIDS))
16142 o = cUNOPx(obase)->op_first;
16148 /* This loop checks all the kid ops, skipping any that cannot pos-
16149 * sibly be responsible for the uninitialized value; i.e., defined
16150 * constants and ops that return nothing. If there is only one op
16151 * left that is not skipped, then we *know* it is responsible for
16152 * the uninitialized value. If there is more than one op left, we
16153 * have to look for an exact match in the while() loop below.
16154 * Note that we skip padrange, because the individual pad ops that
16155 * it replaced are still in the tree, so we work on them instead.
16158 for (kid=o; kid; kid = OpSIBLING(kid)) {
16159 const OPCODE type = kid->op_type;
16160 if ( (type == OP_CONST && SvOK(cSVOPx_sv(kid)))
16161 || (type == OP_NULL && ! (kid->op_flags & OPf_KIDS))
16162 || (type == OP_PUSHMARK)
16163 || (type == OP_PADRANGE)
16167 if (o2) { /* more than one found */
16174 return find_uninit_var(o2, uninit_sv, match, desc_p);
16176 /* scan all args */
16178 sv = find_uninit_var(o, uninit_sv, 1, desc_p);
16190 =for apidoc report_uninit
16192 Print appropriate "Use of uninitialized variable" warning.
16198 Perl_report_uninit(pTHX_ const SV *uninit_sv)
16201 SV* varname = NULL;
16204 desc = PL_op->op_type == OP_STRINGIFY && PL_op->op_folded
16207 if (uninit_sv && PL_curpad) {
16208 varname = find_uninit_var(PL_op, uninit_sv, 0, &desc);
16210 sv_insert(varname, 0, 0, " ", 1);
16212 /* PL_warn_uninit_sv is constant */
16213 GCC_DIAG_IGNORE(-Wformat-nonliteral);
16214 /* diag_listed_as: Use of uninitialized value%s */
16215 Perl_warner(aTHX_ packWARN(WARN_UNINITIALIZED), PL_warn_uninit_sv,
16216 SVfARG(varname ? varname : &PL_sv_no),
16221 /* PL_warn_uninit is constant */
16222 GCC_DIAG_IGNORE(-Wformat-nonliteral);
16223 Perl_warner(aTHX_ packWARN(WARN_UNINITIALIZED), PL_warn_uninit,
16230 * ex: set ts=8 sts=4 sw=4 et: