/*
=for apidoc mro_method_changed_in
Invalidates method caching on any child classes
of the given stash, so that they might notice
the changes in this one.
Ideally, all instances of C<PL_sub_generation++> in
perl source outside of F<mro.c> should be
replaced by calls to this.
Perl automatically handles most of the common
ways a method might be redefined. However, there
are a few ways you could change a method in a stash
without the cache code noticing, in which case you
need to call this method afterwards:
1) Directly manipulating the stash HV entries from
XS code.
2) Assigning a reference to a readonly scalar
constant into a stash entry in order to create
a constant subroutine (like F<constant.pm>
does).
This same method is available from pure perl
via, C<mro::method_changed_in(classname)>.
=cut
*/
void
Perl_mro_method_changed_in(pTHX_ HV *stash)
{
const char * const stashname = HvENAME_get(stash);
const STRLEN stashname_len = HvENAMELEN_get(stash);
SV ** const svp = hv_fetchhek(PL_isarev, HvENAME_HEK(stash), 0);
HV * const isarev = svp ? MUTABLE_HV(*svp) : NULL;
PERL_ARGS_ASSERT_MRO_METHOD_CHANGED_IN;
if(!stashname)
Perl_croak(aTHX_ "Can't call mro_method_changed_in() on anonymous symbol table");
/* Inc the package generation, since a local method changed */
HvMROMETA(stash)->pkg_gen++;
/* DESTROY can be cached in SvSTASH. */
if (!SvOBJECT(stash)) SvSTASH(stash) = NULL;
/* If stash is UNIVERSAL, or one of UNIVERSAL's parents,
invalidate all method caches globally */
if((stashname_len == 9 && strEQ(stashname, "UNIVERSAL"))
|| (isarev && hv_exists(isarev, "UNIVERSAL", 9))) {
PL_sub_generation++;
return;
}
/* else, invalidate the method caches of all child classes,
but not itself */
if(isarev) {
HE* iter;
hv_iterinit(isarev);
while((iter = hv_iternext(isarev))) {
HV* const revstash = gv_stashsv(hv_iterkeysv(iter), 0);
struct mro_meta* mrometa;
if(!revstash) continue;
mrometa = HvMROMETA(revstash);
mrometa->cache_gen++;
if(mrometa->mro_nextmethod)
hv_clear(mrometa->mro_nextmethod);
if (!SvOBJECT(revstash)) SvSTASH(revstash) = NULL;
}
}
/* The method change may be due to *{$package . "::()"} = \&nil; in
overload.pm. */
HvAMAGIC_on(stash);
/* pessimise derefs for now. Will get recalculated by Gv_AMupdate() */
HvAUX(stash)->xhv_aux_flags &= ~HvAUXf_NO_DEREF;
}
static void
tn_encode_hash(SV *data, struct tn_buffer *buf)
{
HV *hash = (HV *)data;
HE *entry;
SV *key;
hv_iterinit(hash);
while(entry = hv_iternext(hash)) {
key = hv_iterkeysv(entry);
SvPOK_on(key);
tn_encode(hv_iterval(hash, entry), buf);
tn_encode(key, buf);
}
}
KHARON_DECL int
encode_map_next(void *data, void **key, void **val)
{
HV *in = data;
HE *elem;
elem = hv_iternext(in);
if (!elem)
return 0;
*key = hv_iterkeysv(elem);
*val = hv_iterval(in, elem);
D(fprintf(stderr, "map_next = (key = %p, val = %p)\n", *key, *val));
return 1;
}
static amf0_data_t* _amf0_data_rv(SV* sv) {
svtype svt = SvTYPE(sv);
int i, len, count;
amf0_data_t* d;
SV** svp;
SV* k;
AV* ary;
HV* hval;
HE* he;
STRLEN strlen;
char* key;
if (SVt_PVAV == svt) {
d = (amf0_data_t*)amf0_strictarray_init();
ary = (AV*)sv;
len = av_len(ary) + 1;
for (i = 0; i < len; ++i) {
svp = av_fetch(ary, i, 0);
if (svp) {
amf0_strictarray_add((amf0_strictarray_t*)d, _amf0_data(*svp));
}
else {
amf0_strictarray_add((amf0_strictarray_t*)d, _amf0_data(NULL));
}
}
}
else if (SVt_PVHV == svt) {
d = (amf0_data_t*)amf0_object_init();
hval = (HV*)sv;
count = hv_iterinit(hval);
while ( (he = hv_iternext(hval)) ) {
k = hv_iterkeysv(he);
key = SvPV(k, strlen);
amf0_object_add((amf0_object_t*)d, key, _amf0_data(HeVAL(he)));
}
}
else {
Perl_croak(aTHX_ "Data::AMF::XS doesn't support references except ARRAY and HASH");
}
return d;
}
void _mpack_item(SV *res, SV *o)
{
size_t len, res_len, new_len;
char *s, *res_s;
res_s = SvPVbyte(res, res_len);
unsigned i;
if (!SvOK(o)) {
new_len = res_len + mp_sizeof_nil();
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
mp_encode_nil(res_s + res_len);
return;
}
if (SvROK(o)) {
o = SvRV(o);
if (SvOBJECT(o)) {
SvGETMAGIC(o);
HV *stash = SvSTASH(o);
GV *mtd = gv_fetchmethod_autoload(stash, "msgpack", 0);
if (!mtd)
croak("Object has no method 'msgpack'");
dSP;
ENTER;
SAVETMPS;
PUSHMARK(SP);
XPUSHs (sv_bless (sv_2mortal (newRV_inc(o)), stash));
PUTBACK;
call_sv((SV *)GvCV(mtd), G_SCALAR);
SPAGAIN;
SV *pkt = POPs;
if (!SvOK(pkt))
croak("O->msgpack returned undef");
s = SvPV(pkt, len);
new_len = res_len + len;
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
memcpy(res_s + res_len, s, len);
PUTBACK;
FREETMPS;
LEAVE;
return;
}
switch(SvTYPE(o)) {
case SVt_PVAV: {
AV *a = (AV *)o;
len = av_len(a) + 1;
new_len = res_len + mp_sizeof_array(len);
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
mp_encode_array(res_s + res_len, len);
for (i = 0; i < len; i++) {
SV **item = av_fetch(a, i, 0);
if (!item)
_mpack_item(res, 0);
else
_mpack_item(res, *item);
}
break;
}
case SVt_PVHV: {
HV *h = (HV *)o;
len = hv_iterinit(h);
new_len = res_len + mp_sizeof_map(len);
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
mp_encode_map(res_s + res_len, len);
for (;;) {
HE * iter = hv_iternext(h);
if (!iter)
break;
SV *k = hv_iterkeysv(iter);
SV *v = HeVAL(iter);
_mpack_item(res, k);
_mpack_item(res, v);
}
break;
}
default:
croak("Can't serialize reference");
}
return;
}
switch(SvTYPE(o)) {
case SVt_PV:
case SVt_PVIV:
case SVt_PVNV:
case SVt_PVMG:
case SVt_REGEXP:
if (!looks_like_number(o)) {
s = SvPV(o, len);
new_len = res_len + mp_sizeof_str(len);
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
mp_encode_str(res_s + res_len, s, len);
break;
}
case SVt_NV: {
NV v = SvNV(o);
IV iv = (IV)v;
if (v != iv) {
new_len = res_len + mp_sizeof_double(v);
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
mp_encode_double(res_s + res_len, v);
break;
}
}
case SVt_IV: {
IV v = SvIV(o);
if (v >= 0) {
new_len = res_len + mp_sizeof_uint(v);
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
mp_encode_uint(res_s + res_len, v);
} else {
new_len = res_len + mp_sizeof_int(v);
res_s = SvGROW(res, new_len);
SvCUR_set(res, new_len);
mp_encode_int(res_s + res_len, v);
}
break;
}
default:
croak("Internal msgpack error %d", SvTYPE(o));
}
}
char *swiftperl_hv_iterkey(void *vp) {
SV *ksv = hv_iterkeysv((HE *)vp);
return SvPV_nolen(ksv);
}
SV *p5_hv_iterkeysv(PerlInterpreter *my_perl, HE *entry) {
PERL_SET_CONTEXT(my_perl);
return hv_iterkeysv(entry);
}
SV *p5_hv_iterkeysv(PerlInterpreter *my_perl, HE *entry) {
return hv_iterkeysv(entry);
}
STATIC void
S_mro_gather_and_rename(pTHX_ HV * const stashes, HV * const seen_stashes,
HV *stash, HV *oldstash, SV *namesv)
{
XPVHV* xhv;
HE *entry;
I32 riter = -1;
I32 items = 0;
const bool stash_had_name = stash && HvENAME(stash);
bool fetched_isarev = FALSE;
HV *seen = NULL;
HV *isarev = NULL;
SV **svp = NULL;
PERL_ARGS_ASSERT_MRO_GATHER_AND_RENAME;
/* We use the seen_stashes hash to keep track of which packages have
been encountered so far. This must be separate from the main list of
stashes, as we need to distinguish between stashes being assigned
and stashes being replaced/deleted. (A nested stash can be on both
sides of an assignment. We cannot simply skip iterating through a
stash on the right if we have seen it on the left, as it will not
get its ename assigned to it.)
To avoid allocating extra SVs, instead of a bitfield we can make
bizarre use of immortals:
&PL_sv_undef: seen on the left (oldstash)
&PL_sv_no : seen on the right (stash)
&PL_sv_yes : seen on both sides
*/
if(oldstash) {
/* Add to the big list. */
struct mro_meta * meta;
HE * const entry
= (HE *)
hv_common(
seen_stashes, NULL, (const char *)&oldstash, sizeof(HV *), 0,
HV_FETCH_LVALUE|HV_FETCH_EMPTY_HE, NULL, 0
);
if(HeVAL(entry) == &PL_sv_undef || HeVAL(entry) == &PL_sv_yes) {
oldstash = NULL;
goto check_stash;
}
HeVAL(entry)
= HeVAL(entry) == &PL_sv_no ? &PL_sv_yes : &PL_sv_undef;
meta = HvMROMETA(oldstash);
(void)
hv_store(
stashes, (const char *)&oldstash, sizeof(HV *),
meta->isa
? SvREFCNT_inc_simple_NN((SV *)meta->isa)
: &PL_sv_yes,
0
);
CLEAR_LINEAR(meta);
/* Update the effective name. */
if(HvENAME_get(oldstash)) {
const HEK * const enamehek = HvENAME_HEK(oldstash);
if(SvTYPE(namesv) == SVt_PVAV) {
items = AvFILLp((AV *)namesv) + 1;
svp = AvARRAY((AV *)namesv);
}
else {
items = 1;
svp = &namesv;
}
while (items--) {
const U32 name_utf8 = SvUTF8(*svp);
STRLEN len;
const char *name = SvPVx_const(*svp, len);
if(PL_stashcache) {
DEBUG_o(Perl_deb(aTHX_ "mro_gather_and_rename clearing PL_stashcache for '%"SVf"'\n",
SVfARG(*svp)));
(void)hv_delete(PL_stashcache, name, name_utf8 ? -(I32)len : (I32)len, G_DISCARD);
}
++svp;
hv_ename_delete(oldstash, name, len, name_utf8);
if (!fetched_isarev) {
/* If the name deletion caused a name change, then we
* are not going to call mro_isa_changed_in with this
* name (and not at all if it has become anonymous) so
* we need to delete old isarev entries here, both
* those in the superclasses and this class's own list
* of subclasses. We simply delete the latter from
* PL_isarev, since we still need it. hv_delete morti-
* fies it for us, so sv_2mortal is not necessary. */
if(HvENAME_HEK(oldstash) != enamehek) {
if(meta->isa && HvARRAY(meta->isa))
mro_clean_isarev(meta->isa, name, len, 0, 0,
name_utf8 ? HVhek_UTF8 : 0);
isarev = (HV *)hv_delete(PL_isarev, name,
name_utf8 ? -(I32)len : (I32)len, 0);
fetched_isarev=TRUE;
}
}
}
}
}
check_stash:
if(stash) {
if(SvTYPE(namesv) == SVt_PVAV) {
items = AvFILLp((AV *)namesv) + 1;
svp = AvARRAY((AV *)namesv);
}
else {
items = 1;
svp = &namesv;
}
while (items--) {
const U32 name_utf8 = SvUTF8(*svp);
STRLEN len;
const char *name = SvPVx_const(*svp++, len);
hv_ename_add(stash, name, len, name_utf8);
}
/* Add it to the big list if it needs
* mro_isa_changed_in called on it. That happens if it was
* detached from the symbol table (so it had no HvENAME) before
* being assigned to the spot named by the 'name' variable, because
* its cached isa linearisation is now stale (the effective name
* having changed), and subclasses will then use that cache when
* mro_package_moved calls mro_isa_changed_in. (See
* [perl #77358].)
*
* If it did have a name, then its previous name is still
* used in isa caches, and there is no need for
* mro_package_moved to call mro_isa_changed_in.
*/
entry
= (HE *)
hv_common(
seen_stashes, NULL, (const char *)&stash, sizeof(HV *), 0,
HV_FETCH_LVALUE|HV_FETCH_EMPTY_HE, NULL, 0
);
if(HeVAL(entry) == &PL_sv_yes || HeVAL(entry) == &PL_sv_no)
stash = NULL;
else {
HeVAL(entry)
= HeVAL(entry) == &PL_sv_undef ? &PL_sv_yes : &PL_sv_no;
if(!stash_had_name)
{
struct mro_meta * const meta = HvMROMETA(stash);
(void)
hv_store(
stashes, (const char *)&stash, sizeof(HV *),
meta->isa
? SvREFCNT_inc_simple_NN((SV *)meta->isa)
: &PL_sv_yes,
0
);
CLEAR_LINEAR(meta);
}
}
}
if(!stash && !oldstash)
/* Both stashes have been encountered already. */
return;
/* Add all the subclasses to the big list. */
if(!fetched_isarev) {
/* If oldstash is not null, then we can use its HvENAME to look up
the isarev hash, since all its subclasses will be listed there.
It will always have an HvENAME. It the HvENAME was removed
above, then fetch_isarev will be true, and this code will not be
reached.
If oldstash is null, then this is an empty spot with no stash in
it, so subclasses could be listed in isarev hashes belonging to
any of the names, so we have to check all of them.
*/
assert(!oldstash || HvENAME(oldstash));
if (oldstash) {
/* Extra variable to avoid a compiler warning */
const HEK * const hvename = HvENAME_HEK(oldstash);
fetched_isarev = TRUE;
svp = hv_fetchhek(PL_isarev, hvename, 0);
if (svp) isarev = MUTABLE_HV(*svp);
}
else if(SvTYPE(namesv) == SVt_PVAV) {
items = AvFILLp((AV *)namesv) + 1;
svp = AvARRAY((AV *)namesv);
}
else {
items = 1;
svp = &namesv;
}
}
if(
isarev || !fetched_isarev
) {
while (fetched_isarev || items--) {
HE *iter;
if (!fetched_isarev) {
HE * const he = hv_fetch_ent(PL_isarev, *svp++, 0, 0);
if (!he || !(isarev = MUTABLE_HV(HeVAL(he)))) continue;
}
hv_iterinit(isarev);
while((iter = hv_iternext(isarev))) {
HV* revstash = gv_stashsv(hv_iterkeysv(iter), 0);
struct mro_meta * meta;
if(!revstash) continue;
meta = HvMROMETA(revstash);
(void)
hv_store(
stashes, (const char *)&revstash, sizeof(HV *),
meta->isa
? SvREFCNT_inc_simple_NN((SV *)meta->isa)
: &PL_sv_yes,
0
);
CLEAR_LINEAR(meta);
}
if (fetched_isarev) break;
}
}
/* This is partly based on code in hv_iternext_flags. We are not call-
ing that here, as we want to avoid resetting the hash iterator. */
/* Skip the entire loop if the hash is empty. */
if(oldstash && HvUSEDKEYS(oldstash)) {
xhv = (XPVHV*)SvANY(oldstash);
seen = (HV *) sv_2mortal((SV *)newHV());
/* Iterate through entries in the oldstash, adding them to the
list, meanwhile doing the equivalent of $seen{$key} = 1.
*/
while (++riter <= (I32)xhv->xhv_max) {
entry = (HvARRAY(oldstash))[riter];
/* Iterate through the entries in this list */
for(; entry; entry = HeNEXT(entry)) {
const char* key;
I32 len;
/* If this entry is not a glob, ignore it.
Try the next. */
if (!isGV(HeVAL(entry))) continue;
key = hv_iterkey(entry, &len);
if ((len > 1 && key[len-2] == ':' && key[len-1] == ':')
|| (len == 1 && key[0] == ':')) {
HV * const oldsubstash = GvHV(HeVAL(entry));
SV ** const stashentry
= stash ? hv_fetch(stash, key, HeUTF8(entry) ? -(I32)len : (I32)len, 0) : NULL;
HV *substash = NULL;
/* Avoid main::main::main::... */
if(oldsubstash == oldstash) continue;
if(
(
stashentry && *stashentry && isGV(*stashentry)
&& (substash = GvHV(*stashentry))
)
|| (oldsubstash && HvENAME_get(oldsubstash))
)
{
/* Add :: and the key (minus the trailing ::)
to each name. */
SV *subname;
if(SvTYPE(namesv) == SVt_PVAV) {
SV *aname;
items = AvFILLp((AV *)namesv) + 1;
svp = AvARRAY((AV *)namesv);
subname = sv_2mortal((SV *)newAV());
while (items--) {
aname = newSVsv(*svp++);
if (len == 1)
sv_catpvs(aname, ":");
else {
sv_catpvs(aname, "::");
sv_catpvn_flags(
aname, key, len-2,
HeUTF8(entry)
? SV_CATUTF8 : SV_CATBYTES
);
}
av_push((AV *)subname, aname);
}
}
else {
subname = sv_2mortal(newSVsv(namesv));
if (len == 1) sv_catpvs(subname, ":");
else {
sv_catpvs(subname, "::");
sv_catpvn_flags(
subname, key, len-2,
HeUTF8(entry) ? SV_CATUTF8 : SV_CATBYTES
);
}
}
mro_gather_and_rename(
stashes, seen_stashes,
substash, oldsubstash, subname
);
}
(void)hv_store(seen, key, HeUTF8(entry) ? -(I32)len : (I32)len, &PL_sv_yes, 0);
}
}
}
}
/* Skip the entire loop if the hash is empty. */
if (stash && HvUSEDKEYS(stash)) {
xhv = (XPVHV*)SvANY(stash);
riter = -1;
/* Iterate through the new stash, skipping $seen{$key} items,
calling mro_gather_and_rename(stashes,seen,entry,NULL, ...). */
while (++riter <= (I32)xhv->xhv_max) {
entry = (HvARRAY(stash))[riter];
/* Iterate through the entries in this list */
for(; entry; entry = HeNEXT(entry)) {
const char* key;
I32 len;
/* If this entry is not a glob, ignore it.
Try the next. */
if (!isGV(HeVAL(entry))) continue;
key = hv_iterkey(entry, &len);
if ((len > 1 && key[len-2] == ':' && key[len-1] == ':')
|| (len == 1 && key[0] == ':')) {
HV *substash;
/* If this entry was seen when we iterated through the
oldstash, skip it. */
if(seen && hv_exists(seen, key, HeUTF8(entry) ? -(I32)len : (I32)len)) continue;
/* We get here only if this stash has no corresponding
entry in the stash being replaced. */
substash = GvHV(HeVAL(entry));
if(substash) {
SV *subname;
/* Avoid checking main::main::main::... */
if(substash == stash) continue;
/* Add :: and the key (minus the trailing ::)
to each name. */
if(SvTYPE(namesv) == SVt_PVAV) {
SV *aname;
items = AvFILLp((AV *)namesv) + 1;
svp = AvARRAY((AV *)namesv);
subname = sv_2mortal((SV *)newAV());
while (items--) {
aname = newSVsv(*svp++);
if (len == 1)
sv_catpvs(aname, ":");
else {
sv_catpvs(aname, "::");
sv_catpvn_flags(
aname, key, len-2,
HeUTF8(entry)
? SV_CATUTF8 : SV_CATBYTES
);
}
av_push((AV *)subname, aname);
}
}
else {
subname = sv_2mortal(newSVsv(namesv));
if (len == 1) sv_catpvs(subname, ":");
else {
sv_catpvs(subname, "::");
sv_catpvn_flags(
subname, key, len-2,
HeUTF8(entry) ? SV_CATUTF8 : SV_CATBYTES
);
}
}
mro_gather_and_rename(
stashes, seen_stashes,
substash, NULL, subname
);
}
}
}
}
}
}
void
Perl_mro_isa_changed_in(pTHX_ HV* stash)
{
HV* isarev;
AV* linear_mro;
HE* iter;
SV** svp;
I32 items;
bool is_universal;
struct mro_meta * meta;
HV *isa = NULL;
const HEK * const stashhek = HvENAME_HEK(stash);
const char * const stashname = HvENAME_get(stash);
const STRLEN stashname_len = HvENAMELEN_get(stash);
PERL_ARGS_ASSERT_MRO_ISA_CHANGED_IN;
if(!stashname)
Perl_croak(aTHX_ "Can't call mro_isa_changed_in() on anonymous symbol table");
/* wipe out the cached linearizations for this stash */
meta = HvMROMETA(stash);
CLEAR_LINEAR(meta);
if (meta->isa) {
/* Steal it for our own purposes. */
isa = (HV *)sv_2mortal((SV *)meta->isa);
meta->isa = NULL;
}
/* Inc the package generation, since our @ISA changed */
meta->pkg_gen++;
/* Wipe the global method cache if this package
is UNIVERSAL or one of its parents */
svp = hv_fetchhek(PL_isarev, stashhek, 0);
isarev = svp ? MUTABLE_HV(*svp) : NULL;
if((stashname_len == 9 && strEQ(stashname, "UNIVERSAL"))
|| (isarev && hv_exists(isarev, "UNIVERSAL", 9))) {
PL_sub_generation++;
is_universal = TRUE;
}
else { /* Wipe the local method cache otherwise */
meta->cache_gen++;
is_universal = FALSE;
}
/* wipe next::method cache too */
if(meta->mro_nextmethod) hv_clear(meta->mro_nextmethod);
/* Changes to @ISA might turn overloading on */
HvAMAGIC_on(stash);
/* pessimise derefs for now. Will get recalculated by Gv_AMupdate() */
HvAUX(stash)->xhv_aux_flags &= ~HvAUXf_NO_DEREF;
/* DESTROY can be cached in SvSTASH. */
if (!SvOBJECT(stash)) SvSTASH(stash) = NULL;
/* Iterate the isarev (classes that are our children),
wiping out their linearization, method and isa caches
and upating PL_isarev. */
if(isarev) {
HV *isa_hashes = NULL;
/* We have to iterate through isarev twice to avoid a chicken and
* egg problem: if A inherits from B and both are in isarev, A might
* be processed before B and use B's previous linearisation.
*/
/* First iteration: Wipe everything, but stash away the isa hashes
* since we still need them for updating PL_isarev.
*/
if(hv_iterinit(isarev)) {
/* Only create the hash if we need it; i.e., if isarev has
any elements. */
isa_hashes = (HV *)sv_2mortal((SV *)newHV());
}
while((iter = hv_iternext(isarev))) {
HV* revstash = gv_stashsv(hv_iterkeysv(iter), 0);
struct mro_meta* revmeta;
if(!revstash) continue;
revmeta = HvMROMETA(revstash);
CLEAR_LINEAR(revmeta);
if(!is_universal)
revmeta->cache_gen++;
if(revmeta->mro_nextmethod)
hv_clear(revmeta->mro_nextmethod);
if (!SvOBJECT(revstash)) SvSTASH(revstash) = NULL;
(void)
hv_store(
isa_hashes, (const char*)&revstash, sizeof(HV *),
revmeta->isa ? (SV *)revmeta->isa : &PL_sv_undef, 0
);
revmeta->isa = NULL;
}
/* Second pass: Update PL_isarev. We can just use isa_hashes to
* avoid another round of stash lookups. */
/* isarev might be deleted from PL_isarev during this loop, so hang
* on to it. */
SvREFCNT_inc_simple_void_NN(sv_2mortal((SV *)isarev));
if(isa_hashes) {
hv_iterinit(isa_hashes);
while((iter = hv_iternext(isa_hashes))) {
HV* const revstash = *(HV **)HEK_KEY(HeKEY_hek(iter));
HV * const isa = (HV *)HeVAL(iter);
const HEK *namehek;
/* We're starting at the 2nd element, skipping revstash */
linear_mro = mro_get_linear_isa(revstash);
svp = AvARRAY(linear_mro) + 1;
items = AvFILLp(linear_mro);
namehek = HvENAME_HEK(revstash);
if (!namehek) namehek = HvNAME_HEK(revstash);
while (items--) {
SV* const sv = *svp++;
HV* mroisarev;
HE *he = hv_fetch_ent(PL_isarev, sv, TRUE, 0);
/* That fetch should not fail. But if it had to create
a new SV for us, then will need to upgrade it to an
HV (which sv_upgrade() can now do for us). */
mroisarev = MUTABLE_HV(HeVAL(he));
SvUPGRADE(MUTABLE_SV(mroisarev), SVt_PVHV);
/* This hash only ever contains PL_sv_yes. Storing it
over itself is almost as cheap as calling hv_exists,
so on aggregate we expect to save time by not making
two calls to the common HV code for the case where
it doesn't exist. */
(void)
hv_storehek(mroisarev, namehek, &PL_sv_yes);
}
if ((SV *)isa != &PL_sv_undef) {
assert(namehek);
mro_clean_isarev(
isa, HEK_KEY(namehek), HEK_LEN(namehek),
HvMROMETA(revstash)->isa, HEK_HASH(namehek),
HEK_UTF8(namehek)
);
}
}
}
}
/* Now iterate our MRO (parents), adding ourselves and everything from
our isarev to their isarev.
*/
/* We're starting at the 2nd element, skipping ourselves here */
linear_mro = mro_get_linear_isa(stash);
svp = AvARRAY(linear_mro) + 1;
items = AvFILLp(linear_mro);
while (items--) {
SV* const sv = *svp++;
HV* mroisarev;
HE *he = hv_fetch_ent(PL_isarev, sv, TRUE, 0);
/* That fetch should not fail. But if it had to create a new SV for
us, then will need to upgrade it to an HV (which sv_upgrade() can
now do for us. */
mroisarev = MUTABLE_HV(HeVAL(he));
SvUPGRADE(MUTABLE_SV(mroisarev), SVt_PVHV);
/* This hash only ever contains PL_sv_yes. Storing it over itself is
almost as cheap as calling hv_exists, so on aggregate we expect to
save time by not making two calls to the common HV code for the
case where it doesn't exist. */
(void)hv_storehek(mroisarev, stashhek, &PL_sv_yes);
}
/* Delete our name from our former parents' isarevs. */
if(isa && HvARRAY(isa))
mro_clean_isarev(isa, stashname, stashname_len, meta->isa,
HEK_HASH(stashhek), HEK_UTF8(stashhek));
}
static gpointer
sv_to_ghash (GITransfer transfer,
GITypeInfo *type_info,
SV *sv)
{
HV *hv;
HE *he;
GITransfer item_transfer;
gpointer hash;
GITypeInfo *key_param_info, *value_param_info;
GITypeTag key_type_tag;
GHashFunc hash_func;
GEqualFunc equal_func;
I32 n_keys;
dwarn ("%s: sv %p\n", G_STRFUNC, sv);
if (!gperl_sv_is_defined (sv))
return NULL;
if (!gperl_sv_is_hash_ref (sv))
ccroak ("need an hash ref to convert to GHashTable");
hv = (HV *) SvRV (sv);
item_transfer = GI_TRANSFER_NOTHING;
switch (transfer) {
case GI_TRANSFER_EVERYTHING:
item_transfer = GI_TRANSFER_EVERYTHING;
break;
case GI_TRANSFER_CONTAINER:
/* nothing special to do */
break;
case GI_TRANSFER_NOTHING:
/* FIXME: need to free hash after call */
break;
}
key_param_info = g_type_info_get_param_type (type_info, 0);
value_param_info = g_type_info_get_param_type (type_info, 1);
key_type_tag = g_type_info_get_tag (key_param_info);
switch (key_type_tag)
{
case GI_TYPE_TAG_FILENAME:
case GI_TYPE_TAG_UTF8:
hash_func = g_str_hash;
equal_func = g_str_equal;
break;
default:
hash_func = NULL;
equal_func = NULL;
break;
}
dwarn (" GHashTable with transfer %d\n"
" key_param_info %p with type tag %d (%s)\n"
" value_param_info %p with type tag %d (%s)\n",
transfer,
key_param_info,
g_type_info_get_tag (key_param_info),
g_type_tag_to_string (g_type_info_get_tag (key_param_info)),
value_param_info,
g_type_info_get_tag (value_param_info),
g_type_tag_to_string (g_type_info_get_tag (value_param_info)));
hash = g_hash_table_new (hash_func, equal_func);
n_keys = hv_iterinit (hv);
if (n_keys == 0)
goto out;
while ((he = hv_iternext (hv)) != NULL) {
SV *sv;
GIArgument arg = { 0, };
gpointer key_p, value_p;
key_p = value_p = NULL;
sv = hv_iterkeysv (he);
if (sv && gperl_sv_is_defined (sv)) {
dwarn (" converting key SV %p\n", sv);
/* FIXME: Is it OK to always allow undef here? */
sv_to_arg (sv, &arg, NULL, key_param_info,
item_transfer, TRUE, NULL);
key_p = arg.v_pointer;
}
sv = hv_iterval (hv, he);
if (sv && gperl_sv_is_defined (sv)) {
dwarn (" converting value SV %p\n", sv);
sv_to_arg (sv, &arg, NULL, key_param_info,
item_transfer, TRUE, NULL);
value_p = arg.v_pointer;
}
if (key_p != NULL && value_p != NULL)
g_hash_table_insert (hash, key_p, value_p);
}
out:
dwarn (" -> hash %p of size %d\n", hash, g_hash_table_size (hash));
g_base_info_unref ((GIBaseInfo *) key_param_info);
g_base_info_unref ((GIBaseInfo *) value_param_info);
return hash;
}
void
plu_munge_lua_code(pTHX_ SV *lcode)
{
/* This just delegates to Perl functions - regexes
* are really rather powerful and calling Perl regexes from
* C is like making mince with a colander and a plunger. */
SV *lexical_rv;
HV *lexical_hv;
AV *lexical_ary;
HE *he;
unsigned int i, n;
PADOFFSET padoff;
SV *name;
char *str;
STRLEN len;
/* First, scan the code for $foo.int and frients */
{
dSP;
int count;
ENTER;
SAVETMPS;
PUSHMARK(SP);
XPUSHs(lcode);
PUTBACK;
count = call_pv("PLua::_scan_lua_code", G_SCALAR);
SPAGAIN;
if (count != 1)
croak("Panic: Scalar context and not exactly one return value? Madness!");
/* These lexicals will need looking up with pad_findmy */
lexical_rv = POPs;
lexical_hv = (HV *)SvRV(lexical_rv);
SvREFCNT_inc(lexical_rv);
PUTBACK;
FREETMPS;
LEAVE;
sv_2mortal(lexical_rv);
}
/* Now do all PAD lookups for lexicals in the HV */
/* Use a tmp array to avoid modifying a hash being looped over.
* This is obvioiusly possible by fuzzing with the HE, but
* my perl API fu is weak and I just want it working for now. FIXME */
lexical_ary = newAV();
sv_2mortal((SV *)lexical_ary);
(void)hv_iterinit(lexical_hv);
while ((he = hv_iternext(lexical_hv))) {
SV *k = hv_iterkeysv(he);
SvREFCNT_inc(k);
av_push(lexical_ary, k);
}
n = (unsigned int)av_len(lexical_ary)+1;
for (i = 0; i < n; ++i) {
name = *av_fetch(lexical_ary, i, 0);
str = SvPV(name, len);
padoff = pad_findmy(str, len, 0);
if (LIKELY( padoff != NOT_IN_PAD ))
(void)hv_store(lexical_hv, str, len, newSViv(padoff), 0);
/* No else needed - skipping from HV will cause exception in
* Perl code called further down. */
}
/* Now actually munge the code based on the PAD lookups. */
{
dSP;
ENTER;
SAVETMPS;
PUSHMARK(SP);
XPUSHs(lcode);
XPUSHs(lexical_rv);
PUTBACK;
call_pv("PLua::_munge_lua_code", G_DISCARD);
FREETMPS;
LEAVE;
}
}
