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av.c
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/* av.c
*
* Copyright (C) 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
* 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008 by Larry Wall and others
*
* You may distribute under the terms of either the GNU General Public
* License or the Artistic License, as specified in the README file.
*
*/
/*
* '...for the Entwives desired order, and plenty, and peace (by which they
* meant that things should remain where they had set them).' --Treebeard
*
* [p.476 of _The Lord of the Rings_, III/iv: "Treebeard"]
*/
#include "EXTERN.h"
#define PERL_IN_AV_C
#include "perl.h"
void
Perl_av_reify(pTHX_ AV *av)
{
SSize_t key;
PERL_ARGS_ASSERT_AV_REIFY;
assert(SvTYPE(av) == SVt_PVAV);
if (AvREAL(av))
return;
#ifdef DEBUGGING
if (SvTIED_mg((const SV *)av, PERL_MAGIC_tied))
Perl_ck_warner_d(aTHX_ packWARN(WARN_DEBUGGING), "av_reify called on tied array");
#endif
key = AvMAX(av) + 1;
while (key > AvFILLp(av) + 1)
AvARRAY(av)[--key] = NULL;
while (key) {
SV * const sv = AvARRAY(av)[--key];
if (sv != &PL_sv_undef)
SvREFCNT_inc_simple_void(sv);
}
key = AvARRAY(av) - AvALLOC(av);
if (key)
Zero(AvALLOC(av), key, SV*);
AvREIFY_off(av);
AvREAL_on(av);
}
/*
=for apidoc av_extend
Pre-extend an array so that it is capable of storing values at indexes
C<0..key>. Thus C<av_extend(av,99)> guarantees that the array can store 100
elements, i.e. that C<av_store(av, 0, sv)> through C<av_store(av, 99, sv)>
on a plain array will work without any further memory allocation.
If the av argument is a tied array then will call the C<EXTEND> tied
array method with an argument of C<(key+1)>.
=cut
*/
void
Perl_av_extend(pTHX_ AV *av, SSize_t key)
{
MAGIC *mg;
PERL_ARGS_ASSERT_AV_EXTEND;
assert(SvTYPE(av) == SVt_PVAV);
mg = SvTIED_mg((const SV *)av, PERL_MAGIC_tied);
if (mg) {
SV *arg1 = sv_newmortal();
/* NOTE: the API for av_extend() is NOT the same as the tie method EXTEND.
*
* The C function takes an *index* (assumes 0 indexed arrays) and ensures
* that the array is at least as large as the index provided.
*
* The tied array method EXTEND takes a *count* and ensures that the array
* is at least that many elements large. Thus we have to +1 the key when
* we call the tied method.
*/
sv_setiv(arg1, (IV)(key + 1));
Perl_magic_methcall(aTHX_ MUTABLE_SV(av), mg, SV_CONST(EXTEND), G_DISCARD, 1,
arg1);
return;
}
av_extend_guts(av,key,&AvMAX(av),&AvALLOC(av),&AvARRAY(av));
}
/* The guts of av_extend. *Not* for general use! */
/* Also called directly from pp_assign, padlist_store, padnamelist_store */
void
Perl_av_extend_guts(pTHX_ AV *av, SSize_t key, SSize_t *maxp, SV ***allocp,
SV ***arrayp)
{
PERL_ARGS_ASSERT_AV_EXTEND_GUTS;
if (key < -1) /* -1 is legal */
Perl_croak(aTHX_
"panic: av_extend_guts() negative count (%" IVdf ")", (IV)key);
if (key > *maxp) {
SSize_t ary_offset = *maxp + 1; /* Start NULL initialization
* from this element */
SSize_t to_null = 0; /* How many elements to Zero */
SSize_t newmax = 0;
if (av && *allocp != *arrayp) { /* a shifted SV* array exists */
/* to_null will contain the number of elements currently
* shifted and about to be unshifted. If the array has not
* been shifted to the maximum possible extent, this will be
* a smaller number than (*maxp - AvFILLp(av)). */
to_null = *arrayp - *allocp;
*maxp += to_null;
ary_offset = AvFILLp(av) + 1;
Move(*arrayp, *allocp, AvFILLp(av)+1, SV*);
if (key > *maxp - 10) {
newmax = key + *maxp;
/* Zero everything above AvFILLp(av), which could be more
* elements than have actually been shifted. If we don't
* do this, trailing elements at the end of the resized
* array may not be correctly initialized. */
to_null = *maxp - AvFILLp(av);
goto resize;
}
} else if (*allocp) { /* a full SV* array exists */
#ifdef Perl_safesysmalloc_size
/* Whilst it would be quite possible to move this logic around
(as I did in the SV code), so as to set AvMAX(av) early,
based on calling Perl_safesysmalloc_size() immediately after
allocation, I'm not convinced that it is a great idea here.
In an array we have to loop round setting everything to
NULL, which means writing to memory, potentially lots
of it, whereas for the SV buffer case we don't touch the
"bonus" memory. So there there is no cost in telling the
world about it, whereas here we have to do work before we can
tell the world about it, and that work involves writing to
memory that might never be read. So, I feel, better to keep
the current lazy system of only writing to it if our caller
has a need for more space. NWC */
newmax = Perl_safesysmalloc_size((void*)*allocp) /
sizeof(const SV *) - 1;
if (key <= newmax)
goto resized;
#endif
/* overflow-safe version of newmax = key + *maxp/5 */
newmax = *maxp / 5;
newmax = (key > SSize_t_MAX - newmax)
? SSize_t_MAX : key + newmax;
resize:
{
/* it should really be newmax+1 here, but if newmax
* happens to equal SSize_t_MAX, then newmax+1 is
* undefined. This means technically we croak one
* index lower than we should in theory; in practice
* its unlikely the system has SSize_t_MAX/sizeof(SV*)
* bytes to spare! */
MEM_WRAP_CHECK_s(newmax, SV*, "Out of memory during array extend");
}
#ifdef STRESS_REALLOC
{
SV ** const old_alloc = *allocp;
Newx(*allocp, newmax+1, SV*);
Copy(old_alloc, *allocp, *maxp + 1, SV*);
Safefree(old_alloc);
}
#else
Renew(*allocp,newmax+1, SV*);
#endif
#ifdef Perl_safesysmalloc_size
resized:
#endif
to_null += newmax - *maxp; /* Initialize all new elements
* (newmax - *maxp) in addition to
* any previously specified */
*maxp = newmax;
/* See GH#18014 for discussion of when this might be needed: */
if (av == PL_curstack) { /* Oops, grew stack (via av_store()?) */
PL_stack_sp = *allocp + (PL_stack_sp - PL_stack_base);
PL_stack_base = *allocp;
PL_stack_max = PL_stack_base + newmax;
}
} else { /* there is no SV* array yet */
*maxp = key < PERL_ARRAY_NEW_MIN_KEY ?
PERL_ARRAY_NEW_MIN_KEY : key;
{
/* see comment above about newmax+1*/
MEM_WRAP_CHECK_s(*maxp, SV*,
"Out of memory during array extend");
}
/* Newxz isn't used below because testing showed it to be slower
* than Newx+Zero (also slower than Newx + the previous while
* loop) for small arrays, which are very common in perl. */
Newx(*allocp, *maxp+1, SV*);
/* Stacks require only the first element to be &PL_sv_undef
* (set elsewhere). However, since non-stack AVs are likely
* to dominate in modern production applications, stacks
* don't get any special treatment here.
* See https://github.com/Perl/perl5/pull/18690 for more detail */
ary_offset = 0;
to_null = *maxp+1; /* Initialize all new array elements */
goto zero;
}
if (av && AvREAL(av)) {
zero:
Zero(*allocp + ary_offset,to_null,SV*);
}
*arrayp = *allocp;
}
}
/*
=for apidoc av_fetch
Returns the SV at the specified index in the array. The C<key> is the
index. If C<lval> is true, you are guaranteed to get a real SV back (in case
it wasn't real before), which you can then modify. Check that the return
value is non-NULL before dereferencing it to a C<SV*>.
See L<perlguts/"Understanding the Magic of Tied Hashes and Arrays"> for
more information on how to use this function on tied arrays.
The rough perl equivalent is C<$myarray[$key]>.
=cut
*/
static bool
S_adjust_index(pTHX_ AV *av, const MAGIC *mg, SSize_t *keyp)
{
bool adjust_index = 1;
if (mg) {
/* Handle negative array indices 20020222 MJD */
SV * const ref = SvTIED_obj(MUTABLE_SV(av), mg);
SvGETMAGIC(ref);
if (SvROK(ref) && SvOBJECT(SvRV(ref))) {
SV * const * const negative_indices_glob =
hv_fetchs(SvSTASH(SvRV(ref)), NEGATIVE_INDICES_VAR, 0);
if (negative_indices_glob && isGV(*negative_indices_glob)
&& SvTRUE(GvSV(*negative_indices_glob)))
adjust_index = 0;
}
}
if (adjust_index) {
*keyp += AvFILL(av) + 1;
if (*keyp < 0)
return FALSE;
}
return TRUE;
}
SV**
Perl_av_fetch(pTHX_ AV *av, SSize_t key, I32 lval)
{
SSize_t neg;
SSize_t size;
PERL_ARGS_ASSERT_AV_FETCH;
assert(SvTYPE(av) == SVt_PVAV);
if (UNLIKELY(SvRMAGICAL(av))) {
const MAGIC * const tied_magic
= mg_find((const SV *)av, PERL_MAGIC_tied);
if (tied_magic || mg_find((const SV *)av, PERL_MAGIC_regdata)) {
SV *sv;
if (key < 0) {
if (!S_adjust_index(aTHX_ av, tied_magic, &key))
return NULL;
}
sv = newSV_type_mortal(SVt_PVLV);
mg_copy(MUTABLE_SV(av), sv, 0, key);
if (!tied_magic) /* for regdata, force leavesub to make copies */
SvTEMP_off(sv);
LvTYPE(sv) = 't';
LvTARG(sv) = sv; /* fake (SV**) */
return &(LvTARG(sv));
}
}
neg = (key < 0);
size = AvFILLp(av) + 1;
key += neg * size; /* handle negative index without using branch */
/* the cast from SSize_t to Size_t allows both (key < 0) and (key >= size)
* to be tested as a single condition */
if ((Size_t)key >= (Size_t)size) {
if (UNLIKELY(neg))
return NULL;
goto emptiness;
}
if (!AvARRAY(av)[key]) {
emptiness:
return lval ? av_store(av,key,newSV_type(SVt_NULL)) : NULL;
}
return &AvARRAY(av)[key];
}
/*
=for apidoc av_store
Stores an SV in an array. The array index is specified as C<key>. The
return value will be C<NULL> if the operation failed or if the value did not
need to be actually stored within the array (as in the case of tied
arrays). Otherwise, it can be dereferenced
to get the C<SV*> that was stored
there (= C<val>)).
Note that the caller is responsible for suitably incrementing the reference
count of C<val> before the call, and decrementing it if the function
returned C<NULL>.
Approximate Perl equivalent: C<splice(@myarray, $key, 1, $val)>.
See L<perlguts/"Understanding the Magic of Tied Hashes and Arrays"> for
more information on how to use this function on tied arrays.
=cut
*/
SV**
Perl_av_store(pTHX_ AV *av, SSize_t key, SV *val)
{
SV** ary;
PERL_ARGS_ASSERT_AV_STORE;
assert(SvTYPE(av) == SVt_PVAV);
/* S_regclass relies on being able to pass in a NULL sv
(unicode_alternate may be NULL).
*/
if (SvRMAGICAL(av)) {
const MAGIC * const tied_magic = mg_find((const SV *)av, PERL_MAGIC_tied);
if (tied_magic) {
if (key < 0) {
if (!S_adjust_index(aTHX_ av, tied_magic, &key))
return 0;
}
if (val) {
mg_copy(MUTABLE_SV(av), val, 0, key);
}
return NULL;
}
}
if (key < 0) {
key += AvFILL(av) + 1;
if (key < 0)
return NULL;
}
if (SvREADONLY(av) && key >= AvFILL(av))
Perl_croak_no_modify();
if (!AvREAL(av) && AvREIFY(av))
av_reify(av);
if (key > AvMAX(av))
av_extend(av,key);
ary = AvARRAY(av);
if (AvFILLp(av) < key) {
if (!AvREAL(av)) {
if (av == PL_curstack && key > PL_stack_sp - PL_stack_base)
PL_stack_sp = PL_stack_base + key; /* XPUSH in disguise */
do {
ary[++AvFILLp(av)] = NULL;
} while (AvFILLp(av) < key);
}
AvFILLp(av) = key;
}
else if (AvREAL(av))
SvREFCNT_dec(ary[key]);
/* store the val into the AV before we call magic so that the magic can
* "see" the new value. Especially set magic on the AV itself. */
ary[key] = val;
if (SvSMAGICAL(av)) {
const MAGIC *mg = SvMAGIC(av);
bool set = TRUE;
/* We have to increment the refcount on val before we call any magic,
* as it is now stored in the AV (just before this block), we will
* then call the magic handlers which might die/Perl_croak, and
* longjmp up the stack to the most recent exception trap. Which means
* the caller code that would be expected to handle the refcount
* increment likely would never be executed, leading to a double free.
* This can happen in a case like
*
* @ary = (1);
*
* or this:
*
* if (av_store(av,n,sv)) SvREFCNT_inc(sv);
*
* where @ary/av has set magic applied to it which can die. In the
* first case the sv representing 1 would be mortalized, so when the
* set magic threw an exception it would be freed as part of the
* normal stack unwind. However this leaves the av structure still
* holding a valid visible pointer to the now freed value. In practice
* the next SV created will reuse the same reference, but without the
* refcount to account for the previous ownership and we end up with
* warnings about a totally different variable being double freed in
* the form of "attempt to free unreferenced variable"
* warnings/errors.
*
* https://github.com/Perl/perl5/issues/20675
*
* Arguably the API for av_store is broken in the face of magic. Instead
* av_store should be responsible for the refcount increment, and only
* not do it when specifically told to do so (eg, when storing an
* otherwise unreferenced scalar into an AV).
*/
SvREFCNT_inc(val); /* see comment above */
for (; mg; mg = mg->mg_moremagic) {
if (!isUPPER(mg->mg_type)) continue;
if (val) {
sv_magic(val, MUTABLE_SV(av), toLOWER(mg->mg_type), 0, key);
}
if (PL_delaymagic && mg->mg_type == PERL_MAGIC_isa) {
PL_delaymagic |= DM_ARRAY_ISA;
set = FALSE;
}
}
if (set)
mg_set(MUTABLE_SV(av));
/* And now we are done the magic, we have to decrement it back as the av_store() api
* says the caller is responsible for the refcount increment, assuming
* av_store returns true. */
SvREFCNT_dec(val);
}
return &ary[key];
}
/*
=for apidoc av_make
Creates a new AV and populates it with a list (C<**strp>, length C<size>) of
SVs. A copy is made of each SV, so their refcounts are not changed. The new
AV will have a reference count of 1.
Perl equivalent: C<my @new_array = ($scalar1, $scalar2, $scalar3...);>
=cut
*/
AV *
Perl_av_make(pTHX_ SSize_t size, SV **strp)
{
AV * const av = newAV();
/* sv_upgrade does AvREAL_only() */
PERL_ARGS_ASSERT_AV_MAKE;
assert(SvTYPE(av) == SVt_PVAV);
if (size) { /* "defined" was returning undef for size==0 anyway. */
SV** ary;
SSize_t i;
SSize_t orig_ix;
Newx(ary,size,SV*);
AvALLOC(av) = ary;
AvARRAY(av) = ary;
AvMAX(av) = size - 1;
/* avoid av being leaked if croak when calling magic below */
EXTEND_MORTAL(1);
PL_tmps_stack[++PL_tmps_ix] = (SV*)av;
orig_ix = PL_tmps_ix;
for (i = 0; i < size; i++) {
assert (*strp);
/* Don't let sv_setsv swipe, since our source array might
have multiple references to the same temp scalar (e.g.
from a list slice) */
SvGETMAGIC(*strp); /* before newSV, in case it dies */
AvFILLp(av)++;
ary[i] = newSV_type(SVt_NULL);
sv_setsv_flags(ary[i], *strp,
SV_DO_COW_SVSETSV|SV_NOSTEAL);
strp++;
}
/* disarm av's leak guard */
if (LIKELY(PL_tmps_ix == orig_ix))
PL_tmps_ix--;
else
PL_tmps_stack[orig_ix] = &PL_sv_undef;
}
return av;
}
/*
=for apidoc newAVav
Creates a new AV and populates it with values copied from an existing AV. The
new AV will have a reference count of 1, and will contain newly created SVs
copied from the original SV. The original source will remain unchanged.
Perl equivalent: C<my @new_array = @existing_array;>
=cut
*/
AV *
Perl_newAVav(pTHX_ AV *oav)
{
PERL_ARGS_ASSERT_NEWAVAV;
Size_t count = av_count(oav);
if(UNLIKELY(!oav) || count == 0)
return newAV();
AV *ret = newAV_alloc_x(count);
/* avoid ret being leaked if croak when calling magic below */
EXTEND_MORTAL(1);
PL_tmps_stack[++PL_tmps_ix] = (SV *)ret;
SSize_t ret_at_tmps_ix = PL_tmps_ix;
Size_t i;
if(LIKELY(!SvRMAGICAL(oav) && AvREAL(oav) && (SvTYPE(oav) == SVt_PVAV))) {
for(i = 0; i < count; i++) {
SV **svp = av_fetch_simple(oav, i, 0);
av_push_simple(ret, svp ? newSVsv(*svp) : &PL_sv_undef);
}
} else {
for(i = 0; i < count; i++) {
SV **svp = av_fetch(oav, i, 0);
av_push_simple(ret, svp ? newSVsv(*svp) : &PL_sv_undef);
}
}
/* disarm leak guard */
if(LIKELY(PL_tmps_ix == ret_at_tmps_ix))
PL_tmps_ix--;
else
PL_tmps_stack[ret_at_tmps_ix] = &PL_sv_undef;
return ret;
}
/*
=for apidoc newAVhv
Creates a new AV and populates it with keys and values copied from an existing
HV. The new AV will have a reference count of 1, and will contain newly
created SVs copied from the original HV. The original source will remain
unchanged.
Perl equivalent: C<my @new_array = %existing_hash;>
=cut
*/
AV *
Perl_newAVhv(pTHX_ HV *ohv)
{
PERL_ARGS_ASSERT_NEWAVHV;
if(UNLIKELY(!ohv))
return newAV();
bool tied = SvRMAGICAL(ohv) && mg_find(MUTABLE_SV(ohv), PERL_MAGIC_tied);
Size_t nkeys = hv_iterinit(ohv);
/* This number isn't perfect but it doesn't matter; it only has to be
* close to make the initial allocation about the right size
*/
AV *ret = newAV_alloc_xz(nkeys ? nkeys * 2 : 2);
/* avoid ret being leaked if croak when calling magic below */
EXTEND_MORTAL(1);
PL_tmps_stack[++PL_tmps_ix] = (SV *)ret;
SSize_t ret_at_tmps_ix = PL_tmps_ix;
HE *he;
while((he = hv_iternext(ohv))) {
if(tied) {
av_push_simple(ret, newSVsv(hv_iterkeysv(he)));
av_push_simple(ret, newSVsv(hv_iterval(ohv, he)));
}
else {
av_push_simple(ret, newSVhek(HeKEY_hek(he)));
av_push_simple(ret, HeVAL(he) ? newSVsv(HeVAL(he)) : &PL_sv_undef);
}
}
/* disarm leak guard */
if(LIKELY(PL_tmps_ix == ret_at_tmps_ix))
PL_tmps_ix--;
else
PL_tmps_stack[ret_at_tmps_ix] = &PL_sv_undef;
return ret;
}
/*
=for apidoc av_clear
Frees all the elements of an array, leaving it empty.
The XS equivalent of C<@array = ()>. See also L</av_undef>.
Note that it is possible that the actions of a destructor called directly
or indirectly by freeing an element of the array could cause the reference
count of the array itself to be reduced (e.g. by deleting an entry in the
symbol table). So it is a possibility that the AV could have been freed
(or even reallocated) on return from the call unless you hold a reference
to it.
=cut
*/
void
Perl_av_clear(pTHX_ AV *av)
{
bool real;
SSize_t orig_ix = 0;
PERL_ARGS_ASSERT_AV_CLEAR;
assert(SvTYPE(av) == SVt_PVAV);
#ifdef DEBUGGING
if (SvREFCNT(av) == 0) {
Perl_ck_warner_d(aTHX_ packWARN(WARN_DEBUGGING), "Attempt to clear deleted array");
}
#endif
if (SvREADONLY(av))
Perl_croak_no_modify();
/* Give any tie a chance to cleanup first */
if (SvRMAGICAL(av)) {
const MAGIC* const mg = SvMAGIC(av);
if (PL_delaymagic && mg && mg->mg_type == PERL_MAGIC_isa)
PL_delaymagic |= DM_ARRAY_ISA;
else
mg_clear(MUTABLE_SV(av));
}
if (AvMAX(av) < 0)
return;
if ((real = cBOOL(AvREAL(av)))) {
SV** const ary = AvARRAY(av);
SSize_t index = AvFILLp(av) + 1;
/* avoid av being freed when calling destructors below */
EXTEND_MORTAL(1);
PL_tmps_stack[++PL_tmps_ix] = SvREFCNT_inc_simple_NN(av);
orig_ix = PL_tmps_ix;
while (index) {
SV * const sv = ary[--index];
/* undef the slot before freeing the value, because a
* destructor might try to modify this array */
ary[index] = NULL;
SvREFCNT_dec(sv);
}
}
AvFILLp(av) = -1;
av_remove_offset(av);
if (real) {
/* disarm av's premature free guard */
if (LIKELY(PL_tmps_ix == orig_ix))
PL_tmps_ix--;
else
PL_tmps_stack[orig_ix] = &PL_sv_undef;
SvREFCNT_dec_NN(av);
}
}
/*
=for apidoc av_undef
Undefines the array. The XS equivalent of C<undef(@array)>.
As well as freeing all the elements of the array (like C<av_clear()>), this
also frees the memory used by the av to store its list of scalars.
See L</av_clear> for a note about the array possibly being invalid on
return.
=cut
*/
void
Perl_av_undef(pTHX_ AV *av)
{
bool real;
SSize_t orig_ix = PL_tmps_ix; /* silence bogus warning about possible uninitialized use */
PERL_ARGS_ASSERT_AV_UNDEF;
assert(SvTYPE(av) == SVt_PVAV);
/* Give any tie a chance to cleanup first */
if (SvTIED_mg((const SV *)av, PERL_MAGIC_tied))
av_fill(av, -1);
real = cBOOL(AvREAL(av));
if (real) {
SSize_t key = AvFILLp(av) + 1;
/* avoid av being freed when calling destructors below */
EXTEND_MORTAL(1);
PL_tmps_stack[++PL_tmps_ix] = SvREFCNT_inc_simple_NN(av);
orig_ix = PL_tmps_ix;
while (key)
SvREFCNT_dec(AvARRAY(av)[--key]);
}
Safefree(AvALLOC(av));
AvALLOC(av) = NULL;
AvARRAY(av) = NULL;
AvMAX(av) = AvFILLp(av) = -1;
if(SvRMAGICAL(av)) mg_clear(MUTABLE_SV(av));
if (real) {
/* disarm av's premature free guard */
if (LIKELY(PL_tmps_ix == orig_ix))
PL_tmps_ix--;
else
PL_tmps_stack[orig_ix] = &PL_sv_undef;
SvREFCNT_dec_NN(av);
}
}
/*
=for apidoc av_create_and_push
Push an SV onto the end of the array, creating the array if necessary.
A small internal helper function to remove a commonly duplicated idiom.
=cut
*/
void
Perl_av_create_and_push(pTHX_ AV **const avp, SV *const val)
{
PERL_ARGS_ASSERT_AV_CREATE_AND_PUSH;
if (!*avp)
*avp = newAV();
av_push(*avp, val);
}
/*
=for apidoc av_push
=for apidoc_item av_push_simple
These each push an SV (transferring control of one reference count) onto the
end of the array. The array will grow automatically to accommodate the
addition.
Perl equivalent: C<push @myarray, $val;>.
C<av_push> is the general purpose form, suitable for all situations.
C<av_push_simple> is a cut-down version of C<av_push> that assumes that the
array is very straightforward, with no magic, not readonly, and is AvREAL
(see L<perlguts/Real AVs - and those that are not>), and that C<key> is not
less than -1. This function MUST NOT be used in situations where any of those
assumptions may not hold.
=cut
*/
void
Perl_av_push(pTHX_ AV *av, SV *val)
{
MAGIC *mg;
PERL_ARGS_ASSERT_AV_PUSH;
assert(SvTYPE(av) == SVt_PVAV);
if (SvREADONLY(av))
Perl_croak_no_modify();
if ((mg = SvTIED_mg((const SV *)av, PERL_MAGIC_tied))) {
Perl_magic_methcall(aTHX_ MUTABLE_SV(av), mg, SV_CONST(PUSH), G_DISCARD, 1,
val);
return;
}
av_store(av,AvFILLp(av)+1,val);
}
/*
=for apidoc av_pop
Removes one SV from the end of the array, reducing its size by one and
returning the SV (transferring control of one reference count) to the
caller. Returns C<&PL_sv_undef> if the array is empty.
Perl equivalent: C<pop(@myarray);>
=cut
*/
SV *
Perl_av_pop(pTHX_ AV *av)
{
SV *retval;
MAGIC* mg;
PERL_ARGS_ASSERT_AV_POP;
assert(SvTYPE(av) == SVt_PVAV);
if (SvREADONLY(av))
Perl_croak_no_modify();
if ((mg = SvTIED_mg((const SV *)av, PERL_MAGIC_tied))) {
retval = Perl_magic_methcall(aTHX_ MUTABLE_SV(av), mg, SV_CONST(POP), 0, 0);
if (retval)
retval = newSVsv(retval);
return retval;
}
if (AvFILL(av) < 0)
return &PL_sv_undef;
retval = AvARRAY(av)[AvFILLp(av)];
AvARRAY(av)[AvFILLp(av)--] = NULL;
if (SvSMAGICAL(av))
mg_set(MUTABLE_SV(av));
return retval ? retval : &PL_sv_undef;
}
/*
=for apidoc av_create_and_unshift_one
Unshifts an SV onto the beginning of the array, creating the array if
necessary.
A small internal helper function to remove a commonly duplicated idiom.
=cut
*/
SV **
Perl_av_create_and_unshift_one(pTHX_ AV **const avp, SV *const val)
{
PERL_ARGS_ASSERT_AV_CREATE_AND_UNSHIFT_ONE;
if (!*avp)
*avp = newAV();
av_unshift(*avp, 1);
return av_store(*avp, 0, val);
}
/*
=for apidoc av_unshift
Unshift the given number of C<undef> values onto the beginning of the
array. The array will grow automatically to accommodate the addition.
Perl equivalent: S<C<unshift @myarray, ((undef) x $num);>>
=cut
*/
void
Perl_av_unshift(pTHX_ AV *av, SSize_t num)
{
SSize_t i;
MAGIC* mg;
PERL_ARGS_ASSERT_AV_UNSHIFT;
assert(SvTYPE(av) == SVt_PVAV);
if (SvREADONLY(av))
Perl_croak_no_modify();
if ((mg = SvTIED_mg((const SV *)av, PERL_MAGIC_tied))) {
Perl_magic_methcall(aTHX_ MUTABLE_SV(av), mg, SV_CONST(UNSHIFT),
G_DISCARD | G_UNDEF_FILL, num);
return;
}
if (num <= 0)
return;
if (!AvREAL(av) && AvREIFY(av))
av_reify(av);
i = AvARRAY(av) - AvALLOC(av);
if (i) {
if (i > num)
i = num;
num -= i;
AvMAX(av) += i;
AvFILLp(av) += i;
AvARRAY(av) = AvARRAY(av) - i;
#ifdef PERL_RC_STACK
Zero(AvARRAY(av), i, SV*);
#endif
}
if (num) {
SV **ary;
const SSize_t i = AvFILLp(av);
/* Create extra elements */
const SSize_t slide = i > 0 ? i : 0;
num += slide;
av_extend(av, i + num);
AvFILLp(av) += num;
ary = AvARRAY(av);
Move(ary, ary + num, i + 1, SV*);
do {
ary[--num] = NULL;
} while (num);
/* Make extra elements into a buffer */
AvMAX(av) -= slide;
AvFILLp(av) -= slide;
AvARRAY(av) = AvARRAY(av) + slide;
}
}
/*
=for apidoc av_shift
Removes one SV from the start of the array, reducing its size by one and
returning the SV (transferring control of one reference count) to the
caller. Returns C<&PL_sv_undef> if the array is empty.
Perl equivalent: C<shift(@myarray);>
=cut
*/
SV *
Perl_av_shift(pTHX_ AV *av)
{
SV *retval;
MAGIC* mg;
PERL_ARGS_ASSERT_AV_SHIFT;
assert(SvTYPE(av) == SVt_PVAV);
if (SvREADONLY(av))
Perl_croak_no_modify();
if ((mg = SvTIED_mg((const SV *)av, PERL_MAGIC_tied))) {
retval = Perl_magic_methcall(aTHX_ MUTABLE_SV(av), mg, SV_CONST(SHIFT), 0, 0);
if (retval)
retval = newSVsv(retval);
return retval;
}
if (AvFILL(av) < 0)
return &PL_sv_undef;
retval = *AvARRAY(av);
#ifndef PERL_RC_STACK
if (AvREAL(av))
*AvARRAY(av) = NULL;
#endif
AvARRAY(av) = AvARRAY(av) + 1;
AvMAX(av)--;
AvFILLp(av)--;
if (SvSMAGICAL(av))
mg_set(MUTABLE_SV(av));
return retval ? retval : &PL_sv_undef;
}
/*
=for apidoc av_top_index
=for apidoc_item av_tindex
=for apidoc_item AvFILL
=for apidoc_item av_len
These behave identically.
If the array C<av> is empty, these return -1; otherwise they return the maximum
value of the indices of all the array elements which are currently defined in
C<av>.
They process 'get' magic.
The Perl equivalent for these is C<$#av>.
Note that, unlike what the name C<av_len> implies, it returns
the maximum index in the array. This is unlike L</sv_len>, which returns what
you would expect. To get the actual number of elements in an array, use
C<L</av_count>>.
=cut
*/