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/* sv.h * * Copyright (C) 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, * 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009 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. * */ #ifdef sv_flags #undef sv_flags /* Convex has this in <signal.h> for sigvec() */ #endif /* =head1 SV Flags =for apidoc AmU||svtype An enum of flags for Perl types. These are found in the file F<sv.h> in the C<svtype> enum. Test these flags with the C<SvTYPE> macro. The types are: SVt_NULL SVt_IV SVt_NV SVt_RV SVt_PV SVt_PVIV SVt_PVNV SVt_PVMG SVt_INVLIST SVt_REGEXP SVt_PVGV SVt_PVLV SVt_PVAV SVt_PVHV SVt_PVCV SVt_PVFM SVt_PVIO These are most easily explained from the bottom up. C<SVt_PVIO> is for I/O objects, C<SVt_PVFM> for formats, C<SVt_PVCV> for subroutines, C<SVt_PVHV> for hashes and C<SVt_PVAV> for arrays. All the others are scalar types, that is, things that can be bound to a C<$> variable. For these, the internal types are mostly orthogonal to types in the Perl language. Hence, checking C<< SvTYPE(sv) < SVt_PVAV >> is the best way to see whether something is a scalar. C<SVt_PVGV> represents a typeglob. If C<!SvFAKE(sv)>, then it is a real, incoercible typeglob. If C<SvFAKE(sv)>, then it is a scalar to which a typeglob has been assigned. Assigning to it again will stop it from being a typeglob. C<SVt_PVLV> represents a scalar that delegates to another scalar behind the scenes. It is used, e.g., for the return value of C<substr> and for tied hash and array elements. It can hold any scalar value, including a typeglob. C<SVt_REGEXP> is for regular expressions. C<SVt_INVLIST> is for Perl core internal use only. C<SVt_PVMG> represents a "normal" scalar (not a typeglob, regular expression, or delegate). Since most scalars do not need all the internal fields of a PVMG, we save memory by allocating smaller structs when possible. All the other types are just simpler forms of C<SVt_PVMG>, with fewer internal fields. C<SVt_NULL> can only hold undef. C<SVt_IV> can hold undef, an integer, or a reference. (C<SVt_RV> is an alias for C<SVt_IV>, which exists for backward compatibility.) C<SVt_NV> can hold any of those or a double. C<SVt_PV> can only hold C<undef> or a string. C<SVt_PVIV> is a superset of C<SVt_PV> and C<SVt_IV>. C<SVt_PVNV> is similar. C<SVt_PVMG> can hold anything C<SVt_PVNV> can hold, but it can, but does not have to, be blessed or magical. =for apidoc AmU||SVt_NULL Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_IV Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_NV Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_PV Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_PVIV Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_PVNV Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_PVMG Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_INVLIST Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_REGEXP Type flag for regular expressions. See L</svtype>. =for apidoc AmU||SVt_PVGV Type flag for typeglobs. See L</svtype>. =for apidoc AmU||SVt_PVLV Type flag for scalars. See L</svtype>. =for apidoc AmU||SVt_PVAV Type flag for arrays. See L</svtype>. =for apidoc AmU||SVt_PVHV Type flag for hashes. See L</svtype>. =for apidoc AmU||SVt_PVCV Type flag for subroutines. See L</svtype>. =for apidoc AmU||SVt_PVFM Type flag for formats. See L</svtype>. =for apidoc AmU||SVt_PVIO Type flag for I/O objects. See L</svtype>. =cut These are ordered so that the simpler types have a lower value; SvUPGRADE doesn't allow you to upgrade from a higher numbered type to a lower numbered one; also there is code that assumes that anything that has as a PV component has a type numbered >= SVt_PV. */ typedef enum { SVt_NULL, /* 0 */ /* BIND was here, before INVLIST replaced it. */ SVt_IV, /* 1 */ SVt_NV, /* 2 */ /* RV was here, before it was merged with IV. */ SVt_PV, /* 3 */ SVt_INVLIST, /* 4, implemented as a PV */ SVt_PVIV, /* 5 */ SVt_PVNV, /* 6 */ SVt_PVMG, /* 7 */ SVt_REGEXP, /* 8 */ /* PVBM was here, before BIND replaced it. */ SVt_PVGV, /* 9 */ SVt_PVLV, /* 10 */ SVt_PVAV, /* 11 */ SVt_PVHV, /* 12 */ SVt_PVCV, /* 13 */ SVt_PVFM, /* 14 */ SVt_PVIO, /* 15 */ SVt_LAST /* keep last in enum. used to size arrays */ } svtype; /* *** any alterations to the SV types above need to be reflected in * SVt_MASK and the various PL_valid_types_* tables. As of this writing those * tables are in perl.h. There are also two affected names tables in dump.c, * one in B.xs, and 'bodies_by_type[]' in sv.c. * * The bits that match 0xf0 are CURRENTLY UNUSED, except that 0xFF means a * freed SV. The bits above that are for flags, like SVf_IOK */ #define SVt_MASK 0xf /* smallest bitmask that covers all types */ #ifndef PERL_CORE /* Fast Boyer Moore tables are now stored in magic attached to PVMGs */ # define SVt_PVBM SVt_PVMG /* Anything wanting to create a reference from clean should ensure that it has a scalar of type SVt_IV now: */ # define SVt_RV SVt_IV #endif /* There is collusion here with sv_clear - sv_clear exits early for SVt_NULL so never reaches the clause at the end that uses sv_type_details->body_size to determine whether to call safefree(). Hence body_size can be set non-zero to record the size of HEs, without fear of bogus frees. */ #if defined(PERL_IN_HV_C) || defined(PERL_IN_XS_APITEST) #define HE_SVSLOT SVt_NULL #endif #ifdef PERL_IN_SV_C # define SVt_FIRST SVt_NULL /* the type of SV that new_SV() in sv.c returns */ #endif #define PERL_ARENA_ROOTS_SIZE (SVt_LAST) /* typedefs to eliminate some typing */ typedef struct he HE; typedef struct hek HEK; /* Using C's structural equivalence to help emulate C++ inheritance here... */ /* start with 2 sv-head building blocks */ #define _SV_HEAD(ptrtype) \ ptrtype sv_any; /* pointer to body */ \ U32 sv_refcnt; /* how many references to us */ \ U32 sv_flags /* what we are */ #if NVSIZE <= IVSIZE # define _NV_BODYLESS_UNION NV svu_nv; #else # define _NV_BODYLESS_UNION #endif #define _SV_HEAD_UNION \ union { \ char* svu_pv; /* pointer to malloced string */ \ IV svu_iv; \ UV svu_uv; \ _NV_BODYLESS_UNION \ SV* svu_rv; /* pointer to another SV */ \ struct regexp* svu_rx; \ SV** svu_array; \ HE** svu_hash; \ GP* svu_gp; \ PerlIO *svu_fp; \ } sv_u \ _SV_HEAD_DEBUG #ifdef DEBUG_LEAKING_SCALARS #define _SV_HEAD_DEBUG ;\ PERL_BITFIELD32 sv_debug_optype:9; /* the type of OP that allocated us */ \ PERL_BITFIELD32 sv_debug_inpad:1; /* was allocated in a pad for an OP */ \ PERL_BITFIELD32 sv_debug_line:16; /* the line where we were allocated */ \ UV sv_debug_serial; /* serial number of sv allocation */ \ char * sv_debug_file; /* the file where we were allocated */ \ SV * sv_debug_parent /* what we were cloned from (ithreads)*/ #else #define _SV_HEAD_DEBUG #endif struct STRUCT_SV { /* struct sv { */ _SV_HEAD(void*); _SV_HEAD_UNION; }; struct gv { _SV_HEAD(XPVGV*); /* pointer to xpvgv body */ _SV_HEAD_UNION; }; struct cv { _SV_HEAD(XPVCV*); /* pointer to xpvcv body */ _SV_HEAD_UNION; }; struct av { _SV_HEAD(XPVAV*); /* pointer to xpvav body */ _SV_HEAD_UNION; }; struct hv { _SV_HEAD(XPVHV*); /* pointer to xpvhv body */ _SV_HEAD_UNION; }; struct io { _SV_HEAD(XPVIO*); /* pointer to xpvio body */ _SV_HEAD_UNION; }; struct p5rx { _SV_HEAD(struct regexp*); /* pointer to regexp body */ _SV_HEAD_UNION; }; #undef _SV_HEAD #undef _SV_HEAD_UNION /* ensure no pollution */ /* =head1 SV Manipulation Functions =for apidoc Am|U32|SvREFCNT|SV* sv Returns the value of the object's reference count. Exposed to perl code via Internals::SvREFCNT(). =for apidoc Am|SV*|SvREFCNT_inc|SV* sv Increments the reference count of the given SV, returning the SV. All of the following C<SvREFCNT_inc>* macros are optimized versions of C<SvREFCNT_inc>, and can be replaced with C<SvREFCNT_inc>. =for apidoc Am|SV*|SvREFCNT_inc_NN|SV* sv Same as C<SvREFCNT_inc>, but can only be used if you know C<sv> is not C<NULL>. Since we don't have to check the NULLness, it's faster and smaller. =for apidoc Am|void|SvREFCNT_inc_void|SV* sv Same as C<SvREFCNT_inc>, but can only be used if you don't need the return value. The macro doesn't need to return a meaningful value. =for apidoc Am|void|SvREFCNT_inc_void_NN|SV* sv Same as C<SvREFCNT_inc>, but can only be used if you don't need the return value, and you know that C<sv> is not C<NULL>. The macro doesn't need to return a meaningful value, or check for NULLness, so it's smaller and faster. =for apidoc Am|SV*|SvREFCNT_inc_simple|SV* sv Same as C<SvREFCNT_inc>, but can only be used with expressions without side effects. Since we don't have to store a temporary value, it's faster. =for apidoc Am|SV*|SvREFCNT_inc_simple_NN|SV* sv Same as C<SvREFCNT_inc_simple>, but can only be used if you know C<sv> is not C<NULL>. Since we don't have to check the NULLness, it's faster and smaller. =for apidoc Am|void|SvREFCNT_inc_simple_void|SV* sv Same as C<SvREFCNT_inc_simple>, but can only be used if you don't need the return value. The macro doesn't need to return a meaningful value. =for apidoc Am|void|SvREFCNT_inc_simple_void_NN|SV* sv Same as C<SvREFCNT_inc>, but can only be used if you don't need the return value, and you know that C<sv> is not C<NULL>. The macro doesn't need to return a meaningful value, or check for NULLness, so it's smaller and faster. =for apidoc Am|void|SvREFCNT_dec|SV* sv Decrements the reference count of the given SV. C<sv> may be C<NULL>. =for apidoc Am|void|SvREFCNT_dec_NN|SV* sv Same as C<SvREFCNT_dec>, but can only be used if you know C<sv> is not C<NULL>. Since we don't have to check the NULLness, it's faster and smaller. =for apidoc Am|svtype|SvTYPE|SV* sv Returns the type of the SV. See C<L</svtype>>. =for apidoc Am|void|SvUPGRADE|SV* sv|svtype type Used to upgrade an SV to a more complex form. Uses C<sv_upgrade> to perform the upgrade if necessary. See C<L</svtype>>. =cut */ #define SvANY(sv) (sv)->sv_any #define SvFLAGS(sv) (sv)->sv_flags #define SvREFCNT(sv) (sv)->sv_refcnt #define SvREFCNT_inc(sv) S_SvREFCNT_inc(MUTABLE_SV(sv)) #define SvREFCNT_inc_simple(sv) SvREFCNT_inc(sv) #define SvREFCNT_inc_NN(sv) S_SvREFCNT_inc_NN(MUTABLE_SV(sv)) #define SvREFCNT_inc_void(sv) S_SvREFCNT_inc_void(MUTABLE_SV(sv)) /* These guys don't need the curly blocks */ #define SvREFCNT_inc_simple_void(sv) STMT_START { if (sv) SvREFCNT(sv)++; } STMT_END #define SvREFCNT_inc_simple_NN(sv) (++(SvREFCNT(sv)),MUTABLE_SV(sv)) #define SvREFCNT_inc_void_NN(sv) (void)(++SvREFCNT(MUTABLE_SV(sv))) #define SvREFCNT_inc_simple_void_NN(sv) (void)(++SvREFCNT(MUTABLE_SV(sv))) #define SvREFCNT_dec(sv) S_SvREFCNT_dec(aTHX_ MUTABLE_SV(sv)) #define SvREFCNT_dec_NN(sv) S_SvREFCNT_dec_NN(aTHX_ MUTABLE_SV(sv)) #define SVTYPEMASK 0xff #define SvTYPE(sv) ((svtype)((sv)->sv_flags & SVTYPEMASK)) /* Sadly there are some parts of the core that have pointers to already-freed SV heads, and rely on being able to tell that they are now free. So mark them all by using a consistent macro. */ #define SvIS_FREED(sv) UNLIKELY(((sv)->sv_flags == SVTYPEMASK)) /* this is defined in this peculiar way to avoid compiler warnings. * See the <20121213131428.GD1842@iabyn.com> thread in p5p */ #define SvUPGRADE(sv, mt) \ ((void)(SvTYPE(sv) >= (mt) || (sv_upgrade(sv, mt),1))) #define SVf_IOK 0x00000100 /* has valid public integer value */ #define SVf_NOK 0x00000200 /* has valid public numeric value */ #define SVf_POK 0x00000400 /* has valid public pointer value */ #define SVf_ROK 0x00000800 /* has a valid reference pointer */ #define SVp_IOK 0x00001000 /* has valid non-public integer value */ #define SVp_NOK 0x00002000 /* has valid non-public numeric value */ #define SVp_POK 0x00004000 /* has valid non-public pointer value */ #define SVp_SCREAM 0x00008000 /* currently unused on plain scalars */ #define SVphv_CLONEABLE SVp_SCREAM /* PVHV (stashes) clone its objects */ #define SVpgv_GP SVp_SCREAM /* GV has a valid GP */ #define SVprv_PCS_IMPORTED SVp_SCREAM /* RV is a proxy for a constant subroutine in another package. Set the GvIMPORTED_CV_on() if it needs to be expanded to a real GV */ /* SVf_PROTECT is what SVf_READONLY should have been: i.e. modifying * this SV is completely illegal. However, SVf_READONLY (via * Internals::SvREADONLY()) has come to be seen as a flag that can be * temporarily set and unset by the user to indicate e.g. whether a hash * is "locked". Now, Hash::Util et al only set SVf_READONLY, while core * sets both (SVf_READONLY|SVf_PROTECT) to indicate both to core and user * code that this SV should not be messed with. */ #define SVf_PROTECT 0x00010000 /* very read-only */ #define SVs_PADTMP 0x00020000 /* in use as tmp */ #define SVs_PADSTALE 0x00040000 /* lexical has gone out of scope; only used when !PADTMP */ #define SVs_TEMP 0x00080000 /* mortal (implies string is stealable) */ #define SVs_OBJECT 0x00100000 /* is "blessed" */ #define SVs_GMG 0x00200000 /* has magical get method */ #define SVs_SMG 0x00400000 /* has magical set method */ #define SVs_RMG 0x00800000 /* has random magical methods */ #define SVf_FAKE 0x01000000 /* 0: glob is just a copy 1: SV head arena wasn't malloc()ed 2: For PVCV, whether CvUNIQUE(cv) refers to an eval or once only [CvEVAL(cv), CvSPECIAL(cv)] 3: HV: informally reserved by DAPM for vtables */ #define SVf_OOK 0x02000000 /* has valid offset value. For a PVHV this means that a hv_aux struct is present after the main array */ #define SVf_BREAK 0x04000000 /* refcnt is artificially low - used by SVs in final arena cleanup. Set in S_regtry on PL_reg_curpm, so that perl_destruct will skip it. Used for mark and sweep by OP_AASSIGN */ #define SVf_READONLY 0x08000000 /* may not be modified */ #define SVf_THINKFIRST (SVf_READONLY|SVf_PROTECT|SVf_ROK|SVf_FAKE \ |SVs_RMG|SVf_IsCOW) #define SVf_OK (SVf_IOK|SVf_NOK|SVf_POK|SVf_ROK| \ SVp_IOK|SVp_NOK|SVp_POK|SVpgv_GP) #define PRIVSHIFT 4 /* (SVp_?OK >> PRIVSHIFT) == SVf_?OK */ /* SVf_AMAGIC means that the stash *may* have have overload methods. It's * set each time a function is compiled into a stash, and is reset by the * overload code when called for the first time and finds that there are * no overload methods. Note that this used to be set on the object; but * is now only set on stashes. */ #define SVf_AMAGIC 0x10000000 /* has magical overloaded methods */ #define SVf_IsCOW 0x10000000 /* copy on write (shared hash key if SvLEN == 0) */ /* Ensure this value does not clash with the GV_ADD* flags in gv.h, or the CV_CKPROTO_* flags in op.c, or the padadd_* flags in pad.h: */ #define SVf_UTF8 0x20000000 /* SvPV is UTF-8 encoded This is also set on RVs whose overloaded stringification is UTF-8. This might only happen as a side effect of SvPV() */ /* PVHV */ #define SVphv_SHAREKEYS 0x20000000 /* PVHV keys live on shared string table */ /* PVAV could probably use 0x2000000 without conflict. I assume that PVFM can be UTF-8 encoded, and PVCVs could well have UTF-8 prototypes. PVIOs haven't been restructured, so sometimes get used as string buffers. */ /* Some private flags. */ /* PVAV */ #define SVpav_REAL 0x40000000 /* free old entries */ /* PVHV */ #define SVphv_LAZYDEL 0x40000000 /* entry in xhv_eiter must be deleted */ /* IV, PVIV, PVNV, PVMG, PVGV and (I assume) PVLV */ #define SVf_IVisUV 0x80000000 /* use XPVUV instead of XPVIV */ /* PVAV */ #define SVpav_REIFY 0x80000000 /* can become real */ /* PVHV */ #define SVphv_HASKFLAGS 0x80000000 /* keys have flag byte after hash */ /* RV upwards. However, SVf_ROK and SVp_IOK are exclusive */ #define SVprv_WEAKREF 0x80000000 /* Weak reference */ /* pad name vars only */ #define _XPV_HEAD \ HV* xmg_stash; /* class package */ \ union _xmgu xmg_u; \ STRLEN xpv_cur; /* length of svu_pv as a C string */ \ union { \ STRLEN xpvlenu_len; /* allocated size */ \ char * xpvlenu_pv; /* regexp string */ \ } xpv_len_u #define xpv_len xpv_len_u.xpvlenu_len union _xnvu { NV xnv_nv; /* numeric value, if any */ HV * xgv_stash; line_t xnv_lines; /* used internally by S_scan_subst() */ bool xnv_bm_tail; /* an SvVALID (BM) SV has an implicit "\n" */ }; union _xivu { IV xivu_iv; /* integer value */ UV xivu_uv; HEK * xivu_namehek; /* xpvlv, xpvgv: GvNAME */ bool xivu_eval_seen; /* used internally by S_scan_subst() */ }; union _xmgu { MAGIC* xmg_magic; /* linked list of magicalness */ STRLEN xmg_hash_index; /* used while freeing hash entries */ }; struct xpv { _XPV_HEAD; }; struct xpviv { _XPV_HEAD; union _xivu xiv_u; }; #define xiv_iv xiv_u.xivu_iv struct xpvuv { _XPV_HEAD; union _xivu xuv_u; }; #define xuv_uv xuv_u.xivu_uv struct xpvnv { _XPV_HEAD; union _xivu xiv_u; union _xnvu xnv_u; }; /* This structure must match the beginning of struct xpvhv in hv.h. */ struct xpvmg { _XPV_HEAD; union _xivu xiv_u; union _xnvu xnv_u; }; struct xpvlv { _XPV_HEAD; union _xivu xiv_u; union _xnvu xnv_u; union { STRLEN xlvu_targoff; SSize_t xlvu_stargoff; } xlv_targoff_u; STRLEN xlv_targlen; SV* xlv_targ; char xlv_type; /* k=keys .=pos x=substr v=vec /=join/re * y=alem/helem/iter t=tie T=tied HE */ char xlv_flags; /* 1 = negative offset 2 = negative len 4 = out of range (vec) */ }; #define xlv_targoff xlv_targoff_u.xlvu_targoff struct xpvinvlist { _XPV_HEAD; IV prev_index; /* caches result of previous invlist_search() */ STRLEN iterator; /* Stores where we are in iterating */ bool is_offset; /* The data structure for all inversion lists begins with an element for code point U+0000. If this bool is set, the actual list contains that 0; otherwise, the list actually begins with the following element. Thus to invert the list, merely toggle this flag */ }; /* This structure works in 2 ways - regular scalar, or GV with GP */ struct xpvgv { _XPV_HEAD; union _xivu xiv_u; union _xnvu xnv_u; }; typedef U32 cv_flags_t; #define _XPVCV_COMMON \ HV * xcv_stash; \ union { \ OP * xcv_start; \ ANY xcv_xsubany; \ } xcv_start_u; \ union { \ OP * xcv_root; \ void (*xcv_xsub) (pTHX_ CV*); \ } xcv_root_u; \ union { \ GV * xcv_gv; \ HEK * xcv_hek; \ } xcv_gv_u; \ char * xcv_file; \ union { \ PADLIST * xcv_padlist; \ void * xcv_hscxt; \ } xcv_padlist_u; \ CV * xcv_outside; \ U32 xcv_outside_seq; /* the COP sequence (at the point of our \ * compilation) in the lexically enclosing \ * sub */ \ cv_flags_t xcv_flags; \ I32 xcv_depth /* >= 2 indicates recursive call */ /* This structure must match XPVCV in cv.h */ struct xpvfm { _XPV_HEAD; _XPVCV_COMMON; }; struct xpvio { _XPV_HEAD; union _xivu xiv_u; /* ifp and ofp are normally the same, but sockets need separate streams */ PerlIO * xio_ofp; /* Cray addresses everything by word boundaries (64 bits) and * code and data pointers cannot be mixed (which is exactly what * Perl_filter_add() tries to do with the dirp), hence the * following union trick (as suggested by Gurusamy Sarathy). * For further information see Geir Johansen's problem report * titled [ID 20000612.002 (#3366)] Perl problem on Cray system * The any pointer (known as IoANY()) will also be a good place * to hang any IO disciplines to. */ union { DIR * xiou_dirp; /* for opendir, readdir, etc */ void * xiou_any; /* for alignment */ } xio_dirpu; /* IV xio_lines is now in IVX $. */ IV xio_page; /* $% */ IV xio_page_len; /* $= */ IV xio_lines_left; /* $- */ char * xio_top_name; /* $^ */ GV * xio_top_gv; /* $^ */ char * xio_fmt_name; /* $~ */ GV * xio_fmt_gv; /* $~ */ char * xio_bottom_name;/* $^B */ GV * xio_bottom_gv; /* $^B */ char xio_type; U8 xio_flags; }; #define xio_dirp xio_dirpu.xiou_dirp #define xio_any xio_dirpu.xiou_any #define IOf_ARGV 1 /* this fp iterates over ARGV */ #define IOf_START 2 /* check for null ARGV and substitute '-' */ #define IOf_FLUSH 4 /* this fp wants a flush after write op */ #define IOf_DIDTOP 8 /* just did top of form */ #define IOf_UNTAINT 16 /* consider this fp (and its data) "safe" */ #define IOf_NOLINE 32 /* slurped a pseudo-line from empty file */ #define IOf_FAKE_DIRP 64 /* xio_dirp is fake (source filters kludge) Also, when this is set, SvPVX() is valid */ /* The following macros define implementation-independent predicates on SVs. */ /* =for apidoc Am|U32|SvNIOK|SV* sv Returns a U32 value indicating whether the SV contains a number, integer or double. =for apidoc Am|U32|SvNIOKp|SV* sv Returns a U32 value indicating whether the SV contains a number, integer or double. Checks the B<private> setting. Use C<SvNIOK> instead. =for apidoc Am|void|SvNIOK_off|SV* sv Unsets the NV/IV status of an SV. =for apidoc Am|U32|SvOK|SV* sv Returns a U32 value indicating whether the value is defined. This is only meaningful for scalars. =for apidoc Am|U32|SvIOKp|SV* sv Returns a U32 value indicating whether the SV contains an integer. Checks the B<private> setting. Use C<SvIOK> instead. =for apidoc Am|U32|SvNOKp|SV* sv Returns a U32 value indicating whether the SV contains a double. Checks the B<private> setting. Use C<SvNOK> instead. =for apidoc Am|U32|SvPOKp|SV* sv Returns a U32 value indicating whether the SV contains a character string. Checks the B<private> setting. Use C<SvPOK> instead. =for apidoc Am|U32|SvIOK|SV* sv Returns a U32 value indicating whether the SV contains an integer. =for apidoc Am|void|SvIOK_on|SV* sv Tells an SV that it is an integer. =for apidoc Am|void|SvIOK_off|SV* sv Unsets the IV status of an SV. =for apidoc Am|void|SvIOK_only|SV* sv Tells an SV that it is an integer and disables all other C<OK> bits. =for apidoc Am|void|SvIOK_only_UV|SV* sv Tells an SV that it is an unsigned integer and disables all other C<OK> bits. =for apidoc Am|bool|SvIOK_UV|SV* sv Returns a boolean indicating whether the SV contains an integer that must be interpreted as unsigned. A non-negative integer whose value is within the range of both an IV and a UV may be be flagged as either C<SvUOK> or C<SVIOK>. =for apidoc Am|bool|SvUOK|SV* sv Returns a boolean indicating whether the SV contains an integer that must be interpreted as unsigned. A non-negative integer whose value is within the range of both an IV and a UV may be be flagged as either C<SvUOK> or C<SVIOK>. =for apidoc Am|bool|SvIOK_notUV|SV* sv Returns a boolean indicating whether the SV contains a signed integer. =for apidoc Am|U32|SvNOK|SV* sv Returns a U32 value indicating whether the SV contains a double. =for apidoc Am|void|SvNOK_on|SV* sv Tells an SV that it is a double. =for apidoc Am|void|SvNOK_off|SV* sv Unsets the NV status of an SV. =for apidoc Am|void|SvNOK_only|SV* sv Tells an SV that it is a double and disables all other OK bits. =for apidoc Am|U32|SvPOK|SV* sv Returns a U32 value indicating whether the SV contains a character string. =for apidoc Am|void|SvPOK_on|SV* sv Tells an SV that it is a string. =for apidoc Am|void|SvPOK_off|SV* sv Unsets the PV status of an SV. =for apidoc Am|void|SvPOK_only|SV* sv Tells an SV that it is a string and disables all other C<OK> bits. Will also turn off the UTF-8 status. =for apidoc Am|bool|SvVOK|SV* sv Returns a boolean indicating whether the SV contains a v-string. =for apidoc Am|U32|SvOOK|SV* sv Returns a U32 indicating whether the pointer to the string buffer is offset. This hack is used internally to speed up removal of characters from the beginning of a C<SvPV>. When C<SvOOK> is true, then the start of the allocated string buffer is actually C<SvOOK_offset()> bytes before C<SvPVX>. This offset used to be stored in C<SvIVX>, but is now stored within the spare part of the buffer. =for apidoc Am|U32|SvROK|SV* sv Tests if the SV is an RV. =for apidoc Am|void|SvROK_on|SV* sv Tells an SV that it is an RV. =for apidoc Am|void|SvROK_off|SV* sv Unsets the RV status of an SV. =for apidoc Am|SV*|SvRV|SV* sv Dereferences an RV to return the SV. =for apidoc Am|IV|SvIVX|SV* sv Returns the raw value in the SV's IV slot, without checks or conversions. Only use when you are sure C<SvIOK> is true. See also C<L</SvIV>>. =for apidoc Am|UV|SvUVX|SV* sv Returns the raw value in the SV's UV slot, without checks or conversions. Only use when you are sure C<SvIOK> is true. See also C<L</SvUV>>. =for apidoc Am|NV|SvNVX|SV* sv Returns the raw value in the SV's NV slot, without checks or conversions. Only use when you are sure C<SvNOK> is true. See also C<L</SvNV>>. =for apidoc Am|char*|SvPVX|SV* sv Returns a pointer to the physical string in the SV. The SV must contain a string. Prior to 5.9.3 it is not safe to execute this macro unless the SV's type >= C<SVt_PV>. This is also used to store the name of an autoloaded subroutine in an XS AUTOLOAD routine. See L<perlguts/Autoloading with XSUBs>. =for apidoc Am|STRLEN|SvCUR|SV* sv Returns the length of the string which is in the SV. See C<L</SvLEN>>. =for apidoc Am|STRLEN|SvLEN|SV* sv Returns the size of the string buffer in the SV, not including any part attributable to C<SvOOK>. See C<L</SvCUR>>. =for apidoc Am|char*|SvEND|SV* sv Returns a pointer to the spot just after the last character in the string which is in the SV, where there is usually a trailing C<NUL> character (even though Perl scalars do not strictly require it). See C<L</SvCUR>>. Access the character as C<*(SvEND(sv))>. Warning: If C<SvCUR> is equal to C<SvLEN>, then C<SvEND> points to unallocated memory. =for apidoc Am|HV*|SvSTASH|SV* sv Returns the stash of the SV. =for apidoc Am|void|SvIV_set|SV* sv|IV val Set the value of the IV pointer in sv to val. It is possible to perform the same function of this macro with an lvalue assignment to C<SvIVX>. With future Perls, however, it will be more efficient to use C<SvIV_set> instead of the lvalue assignment to C<SvIVX>. =for apidoc Am|void|SvNV_set|SV* sv|NV val Set the value of the NV pointer in C<sv> to val. See C<L</SvIV_set>>. =for apidoc Am|void|SvPV_set|SV* sv|char* val This is probably not what you want to use, you probably wanted L</sv_usepvn_flags> or L</sv_setpvn> or L</sv_setpvs>. Set the value of the PV pointer in C<sv> to the Perl allocated C<NUL>-terminated string C<val>. See also C<L</SvIV_set>>. Remember to free the previous PV buffer. There are many things to check. Beware that the existing pointer may be involved in copy-on-write or other mischief, so do C<SvOOK_off(sv)> and use C<sv_force_normal> or C<SvPV_force> (or check the C<SvIsCOW> flag) first to make sure this modification is safe. Then finally, if it is not a COW, call C<SvPV_free> to free the previous PV buffer. =for apidoc Am|void|SvUV_set|SV* sv|UV val Set the value of the UV pointer in C<sv> to val. See C<L</SvIV_set>>. =for apidoc Am|void|SvRV_set|SV* sv|SV* val Set the value of the RV pointer in C<sv> to val. See C<L</SvIV_set>>. =for apidoc Am|void|SvMAGIC_set|SV* sv|MAGIC* val Set the value of the MAGIC pointer in C<sv> to val. See C<L</SvIV_set>>. =for apidoc Am|void|SvSTASH_set|SV* sv|HV* val Set the value of the STASH pointer in C<sv> to val. See C<L</SvIV_set>>. =for apidoc Am|void|SvCUR_set|SV* sv|STRLEN len Set the current length of the string which is in the SV. See C<L</SvCUR>> and C<SvIV_set>>. =for apidoc Am|void|SvLEN_set|SV* sv|STRLEN len Set the size of the string buffer for the SV. See C<L</SvLEN>>. =cut */ #define SvNIOK(sv) (SvFLAGS(sv) & (SVf_IOK|SVf_NOK)) #define SvNIOKp(sv) (SvFLAGS(sv) & (SVp_IOK|SVp_NOK)) #define SvNIOK_off(sv) (SvFLAGS(sv) &= ~(SVf_IOK|SVf_NOK| \ SVp_IOK|SVp_NOK|SVf_IVisUV)) #define assert_not_ROK(sv) assert_(!SvROK(sv) || !SvRV(sv)) #define assert_not_glob(sv) assert_(!isGV_with_GP(sv)) #define SvOK(sv) (SvFLAGS(sv) & SVf_OK || isREGEXP(sv)) #define SvOK_off(sv) (assert_not_ROK(sv) assert_not_glob(sv) \ SvFLAGS(sv) &= ~(SVf_OK| \ SVf_IVisUV|SVf_UTF8), \ SvOOK_off(sv)) #define SvOK_off_exc_UV(sv) (assert_not_ROK(sv) \ SvFLAGS(sv) &= ~(SVf_OK| \ SVf_UTF8), \ SvOOK_off(sv)) #define SvOKp(sv) (SvFLAGS(sv) & (SVp_IOK|SVp_NOK|SVp_POK)) #define SvIOKp(sv) (SvFLAGS(sv) & SVp_IOK) #define SvIOKp_on(sv) (assert_not_glob(sv) \ SvFLAGS(sv) |= SVp_IOK) #define SvNOKp(sv) (SvFLAGS(sv) & SVp_NOK) #define SvNOKp_on(sv) (assert_not_glob(sv) SvFLAGS(sv) |= SVp_NOK) #define SvPOKp(sv) (SvFLAGS(sv) & SVp_POK) #define SvPOKp_on(sv) (assert_not_ROK(sv) assert_not_glob(sv) \ SvFLAGS(sv) |= SVp_POK) #define SvIOK(sv) (SvFLAGS(sv) & SVf_IOK) #define SvIOK_on(sv) (assert_not_glob(sv) \ SvFLAGS(sv) |= (SVf_IOK|SVp_IOK)) #define SvIOK_off(sv) (SvFLAGS(sv) &= ~(SVf_IOK|SVp_IOK|SVf_IVisUV)) #define SvIOK_only(sv) (SvOK_off(sv), \ SvFLAGS(sv) |= (SVf_IOK|SVp_IOK)) #define SvIOK_only_UV(sv) (assert_not_glob(sv) SvOK_off_exc_UV(sv), \ SvFLAGS(sv) |= (SVf_IOK|SVp_IOK)) #define SvIOK_UV(sv) ((SvFLAGS(sv) & (SVf_IOK|SVf_IVisUV)) \ == (SVf_IOK|SVf_IVisUV)) #define SvUOK(sv) SvIOK_UV(sv) #define SvIOK_notUV(sv) ((SvFLAGS(sv) & (SVf_IOK|SVf_IVisUV)) \ == SVf_IOK) #define SvIsUV(sv) (SvFLAGS(sv) & SVf_IVisUV) #define SvIsUV_on(sv) (SvFLAGS(sv) |= SVf_IVisUV) #define SvIsUV_off(sv) (SvFLAGS(sv) &= ~SVf_IVisUV) #define SvNOK(sv) (SvFLAGS(sv) & SVf_NOK) #define SvNOK_on(sv) (assert_not_glob(sv) \ SvFLAGS(sv) |= (SVf_NOK|SVp_NOK)) #define SvNOK_off(sv) (SvFLAGS(sv) &= ~(SVf_NOK|SVp_NOK)) #define SvNOK_only(sv) (SvOK_off(sv), \ SvFLAGS(sv) |= (SVf_NOK|SVp_NOK)) /* =for apidoc Am|U32|SvUTF8|SV* sv Returns a U32 value indicating the UTF-8 status of an SV. If things are set-up properly, this indicates whether or not the SV contains UTF-8 encoded data. You should use this I<after> a call to C<SvPV()> or one of its variants, in case any call to string overloading updates the internal flag. If you want to take into account the L<bytes> pragma, use C<L</DO_UTF8>> instead. =for apidoc Am|void|SvUTF8_on|SV *sv Turn on the UTF-8 status of an SV (the data is not changed, just the flag). Do not use frivolously. =for apidoc Am|void|SvUTF8_off|SV *sv Unsets the UTF-8 status of an SV (the data is not changed, just the flag). Do not use frivolously. =for apidoc Am|void|SvPOK_only_UTF8|SV* sv Tells an SV that it is a string and disables all other C<OK> bits, and leaves the UTF-8 status as it was. =cut */ /* Ensure the return value of this macro does not clash with the GV_ADD* flags in gv.h: */ #define SvUTF8(sv) (SvFLAGS(sv) & SVf_UTF8) #define SvUTF8_on(sv) (SvFLAGS(sv) |= (SVf_UTF8)) #define SvUTF8_off(sv) (SvFLAGS(sv) &= ~(SVf_UTF8)) #define SvPOK(sv) (SvFLAGS(sv) & SVf_POK) #define SvPOK_on(sv) (assert_not_ROK(sv) assert_not_glob(sv) \ SvFLAGS(sv) |= (SVf_POK|SVp_POK)) #define SvPOK_off(sv) (SvFLAGS(sv) &= ~(SVf_POK|SVp_POK)) #define SvPOK_only(sv) (assert_not_ROK(sv) assert_not_glob(sv) \ SvFLAGS(sv) &= ~(SVf_OK| \ SVf_IVisUV|SVf_UTF8), \ SvFLAGS(sv) |= (SVf_POK|SVp_POK)) #define SvPOK_only_UTF8(sv) (assert_not_ROK(sv) assert_not_glob(sv) \ SvFLAGS(sv) &= ~(SVf_OK| \ SVf_IVisUV), \ SvFLAGS(sv) |= (SVf_POK|SVp_POK)) #define SvVOK(sv) (SvMAGICAL(sv) \ && mg_find(sv,PERL_MAGIC_vstring)) /* returns the vstring magic, if any */ #define SvVSTRING_mg(sv) (SvMAGICAL(sv) \ ? mg_find(sv,PERL_MAGIC_vstring) : NULL) #define SvOOK(sv) (SvFLAGS(sv) & SVf_OOK) #define SvOOK_on(sv) (SvFLAGS(sv) |= SVf_OOK) #define SvOOK_off(sv) ((void)(SvOOK(sv) && (sv_backoff(sv),0))) #define SvFAKE(sv) (SvFLAGS(sv) & SVf_FAKE) #define SvFAKE_on(sv) (SvFLAGS(sv) |= SVf_FAKE) #define SvFAKE_off(sv) (SvFLAGS(sv) &= ~SVf_FAKE) #define SvROK(sv) (SvFLAGS(sv) & SVf_ROK) #define SvROK_on(sv) (SvFLAGS(sv) |= SVf_ROK) #define SvROK_off(sv) (SvFLAGS(sv) &= ~(SVf_ROK)) #define SvMAGICAL(sv) (SvFLAGS(sv) & (SVs_GMG|SVs_SMG|SVs_RMG)) #define SvMAGICAL_on(sv) (SvFLAGS(sv) |= (SVs_GMG|SVs_SMG|SVs_RMG)) #define SvMAGICAL_off(sv) (SvFLAGS(sv) &= ~(SVs_GMG|SVs_SMG|SVs_RMG)) #define SvGMAGICAL(sv) (SvFLAGS(sv) & SVs_GMG) #define SvGMAGICAL_on(sv) (SvFLAGS(sv) |= SVs_GMG) #define SvGMAGICAL_off(sv) (SvFLAGS(sv) &= ~SVs_GMG) #define SvSMAGICAL(sv) (SvFLAGS(sv) & SVs_SMG) #define SvSMAGICAL_on(sv) (SvFLAGS(sv) |= SVs_SMG) #define SvSMAGICAL_off(sv) (SvFLAGS(sv) &= ~SVs_SMG) #define SvRMAGICAL(sv) (SvFLAGS(sv) & SVs_RMG) #define SvRMAGICAL_on(sv) (SvFLAGS(sv) |= SVs_RMG) #define SvRMAGICAL_off(sv) (SvFLAGS(sv) &= ~SVs_RMG) #define SvAMAGIC(sv) (SvROK(sv) && SvOBJECT(SvRV(sv)) && \ HvAMAGIC(SvSTASH(SvRV(sv)))) /* To be used on the stashes themselves: */ #define HvAMAGIC(hv) (SvFLAGS(hv) & SVf_AMAGIC) #define HvAMAGIC_on(hv) (SvFLAGS(hv) |= SVf_AMAGIC) #define HvAMAGIC_off(hv) (SvFLAGS(hv) &=~ SVf_AMAGIC) /* "nog" means "doesn't have get magic" */ #define SvPOK_nog(sv) ((SvFLAGS(sv) & (SVf_POK|SVs_GMG)) == SVf_POK) #define SvIOK_nog(sv) ((SvFLAGS(sv) & (SVf_IOK|SVs_GMG)) == SVf_IOK) #define SvUOK_nog(sv) ((SvFLAGS(sv) & (SVf_IOK|SVf_IVisUV|SVs_GMG)) == (SVf_IOK|SVf_IVisUV)) #define SvNOK_nog(sv) ((SvFLAGS(sv) & (SVf_NOK|SVs_GMG)) == SVf_NOK) #define SvNIOK_nog(sv) (SvNIOK(sv) && !(SvFLAGS(sv) & SVs_GMG)) #define SvPOK_nogthink(sv) ((SvFLAGS(sv) & (SVf_POK|SVf_THINKFIRST|SVs_GMG)) == SVf_POK) #define SvIOK_nogthink(sv) ((SvFLAGS(sv) & (SVf_IOK|SVf_THINKFIRST|SVs_GMG)) == SVf_IOK) #define SvUOK_nogthink(sv) ((SvFLAGS(sv) & (SVf_IOK|SVf_IVisUV|SVf_THINKFIRST|SVs_GMG)) == (SVf_IOK|SVf_IVisUV)) #define SvNOK_nogthink(sv) ((SvFLAGS(sv) & (SVf_NOK|SVf_THINKFIRST|SVs_GMG)) == SVf_NOK) #define SvNIOK_nogthink(sv) (SvNIOK(sv) && !(SvFLAGS(sv) & (SVf_THINKFIRST|SVs_GMG))) #define SvPOK_utf8_nog(sv) ((SvFLAGS(sv) & (SVf_POK|SVf_UTF8|SVs_GMG)) == (SVf_POK|SVf_UTF8)) #define SvPOK_utf8_nogthink(sv) ((SvFLAGS(sv) & (SVf_POK|SVf_UTF8|SVf_THINKFIRST|SVs_GMG)) == (SVf_POK|SVf_UTF8)) #define SvPOK_byte_nog(sv) ((SvFLAGS(sv) & (SVf_POK|SVf_UTF8|SVs_GMG)) == SVf_POK) #define SvPOK_byte_nogthink(sv) ((SvFLAGS(sv) & (SVf_POK|SVf_UTF8|SVf_THINKFIRST|SVs_GMG)) == SVf_POK) #define SvPOK_pure_nogthink(sv) \ ((SvFLAGS(sv) & (SVf_POK|SVf_IOK|SVf_NOK|SVf_ROK|SVpgv_GP|SVf_THINKFIRST|SVs_GMG)) == SVf_POK) #define SvPOK_utf8_pure_nogthink(sv) \ ((SvFLAGS(sv) & (SVf_POK|SVf_UTF8|SVf_IOK|SVf_NOK|SVf_ROK|SVpgv_GP|SVf_THINKFIRST|SVs_GMG)) == (SVf_POK|SVf_UTF8)) #define SvPOK_byte_pure_nogthink(sv) \ ((SvFLAGS(sv) & (SVf_POK|SVf_UTF8|SVf_IOK|SVf_NOK|SVf_ROK|SVpgv_GP|SVf_THINKFIRST|SVs_GMG)) == SVf_POK) /* =for apidoc Am|U32|SvGAMAGIC|SV* sv Returns true if the SV has get magic or overloading. If either is true then the scalar is active data, and has the potential to return a new value every time it is accessed. Hence you must be careful to only read it once per user logical operation and work with that returned value. If neither is true then the scalar's value cannot change unless written to. =cut */ #define SvGAMAGIC(sv) (SvGMAGICAL(sv) || SvAMAGIC(sv)) #define Gv_AMG(stash) \ (HvNAME(stash) && Gv_AMupdate(stash,FALSE) \ ? 1 \ : (HvAMAGIC_off(stash), 0)) #define SvWEAKREF(sv) ((SvFLAGS(sv) & (SVf_ROK|SVprv_WEAKREF)) \ == (SVf_ROK|SVprv_WEAKREF)) #define SvWEAKREF_on(sv) (SvFLAGS(sv) |= (SVf_ROK|SVprv_WEAKREF)) #define SvWEAKREF_off(sv) (SvFLAGS(sv) &= ~(SVf_ROK|SVprv_WEAKREF)) #define SvPCS_IMPORTED(sv) ((SvFLAGS(sv) & (SVf_ROK|SVprv_PCS_IMPORTED)) \ == (SVf_ROK|SVprv_PCS_IMPORTED)) #define SvPCS_IMPORTED_on(sv) (SvFLAGS(sv) |= (SVf_ROK|SVprv_PCS_IMPORTED)) #define SvPCS_IMPORTED_off(sv) (SvFLAGS(sv) &= ~(SVf_ROK|SVprv_PCS_IMPORTED)) /* =for apidoc m|U32|SvTHINKFIRST|SV *sv A quick flag check to see whether an C<sv> should be passed to C<sv_force_normal> to be "downgraded" before C<SvIVX> or C<SvPVX> can be modified directly. For example, if your scalar is a reference and you want to modify the C<SvIVX> slot, you can't just do C<SvROK_off>, as that will leak the referent. This is used internally by various sv-modifying functions, such as C<sv_setsv>, C<sv_setiv> and C<sv_pvn_force>. One case that this does not handle is a gv without SvFAKE set. After if (SvTHINKFIRST(gv)) sv_force_normal(gv); it will still be a gv. C<SvTHINKFIRST> sometimes produces false positives. In those cases C<sv_force_normal> does nothing. =cut */ #define SvTHINKFIRST(sv) (SvFLAGS(sv) & SVf_THINKFIRST) #define SVs_PADMY 0 #define SvPADMY(sv) !(SvFLAGS(sv) & SVs_PADTMP) #ifndef PERL_CORE # define SvPADMY_on(sv) SvPADTMP_off(sv) #endif #define SvPADTMP(sv) (SvFLAGS(sv) & (SVs_PADTMP)) #define SvPADSTALE(sv) (SvFLAGS(sv) & (SVs_PADSTALE)) #define SvPADTMP_on(sv) (SvFLAGS(sv) |= SVs_PADTMP) #define SvPADTMP_off(sv) (SvFLAGS(sv) &= ~SVs_PADTMP) #define SvPADSTALE_on(sv) S_SvPADSTALE_on(MUTABLE_SV(sv)) #define SvPADSTALE_off(sv) S_SvPADSTALE_off(MUTABLE_SV(sv)) #define SvTEMP(sv) (SvFLAGS(sv) & SVs_TEMP) #define SvTEMP_on(sv) (SvFLAGS(sv) |= SVs_TEMP) #define SvTEMP_off(sv) (SvFLAGS(sv) &= ~SVs_TEMP) #define SvOBJECT(sv) (SvFLAGS(sv) & SVs_OBJECT) #define SvOBJECT_on(sv) (SvFLAGS(sv) |= SVs_OBJECT) #define SvOBJECT_off(sv) (SvFLAGS(sv) &= ~SVs_OBJECT) /* =for apidoc Am|U32|SvREADONLY|SV* sv Returns true if the argument is readonly, otherwise returns false. Exposed to to perl code via Internals::SvREADONLY(). =for apidoc Am|U32|SvREADONLY_on|SV* sv Mark an object as readonly. Exactly what this means depends on the object type. Exposed to perl code via Internals::SvREADONLY(). =for apidoc Am|U32|SvREADONLY_off|SV* sv Mark an object as not-readonly. Exactly what this mean depends on the object type. Exposed to perl code via Internals::SvREADONLY(). =cut */ #define SvREADONLY(sv) (SvFLAGS(sv) & (SVf_READONLY|SVf_PROTECT)) #ifdef PERL_CORE # define SvREADONLY_on(sv) (SvFLAGS(sv) |= (SVf_READONLY|SVf_PROTECT)) # define SvREADONLY_off(sv) (SvFLAGS(sv) &=~(SVf_READONLY|SVf_PROTECT)) #else # define SvREADONLY_on(sv) (SvFLAGS(sv) |= SVf_READONLY) # define SvREADONLY_off(sv) (SvFLAGS(sv) &= ~SVf_READONLY) #endif #define SvSCREAM(sv) ((SvFLAGS(sv) & (SVp_SCREAM|SVp_POK)) == (SVp_SCREAM|SVp_POK)) #define SvSCREAM_on(sv) (SvFLAGS(sv) |= SVp_SCREAM) #define SvSCREAM_off(sv) (SvFLAGS(sv) &= ~SVp_SCREAM) #ifndef PERL_CORE # define SvCOMPILED(sv) 0 # define SvCOMPILED_on(sv) # define SvCOMPILED_off(sv) #endif #if defined (DEBUGGING) && defined(__GNUC__) && !defined(PERL_GCC_BRACE_GROUPS_FORBIDDEN) # define SvTAIL(sv) ({ const SV *const _svtail = (const SV *)(sv); \ assert(SvTYPE(_svtail) != SVt_PVAV); \ assert(SvTYPE(_svtail) != SVt_PVHV); \ assert(!(SvFLAGS(_svtail) & (SVf_NOK|SVp_NOK))); \ assert(SvVALID(_svtail)); \ ((XPVNV*)SvANY(_svtail))->xnv_u.xnv_bm_tail; \ }) #else # define SvTAIL(_svtail) (((XPVNV*)SvANY(_svtail))->xnv_u.xnv_bm_tail) #endif /* Does the SV have a Boyer-Moore table attached as magic? * 'VALID' is a poor name, but is kept for historical reasons. */ #define SvVALID(_svvalid) ( \ SvPOKp(_svvalid) \ && SvSMAGICAL(_svvalid) \ && SvMAGIC(_svvalid) \ && (SvMAGIC(_svvalid)->mg_type == PERL_MAGIC_bm \ || mg_find(_svvalid, PERL_MAGIC_bm)) \ ) #define SvRVx(sv) SvRV(sv) #ifdef PERL_DEBUG_COW /* Need -0.0 for SvNVX to preserve IEEE FP "negative zero" because +0.0 + -0.0 => +0.0 but -0.0 + -0.0 => -0.0 */ # define SvIVX(sv) (0 + ((XPVIV*) SvANY(sv))->xiv_iv) # define SvUVX(sv) (0 + ((XPVUV*) SvANY(sv))->xuv_uv) # define SvNVX(sv) (-0.0 + ((XPVNV*) SvANY(sv))->xnv_u.xnv_nv) # define SvRV(sv) (0 + (sv)->sv_u.svu_rv) # define SvRV_const(sv) (0 + (sv)->sv_u.svu_rv) /* Don't test the core XS code yet. */ # if defined (PERL_CORE) && PERL_DEBUG_COW > 1 # define SvPVX(sv) (0 + (assert_(!SvREADONLY(sv)) (sv)->sv_u.svu_pv)) # else # define SvPVX(sv) SvPVX_mutable(sv) # endif # define SvCUR(sv) (0 + ((XPV*) SvANY(sv))->xpv_cur) # define SvLEN(sv) (0 + ((XPV*) SvANY(sv))->xpv_len) # define SvEND(sv) ((sv)->sv_u.svu_pv + ((XPV*)SvANY(sv))->xpv_cur) # define SvMAGIC(sv) (0 + *(assert_(SvTYPE(sv) >= SVt_PVMG) &((XPVMG*) SvANY(sv))->xmg_u.xmg_magic)) # define SvSTASH(sv) (0 + *(assert_(SvTYPE(sv) >= SVt_PVMG) &((XPVMG*) SvANY(sv))->xmg_stash)) #else # define SvLEN(sv) ((XPV*) SvANY(sv))->xpv_len # define SvEND(sv) ((sv)->sv_u.svu_pv + ((XPV*)SvANY(sv))->xpv_cur) # if defined (DEBUGGING) && defined(__GNUC__) && !defined(PERL_GCC_BRACE_GROUPS_FORBIDDEN) /* These get expanded inside other macros that already use a variable _sv */ # define SvPVX(sv) \ (*({ SV *const _svpvx = MUTABLE_SV(sv); \ assert(PL_valid_types_PVX[SvTYPE(_svpvx) & SVt_MASK]); \ assert(!isGV_with_GP(_svpvx)); \ assert(!(SvTYPE(_svpvx) == SVt_PVIO \ && !(IoFLAGS(_svpvx) & IOf_FAKE_DIRP))); \ &((_svpvx)->sv_u.svu_pv); \ })) # define SvCUR(sv) \ (*({ const SV *const _svcur = (const SV *)(sv); \ assert(PL_valid_types_PVX[SvTYPE(_svcur) & SVt_MASK] \ || SvTYPE(_svcur) == SVt_REGEXP); \ assert(!isGV_with_GP(_svcur)); \ assert(!(SvTYPE(_svcur) == SVt_PVIO \ && !(IoFLAGS(_svcur) & IOf_FAKE_DIRP))); \ &(((XPV*) MUTABLE_PTR(SvANY(_svcur)))->xpv_cur); \ })) # define SvIVX(sv) \ (*({ const SV *const _svivx = (const SV *)(sv); \ assert(PL_valid_types_IVX[SvTYPE(_svivx) & SVt_MASK]); \ assert(!isGV_with_GP(_svivx)); \ &(((XPVIV*) MUTABLE_PTR(SvANY(_svivx)))->xiv_iv); \ })) # define SvUVX(sv) \ (*({ const SV *const _svuvx = (const SV *)(sv); \ assert(PL_valid_types_IVX[SvTYPE(_svuvx) & SVt_MASK]); \ assert(!isGV_with_GP(_svuvx)); \ &(((XPVUV*) MUTABLE_PTR(SvANY(_svuvx)))->xuv_uv); \ })) # define SvNVX(sv) \ (*({ const SV *const _svnvx = (const SV *)(sv); \ assert(PL_valid_types_NVX[SvTYPE(_svnvx) & SVt_MASK]); \ assert(!isGV_with_GP(_svnvx)); \ &(((XPVNV*) MUTABLE_PTR(SvANY(_svnvx)))->xnv_u.xnv_nv); \ })) # define SvRV(sv) \ (*({ SV *const _svrv = MUTABLE_SV(sv); \ assert(PL_valid_types_RV[SvTYPE(_svrv) & SVt_MASK]); \ assert(!isGV_with_GP(_svrv)); \ assert(!(SvTYPE(_svrv) == SVt_PVIO \ && !(IoFLAGS(_svrv) & IOf_FAKE_DIRP))); \ &((_svrv)->sv_u.svu_rv); \ })) # define SvRV_const(sv) \ ({ const SV *const _svrv = (const SV *)(sv); \ assert(PL_valid_types_RV[SvTYPE(_svrv) & SVt_MASK]); \ assert(!isGV_with_GP(_svrv)); \ assert(!(SvTYPE(_svrv) == SVt_PVIO \ && !(IoFLAGS(_svrv) & IOf_FAKE_DIRP))); \ (_svrv)->sv_u.svu_rv; \ }) # define SvMAGIC(sv) \ (*({ const SV *const _svmagic = (const SV *)(sv); \ assert(SvTYPE(_svmagic) >= SVt_PVMG); \ &(((XPVMG*) MUTABLE_PTR(SvANY(_svmagic)))->xmg_u.xmg_magic); \ })) # define SvSTASH(sv) \ (*({ const SV *const _svstash = (const SV *)(sv); \ assert(SvTYPE(_svstash) >= SVt_PVMG); \ &(((XPVMG*) MUTABLE_PTR(SvANY(_svstash)))->xmg_stash); \ })) # else # define SvPVX(sv) ((sv)->sv_u.svu_pv) # define SvCUR(sv) ((XPV*) SvANY(sv))->xpv_cur # define SvIVX(sv) ((XPVIV*) SvANY(sv))->xiv_iv # define SvUVX(sv) ((XPVUV*) SvANY(sv))->xuv_uv # define SvNVX(sv) ((XPVNV*) SvANY(sv))->xnv_u.xnv_nv # define SvRV(sv) ((sv)->sv_u.svu_rv) # define SvRV_const(sv) (0 + (sv)->sv_u.svu_rv) # define SvMAGIC(sv) ((XPVMG*) SvANY(sv))->xmg_u.xmg_magic # define SvSTASH(sv) ((XPVMG*) SvANY(sv))->xmg_stash # endif #endif #ifndef PERL_POISON /* Given that these two are new, there can't be any existing code using them * as LVALUEs */ # define SvPVX_mutable(sv) (0 + (sv)->sv_u.svu_pv) # define SvPVX_const(sv) ((const char*)(0 + (sv)->sv_u.svu_pv)) #else /* Except for the poison code, which uses & to scribble over the pointer after free() is called. */ # define SvPVX_mutable(sv) ((sv)->sv_u.svu_pv) # define SvPVX_const(sv) ((const char*)((sv)->sv_u.svu_pv)) #endif #define SvIVXx(sv) SvIVX(sv) #define SvUVXx(sv) SvUVX(sv) #define SvNVXx(sv) SvNVX(sv) #define SvPVXx(sv) SvPVX(sv) #define SvLENx(sv) SvLEN(sv) #define SvENDx(sv) ((PL_Sv = (sv)), SvEND(PL_Sv)) /* Ask a scalar nicely to try to become an IV, if possible. Not guaranteed to stay returning void */ /* Macro won't actually call sv_2iv if already IOK */ #define SvIV_please(sv) \ STMT_START {if (!SvIOKp(sv) && (SvFLAGS(sv) & (SVf_NOK|SVf_POK))) \ (void) SvIV(sv); } STMT_END #define SvIV_please_nomg(sv) \ (!(SvFLAGS(sv) & (SVf_IOK|SVp_IOK)) && (SvFLAGS(sv) & (SVf_NOK|SVf_POK)) \ ? (sv_2iv_flags(sv, 0), SvIOK(sv)) \ : SvIOK(sv)) #define SvIV_set(sv, val) \ STMT_START { \ assert(PL_valid_types_IV_set[SvTYPE(sv) & SVt_MASK]); \ assert(!isGV_with_GP(sv)); \ (((XPVIV*) SvANY(sv))->xiv_iv = (val)); } STMT_END #define SvNV_set(sv, val) \ STMT_START { \ assert(PL_valid_types_NV_set[SvTYPE(sv) & SVt_MASK]); \ assert(!isGV_with_GP(sv)); \ (((XPVNV*)SvANY(sv))->xnv_u.xnv_nv = (val)); } STMT_END #define SvPV_set(sv, val) \ STMT_START { \ assert(PL_valid_types_PVX[SvTYPE(sv) & SVt_MASK]); \ assert(!isGV_with_GP(sv)); \ assert(!(SvTYPE(sv) == SVt_PVIO \ && !(IoFLAGS(sv) & IOf_FAKE_DIRP))); \ ((sv)->sv_u.svu_pv = (val)); } STMT_END #define SvUV_set(sv, val) \ STMT_START { \ assert(PL_valid_types_IV_set[SvTYPE(sv) & SVt_MASK]); \ assert(!isGV_with_GP(sv)); \ (((XPVUV*)SvANY(sv))->xuv_uv = (val)); } STMT_END #define SvRV_set(sv, val) \ STMT_START { \ assert(PL_valid_types_RV[SvTYPE(sv) & SVt_MASK]); \ assert(!isGV_with_GP(sv)); \ assert(!(SvTYPE(sv) == SVt_PVIO \ && !(IoFLAGS(sv) & IOf_FAKE_DIRP))); \ ((sv)->sv_u.svu_rv = (val)); } STMT_END #define SvMAGIC_set(sv, val) \ STMT_START { assert(SvTYPE(sv) >= SVt_PVMG); \ (((XPVMG*)SvANY(sv))->xmg_u.xmg_magic = (val)); } STMT_END #define SvSTASH_set(sv, val) \ STMT_START { assert(SvTYPE(sv) >= SVt_PVMG); \ (((XPVMG*) SvANY(sv))->xmg_stash = (val)); } STMT_END #define SvCUR_set(sv, val) \ STMT_START { \ assert(PL_valid_types_PVX[SvTYPE(sv) & SVt_MASK] \ || SvTYPE(sv) == SVt_REGEXP); \ assert(!isGV_with_GP(sv)); \ assert(!(SvTYPE(sv) == SVt_PVIO \ && !(IoFLAGS(sv) & IOf_FAKE_DIRP))); \ (((XPV*) SvANY(sv))->xpv_cur = (val)); } STMT_END #define SvLEN_set(sv, val) \ STMT_START { \ assert(PL_valid_types_PVX[SvTYPE(sv) & SVt_MASK]); \ assert(!isGV_with_GP(sv)); \ assert(!(SvTYPE(sv) == SVt_PVIO \ && !(IoFLAGS(sv) & IOf_FAKE_DIRP))); \ (((XPV*) SvANY(sv))->xpv_len = (val)); } STMT_END #define SvEND_set(sv, val) \ STMT_START { assert(SvTYPE(sv) >= SVt_PV); \ SvCUR_set(sv, (val) - SvPVX(sv)); } STMT_END #define SvPV_renew(sv,n) \ STMT_START { SvLEN_set(sv, n); \ SvPV_set((sv), (MEM_WRAP_CHECK_(n,char) \ (char*)saferealloc((Malloc_t)SvPVX(sv), \ (MEM_SIZE)((n))))); \ } STMT_END #define SvPV_shrink_to_cur(sv) STMT_START { \ const STRLEN _lEnGtH = SvCUR(sv) + 1; \ SvPV_renew(sv, _lEnGtH); \ } STMT_END #define SvPV_free(sv) \ STMT_START { \ assert(SvTYPE(sv) >= SVt_PV); \ if (SvLEN(sv)) { \ assert(!SvROK(sv)); \ if(UNLIKELY(SvOOK(sv))) { \ STRLEN zok; \ SvOOK_offset(sv, zok); \ SvPV_set(sv, SvPVX_mutable(sv) - zok); \ SvFLAGS(sv) &= ~SVf_OOK; \ } \ Safefree(SvPVX(sv)); \ } \ } STMT_END #ifdef PERL_CORE /* Code that crops up in three places to take a scalar and ready it to hold a reference */ # define prepare_SV_for_RV(sv) \ STMT_START { \ if (SvTYPE(sv) < SVt_PV && SvTYPE(sv) != SVt_IV) \ sv_upgrade(sv, SVt_IV); \ else if (SvTYPE(sv) >= SVt_PV) { \ SvPV_free(sv); \ SvLEN_set(sv, 0); \ SvCUR_set(sv, 0); \ } \ } STMT_END #endif #ifndef PERL_CORE # define BmFLAGS(sv) (SvTAIL(sv) ? FBMcf_TAIL : 0) #endif #if defined (DEBUGGING) && defined(__GNUC__) && !defined(PERL_GCC_BRACE_GROUPS_FORBIDDEN) # define BmUSEFUL(sv) \ (*({ SV *const _bmuseful = MUTABLE_SV(sv); \ assert(SvTYPE(_bmuseful) >= SVt_PVIV); \ assert(SvVALID(_bmuseful)); \ assert(!SvIOK(_bmuseful)); \ &(((XPVIV*) SvANY(_bmuseful))->xiv_u.xivu_iv); \ })) #else # define BmUSEFUL(sv) ((XPVIV*) SvANY(sv))->xiv_u.xivu_iv #endif #ifndef PERL_CORE # define BmRARE(sv) 0 # define BmPREVIOUS(sv) 0 #endif #define FmLINES(sv) ((XPVIV*) SvANY(sv))->xiv_iv #define LvTYPE(sv) ((XPVLV*) SvANY(sv))->xlv_type #define LvTARG(sv) ((XPVLV*) SvANY(sv))->xlv_targ #define LvTARGOFF(sv) ((XPVLV*) SvANY(sv))->xlv_targoff #define LvSTARGOFF(sv) ((XPVLV*) SvANY(sv))->xlv_targoff_u.xlvu_stargoff #define LvTARGLEN(sv) ((XPVLV*) SvANY(sv))->xlv_targlen #define LvFLAGS(sv) ((XPVLV*) SvANY(sv))->xlv_flags #define IoIFP(sv) (sv)->sv_u.svu_fp #define IoOFP(sv) ((XPVIO*) SvANY(sv))->xio_ofp #define IoDIRP(sv) ((XPVIO*) SvANY(sv))->xio_dirp #define IoANY(sv) ((XPVIO*) SvANY(sv))->xio_any #define IoLINES(sv) ((XPVIO*) SvANY(sv))->xiv_u.xivu_iv #define IoPAGE(sv) ((XPVIO*) SvANY(sv))->xio_page #define IoPAGE_LEN(sv) ((XPVIO*) SvANY(sv))->xio_page_len #define IoLINES_LEFT(sv)((XPVIO*) SvANY(sv))->xio_lines_left #define IoTOP_NAME(sv) ((XPVIO*) SvANY(sv))->xio_top_name #define IoTOP_GV(sv) ((XPVIO*) SvANY(sv))->xio_top_gv #define IoFMT_NAME(sv) ((XPVIO*) SvANY(sv))->xio_fmt_name #define IoFMT_GV(sv) ((XPVIO*) SvANY(sv))->xio_fmt_gv #define IoBOTTOM_NAME(sv)((XPVIO*) SvANY(sv))->xio_bottom_name #define IoBOTTOM_GV(sv) ((XPVIO*) SvANY(sv))->xio_bottom_gv #define IoTYPE(sv) ((XPVIO*) SvANY(sv))->xio_type #define IoFLAGS(sv) ((XPVIO*) SvANY(sv))->xio_flags /* IoTYPE(sv) is a single character telling the type of I/O connection. */ #define IoTYPE_RDONLY '<' #define IoTYPE_WRONLY '>' #define IoTYPE_RDWR '+' #define IoTYPE_APPEND 'a' #define IoTYPE_PIPE '|' #define IoTYPE_STD '-' /* stdin or stdout */ #define IoTYPE_SOCKET 's' #define IoTYPE_CLOSED ' ' #define IoTYPE_IMPLICIT 'I' /* stdin or stdout or stderr */ #define IoTYPE_NUMERIC '#' /* fdopen */ /* =for apidoc Am|bool|SvTAINTED|SV* sv Checks to see if an SV is tainted. Returns TRUE if it is, FALSE if not. =for apidoc Am|void|SvTAINTED_on|SV* sv Marks an SV as tainted if tainting is enabled. =for apidoc Am|void|SvTAINTED_off|SV* sv Untaints an SV. Be I<very> careful with this routine, as it short-circuits some of Perl's fundamental security features. XS module authors should not use this function unless they fully understand all the implications of unconditionally untainting the value. Untainting should be done in the standard perl fashion, via a carefully crafted regexp, rather than directly untainting variables. =for apidoc Am|void|SvTAINT|SV* sv Taints an SV if tainting is enabled, and if some input to the current expression is tainted--usually a variable, but possibly also implicit inputs such as locale settings. C<SvTAINT> propagates that taintedness to the outputs of an expression in a pessimistic fashion; i.e., without paying attention to precisely which outputs are influenced by which inputs. =cut */ #define sv_taint(sv) sv_magic((sv), NULL, PERL_MAGIC_taint, NULL, 0) #ifdef NO_TAINT_SUPPORT # define SvTAINTED(sv) 0 #else # define SvTAINTED(sv) (SvMAGICAL(sv) && sv_tainted(sv)) #endif #define SvTAINTED_on(sv) STMT_START{ if(UNLIKELY(TAINTING_get)){sv_taint(sv);} }STMT_END #define SvTAINTED_off(sv) STMT_START{ if(UNLIKELY(TAINTING_get)){sv_untaint(sv);} }STMT_END #define SvTAINT(sv) \ STMT_START { \ assert(TAINTING_get || !TAINT_get); \ if (UNLIKELY(TAINT_get)) \ SvTAINTED_on(sv); \ } STMT_END /* =for apidoc Am|char*|SvPV_force|SV* sv|STRLEN len Like C<SvPV> but will force the SV into containing a string (C<SvPOK>), and only a string (C<SvPOK_only>), by hook or by crook. You need force if you are going to update the C<SvPVX> directly. Processes get magic. Note that coercing an arbitrary scalar into a plain PV will potentially strip useful data from it. For example if the SV was C<SvROK>, then the referent will have its reference count decremented, and the SV itself may be converted to an C<SvPOK> scalar with a string buffer containing a value such as C<"ARRAY(0x1234)">. =for apidoc Am|char*|SvPV_force_nomg|SV* sv|STRLEN len Like C<SvPV_force>, but doesn't process get magic. =for apidoc Am|char*|SvPV|SV* sv|STRLEN len Returns a pointer to the string in the SV, or a stringified form of the SV if the SV does not contain a string. The SV may cache the stringified version becoming C<SvPOK>. Handles 'get' magic. The C<len> variable will be set to the length of the string (this is a macro, so don't use C<&len>). See also C<L</SvPVx>> for a version which guarantees to evaluate C<sv> only once. Note that there is no guarantee that the return value of C<SvPV()> is equal to C<SvPVX(sv)>, or that C<SvPVX(sv)> contains valid data, or that successive calls to C<SvPV(sv)> will return the same pointer value each time. This is due to the way that things like overloading and Copy-On-Write are handled. In these cases, the return value may point to a temporary buffer or similar. If you absolutely need the C<SvPVX> field to be valid (for example, if you intend to write to it), then see C<L</SvPV_force>>. =for apidoc Am|char*|SvPVx|SV* sv|STRLEN len A version of C<SvPV> which guarantees to evaluate C<sv> only once. Only use this if C<sv> is an expression with side effects, otherwise use the more efficient C<SvPV>. =for apidoc Am|char*|SvPV_nomg|SV* sv|STRLEN len Like C<SvPV> but doesn't process magic. =for apidoc Am|char*|SvPV_nolen|SV* sv Like C<SvPV> but doesn't set a length variable. =for apidoc Am|char*|SvPV_nomg_nolen|SV* sv Like C<SvPV_nolen> but doesn't process magic. =for apidoc Am|IV|SvIV|SV* sv Coerces the given SV to IV and returns it. The returned value in many circumstances will get stored in C<sv>'s IV slot, but not in all cases. (Use C<L</sv_setiv>> to make sure it does). See C<L</SvIVx>> for a version which guarantees to evaluate C<sv> only once. =for apidoc Am|IV|SvIV_nomg|SV* sv Like C<SvIV> but doesn't process magic. =for apidoc Am|IV|SvIVx|SV* sv Coerces the given SV to IV and returns it. The returned value in many circumstances will get stored in C<sv>'s IV slot, but not in all cases. (Use C<L</sv_setiv>> to make sure it does). This form guarantees to evaluate C<sv> only once. Only use this if C<sv> is an expression with side effects, otherwise use the more efficient C<SvIV>. =for apidoc Am|NV|SvNV|SV* sv Coerces the given SV to NV and returns it. The returned value in many circumstances will get stored in C<sv>'s NV slot, but not in all cases. (Use C<L</sv_setnv>> to make sure it does). See C<L</SvNVx>> for a version which guarantees to evaluate C<sv> only once. =for apidoc Am|NV|SvNV_nomg|SV* sv Like C<SvNV> but doesn't process magic. =for apidoc Am|NV|SvNVx|SV* sv Coerces the given SV to NV and returns it. The returned value in many circumstances will get stored in C<sv>'s NV slot, but not in all cases. (Use C<L</sv_setnv>> to make sure it does). This form guarantees to evaluate C<sv> only once. Only use this if C<sv> is an expression with side effects, otherwise use the more efficient C<SvNV>. =for apidoc Am|UV|SvUV|SV* sv Coerces the given SV to UV and returns it. The returned value in many circumstances will get stored in C<sv>'s UV slot, but not in all cases. (Use C<L</sv_setuv>> to make sure it does). See C<L</SvUVx>> for a version which guarantees to evaluate C<sv> only once. =for apidoc Am|UV|SvUV_nomg|SV* sv Like C<SvUV> but doesn't process magic. =for apidoc Am|UV|SvUVx|SV* sv Coerces the given SV to UV and returns it. The returned value in many circumstances will get stored in C<sv>'s UV slot, but not in all cases. (Use C<L</sv_setuv>> to make sure it does). This form guarantees to evaluate C<sv> only once. Only use this if C<sv> is an expression with side effects, otherwise use the more efficient C<SvUV>. =for apidoc Am|bool|SvTRUE|SV* sv Returns a boolean indicating whether Perl would evaluate the SV as true or false. See C<L</SvOK>> for a defined/undefined test. Handles 'get' magic unless the scalar is already C<SvPOK>, C<SvIOK> or C<SvNOK> (the public, not the private flags). =for apidoc Am|bool|SvTRUE_nomg|SV* sv Returns a boolean indicating whether Perl would evaluate the SV as true or false. See C<L</SvOK>> for a defined/undefined test. Does not handle 'get' magic. =for apidoc Am|char*|SvPVutf8_force|SV* sv|STRLEN len Like C<SvPV_force>, but converts C<sv> to UTF-8 first if necessary. =for apidoc Am|char*|SvPVutf8|SV* sv|STRLEN len Like C<SvPV>, but converts C<sv> to UTF-8 first if necessary. =for apidoc Am|char*|SvPVutf8_nolen|SV* sv Like C<SvPV_nolen>, but converts C<sv> to UTF-8 first if necessary. =for apidoc Am|char*|SvPVbyte_force|SV* sv|STRLEN len Like C<SvPV_force>, but converts C<sv> to byte representation first if necessary. =for apidoc Am|char*|SvPVbyte|SV* sv|STRLEN len Like C<SvPV>, but converts C<sv> to byte representation first if necessary. =for apidoc Am|char*|SvPVbyte_nolen|SV* sv Like C<SvPV_nolen>, but converts C<sv> to byte representation first if necessary. =for apidoc Am|char*|SvPVutf8x_force|SV* sv|STRLEN len Like C<SvPV_force>, but converts C<sv> to UTF-8 first if necessary. Guarantees to evaluate C<sv> only once; use the more efficient C<SvPVutf8_force> otherwise. =for apidoc Am|char*|SvPVutf8x|SV* sv|STRLEN len Like C<SvPV>, but converts C<sv> to UTF-8 first if necessary. Guarantees to evaluate C<sv> only once; use the more efficient C<SvPVutf8> otherwise. =for apidoc Am|char*|SvPVbytex_force|SV* sv|STRLEN len Like C<SvPV_force>, but converts C<sv> to byte representation first if necessary. Guarantees to evaluate C<sv> only once; use the more efficient C<SvPVbyte_force> otherwise. =for apidoc Am|char*|SvPVbytex|SV* sv|STRLEN len Like C<SvPV>, but converts C<sv> to byte representation first if necessary. Guarantees to evaluate C<sv> only once; use the more efficient C<SvPVbyte> otherwise. =for apidoc Am|U32|SvIsCOW|SV* sv Returns a U32 value indicating whether the SV is Copy-On-Write (either shared hash key scalars, or full Copy On Write scalars if 5.9.0 is configured for COW). =for apidoc Am|bool|SvIsCOW_shared_hash|SV* sv Returns a boolean indicating whether the SV is Copy-On-Write shared hash key scalar. =for apidoc Am|void|sv_catpvn_nomg|SV* sv|const char* ptr|STRLEN len Like C<sv_catpvn> but doesn't process magic. =for apidoc Am|void|sv_catpv_nomg|SV* sv|const char* ptr Like C<sv_catpv> but doesn't process magic. =for apidoc Am|void|sv_setsv_nomg|SV* dsv|SV* ssv Like C<sv_setsv> but doesn't process magic. =for apidoc Am|void|sv_catsv_nomg|SV* dsv|SV* ssv Like C<sv_catsv> but doesn't process magic. =for apidoc Amdb|STRLEN|sv_utf8_upgrade_nomg|NN SV *sv Like C<sv_utf8_upgrade>, but doesn't do magic on C<sv>. =cut */ /* Let us hope that bitmaps for UV and IV are the same */ #define SvIV(sv) (SvIOK_nog(sv) ? SvIVX(sv) : sv_2iv(sv)) #define SvUV(sv) (SvUOK_nog(sv) ? SvUVX(sv) : sv_2uv(sv)) #define SvNV(sv) (SvNOK_nog(sv) ? SvNVX(sv) : sv_2nv(sv)) #define SvIV_nomg(sv) (SvIOK(sv) ? SvIVX(sv) : sv_2iv_flags(sv, 0)) #define SvUV_nomg(sv) (SvIOK(sv) ? SvUVX(sv) : sv_2uv_flags(sv, 0)) #define SvNV_nomg(sv) (SvNOK(sv) ? SvNVX(sv) : sv_2nv_flags(sv, 0)) /* ----*/ #define SvPV(sv, lp) SvPV_flags(sv, lp, SV_GMAGIC) #define SvPV_const(sv, lp) SvPV_flags_const(sv, lp, SV_GMAGIC) #define SvPV_mutable(sv, lp) SvPV_flags_mutable(sv, lp, SV_GMAGIC) #define SvPV_flags(sv, lp, flags) \ (SvPOK_nog(sv) \ ? ((lp = SvCUR(sv)), SvPVX(sv)) : sv_2pv_flags(sv, &lp, flags)) #define SvPV_flags_const(sv, lp, flags) \ (SvPOK_nog(sv) \ ? ((lp = SvCUR(sv)), SvPVX_const(sv)) : \ (const char*) sv_2pv_flags(sv, &lp, (flags|SV_CONST_RETURN))) #define SvPV_flags_const_nolen(sv, flags) \ (SvPOK_nog(sv) \ ? SvPVX_const(sv) : \ (const char*) sv_2pv_flags(sv, 0, (flags|SV_CONST_RETURN))) #define SvPV_flags_mutable(sv, lp, flags) \ (SvPOK_nog(sv) \ ? ((lp = SvCUR(sv)), SvPVX_mutable(sv)) : \ sv_2pv_flags(sv, &lp, (flags|SV_MUTABLE_RETURN))) #define SvPV_force(sv, lp) SvPV_force_flags(sv, lp, SV_GMAGIC) #define SvPV_force_nolen(sv) SvPV_force_flags_nolen(sv, SV_GMAGIC) #define SvPV_force_mutable(sv, lp) SvPV_force_flags_mutable(sv, lp, SV_GMAGIC) #define SvPV_force_nomg(sv, lp) SvPV_force_flags(sv, lp, 0) #define SvPV_force_nomg_nolen(sv) SvPV_force_flags_nolen(sv, 0) #define SvPV_force_flags(sv, lp, flags) \ (SvPOK_pure_nogthink(sv) \ ? ((lp = SvCUR(sv)), SvPVX(sv)) : sv_pvn_force_flags(sv, &lp, flags)) #define SvPV_force_flags_nolen(sv, flags) \ (SvPOK_pure_nogthink(sv) \ ? SvPVX(sv) : sv_pvn_force_flags(sv, 0, flags)) #define SvPV_force_flags_mutable(sv, lp, flags) \ (SvPOK_pure_nogthink(sv) \ ? ((lp = SvCUR(sv)), SvPVX_mutable(sv)) \ : sv_pvn_force_flags(sv, &lp, flags|SV_MUTABLE_RETURN)) #define SvPV_nolen(sv) \ (SvPOK_nog(sv) \ ? SvPVX(sv) : sv_2pv_flags(sv, 0, SV_GMAGIC)) /* "_nomg" in these defines means no mg_get() */ #define SvPV_nomg_nolen(sv) \ (SvPOK_nog(sv) \ ? SvPVX(sv) : sv_2pv_flags(sv, 0, 0)) #define SvPV_nolen_const(sv) \ (SvPOK_nog(sv) \ ? SvPVX_const(sv) : sv_2pv_flags(sv, 0, SV_GMAGIC|SV_CONST_RETURN)) #define SvPV_nomg(sv, lp) SvPV_flags(sv, lp, 0) #define SvPV_nomg_const(sv, lp) SvPV_flags_const(sv, lp, 0) #define SvPV_nomg_const_nolen(sv) SvPV_flags_const_nolen(sv, 0) /* ----*/ #define SvPVutf8(sv, lp) \ (SvPOK_utf8_nog(sv) \ ? ((lp = SvCUR(sv)), SvPVX(sv)) : sv_2pvutf8(sv, &lp)) #define SvPVutf8_force(sv, lp) \ (SvPOK_utf8_pure_nogthink(sv) \ ? ((lp = SvCUR(sv)), SvPVX(sv)) : sv_pvutf8n_force(sv, &lp)) #define SvPVutf8_nolen(sv) \ (SvPOK_utf8_nog(sv) \ ? SvPVX(sv) : sv_2pvutf8(sv, 0)) /* ----*/ #define SvPVbyte(sv, lp) \ (SvPOK_byte_nog(sv) \ ? ((lp = SvCUR(sv)), SvPVX(sv)) : sv_2pvbyte(sv, &lp)) #define SvPVbyte_force(sv, lp) \ (SvPOK_byte_pure_nogthink(sv) \ ? ((lp = SvCUR(sv)), SvPVX(sv)) : sv_pvbyten_force(sv, &lp)) #define SvPVbyte_nolen(sv) \ (SvPOK_byte_nog(sv) \ ? SvPVX(sv) : sv_2pvbyte(sv, 0)) /* define FOOx(): idempotent versions of FOO(). If possible, use a local * var to evaluate the arg once; failing that, use a global if possible; * failing that, call a function to do the work */ #define SvPVx_force(sv, lp) sv_pvn_force(sv, &lp) #define SvPVutf8x_force(sv, lp) sv_pvutf8n_force(sv, &lp) #define SvPVbytex_force(sv, lp) sv_pvbyten_force(sv, &lp) #define SvTRUE(sv) (LIKELY(sv) && (UNLIKELY(SvGMAGICAL(sv)) ? sv_2bool(sv) : SvTRUE_common(sv, sv_2bool_nomg(sv)))) #define SvTRUE_nomg(sv) (LIKELY(sv) && ( SvTRUE_common(sv, sv_2bool_nomg(sv)))) #define SvTRUE_NN(sv) (UNLIKELY(SvGMAGICAL(sv)) ? sv_2bool(sv) : SvTRUE_common(sv, sv_2bool_nomg(sv))) #define SvTRUE_nomg_NN(sv) ( SvTRUE_common(sv, sv_2bool_nomg(sv))) #define SvTRUE_common(sv,fallback) ( \ !SvOK(sv) \ ? 0 \ : SvPOK(sv) \ ? SvPVXtrue(sv) \ : (SvFLAGS(sv) & (SVf_IOK|SVf_NOK)) \ ? ( (SvIOK(sv) && SvIVX(sv) != 0) \ || (SvNOK(sv) && SvNVX(sv) != 0.0)) \ : (fallback)) #if defined(__GNUC__) && !defined(PERL_GCC_BRACE_GROUPS_FORBIDDEN) # define SvIVx(sv) ({SV *_sv = MUTABLE_SV(sv); SvIV(_sv); }) # define SvUVx(sv) ({SV *_sv = MUTABLE_SV(sv); SvUV(_sv); }) # define SvNVx(sv) ({SV *_sv = MUTABLE_SV(sv); SvNV(_sv); }) # define SvPVx(sv, lp) ({SV *_sv = (sv); SvPV(_sv, lp); }) # define SvPVx_const(sv, lp) ({SV *_sv = (sv); SvPV_const(_sv, lp); }) # define SvPVx_nolen(sv) ({SV *_sv = (sv); SvPV_nolen(_sv); }) # define SvPVx_nolen_const(sv) ({SV *_sv = (sv); SvPV_nolen_const(_sv); }) # define SvPVutf8x(sv, lp) ({SV *_sv = (sv); SvPVutf8(_sv, lp); }) # define SvPVbytex(sv, lp) ({SV *_sv = (sv); SvPVbyte(_sv, lp); }) # define SvPVbytex_nolen(sv) ({SV *_sv = (sv); SvPVbyte_nolen(_sv); }) # define SvTRUEx(sv) ({SV *_sv = (sv); SvTRUE(_sv); }) # define SvTRUEx_nomg(sv) ({SV *_sv = (sv); SvTRUE_nomg(_sv); }) #else /* __GNUC__ */ /* These inlined macros use globals, which will require a thread * declaration in user code, so we avoid them under threads */ # define SvIVx(sv) ((PL_Sv = (sv)), SvIV(PL_Sv)) # define SvUVx(sv) ((PL_Sv = (sv)), SvUV(PL_Sv)) # define SvNVx(sv) ((PL_Sv = (sv)), SvNV(PL_Sv)) # define SvPVx(sv, lp) ((PL_Sv = (sv)), SvPV(PL_Sv, lp)) # define SvPVx_const(sv, lp) ((PL_Sv = (sv)), SvPV_const(PL_Sv, lp)) # define SvPVx_nolen(sv) ((PL_Sv = (sv)), SvPV_nolen(PL_Sv)) # define SvPVx_nolen_const(sv) ((PL_Sv = (sv)), SvPV_nolen_const(PL_Sv)) # define SvPVutf8x(sv, lp) ((PL_Sv = (sv)), SvPVutf8(PL_Sv, lp)) # define SvPVbytex(sv, lp) ((PL_Sv = (sv)), SvPVbyte(PL_Sv, lp)) # define SvPVbytex_nolen(sv) ((PL_Sv = (sv)), SvPVbyte_nolen(PL_Sv)) # define SvTRUEx(sv) ((PL_Sv = (sv)), SvTRUE(PL_Sv)) # define SvTRUEx_nomg(sv) ((PL_Sv = (sv)), SvTRUE_nomg(PL_Sv)) #endif /* __GNU__ */ #define SvPVXtrue(sv) ( \ ((XPV*)SvANY((sv))) \ && ( \ ((XPV*)SvANY((sv)))->xpv_cur > 1 \ || ( \ ((XPV*)SvANY((sv)))->xpv_cur \ && *(sv)->sv_u.svu_pv != '0' \ ) \ ) \ ) #define SvIsCOW(sv) (SvFLAGS(sv) & SVf_IsCOW) #define SvIsCOW_on(sv) (SvFLAGS(sv) |= SVf_IsCOW) #define SvIsCOW_off(sv) (SvFLAGS(sv) &= ~SVf_IsCOW) #define SvIsCOW_shared_hash(sv) (SvIsCOW(sv) && SvLEN(sv) == 0) #define SvSHARED_HEK_FROM_PV(pvx) \ ((struct hek*)(pvx - STRUCT_OFFSET(struct hek, hek_key))) #define SvSHARED_HASH(sv) (0 + SvSHARED_HEK_FROM_PV(SvPVX_const(sv))->hek_hash) /* flag values for sv_*_flags functions */ #define SV_UTF8_NO_ENCODING 0 /* No longer used */ #define SV_IMMEDIATE_UNREF 1 #define SV_GMAGIC 2 #define SV_COW_DROP_PV 4 #define SV_NOSTEAL 16 #define SV_CONST_RETURN 32 #define SV_MUTABLE_RETURN 64 #define SV_SMAGIC 128 #define SV_HAS_TRAILING_NUL 256 #define SV_COW_SHARED_HASH_KEYS 512 /* This one is only enabled for PERL_OLD_COPY_ON_WRITE */ /* XXX This flag actually enabled for any COW. But it appears not to do anything. Can we just remove it? Or will it serve some future purpose. */ #define SV_COW_OTHER_PVS 1024 /* Make sv_2pv_flags return NULL if something is undefined. */ #define SV_UNDEF_RETURNS_NULL 2048 /* Tell sv_utf8_upgrade() to not check to see if an upgrade is really needed. * This is used when the caller has already determined it is, and avoids * redundant work */ #define SV_FORCE_UTF8_UPGRADE 4096 /* if (after resolving magic etc), the SV is found to be overloaded, * don't call the overload magic, just return as-is */ #define SV_SKIP_OVERLOAD 8192 #define SV_CATBYTES 16384 #define SV_CATUTF8 32768 /* The core is safe for this COW optimisation. XS code on CPAN may not be. So only default to doing the COW setup if we're in the core. */ #ifdef PERL_CORE # ifndef SV_DO_COW_SVSETSV # define SV_DO_COW_SVSETSV SV_COW_SHARED_HASH_KEYS|SV_COW_OTHER_PVS # endif #endif #ifndef SV_DO_COW_SVSETSV # define SV_DO_COW_SVSETSV 0 #endif #define sv_unref(sv) sv_unref_flags(sv, 0) #define sv_force_normal(sv) sv_force_normal_flags(sv, 0) #define sv_usepvn(sv, p, l) sv_usepvn_flags(sv, p, l, 0) #define sv_usepvn_mg(sv, p, l) sv_usepvn_flags(sv, p, l, SV_SMAGIC) /* We are about to replace the SV's current value. So if it's copy on write we need to normalise it. Use the SV_COW_DROP_PV flag hint to say that the value is about to get thrown away, so drop the PV rather than go to the effort of making a read-write copy only for it to get immediately discarded. */ #define SV_CHECK_THINKFIRST_COW_DROP(sv) if (SvTHINKFIRST(sv)) \ sv_force_normal_flags(sv, SV_COW_DROP_PV) #ifdef PERL_COPY_ON_WRITE # define SvCANCOW(sv) \ (SvIsCOW(sv) \ ? SvLEN(sv) ? CowREFCNT(sv) != SV_COW_REFCNT_MAX : 1 \ : (SvFLAGS(sv) & CAN_COW_MASK) == CAN_COW_FLAGS \ && SvCUR(sv)+1 < SvLEN(sv)) /* Note: To allow 256 COW "copies", a refcnt of 0 means 1. */ # define CowREFCNT(sv) (*(U8 *)(SvPVX(sv)+SvLEN(sv)-1)) # define SV_COW_REFCNT_MAX ((1 << sizeof(U8)*8) - 1) # define CAN_COW_MASK (SVf_POK|SVf_ROK|SVp_POK|SVf_FAKE| \ SVf_OOK|SVf_BREAK|SVf_READONLY|SVf_PROTECT) #endif #define CAN_COW_FLAGS (SVp_POK|SVf_POK) #define SV_CHECK_THINKFIRST(sv) if (SvTHINKFIRST(sv)) \ sv_force_normal_flags(sv, 0) /* all these 'functions' are now just macros */ #define sv_pv(sv) SvPV_nolen(sv) #define sv_pvutf8(sv) SvPVutf8_nolen(sv) #define sv_pvbyte(sv) SvPVbyte_nolen(sv) #define sv_pvn_force_nomg(sv, lp) sv_pvn_force_flags(sv, lp, 0) #define sv_utf8_upgrade_flags(sv, flags) sv_utf8_upgrade_flags_grow(sv, flags, 0) #define sv_utf8_upgrade_nomg(sv) sv_utf8_upgrade_flags(sv, 0) #define sv_catpvn_nomg(dsv, sstr, slen) sv_catpvn_flags(dsv, sstr, slen, 0) #define sv_catpv_nomg(dsv, sstr) sv_catpv_flags(dsv, sstr, 0) #define sv_setsv(dsv, ssv) \ sv_setsv_flags(dsv, ssv, SV_GMAGIC|SV_DO_COW_SVSETSV) #define sv_setsv_nomg(dsv, ssv) sv_setsv_flags(dsv, ssv, SV_DO_COW_SVSETSV) #define sv_catsv(dsv, ssv) sv_catsv_flags(dsv, ssv, SV_GMAGIC) #define sv_catsv_nomg(dsv, ssv) sv_catsv_flags(dsv, ssv, 0) #define sv_catsv_mg(dsv, ssv) sv_catsv_flags(dsv, ssv, SV_GMAGIC|SV_SMAGIC) #define sv_catpvn(dsv, sstr, slen) sv_catpvn_flags(dsv, sstr, slen, SV_GMAGIC) #define sv_catpvn_mg(sv, sstr, slen) sv_catpvn_flags(sv, sstr, slen, SV_GMAGIC|SV_SMAGIC); #define sv_copypv(dsv, ssv) sv_copypv_flags(dsv, ssv, SV_GMAGIC) #define sv_copypv_nomg(dsv, ssv) sv_copypv_flags(dsv, ssv, 0) #define sv_2pv(sv, lp) sv_2pv_flags(sv, lp, SV_GMAGIC) #define sv_2pv_nolen(sv) sv_2pv(sv, 0) #define sv_2pvbyte_nolen(sv) sv_2pvbyte(sv, 0) #define sv_2pvutf8_nolen(sv) sv_2pvutf8(sv, 0) #define sv_2pv_nomg(sv, lp) sv_2pv_flags(sv, lp, 0) #define sv_pvn_force(sv, lp) sv_pvn_force_flags(sv, lp, SV_GMAGIC) #define sv_utf8_upgrade(sv) sv_utf8_upgrade_flags(sv, SV_GMAGIC) #define sv_2iv(sv) sv_2iv_flags(sv, SV_GMAGIC) #define sv_2uv(sv) sv_2uv_flags(sv, SV_GMAGIC) #define sv_2nv(sv) sv_2nv_flags(sv, SV_GMAGIC) #define sv_eq(sv1, sv2) sv_eq_flags(sv1, sv2, SV_GMAGIC) #define sv_cmp(sv1, sv2) sv_cmp_flags(sv1, sv2, SV_GMAGIC) #define sv_cmp_locale(sv1, sv2) sv_cmp_locale_flags(sv1, sv2, SV_GMAGIC) #define sv_collxfrm(sv, nxp) sv_cmp_flags(sv, nxp, SV_GMAGIC) #define sv_2bool(sv) sv_2bool_flags(sv, SV_GMAGIC) #define sv_2bool_nomg(sv) sv_2bool_flags(sv, 0) #define sv_insert(bigstr, offset, len, little, littlelen) \ Perl_sv_insert_flags(aTHX_ (bigstr),(offset), (len), (little), \ (littlelen), SV_GMAGIC) #define sv_mortalcopy(sv) \ Perl_sv_mortalcopy_flags(aTHX_ sv, SV_GMAGIC|SV_DO_COW_SVSETSV) #define sv_cathek(sv,hek) \ STMT_START { \ HEK * const bmxk = hek; \ sv_catpvn_flags(sv, HEK_KEY(bmxk), HEK_LEN(bmxk), \ HEK_UTF8(bmxk) ? SV_CATUTF8 : SV_CATBYTES); \ } STMT_END /* Should be named SvCatPVN_utf8_upgrade? */ #define sv_catpvn_nomg_utf8_upgrade(dsv, sstr, slen, nsv) \ STMT_START { \ if (!(nsv)) \ nsv = newSVpvn_flags(sstr, slen, SVs_TEMP); \ else \ sv_setpvn(nsv, sstr, slen); \ SvUTF8_off(nsv); \ sv_utf8_upgrade(nsv); \ sv_catsv_nomg(dsv, nsv); \ } STMT_END #define sv_catpvn_nomg_maybeutf8(dsv, sstr, slen, is_utf8) \ sv_catpvn_flags(dsv, sstr, slen, (is_utf8)?SV_CATUTF8:SV_CATBYTES) #if defined(PERL_CORE) || defined(PERL_EXT) # define sv_or_pv_len_utf8(sv, pv, bytelen) \ (SvGAMAGIC(sv) \ ? utf8_length((U8 *)(pv), (U8 *)(pv)+(bytelen)) \ : sv_len_utf8(sv)) #endif /* =for apidoc Am|SV*|newRV_inc|SV* sv Creates an RV wrapper for an SV. The reference count for the original SV is incremented. =cut */ #define newRV_inc(sv) newRV(sv) /* the following macros update any magic values this C<sv> is associated with */ /* =head1 Magical Functions =for apidoc Am|void|SvGETMAGIC|SV* sv Invokes C<mg_get> on an SV if it has 'get' magic. For example, this will call C<FETCH> on a tied variable. This macro evaluates its argument more than once. =for apidoc Am|void|SvSETMAGIC|SV* sv Invokes C<mg_set> on an SV if it has 'set' magic. This is necessary after modifying a scalar, in case it is a magical variable like C<$|> or a tied variable (it calls C<STORE>). This macro evaluates its argument more than once. =for apidoc Am|void|SvSetSV|SV* dsv|SV* ssv Calls C<sv_setsv> if C<dsv> is not the same as C<ssv>. May evaluate arguments more than once. Does not handle 'set' magic on the destination SV. =for apidoc Am|void|SvSetSV_nosteal|SV* dsv|SV* ssv Calls a non-destructive version of C<sv_setsv> if C<dsv> is not the same as C<ssv>. May evaluate arguments more than once. =for apidoc Am|void|SvSetMagicSV|SV* dsv|SV* ssv Like C<SvSetSV>, but does any set magic required afterwards. =for apidoc Am|void|SvSetMagicSV_nosteal|SV* dsv|SV* ssv Like C<SvSetSV_nosteal>, but does any set magic required afterwards. =for apidoc Am|void|SvSHARE|SV* sv Arranges for C<sv> to be shared between threads if a suitable module has been loaded. =for apidoc Am|void|SvLOCK|SV* sv Arranges for a mutual exclusion lock to be obtained on C<sv> if a suitable module has been loaded. =for apidoc Am|void|SvUNLOCK|SV* sv Releases a mutual exclusion lock on C<sv> if a suitable module has been loaded. =head1 SV Manipulation Functions =for apidoc Am|char *|SvGROW|SV* sv|STRLEN len Expands the character buffer in the SV so that it has room for the indicated number of bytes (remember to reserve space for an extra trailing C<NUL> character). Calls C<sv_grow> to perform the expansion if necessary. Returns a pointer to the character buffer. SV must be of type >= C<SVt_PV>. One alternative is to call C<sv_grow> if you are not sure of the type of SV. You might mistakenly think that C<len> is the number of bytes to add to the existing size, but instead it is the total size C<sv> should be. =for apidoc Am|char *|SvPVCLEAR|SV* sv Ensures that sv is a SVt_PV and that its SvCUR is 0, and that it is properly null terminated. Equivalent to sv_setpvs(""), but more efficient. =cut */ #define SvPVCLEAR(sv) sv_setpv_bufsize(sv,0,0) #define SvSHARE(sv) PL_sharehook(aTHX_ sv) #define SvLOCK(sv) PL_lockhook(aTHX_ sv) #define SvUNLOCK(sv) PL_unlockhook(aTHX_ sv) #define SvDESTROYABLE(sv) PL_destroyhook(aTHX_ sv) #define SvGETMAGIC(x) ((void)(UNLIKELY(SvGMAGICAL(x)) && mg_get(x))) #define SvSETMAGIC(x) STMT_START { if (UNLIKELY(SvSMAGICAL(x))) mg_set(x); } STMT_END #define SvSetSV_and(dst,src,finally) \ STMT_START { \ if (LIKELY((dst) != (src))) { \ sv_setsv(dst, src); \ finally; \ } \ } STMT_END #define SvSetSV_nosteal_and(dst,src,finally) \ STMT_START { \ if (LIKELY((dst) != (src))) { \ sv_setsv_flags(dst, src, SV_GMAGIC | SV_NOSTEAL | SV_DO_COW_SVSETSV); \ finally; \ } \ } STMT_END #define SvSetSV(dst,src) \ SvSetSV_and(dst,src,/*nothing*/;) #define SvSetSV_nosteal(dst,src) \ SvSetSV_nosteal_and(dst,src,/*nothing*/;) #define SvSetMagicSV(dst,src) \ SvSetSV_and(dst,src,SvSETMAGIC(dst)) #define SvSetMagicSV_nosteal(dst,src) \ SvSetSV_nosteal_and(dst,src,SvSETMAGIC(dst)) #if !defined(SKIP_DEBUGGING) #define SvPEEK(sv) sv_peek(sv) #else #define SvPEEK(sv) "" #endif #define SvIMMORTAL(sv) (SvREADONLY(sv) && ((sv)==&PL_sv_undef || (sv)==&PL_sv_yes || (sv)==&PL_sv_no || (sv)==&PL_sv_placeholder)) #ifdef DEBUGGING /* exercise the immortal resurrection code in sv_free2() */ # define SvREFCNT_IMMORTAL 1000 #else # define SvREFCNT_IMMORTAL ((~(U32)0)/2) #endif /* =for apidoc Am|SV *|boolSV|bool b Returns a true SV if C<b> is a true value, or a false SV if C<b> is 0. See also C<L</PL_sv_yes>> and C<L</PL_sv_no>>. =cut */ #define boolSV(b) ((b) ? &PL_sv_yes : &PL_sv_no) #define isGV(sv) (SvTYPE(sv) == SVt_PVGV) /* If I give every macro argument a different name, then there won't be bugs where nested macros get confused. Been there, done that. */ #define isGV_with_GP(pwadak) \ (((SvFLAGS(pwadak) & (SVp_POK|SVpgv_GP)) == SVpgv_GP) \ && (SvTYPE(pwadak) == SVt_PVGV || SvTYPE(pwadak) == SVt_PVLV)) #define isGV_with_GP_on(sv) STMT_START { \ assert (SvTYPE(sv) == SVt_PVGV || SvTYPE(sv) == SVt_PVLV); \ assert (!SvPOKp(sv)); \ assert (!SvIOKp(sv)); \ (SvFLAGS(sv) |= SVpgv_GP); \ } STMT_END #define isGV_with_GP_off(sv) STMT_START { \ assert (SvTYPE(sv) == SVt_PVGV || SvTYPE(sv) == SVt_PVLV); \ assert (!SvPOKp(sv)); \ assert (!SvIOKp(sv)); \ (SvFLAGS(sv) &= ~SVpgv_GP); \ } STMT_END #define isREGEXP(sv) \ (SvTYPE(sv) == SVt_REGEXP \ || (SvFLAGS(sv) & (SVTYPEMASK|SVp_POK|SVpgv_GP|SVf_FAKE)) \ == (SVt_PVLV|SVf_FAKE)) #ifdef PERL_ANY_COW # define SvGROW(sv,len) \ (SvIsCOW(sv) || SvLEN(sv) < (len) ? sv_grow(sv,len) : SvPVX(sv)) #else # define SvGROW(sv,len) (SvLEN(sv) < (len) ? sv_grow(sv,len) : SvPVX(sv)) #endif #define SvGROW_mutable(sv,len) \ (SvLEN(sv) < (len) ? sv_grow(sv,len) : SvPVX_mutable(sv)) #define Sv_Grow sv_grow #define CLONEf_COPY_STACKS 1 #define CLONEf_KEEP_PTR_TABLE 2 #define CLONEf_CLONE_HOST 4 #define CLONEf_JOIN_IN 8 struct clone_params { AV* stashes; UV flags; PerlInterpreter *proto_perl; PerlInterpreter *new_perl; AV *unreferenced; }; /* =for apidoc Am|SV*|newSVpvn_utf8|NULLOK const char* s|STRLEN len|U32 utf8 Creates a new SV and copies a string (which may contain C<NUL> (C<\0>) characters) into it. If C<utf8> is true, calls C<SvUTF8_on> on the new SV. Implemented as a wrapper around C<newSVpvn_flags>. =cut */ #define newSVpvn_utf8(s, len, u) newSVpvn_flags((s), (len), (u) ? SVf_UTF8 : 0) /* =for apidoc Amx|SV*|newSVpadname|PADNAME *pn Creates a new SV containing the pad name. =cut */ #define newSVpadname(pn) newSVpvn_utf8(PadnamePV(pn), PadnameLEN(pn), TRUE) /* =for apidoc Am|void|SvOOK_offset|NN SV*sv|STRLEN len Reads into C<len> the offset from C<SvPVX> back to the true start of the allocated buffer, which will be non-zero if C<sv_chop> has been used to efficiently remove characters from start of the buffer. Implemented as a macro, which takes the address of C<len>, which must be of type C<STRLEN>. Evaluates C<sv> more than once. Sets C<len> to 0 if C<SvOOK(sv)> is false. =cut */ #ifdef DEBUGGING /* Does the bot know something I don't? 10:28 <@Nicholas> metabatman 10:28 <+meta> Nicholas: crash */ # define SvOOK_offset(sv, offset) STMT_START { \ assert(sizeof(offset) == sizeof(STRLEN)); \ if (SvOOK(sv)) { \ const U8 *_crash = (U8*)SvPVX_const(sv); \ (offset) = *--_crash; \ if (!(offset)) { \ _crash -= sizeof(STRLEN); \ Copy(_crash, (U8 *)&(offset), sizeof(STRLEN), U8); \ } \ { \ /* Validate the preceding buffer's sentinels to \ verify that no-one is using it. */ \ const U8 *const _bonk = (U8*)SvPVX_const(sv) - (offset);\ while (_crash > _bonk) { \ --_crash; \ assert (*_crash == (U8)PTR2UV(_crash)); \ } \ } \ } else { \ (offset) = 0; \ } \ } STMT_END #else /* This is the same code, but avoids using any temporary variables: */ # define SvOOK_offset(sv, offset) STMT_START { \ assert(sizeof(offset) == sizeof(STRLEN)); \ if (SvOOK(sv)) { \ (offset) = ((U8*)SvPVX_const(sv))[-1]; \ if (!(offset)) { \ Copy(SvPVX_const(sv) - 1 - sizeof(STRLEN), \ (U8*)&(offset), sizeof(STRLEN), U8); \ } \ } else { \ (offset) = 0; \ } \ } STMT_END #endif #define newIO() MUTABLE_IO(newSV_type(SVt_PVIO)) #define SV_CONST(name) \ PL_sv_consts[SV_CONST_##name] \ ? PL_sv_consts[SV_CONST_##name] \ : (PL_sv_consts[SV_CONST_##name] = newSVpv_share(#name, 0)) #define SV_CONST_TIESCALAR 0 #define SV_CONST_TIEARRAY 1 #define SV_CONST_TIEHASH 2 #define SV_CONST_TIEHANDLE 3 #define SV_CONST_FETCH 4 #define SV_CONST_FETCHSIZE 5 #define SV_CONST_STORE 6 #define SV_CONST_STORESIZE 7 #define SV_CONST_EXISTS 8 #define SV_CONST_PUSH 9 #define SV_CONST_POP 10 #define SV_CONST_SHIFT 11 #define SV_CONST_UNSHIFT 12 #define SV_CONST_SPLICE 13 #define SV_CONST_EXTEND 14 #define SV_CONST_FIRSTKEY 15 #define SV_CONST_NEXTKEY 16 #define SV_CONST_SCALAR 17 #define SV_CONST_OPEN 18 #define SV_CONST_WRITE 19 #define SV_CONST_PRINT 20 #define SV_CONST_PRINTF 21 #define SV_CONST_READ 22 #define SV_CONST_READLINE 23 #define SV_CONST_GETC 24 #define SV_CONST_SEEK 25 #define SV_CONST_TELL 26 #define SV_CONST_EOF 27 #define SV_CONST_BINMODE 28 #define SV_CONST_FILENO 29 #define SV_CONST_CLOSE 30 #define SV_CONST_DELETE 31 #define SV_CONST_CLEAR 32 #define SV_CONST_UNTIE 33 #define SV_CONST_DESTROY 34 #define SV_CONSTS_COUNT 35 /* * Bodyless IVs and NVs! * * Since 5.9.2, we can avoid allocating a body for SVt_IV-type SVs. * Since the larger IV-holding variants of SVs store their integer * values in their respective bodies, the family of SvIV() accessor * macros would naively have to branch on the SV type to find the * integer value either in the HEAD or BODY. In order to avoid this * expensive branch, a clever soul has deployed a great hack: * We set up the SvANY pointer such that instead of pointing to a * real body, it points into the memory before the location of the * head. We compute this pointer such that the location of * the integer member of the hypothetical body struct happens to * be the same as the location of the integer member of the bodyless * SV head. This now means that the SvIV() family of accessors can * always read from the (hypothetical or real) body via SvANY. * * Since the 5.21 dev series, we employ the same trick for NVs * if the architecture can support it (NVSIZE <= IVSIZE). */ /* The following two macros compute the necessary offsets for the above * trick and store them in SvANY for SvIV() (and friends) to use. */ #ifdef PERL_CORE # define SET_SVANY_FOR_BODYLESS_IV(sv) \ SvANY(sv) = (XPVIV*)((char*)&(sv->sv_u.svu_iv) \ - STRUCT_OFFSET(XPVIV, xiv_iv)) # define SET_SVANY_FOR_BODYLESS_NV(sv) \ SvANY(sv) = (XPVNV*)((char*)&(sv->sv_u.svu_nv) \ - STRUCT_OFFSET(XPVNV, xnv_u.xnv_nv)) #endif /* * ex: set ts=8 sts=4 sw=4 et: */