NAME

perlguts - Perl's Internal Functions

DESCRIPTION

This document attempts to describe some of the internal functions of the Perl executable. It is far from complete and probably contains many errors. Please refer any questions or comments to the author below.

Variables

Datatypes

Perl has three typedefs that handle Perl's three main data types:

SV  Scalar Value
AV  Array Value
HV  Hash Value

Each typedef has specific routines that manipulate the various data types.

What is an "IV"?

Perl uses a special typedef IV which is a simple integer type that is guaranteed to be large enough to hold a pointer (as well as an integer).

Perl also uses two special typedefs, I32 and I16, which will always be at least 32-bits and 16-bits long, respectively.

Working with SVs

An SV can be created and loaded with one command. There are four types of values that can be loaded: an integer value (IV), a double (NV), a string, (PV), and another scalar (SV).

The five routines are:

SV*  newSViv(IV);
SV*  newSVnv(double);
SV*  newSVpv(char*, int);
SV*  newSVpvf(const char*, ...);
SV*  newSVsv(SV*);

To change the value of an *already-existing* SV, there are six routines:

void  sv_setiv(SV*, IV);
void  sv_setnv(SV*, double);
void  sv_setpv(SV*, char*);
void  sv_setpvn(SV*, char*, int)
void  sv_setpvf(SV*, const char*, ...);
void  sv_setsv(SV*, SV*);

Notice that you can choose to specify the length of the string to be assigned by using sv_setpvn or newSVpv, or you may allow Perl to calculate the length by using sv_setpv or by specifying 0 as the second argument to newSVpv. Be warned, though, that Perl will determine the string's length by using strlen, which depends on the string terminating with a NUL character. The arguments of sv_setpvf are processed like sprintf, and the formatted output becomes the value.

All SVs that will contain strings should, but need not, be terminated with a NUL character. If it is not NUL-terminated there is a risk of core dumps and corruptions from code which passes the string to C functions or system calls which expect a NUL-terminated string. Perl's own functions typically add a trailing NUL for this reason. Nevertheless, you should be very careful when you pass a string stored in an SV to a C function or system call.

To access the actual value that an SV points to, you can use the macros:

SvIV(SV*)
SvNV(SV*)
SvPV(SV*, STRLEN len)

which will automatically coerce the actual scalar type into an IV, double, or string.

In the SvPV macro, the length of the string returned is placed into the variable len (this is a macro, so you do not use &len). If you do not care what the length of the data is, use the global variable na. Remember, however, that Perl allows arbitrary strings of data that may both contain NULs and might not be terminated by a NUL.

If you want to know if the scalar value is TRUE, you can use:

SvTRUE(SV*)

Although Perl will automatically grow strings for you, if you need to force Perl to allocate more memory for your SV, you can use the macro

SvGROW(SV*, STRLEN newlen)

which will determine if more memory needs to be allocated. If so, it will call the function sv_grow. Note that SvGROW can only increase, not decrease, the allocated memory of an SV and that it does not automatically add a byte for the a trailing NUL (perl's own string functions typically do SvGROW(sv, len + 1)).

If you have an SV and want to know what kind of data Perl thinks is stored in it, you can use the following macros to check the type of SV you have.

SvIOK(SV*)
SvNOK(SV*)
SvPOK(SV*)

You can get and set the current length of the string stored in an SV with the following macros:

SvCUR(SV*)
SvCUR_set(SV*, I32 val)

You can also get a pointer to the end of the string stored in the SV with the macro:

SvEND(SV*)

But note that these last three macros are valid only if SvPOK() is true.

If you want to append something to the end of string stored in an SV*, you can use the following functions:

void  sv_catpv(SV*, char*);
void  sv_catpvn(SV*, char*, int);
void  sv_catpvf(SV*, const char*, ...);
void  sv_catsv(SV*, SV*);

The first function calculates the length of the string to be appended by using strlen. In the second, you specify the length of the string yourself. The third function processes its arguments like sprintf and appends the formatted output. The fourth function extends the string stored in the first SV with the string stored in the second SV. It also forces the second SV to be interpreted as a string.

If you know the name of a scalar variable, you can get a pointer to its SV by using the following:

SV*  perl_get_sv("package::varname", FALSE);

This returns NULL if the variable does not exist.

If you want to know if this variable (or any other SV) is actually defined, you can call:

SvOK(SV*)

The scalar undef value is stored in an SV instance called sv_undef. Its address can be used whenever an SV* is needed.

There are also the two values sv_yes and sv_no, which contain Boolean TRUE and FALSE values, respectively. Like sv_undef, their addresses can be used whenever an SV* is needed.

Do not be fooled into thinking that (SV *) 0 is the same as &sv_undef. Take this code:

SV* sv = (SV*) 0;
if (I-am-to-return-a-real-value) {
        sv = sv_2mortal(newSViv(42));
}
sv_setsv(ST(0), sv);

This code tries to return a new SV (which contains the value 42) if it should return a real value, or undef otherwise. Instead it has returned a NULL pointer which, somewhere down the line, will cause a segmentation violation, bus error, or just weird results. Change the zero to &sv_undef in the first line and all will be well.

To free an SV that you've created, call SvREFCNT_dec(SV*). Normally this call is not necessary (see "Reference Counts and Mortality").

What's Really Stored in an SV?

Recall that the usual method of determining the type of scalar you have is to use Sv*OK macros. Because a scalar can be both a number and a string, usually these macros will always return TRUE and calling the Sv*V macros will do the appropriate conversion of string to integer/double or integer/double to string.

If you really need to know if you have an integer, double, or string pointer in an SV, you can use the following three macros instead:

SvIOKp(SV*)
SvNOKp(SV*)
SvPOKp(SV*)

These will tell you if you truly have an integer, double, or string pointer stored in your SV. The "p" stands for private.

In general, though, it's best to use the Sv*V macros.

Working with AVs

There are two ways to create and load an AV. The first method creates an empty AV:

AV*  newAV();

The second method both creates the AV and initially populates it with SVs:

AV*  av_make(I32 num, SV **ptr);

The second argument points to an array containing num SV*'s. Once the AV has been created, the SVs can be destroyed, if so desired.

Once the AV has been created, the following operations are possible on AVs:

void  av_push(AV*, SV*);
SV*   av_pop(AV*);
SV*   av_shift(AV*);
void  av_unshift(AV*, I32 num);

These should be familiar operations, with the exception of av_unshift. This routine adds num elements at the front of the array with the undef value. You must then use av_store (described below) to assign values to these new elements.

Here are some other functions:

I32   av_len(AV*);
SV**  av_fetch(AV*, I32 key, I32 lval);
SV**  av_store(AV*, I32 key, SV* val);

The av_len function returns the highest index value in array (just like $#array in Perl). If the array is empty, -1 is returned. The av_fetch function returns the value at index key, but if lval is non-zero, then av_fetch will store an undef value at that index. The av_store function stores the value val at index key, and does not increment the reference count of val. Thus the caller is responsible for taking care of that, and if av_store returns NULL, the caller will have to decrement the reference count to avoid a memory leak. Note that av_fetch and av_store both return SV**'s, not SV*'s as their return value.

void  av_clear(AV*);
void  av_undef(AV*);
void  av_extend(AV*, I32 key);

The av_clear function deletes all the elements in the AV* array, but does not actually delete the array itself. The av_undef function will delete all the elements in the array plus the array itself. The av_extend function extends the array so that it contains key elements. If key is less than the current length of the array, then nothing is done.

If you know the name of an array variable, you can get a pointer to its AV by using the following:

AV*  perl_get_av("package::varname", FALSE);

This returns NULL if the variable does not exist.

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use the array access functions on tied arrays.

Working with HVs

To create an HV, you use the following routine:

HV*  newHV();

Once the HV has been created, the following operations are possible on HVs:

SV**  hv_store(HV*, char* key, U32 klen, SV* val, U32 hash);
SV**  hv_fetch(HV*, char* key, U32 klen, I32 lval);

The klen parameter is the length of the key being passed in (Note that you cannot pass 0 in as a value of klen to tell Perl to measure the length of the key). The val argument contains the SV pointer to the scalar being stored, and hash is the precomputed hash value (zero if you want hv_store to calculate it for you). The lval parameter indicates whether this fetch is actually a part of a store operation, in which case a new undefined value will be added to the HV with the supplied key and hv_fetch will return as if the value had already existed.

Remember that hv_store and hv_fetch return SV**'s and not just SV*. To access the scalar value, you must first dereference the return value. However, you should check to make sure that the return value is not NULL before dereferencing it.

These two functions check if a hash table entry exists, and deletes it.

bool  hv_exists(HV*, char* key, U32 klen);
SV*   hv_delete(HV*, char* key, U32 klen, I32 flags);

If flags does not include the G_DISCARD flag then hv_delete will create and return a mortal copy of the deleted value.

And more miscellaneous functions:

void   hv_clear(HV*);
void   hv_undef(HV*);

Like their AV counterparts, hv_clear deletes all the entries in the hash table but does not actually delete the hash table. The hv_undef deletes both the entries and the hash table itself.

Perl keeps the actual data in linked list of structures with a typedef of HE. These contain the actual key and value pointers (plus extra administrative overhead). The key is a string pointer; the value is an SV*. However, once you have an HE*, to get the actual key and value, use the routines specified below.

    I32    hv_iterinit(HV*);
            /* Prepares starting point to traverse hash table */
    HE*    hv_iternext(HV*);
            /* Get the next entry, and return a pointer to a
               structure that has both the key and value */
    char*  hv_iterkey(HE* entry, I32* retlen);
            /* Get the key from an HE structure and also return
               the length of the key string */
    SV*    hv_iterval(HV*, HE* entry);
            /* Return a SV pointer to the value of the HE
               structure */
    SV*    hv_iternextsv(HV*, char** key, I32* retlen);
            /* This convenience routine combines hv_iternext,
	       hv_iterkey, and hv_iterval.  The key and retlen
	       arguments are return values for the key and its
	       length.  The value is returned in the SV* argument */

If you know the name of a hash variable, you can get a pointer to its HV by using the following:

HV*  perl_get_hv("package::varname", FALSE);

This returns NULL if the variable does not exist.

The hash algorithm is defined in the PERL_HASH(hash, key, klen) macro:

    i = klen;
    hash = 0;
    s = key;
    while (i--)
	hash = hash * 33 + *s++;

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use the hash access functions on tied hashes.

Hash API Extensions

Beginning with version 5.004, the following functions are also supported:

HE*     hv_fetch_ent  (HV* tb, SV* key, I32 lval, U32 hash);
HE*     hv_store_ent  (HV* tb, SV* key, SV* val, U32 hash);

bool    hv_exists_ent (HV* tb, SV* key, U32 hash);
SV*     hv_delete_ent (HV* tb, SV* key, I32 flags, U32 hash);

SV*     hv_iterkeysv  (HE* entry);

Note that these functions take SV* keys, which simplifies writing of extension code that deals with hash structures. These functions also allow passing of SV* keys to tie functions without forcing you to stringify the keys (unlike the previous set of functions).

They also return and accept whole hash entries (HE*), making their use more efficient (since the hash number for a particular string doesn't have to be recomputed every time). See "API LISTING" later in this document for detailed descriptions.

The following macros must always be used to access the contents of hash entries. Note that the arguments to these macros must be simple variables, since they may get evaluated more than once. See "API LISTING" later in this document for detailed descriptions of these macros.

HePV(HE* he, STRLEN len)
HeVAL(HE* he)
HeHASH(HE* he)
HeSVKEY(HE* he)
HeSVKEY_force(HE* he)
HeSVKEY_set(HE* he, SV* sv)

These two lower level macros are defined, but must only be used when dealing with keys that are not SV*s:

HeKEY(HE* he)
HeKLEN(HE* he)

Note that both hv_store and hv_store_ent do not increment the reference count of the stored val, which is the caller's responsibility. If these functions return a NULL value, the caller will usually have to decrement the reference count of val to avoid a memory leak.

References

References are a special type of scalar that point to other data types (including references).

To create a reference, use either of the following functions:

SV* newRV_inc((SV*) thing);
SV* newRV_noinc((SV*) thing);

The thing argument can be any of an SV*, AV*, or HV*. The functions are identical except that newRV_inc increments the reference count of the thing, while newRV_noinc does not. For historical reasons, newRV is a synonym for newRV_inc.

Once you have a reference, you can use the following macro to dereference the reference:

SvRV(SV*)

then call the appropriate routines, casting the returned SV* to either an AV* or HV*, if required.

To determine if an SV is a reference, you can use the following macro:

SvROK(SV*)

To discover what type of value the reference refers to, use the following macro and then check the return value.

SvTYPE(SvRV(SV*))

The most useful types that will be returned are:

SVt_IV    Scalar
SVt_NV    Scalar
SVt_PV    Scalar
SVt_RV    Scalar
SVt_PVAV  Array
SVt_PVHV  Hash
SVt_PVCV  Code
SVt_PVGV  Glob (possible a file handle)
SVt_PVMG  Blessed or Magical Scalar

See the sv.h header file for more details.

Blessed References and Class Objects

References are also used to support object-oriented programming. In the OO lexicon, an object is simply a reference that has been blessed into a package (or class). Once blessed, the programmer may now use the reference to access the various methods in the class.

A reference can be blessed into a package with the following function:

SV* sv_bless(SV* sv, HV* stash);

The sv argument must be a reference. The stash argument specifies which class the reference will belong to. See "Stashes and Globs" for information on converting class names into stashes.

/* Still under construction */

Upgrades rv to reference if not already one. Creates new SV for rv to point to. If classname is non-null, the SV is blessed into the specified class. SV is returned.

SV* newSVrv(SV* rv, char* classname);

Copies integer or double into an SV whose reference is rv. SV is blessed if classname is non-null.

SV* sv_setref_iv(SV* rv, char* classname, IV iv);
SV* sv_setref_nv(SV* rv, char* classname, NV iv);

Copies the pointer value (the address, not the string!) into an SV whose reference is rv. SV is blessed if classname is non-null.

SV* sv_setref_pv(SV* rv, char* classname, PV iv);

Copies string into an SV whose reference is rv. Set length to 0 to let Perl calculate the string length. SV is blessed if classname is non-null.

SV* sv_setref_pvn(SV* rv, char* classname, PV iv, int length);

int sv_isa(SV* sv, char* name);
int sv_isobject(SV* sv);

Creating New Variables

To create a new Perl variable with an undef value which can be accessed from your Perl script, use the following routines, depending on the variable type.

SV*  perl_get_sv("package::varname", TRUE);
AV*  perl_get_av("package::varname", TRUE);
HV*  perl_get_hv("package::varname", TRUE);

Notice the use of TRUE as the second parameter. The new variable can now be set, using the routines appropriate to the data type.

There are additional macros whose values may be bitwise OR'ed with the TRUE argument to enable certain extra features. Those bits are:

    GV_ADDMULTI	Marks the variable as multiply defined, thus preventing the
		"Name <varname> used only once: possible typo" warning.
    GV_ADDWARN	Issues the warning "Had to create <varname> unexpectedly" if
		the variable did not exist before the function was called.

If you do not specify a package name, the variable is created in the current package.

Reference Counts and Mortality

Perl uses an reference count-driven garbage collection mechanism. SVs, AVs, or HVs (xV for short in the following) start their life with a reference count of 1. If the reference count of an xV ever drops to 0, then it will be destroyed and its memory made available for reuse.

This normally doesn't happen at the Perl level unless a variable is undef'ed or the last variable holding a reference to it is changed or overwritten. At the internal level, however, reference counts can be manipulated with the following macros:

int SvREFCNT(SV* sv);
SV* SvREFCNT_inc(SV* sv);
void SvREFCNT_dec(SV* sv);

However, there is one other function which manipulates the reference count of its argument. The newRV_inc function, you will recall, creates a reference to the specified argument. As a side effect, it increments the argument's reference count. If this is not what you want, use newRV_noinc instead.

For example, imagine you want to return a reference from an XSUB function. Inside the XSUB routine, you create an SV which initially has a reference count of one. Then you call newRV_inc, passing it the just-created SV. This returns the reference as a new SV, but the reference count of the SV you passed to newRV_inc has been incremented to two. Now you return the reference from the XSUB routine and forget about the SV. But Perl hasn't! Whenever the returned reference is destroyed, the reference count of the original SV is decreased to one and nothing happens. The SV will hang around without any way to access it until Perl itself terminates. This is a memory leak.

The correct procedure, then, is to use newRV_noinc instead of newRV_inc. Then, if and when the last reference is destroyed, the reference count of the SV will go to zero and it will be destroyed, stopping any memory leak.

There are some convenience functions available that can help with the destruction of xVs. These functions introduce the concept of "mortality". An xV that is mortal has had its reference count marked to be decremented, but not actually decremented, until "a short time later". Generally the term "short time later" means a single Perl statement, such as a call to an XSUB function. The actual determinant for when mortal xVs have their reference count decremented depends on two macros, SAVETMPS and FREETMPS. See perlcall and perlxs for more details on these macros.

"Mortalization" then is at its simplest a deferred SvREFCNT_dec. However, if you mortalize a variable twice, the reference count will later be decremented twice.

You should be careful about creating mortal variables. Strange things can happen if you make the same value mortal within multiple contexts, or if you make a variable mortal multiple times.

To create a mortal variable, use the functions:

SV*  sv_newmortal()
SV*  sv_2mortal(SV*)
SV*  sv_mortalcopy(SV*)

The first call creates a mortal SV, the second converts an existing SV to a mortal SV (and thus defers a call to SvREFCNT_dec), and the third creates a mortal copy of an existing SV.

The mortal routines are not just for SVs -- AVs and HVs can be made mortal by passing their address (type-casted to SV*) to the sv_2mortal or sv_mortalcopy routines.

Stashes and Globs

A "stash" is a hash that contains all of the different objects that are contained within a package. Each key of the stash is a symbol name (shared by all the different types of objects that have the same name), and each value in the hash table is a GV (Glob Value). This GV in turn contains references to the various objects of that name, including (but not limited to) the following:

Scalar Value
Array Value
Hash Value
File Handle
Directory Handle
Format
Subroutine

There is a single stash called "defstash" that holds the items that exist in the "main" package. To get at the items in other packages, append the string "::" to the package name. The items in the "Foo" package are in the stash "Foo::" in defstash. The items in the "Bar::Baz" package are in the stash "Baz::" in "Bar::"'s stash.

To get the stash pointer for a particular package, use the function:

HV*  gv_stashpv(char* name, I32 create)
HV*  gv_stashsv(SV*, I32 create)

The first function takes a literal string, the second uses the string stored in the SV. Remember that a stash is just a hash table, so you get back an HV*. The create flag will create a new package if it is set.

The name that gv_stash*v wants is the name of the package whose symbol table you want. The default package is called main. If you have multiply nested packages, pass their names to gv_stash*v, separated by :: as in the Perl language itself.

Alternately, if you have an SV that is a blessed reference, you can find out the stash pointer by using:

HV*  SvSTASH(SvRV(SV*));

then use the following to get the package name itself:

char*  HvNAME(HV* stash);

If you need to bless or re-bless an object you can use the following function:

SV*  sv_bless(SV*, HV* stash)

where the first argument, an SV*, must be a reference, and the second argument is a stash. The returned SV* can now be used in the same way as any other SV.

For more information on references and blessings, consult perlref.

Double-Typed SVs

Scalar variables normally contain only one type of value, an integer, double, pointer, or reference. Perl will automatically convert the actual scalar data from the stored type into the requested type.

Some scalar variables contain more than one type of scalar data. For example, the variable $! contains either the numeric value of errno or its string equivalent from either strerror or sys_errlist[].

To force multiple data values into an SV, you must do two things: use the sv_set*v routines to add the additional scalar type, then set a flag so that Perl will believe it contains more than one type of data. The four macros to set the flags are:

SvIOK_on
SvNOK_on
SvPOK_on
SvROK_on

The particular macro you must use depends on which sv_set*v routine you called first. This is because every sv_set*v routine turns on only the bit for the particular type of data being set, and turns off all the rest.

For example, to create a new Perl variable called "dberror" that contains both the numeric and descriptive string error values, you could use the following code:

extern int  dberror;
extern char *dberror_list;

SV* sv = perl_get_sv("dberror", TRUE);
sv_setiv(sv, (IV) dberror);
sv_setpv(sv, dberror_list[dberror]);
SvIOK_on(sv);

If the order of sv_setiv and sv_setpv had been reversed, then the macro SvPOK_on would need to be called instead of SvIOK_on.

Magic Variables

[This section still under construction. Ignore everything here. Post no bills. Everything not permitted is forbidden.]

Any SV may be magical, that is, it has special features that a normal SV does not have. These features are stored in the SV structure in a linked list of struct magic's, typedef'ed to MAGIC.

struct magic {
    MAGIC*      mg_moremagic;
    MGVTBL*     mg_virtual;
    U16         mg_private;
    char        mg_type;
    U8          mg_flags;
    SV*         mg_obj;
    char*       mg_ptr;
    I32         mg_len;
};

Note this is current as of patchlevel 0, and could change at any time.

Assigning Magic

Perl adds magic to an SV using the sv_magic function:

void sv_magic(SV* sv, SV* obj, int how, char* name, I32 namlen);

The sv argument is a pointer to the SV that is to acquire a new magical feature.

If sv is not already magical, Perl uses the SvUPGRADE macro to set the SVt_PVMG flag for the sv. Perl then continues by adding it to the beginning of the linked list of magical features. Any prior entry of the same type of magic is deleted. Note that this can be overridden, and multiple instances of the same type of magic can be associated with an SV.

The name and namlen arguments are used to associate a string with the magic, typically the name of a variable. namlen is stored in the mg_len field and if name is non-null and namlen >= 0 a malloc'd copy of the name is stored in mg_ptr field.

The sv_magic function uses how to determine which, if any, predefined "Magic Virtual Table" should be assigned to the mg_virtual field. See the "Magic Virtual Table" section below. The how argument is also stored in the mg_type field.

The obj argument is stored in the mg_obj field of the MAGIC structure. If it is not the same as the sv argument, the reference count of the obj object is incremented. If it is the same, or if the how argument is "#", or if it is a NULL pointer, then obj is merely stored, without the reference count being incremented.

There is also a function to add magic to an HV:

void hv_magic(HV *hv, GV *gv, int how);

This simply calls sv_magic and coerces the gv argument into an SV.

To remove the magic from an SV, call the function sv_unmagic:

void sv_unmagic(SV *sv, int type);

The type argument should be equal to the how value when the SV was initially made magical.

Magic Virtual Tables

The mg_virtual field in the MAGIC structure is a pointer to a MGVTBL, which is a structure of function pointers and stands for "Magic Virtual Table" to handle the various operations that might be applied to that variable.

The MGVTBL has five pointers to the following routine types:

int  (*svt_get)(SV* sv, MAGIC* mg);
int  (*svt_set)(SV* sv, MAGIC* mg);
U32  (*svt_len)(SV* sv, MAGIC* mg);
int  (*svt_clear)(SV* sv, MAGIC* mg);
int  (*svt_free)(SV* sv, MAGIC* mg);

This MGVTBL structure is set at compile-time in perl.h and there are currently 19 types (or 21 with overloading turned on). These different structures contain pointers to various routines that perform additional actions depending on which function is being called.

Function pointer    Action taken
----------------    ------------
svt_get             Do something after the value of the SV is retrieved.
svt_set             Do something after the SV is assigned a value.
svt_len             Report on the SV's length.
svt_clear		Clear something the SV represents.
svt_free            Free any extra storage associated with the SV.

For instance, the MGVTBL structure called vtbl_sv (which corresponds to an mg_type of '\0') contains:

{ magic_get, magic_set, magic_len, 0, 0 }

Thus, when an SV is determined to be magical and of type '\0', if a get operation is being performed, the routine magic_get is called. All the various routines for the various magical types begin with magic_.

The current kinds of Magic Virtual Tables are:

mg_type  MGVTBL              Type of magic
-------  ------              ----------------------------
\0       vtbl_sv             Special scalar variable
A        vtbl_amagic         %OVERLOAD hash
a        vtbl_amagicelem     %OVERLOAD hash element
c        (none)              Holds overload table (AMT) on stash
B        vtbl_bm             Boyer-Moore (fast string search)
E        vtbl_env            %ENV hash
e        vtbl_envelem        %ENV hash element
f        vtbl_fm             Formline ('compiled' format)
g        vtbl_mglob          m//g target / study()ed string
I        vtbl_isa            @ISA array
i        vtbl_isaelem        @ISA array element
k        vtbl_nkeys          scalar(keys()) lvalue
L        (none)              Debugger %_<filename 
l        vtbl_dbline         Debugger %_<filename element
o        vtbl_collxfrm       Locale transformation
P        vtbl_pack           Tied array or hash
p        vtbl_packelem       Tied array or hash element
q        vtbl_packelem       Tied scalar or handle
S        vtbl_sig            %SIG hash
s        vtbl_sigelem        %SIG hash element
t        vtbl_taint          Taintedness
U        vtbl_uvar           Available for use by extensions
v        vtbl_vec            vec() lvalue
x        vtbl_substr         substr() lvalue
y        vtbl_defelem        Shadow "foreach" iterator variable /
                              smart parameter vivification
*        vtbl_glob           GV (typeglob)
#        vtbl_arylen         Array length ($#ary)
.        vtbl_pos            pos() lvalue
~        (none)              Available for use by extensions

When an uppercase and lowercase letter both exist in the table, then the uppercase letter is used to represent some kind of composite type (a list or a hash), and the lowercase letter is used to represent an element of that composite type.

The '~' and 'U' magic types are defined specifically for use by extensions and will not be used by perl itself. Extensions can use '~' magic to 'attach' private information to variables (typically objects). This is especially useful because there is no way for normal perl code to corrupt this private information (unlike using extra elements of a hash object).

Similarly, 'U' magic can be used much like tie() to call a C function any time a scalar's value is used or changed. The MAGIC's mg_ptr field points to a ufuncs structure:

struct ufuncs {
    I32 (*uf_val)(IV, SV*);
    I32 (*uf_set)(IV, SV*);
    IV uf_index;
};

When the SV is read from or written to, the uf_val or uf_set function will be called with uf_index as the first arg and a pointer to the SV as the second.

Note that because multiple extensions may be using '~' or 'U' magic, it is important for extensions to take extra care to avoid conflict. Typically only using the magic on objects blessed into the same class as the extension is sufficient. For '~' magic, it may also be appropriate to add an I32 'signature' at the top of the private data area and check that.

Finding Magic

MAGIC* mg_find(SV*, int type); /* Finds the magic pointer of that type */

This routine returns a pointer to the MAGIC structure stored in the SV. If the SV does not have that magical feature, NULL is returned. Also, if the SV is not of type SVt_PVMG, Perl may core dump.

int mg_copy(SV* sv, SV* nsv, char* key, STRLEN klen);

This routine checks to see what types of magic sv has. If the mg_type field is an uppercase letter, then the mg_obj is copied to nsv, but the mg_type field is changed to be the lowercase letter.

Understanding the Magic of Tied Hashes and Arrays

Tied hashes and arrays are magical beasts of the 'P' magic type.

WARNING: As of the 5.004 release, proper usage of the array and hash access functions requires understanding a few caveats. Some of these caveats are actually considered bugs in the API, to be fixed in later releases, and are bracketed with [MAYCHANGE] below. If you find yourself actually applying such information in this section, be aware that the behavior may change in the future, umm, without warning.

The av_store function, when given a tied array argument, merely copies the magic of the array onto the value to be "stored", using mg_copy. It may also return NULL, indicating that the value did not actually need to be stored in the array. [MAYCHANGE] After a call to av_store on a tied array, the caller will usually need to call mg_set(val) to actually invoke the perl level "STORE" method on the TIEARRAY object. If av_store did return NULL, a call to SvREFCNT_dec(val) will also be usually necessary to avoid a memory leak. [/MAYCHANGE]

The previous paragraph is applicable verbatim to tied hash access using the hv_store and hv_store_ent functions as well.

av_fetch and the corresponding hash functions hv_fetch and hv_fetch_ent actually return an undefined mortal value whose magic has been initialized using mg_copy. Note the value so returned does not need to be deallocated, as it is already mortal. [MAYCHANGE] But you will need to call mg_get() on the returned value in order to actually invoke the perl level "FETCH" method on the underlying TIE object. Similarly, you may also call mg_set() on the return value after possibly assigning a suitable value to it using sv_setsv, which will invoke the "STORE" method on the TIE object. [/MAYCHANGE]

[MAYCHANGE] In other words, the array or hash fetch/store functions don't really fetch and store actual values in the case of tied arrays and hashes. They merely call mg_copy to attach magic to the values that were meant to be "stored" or "fetched". Later calls to mg_get and mg_set actually do the job of invoking the TIE methods on the underlying objects. Thus the magic mechanism currently implements a kind of lazy access to arrays and hashes.

Currently (as of perl version 5.004), use of the hash and array access functions requires the user to be aware of whether they are operating on "normal" hashes and arrays, or on their tied variants. The API may be changed to provide more transparent access to both tied and normal data types in future versions. [/MAYCHANGE]

You would do well to understand that the TIEARRAY and TIEHASH interfaces are mere sugar to invoke some perl method calls while using the uniform hash and array syntax. The use of this sugar imposes some overhead (typically about two to four extra opcodes per FETCH/STORE operation, in addition to the creation of all the mortal variables required to invoke the methods). This overhead will be comparatively small if the TIE methods are themselves substantial, but if they are only a few statements long, the overhead will not be insignificant.

Localizing changes

Perl has a very handy construction

{
  local $var = 2;
  ...
}

This construction is approximately equivalent to

{
  my $oldvar = $var;
  $var = 2;
  ...
  $var = $oldvar;
}

The biggest difference is that the first construction would reinstate the initial value of $var, irrespective of how control exits the block: goto, return, die/eval etc. It is a little bit more efficient as well.

There is a way to achieve a similar task from C via Perl API: create a pseudo-block, and arrange for some changes to be automatically undone at the end of it, either explicit, or via a non-local exit (via die()). A block-like construct is created by a pair of ENTER/LEAVE macros (see "EXAMPLE/"Returning a Scalar"" in perlcall). Such a construct may be created specially for some important localized task, or an existing one (like boundaries of enclosing Perl subroutine/block, or an existing pair for freeing TMPs) may be used. (In the second case the overhead of additional localization must be almost negligible.) Note that any XSUB is automatically enclosed in an ENTER/LEAVE pair.

Inside such a pseudo-block the following service is available:

SAVEINT(int i)
SAVEIV(IV i)
SAVEI32(I32 i)
SAVELONG(long i)

These macros arrange things to restore the value of integer variable i at the end of enclosing pseudo-block.

SAVESPTR(s)
SAVEPPTR(p)

These macros arrange things to restore the value of pointers s and p. s must be a pointer of a type which survives conversion to SV* and back, p should be able to survive conversion to char* and back.

SAVEFREESV(SV *sv)

The refcount of sv would be decremented at the end of pseudo-block. This is similar to sv_2mortal, which should (?) be used instead.

SAVEFREEOP(OP *op)

The OP * is op_free()ed at the end of pseudo-block.

SAVEFREEPV(p)

The chunk of memory which is pointed to by p is Safefree()ed at the end of pseudo-block.

SAVECLEARSV(SV *sv)

Clears a slot in the current scratchpad which corresponds to sv at the end of pseudo-block.

SAVEDELETE(HV *hv, char *key, I32 length)

The key key of hv is deleted at the end of pseudo-block. The string pointed to by key is Safefree()ed. If one has a key in short-lived storage, the corresponding string may be reallocated like this:

SAVEDELETE(defstash, savepv(tmpbuf), strlen(tmpbuf));
SAVEDESTRUCTOR(f,p)

At the end of pseudo-block the function f is called with the only argument (of type void*) p.

SAVESTACK_POS()

The current offset on the Perl internal stack (cf. SP) is restored at the end of pseudo-block.

The following API list contains functions, thus one needs to provide pointers to the modifiable data explicitly (either C pointers, or Perlish GV *s). Where the above macros take int, a similar function takes int *.

SV* save_scalar(GV *gv)

Equivalent to Perl code local $gv.

AV* save_ary(GV *gv)
HV* save_hash(GV *gv)

Similar to save_scalar, but localize @gv and %gv.

void save_item(SV *item)

Duplicates the current value of SV, on the exit from the current ENTER/LEAVE pseudo-block will restore the value of SV using the stored value.

void save_list(SV **sarg, I32 maxsarg)

A variant of save_item which takes multiple arguments via an array sarg of SV* of length maxsarg.

SV* save_svref(SV **sptr)

Similar to save_scalar, but will reinstate a SV *.

void save_aptr(AV **aptr)
void save_hptr(HV **hptr)

Similar to save_svref, but localize AV * and HV *.

The Alias module implements localization of the basic types within the caller's scope. People who are interested in how to localize things in the containing scope should take a look there too.

Subroutines

XSUBs and the Argument Stack

The XSUB mechanism is a simple way for Perl programs to access C subroutines. An XSUB routine will have a stack that contains the arguments from the Perl program, and a way to map from the Perl data structures to a C equivalent.

The stack arguments are accessible through the ST(n) macro, which returns the n'th stack argument. Argument 0 is the first argument passed in the Perl subroutine call. These arguments are SV*, and can be used anywhere an SV* is used.

Most of the time, output from the C routine can be handled through use of the RETVAL and OUTPUT directives. However, there are some cases where the argument stack is not already long enough to handle all the return values. An example is the POSIX tzname() call, which takes no arguments, but returns two, the local time zone's standard and summer time abbreviations.

To handle this situation, the PPCODE directive is used and the stack is extended using the macro:

EXTEND(sp, num);

where sp is the stack pointer, and num is the number of elements the stack should be extended by.

Now that there is room on the stack, values can be pushed on it using the macros to push IVs, doubles, strings, and SV pointers respectively:

PUSHi(IV)
PUSHn(double)
PUSHp(char*, I32)
PUSHs(SV*)

And now the Perl program calling tzname, the two values will be assigned as in:

($standard_abbrev, $summer_abbrev) = POSIX::tzname;

An alternate (and possibly simpler) method to pushing values on the stack is to use the macros:

XPUSHi(IV)
XPUSHn(double)
XPUSHp(char*, I32)
XPUSHs(SV*)

These macros automatically adjust the stack for you, if needed. Thus, you do not need to call EXTEND to extend the stack.

For more information, consult perlxs and perlxstut.

Calling Perl Routines from within C Programs

There are four routines that can be used to call a Perl subroutine from within a C program. These four are:

I32  perl_call_sv(SV*, I32);
I32  perl_call_pv(char*, I32);
I32  perl_call_method(char*, I32);
I32  perl_call_argv(char*, I32, register char**);

The routine most often used is perl_call_sv. The SV* argument contains either the name of the Perl subroutine to be called, or a reference to the subroutine. The second argument consists of flags that control the context in which the subroutine is called, whether or not the subroutine is being passed arguments, how errors should be trapped, and how to treat return values.

All four routines return the number of arguments that the subroutine returned on the Perl stack.

When using any of these routines (except perl_call_argv), the programmer must manipulate the Perl stack. These include the following macros and functions:

dSP
PUSHMARK()
PUTBACK
SPAGAIN
ENTER
SAVETMPS
FREETMPS
LEAVE
XPUSH*()
POP*()

For a detailed description of calling conventions from C to Perl, consult perlcall.

Memory Allocation

It is suggested that you use the version of malloc that is distributed with Perl. It keeps pools of various sizes of unallocated memory in order to satisfy allocation requests more quickly. However, on some platforms, it may cause spurious malloc or free errors.

New(x, pointer, number, type);
Newc(x, pointer, number, type, cast);
Newz(x, pointer, number, type);

These three macros are used to initially allocate memory.

The first argument x was a "magic cookie" that was used to keep track of who called the macro, to help when debugging memory problems. However, the current code makes no use of this feature (most Perl developers now use run-time memory checkers), so this argument can be any number.

The second argument pointer should be the name of a variable that will point to the newly allocated memory.

The third and fourth arguments number and type specify how many of the specified type of data structure should be allocated. The argument type is passed to sizeof. The final argument to Newc, cast, should be used if the pointer argument is different from the type argument.

Unlike the New and Newc macros, the Newz macro calls memzero to zero out all the newly allocated memory.

Renew(pointer, number, type);
Renewc(pointer, number, type, cast);
Safefree(pointer)

These three macros are used to change a memory buffer size or to free a piece of memory no longer needed. The arguments to Renew and Renewc match those of New and Newc with the exception of not needing the "magic cookie" argument.

Move(source, dest, number, type);
Copy(source, dest, number, type);
Zero(dest, number, type);

These three macros are used to move, copy, or zero out previously allocated memory. The source and dest arguments point to the source and destination starting points. Perl will move, copy, or zero out number instances of the size of the type data structure (using the sizeof function).

PerlIO

The most recent development releases of Perl has been experimenting with removing Perl's dependency on the "normal" standard I/O suite and allowing other stdio implementations to be used. This involves creating a new abstraction layer that then calls whichever implementation of stdio Perl was compiled with. All XSUBs should now use the functions in the PerlIO abstraction layer and not make any assumptions about what kind of stdio is being used.

For a complete description of the PerlIO abstraction, consult perlapio.

Putting a C value on Perl stack

A lot of opcodes (this is an elementary operation in the internal perl stack machine) put an SV* on the stack. However, as an optimization the corresponding SV is (usually) not recreated each time. The opcodes reuse specially assigned SVs (targets) which are (as a corollary) not constantly freed/created.

Each of the targets is created only once (but see "Scratchpads and recursion" below), and when an opcode needs to put an integer, a double, or a string on stack, it just sets the corresponding parts of its target and puts the target on stack.

The macro to put this target on stack is PUSHTARG, and it is directly used in some opcodes, as well as indirectly in zillions of others, which use it via (X)PUSH[pni].

Scratchpads

The question remains on when the SVs which are targets for opcodes are created. The answer is that they are created when the current unit -- a subroutine or a file (for opcodes for statements outside of subroutines) -- is compiled. During this time a special anonymous Perl array is created, which is called a scratchpad for the current unit.

A scratchpad keeps SVs which are lexicals for the current unit and are targets for opcodes. One can deduce that an SV lives on a scratchpad by looking on its flags: lexicals have SVs_PADMY set, and targets have SVs_PADTMP set.

The correspondence between OPs and targets is not 1-to-1. Different OPs in the compile tree of the unit can use the same target, if this would not conflict with the expected life of the temporary.

Scratchpads and recursion

In fact it is not 100% true that a compiled unit contains a pointer to the scratchpad AV. In fact it contains a pointer to an AV of (initially) one element, and this element is the scratchpad AV. Why do we need an extra level of indirection?

The answer is recursion, and maybe (sometime soon) threads. Both these can create several execution pointers going into the same subroutine. For the subroutine-child not write over the temporaries for the subroutine-parent (lifespan of which covers the call to the child), the parent and the child should have different scratchpads. (And the lexicals should be separate anyway!)

So each subroutine is born with an array of scratchpads (of length 1). On each entry to the subroutine it is checked that the current depth of the recursion is not more than the length of this array, and if it is, new scratchpad is created and pushed into the array.

The targets on this scratchpad are undefs, but they are already marked with correct flags.

Compiled code

Code tree

Here we describe the internal form your code is converted to by Perl. Start with a simple example:

$a = $b + $c;

This is converted to a tree similar to this one:

       assign-to
     /           \
    +             $a
  /   \
$b     $c

(but slightly more complicated). This tree reflect the way Perl parsed your code, but has nothing to do with the execution order. There is an additional "thread" going through the nodes of the tree which shows the order of execution of the nodes. In our simplified example above it looks like:

$b ---> $c ---> + ---> $a ---> assign-to

But with the actual compile tree for $a = $b + $c it is different: some nodes optimized away. As a corollary, though the actual tree contains more nodes than our simplified example, the execution order is the same as in our example.

Examining the tree

If you have your perl compiled for debugging (usually done with -D optimize=-g on Configure command line), you may examine the compiled tree by specifying -Dx on the Perl command line. The output takes several lines per node, and for $b+$c it looks like this:

5           TYPE = add  ===> 6
            TARG = 1
            FLAGS = (SCALAR,KIDS)
            {
                TYPE = null  ===> (4)
                  (was rv2sv)
                FLAGS = (SCALAR,KIDS)
                {
3                   TYPE = gvsv  ===> 4
                    FLAGS = (SCALAR)
                    GV = main::b
                }
            }
            {
                TYPE = null  ===> (5)
                  (was rv2sv)
                FLAGS = (SCALAR,KIDS)
                {
4                   TYPE = gvsv  ===> 5
                    FLAGS = (SCALAR)
                    GV = main::c
                }
            }

This tree has 5 nodes (one per TYPE specifier), only 3 of them are not optimized away (one per number in the left column). The immediate children of the given node correspond to {} pairs on the same level of indentation, thus this listing corresponds to the tree:

    add
  /     \
null    null
 |       |
gvsv    gvsv

The execution order is indicated by ===> marks, thus it is 3 4 5 6 (node 6 is not included into above listing), i.e., gvsv gvsv add whatever.

Compile pass 1: check routines

The tree is created by the pseudo-compiler while yacc code feeds it the constructions it recognizes. Since yacc works bottom-up, so does the first pass of perl compilation.

What makes this pass interesting for perl developers is that some optimization may be performed on this pass. This is optimization by so-called check routines. The correspondence between node names and corresponding check routines is described in opcode.pl (do not forget to run make regen_headers if you modify this file).

A check routine is called when the node is fully constructed except for the execution-order thread. Since at this time there is no back-links to the currently constructed node, one can do most any operation to the top-level node, including freeing it and/or creating new nodes above/below it.

The check routine returns the node which should be inserted into the tree (if the top-level node was not modified, check routine returns its argument).

By convention, check routines have names ck_*. They are usually called from new*OP subroutines (or convert) (which in turn are called from perly.y).

Compile pass 1a: constant folding

Immediately after the check routine is called the returned node is checked for being compile-time executable. If it is (the value is judged to be constant) it is immediately executed, and a constant node with the "return value" of the corresponding subtree is substituted instead. The subtree is deleted.

If constant folding was not performed, the execution-order thread is created.

Compile pass 2: context propagation

When a context for a part of compile tree is known, it is propagated down through the tree. Aat this time the context can have 5 values (instead of 2 for runtime context): void, boolean, scalar, list, and lvalue. In contrast with the pass 1 this pass is processed from top to bottom: a node's context determines the context for its children.

Additional context-dependent optimizations are performed at this time. Since at this moment the compile tree contains back-references (via "thread" pointers), nodes cannot be free()d now. To allow optimized-away nodes at this stage, such nodes are null()ified instead of free()ing (i.e. their type is changed to OP_NULL).

Compile pass 3: peephole optimization

After the compile tree for a subroutine (or for an eval or a file) is created, an additional pass over the code is performed. This pass is neither top-down or bottom-up, but in the execution order (with additional compilications for conditionals). These optimizations are done in the subroutine peep(). Optimizations performed at this stage are subject to the same restrictions as in the pass 2.

API LISTING

This is a listing of functions, macros, flags, and variables that may be useful to extension writers or that may be found while reading other extensions.

AvFILL

See av_len.

av_clear

Clears an array, making it empty. Does not free the memory used by the array itself.

void	av_clear _((AV* ar));
av_extend

Pre-extend an array. The key is the index to which the array should be extended.

void	av_extend _((AV* ar, I32 key));
av_fetch

Returns the SV at the specified index in the array. The key is the index. If lval is set then the fetch will be part of a store. Check that the return value is non-null before dereferencing it to a SV*.

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use this function on tied arrays.

SV**	av_fetch _((AV* ar, I32 key, I32 lval));
av_len

Returns the highest index in the array. Returns -1 if the array is empty.

I32	av_len _((AV* ar));
av_make

Creates a new AV and populates it with a list of SVs. The SVs are copied into the array, so they may be freed after the call to av_make. The new AV will have a reference count of 1.

AV*	av_make _((I32 size, SV** svp));
av_pop

Pops an SV off the end of the array. Returns &sv_undef if the array is empty.

SV*	av_pop _((AV* ar));
av_push

Pushes an SV onto the end of the array. The array will grow automatically to accommodate the addition.

void	av_push _((AV* ar, SV* val));
av_shift

Shifts an SV off the beginning of the array.

SV*	av_shift _((AV* ar));
av_store

Stores an SV in an array. The array index is specified as key. The return value will be NULL if the operation failed or if the value did not need to be actually stored within the array (as in the case of tied arrays). Otherwise it can be dereferenced to get the original SV*. Note that the caller is responsible for suitably incrementing the reference count of val before the call, and decrementing it if the function returned NULL.

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use this function on tied arrays.

SV**	av_store _((AV* ar, I32 key, SV* val));
av_undef

Undefines the array. Frees the memory used by the array itself.

void	av_undef _((AV* ar));
av_unshift

Unshift the given number of undef values onto the beginning of the array. The array will grow automatically to accommodate the addition. You must then use av_store to assign values to these new elements.

void	av_unshift _((AV* ar, I32 num));
CLASS

Variable which is setup by xsubpp to indicate the class name for a C++ XS constructor. This is always a char*. See THIS and "Using XS With C++" in perlxs.

Copy

The XSUB-writer's interface to the C memcpy function. The s is the source, d is the destination, n is the number of items, and t is the type. May fail on overlapping copies. See also Move.

(void) Copy( s, d, n, t );
croak

This is the XSUB-writer's interface to Perl's die function. Use this function the same way you use the C printf function. See warn.

CvSTASH

Returns the stash of the CV.

HV * CvSTASH( SV* sv )
DBsingle

When Perl is run in debugging mode, with the -d switch, this SV is a boolean which indicates whether subs are being single-stepped. Single-stepping is automatically turned on after every step. This is the C variable which corresponds to Perl's $DB::single variable. See DBsub.

DBsub

When Perl is run in debugging mode, with the -d switch, this GV contains the SV which holds the name of the sub being debugged. This is the C variable which corresponds to Perl's $DB::sub variable. See DBsingle. The sub name can be found by

SvPV( GvSV( DBsub ), na )
DBtrace

Trace variable used when Perl is run in debugging mode, with the -d switch. This is the C variable which corresponds to Perl's $DB::trace variable. See DBsingle.

dMARK

Declare a stack marker variable, mark, for the XSUB. See MARK and dORIGMARK.

dORIGMARK

Saves the original stack mark for the XSUB. See ORIGMARK.

dowarn

The C variable which corresponds to Perl's $^W warning variable.

dSP

Declares a stack pointer variable, sp, for the XSUB. See SP.

dXSARGS

Sets up stack and mark pointers for an XSUB, calling dSP and dMARK. This is usually handled automatically by xsubpp. Declares the items variable to indicate the number of items on the stack.

dXSI32

Sets up the ix variable for an XSUB which has aliases. This is usually handled automatically by xsubpp.

ENTER

Opening bracket on a callback. See LEAVE and perlcall.

ENTER;
EXTEND

Used to extend the argument stack for an XSUB's return values.

EXTEND( sp, int x );
FREETMPS

Closing bracket for temporaries on a callback. See SAVETMPS and perlcall.

FREETMPS;
G_ARRAY

Used to indicate array context. See GIMME_V, GIMME and perlcall.

G_DISCARD

Indicates that arguments returned from a callback should be discarded. See perlcall.

G_EVAL

Used to force a Perl eval wrapper around a callback. See perlcall.

GIMME

A backward-compatible version of GIMME_V which can only return G_SCALAR or G_ARRAY; in a void context, it returns G_SCALAR.

GIMME_V

The XSUB-writer's equivalent to Perl's wantarray. Returns G_VOID, G_SCALAR or G_ARRAY for void, scalar or array context, respectively.

G_NOARGS

Indicates that no arguments are being sent to a callback. See perlcall.

G_SCALAR

Used to indicate scalar context. See GIMME_V, GIMME, and perlcall.

G_VOID

Used to indicate void context. See GIMME_V and perlcall.

gv_fetchmeth

Returns the glob with the given name and a defined subroutine or NULL. The glob lives in the given stash, or in the stashes accessable via @ISA and @<UNIVERSAL>.

The argument level should be either 0 or -1. If level==0, as a side-effect creates a glob with the given name in the given stash which in the case of success contains an alias for the subroutine, and sets up caching info for this glob. Similarly for all the searched stashes.

This function grants "SUPER" token as a postfix of the stash name.

The GV returned from gv_fetchmeth may be a method cache entry, which is not visible to Perl code. So when calling perl_call_sv, you should not use the GV directly; instead, you should use the method's CV, which can be obtained from the GV with the GvCV macro.

GV*     gv_fetchmeth _((HV* stash, char* name, STRLEN len, I32 level));
gv_fetchmethod
gv_fetchmethod_autoload

Returns the glob which contains the subroutine to call to invoke the method on the stash. In fact in the presense of autoloading this may be the glob for "AUTOLOAD". In this case the corresponding variable $AUTOLOAD is already setup.

The third parameter of gv_fetchmethod_autoload determines whether AUTOLOAD lookup is performed if the given method is not present: non-zero means yes, look for AUTOLOAD; zero means no, don't look for AUTOLOAD. Calling gv_fetchmethod is equivalent to calling gv_fetchmethod_autoload with a non-zero autoload parameter.

These functions grant "SUPER" token as a prefix of the method name.

Note that if you want to keep the returned glob for a long time, you need to check for it being "AUTOLOAD", since at the later time the call may load a different subroutine due to $AUTOLOAD changing its value. Use the glob created via a side effect to do this.

These functions have the same side-effects and as gv_fetchmeth with level==0. name should be writable if contains ':' or '\''. The warning against passing the GV returned by gv_fetchmeth to perl_call_sv apply equally to these functions.

GV*     gv_fetchmethod _((HV* stash, char* name));
GV*     gv_fetchmethod_autoload _((HV* stash, char* name,
                                   I32 autoload));
gv_stashpv

Returns a pointer to the stash for a specified package. If create is set then the package will be created if it does not already exist. If create is not set and the package does not exist then NULL is returned.

HV*	gv_stashpv _((char* name, I32 create));
gv_stashsv

Returns a pointer to the stash for a specified package. See gv_stashpv.

HV*	gv_stashsv _((SV* sv, I32 create));
GvSV

Return the SV from the GV.

HEf_SVKEY

This flag, used in the length slot of hash entries and magic structures, specifies the structure contains a SV* pointer where a char* pointer is to be expected. (For information only--not to be used).

HeHASH

Returns the computed hash (type U32) stored in the hash entry.

HeHASH(HE* he)
HeKEY

Returns the actual pointer stored in the key slot of the hash entry. The pointer may be either char* or SV*, depending on the value of HeKLEN(). Can be assigned to. The HePV() or HeSVKEY() macros are usually preferable for finding the value of a key.

HeKEY(HE* he)
HeKLEN

If this is negative, and amounts to HEf_SVKEY, it indicates the entry holds an SV* key. Otherwise, holds the actual length of the key. Can be assigned to. The HePV() macro is usually preferable for finding key lengths.

HeKLEN(HE* he)
HePV

Returns the key slot of the hash entry as a char* value, doing any necessary dereferencing of possibly SV* keys. The length of the string is placed in len (this is a macro, so do not use &len). If you do not care about what the length of the key is, you may use the global variable na. Remember though, that hash keys in perl are free to contain embedded nulls, so using strlen() or similar is not a good way to find the length of hash keys. This is very similar to the SvPV() macro described elsewhere in this document.

HePV(HE* he, STRLEN len)
HeSVKEY

Returns the key as an SV*, or Nullsv if the hash entry does not contain an SV* key.

HeSVKEY(HE* he)
HeSVKEY_force

Returns the key as an SV*. Will create and return a temporary mortal SV* if the hash entry contains only a char* key.

HeSVKEY_force(HE* he)
HeSVKEY_set

Sets the key to a given SV*, taking care to set the appropriate flags to indicate the presence of an SV* key, and returns the same SV*.

HeSVKEY_set(HE* he, SV* sv)
HeVAL

Returns the value slot (type SV*) stored in the hash entry.

HeVAL(HE* he)
hv_clear

Clears a hash, making it empty.

void	hv_clear _((HV* tb));
hv_delayfree_ent

Releases a hash entry, such as while iterating though the hash, but delays actual freeing of key and value until the end of the current statement (or thereabouts) with sv_2mortal. See hv_iternext and hv_free_ent.

void    hv_delayfree_ent _((HV* hv, HE* entry));
hv_delete

Deletes a key/value pair in the hash. The value SV is removed from the hash and returned to the caller. The klen is the length of the key. The flags value will normally be zero; if set to G_DISCARD then NULL will be returned.

SV*	hv_delete _((HV* tb, char* key, U32 klen, I32 flags));
hv_delete_ent

Deletes a key/value pair in the hash. The value SV is removed from the hash and returned to the caller. The flags value will normally be zero; if set to G_DISCARD then NULL will be returned. hash can be a valid precomputed hash value, or 0 to ask for it to be computed.

SV*     hv_delete_ent _((HV* tb, SV* key, I32 flags, U32 hash));
hv_exists

Returns a boolean indicating whether the specified hash key exists. The klen is the length of the key.

bool	hv_exists _((HV* tb, char* key, U32 klen));
hv_exists_ent

Returns a boolean indicating whether the specified hash key exists. hash can be a valid precomputed hash value, or 0 to ask for it to be computed.

bool    hv_exists_ent _((HV* tb, SV* key, U32 hash));
hv_fetch

Returns the SV which corresponds to the specified key in the hash. The klen is the length of the key. If lval is set then the fetch will be part of a store. Check that the return value is non-null before dereferencing it to a SV*.

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use this function on tied hashes.

SV**	hv_fetch _((HV* tb, char* key, U32 klen, I32 lval));
hv_fetch_ent

Returns the hash entry which corresponds to the specified key in the hash. hash must be a valid precomputed hash number for the given key, or 0 if you want the function to compute it. IF lval is set then the fetch will be part of a store. Make sure the return value is non-null before accessing it. The return value when tb is a tied hash is a pointer to a static location, so be sure to make a copy of the structure if you need to store it somewhere.

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use this function on tied hashes.

HE*     hv_fetch_ent  _((HV* tb, SV* key, I32 lval, U32 hash));
hv_free_ent

Releases a hash entry, such as while iterating though the hash. See hv_iternext and hv_delayfree_ent.

void    hv_free_ent _((HV* hv, HE* entry));
hv_iterinit

Prepares a starting point to traverse a hash table.

I32	hv_iterinit _((HV* tb));
hv_iterkey

Returns the key from the current position of the hash iterator. See hv_iterinit.

char*	hv_iterkey _((HE* entry, I32* retlen));
hv_iterkeysv

Returns the key as an SV* from the current position of the hash iterator. The return value will always be a mortal copy of the key. Also see hv_iterinit.

SV*     hv_iterkeysv  _((HE* entry));
hv_iternext

Returns entries from a hash iterator. See hv_iterinit.

HE*	hv_iternext _((HV* tb));
hv_iternextsv

Performs an hv_iternext, hv_iterkey, and hv_iterval in one operation.

SV *	hv_iternextsv _((HV* hv, char** key, I32* retlen));
hv_iterval

Returns the value from the current position of the hash iterator. See hv_iterkey.

SV*	hv_iterval _((HV* tb, HE* entry));
hv_magic

Adds magic to a hash. See sv_magic.

void	hv_magic _((HV* hv, GV* gv, int how));
HvNAME

Returns the package name of a stash. See SvSTASH, CvSTASH.

char *HvNAME (HV* stash)
hv_store

Stores an SV in a hash. The hash key is specified as key and klen is the length of the key. The hash parameter is the precomputed hash value; if it is zero then Perl will compute it. The return value will be NULL if the operation failed or if the value did not need to be actually stored within the hash (as in the case of tied hashes). Otherwise it can be dereferenced to get the original SV*. Note that the caller is responsible for suitably incrementing the reference count of val before the call, and decrementing it if the function returned NULL.

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use this function on tied hashes.

SV**	hv_store _((HV* tb, char* key, U32 klen, SV* val, U32 hash));
hv_store_ent

Stores val in a hash. The hash key is specified as key. The hash parameter is the precomputed hash value; if it is zero then Perl will compute it. The return value is the new hash entry so created. It will be NULL if the operation failed or if the value did not need to be actually stored within the hash (as in the case of tied hashes). Otherwise the contents of the return value can be accessed using the He??? macros described here. Note that the caller is responsible for suitably incrementing the reference count of val before the call, and decrementing it if the function returned NULL.

See "Understanding the Magic of Tied Hashes and Arrays" for more information on how to use this function on tied hashes.

HE*     hv_store_ent  _((HV* tb, SV* key, SV* val, U32 hash));
hv_undef

Undefines the hash.

void	hv_undef _((HV* tb));
isALNUM

Returns a boolean indicating whether the C char is an ascii alphanumeric character or digit.

int isALNUM (char c)
isALPHA

Returns a boolean indicating whether the C char is an ascii alphabetic character.

int isALPHA (char c)
isDIGIT

Returns a boolean indicating whether the C char is an ascii digit.

int isDIGIT (char c)
isLOWER

Returns a boolean indicating whether the C char is a lowercase character.

int isLOWER (char c)
isSPACE

Returns a boolean indicating whether the C char is whitespace.

int isSPACE (char c)
isUPPER

Returns a boolean indicating whether the C char is an uppercase character.

int isUPPER (char c)
items

Variable which is setup by xsubpp to indicate the number of items on the stack. See "Variable-length Parameter Lists" in perlxs.

ix

Variable which is setup by xsubpp to indicate which of an XSUB's aliases was used to invoke it. See "The ALIAS: Keyword" in perlxs.

LEAVE

Closing bracket on a callback. See ENTER and perlcall.

LEAVE;
MARK

Stack marker variable for the XSUB. See dMARK.

mg_clear

Clear something magical that the SV represents. See sv_magic.

int	mg_clear _((SV* sv));
mg_copy

Copies the magic from one SV to another. See sv_magic.

int	mg_copy _((SV *, SV *, char *, STRLEN));
mg_find

Finds the magic pointer for type matching the SV. See sv_magic.

MAGIC*	mg_find _((SV* sv, int type));
mg_free

Free any magic storage used by the SV. See sv_magic.

int	mg_free _((SV* sv));
mg_get

Do magic after a value is retrieved from the SV. See sv_magic.

int	mg_get _((SV* sv));
mg_len

Report on the SV's length. See sv_magic.

U32	mg_len _((SV* sv));
mg_magical

Turns on the magical status of an SV. See sv_magic.

void	mg_magical _((SV* sv));
mg_set

Do magic after a value is assigned to the SV. See sv_magic.

int	mg_set _((SV* sv));
Move

The XSUB-writer's interface to the C memmove function. The s is the source, d is the destination, n is the number of items, and t is the type. Can do overlapping moves. See also Copy.

(void) Move( s, d, n, t );
na

A variable which may be used with SvPV to tell Perl to calculate the string length.

New

The XSUB-writer's interface to the C malloc function.

void * New( x, void *ptr, int size, type )
Newc

The XSUB-writer's interface to the C malloc function, with cast.

void * Newc( x, void *ptr, int size, type, cast )
Newz

The XSUB-writer's interface to the C malloc function. The allocated memory is zeroed with memzero.

void * Newz( x, void *ptr, int size, type )
newAV

Creates a new AV. The reference count is set to 1.

AV*	newAV _((void));
newHV

Creates a new HV. The reference count is set to 1.

HV*	newHV _((void));
newRV_inc

Creates an RV wrapper for an SV. The reference count for the original SV is incremented.

SV*	newRV_inc _((SV* ref));

For historical reasons, "newRV" is a synonym for "newRV_inc".

newRV_noinc

Creates an RV wrapper for an SV. The reference count for the original SV is not incremented.

SV*     newRV_noinc _((SV* ref));
newSV

Creates a new SV. The len parameter indicates the number of bytes of preallocated string space the SV should have. The reference count for the new SV is set to 1.

SV*	newSV _((STRLEN len));
newSViv

Creates a new SV and copies an integer into it. The reference count for the SV is set to 1.

SV*	newSViv _((IV i));
newSVnv

Creates a new SV and copies a double into it. The reference count for the SV is set to 1.

SV*	newSVnv _((NV i));
newSVpv

Creates a new SV and copies a string into it. The reference count for the SV is set to 1. If len is zero then Perl will compute the length.

SV*	newSVpv _((char* s, STRLEN len));
newSVrv

Creates a new SV for the RV, rv, to point to. If rv is not an RV then it will be upgraded to one. If classname is non-null then the new SV will be blessed in the specified package. The new SV is returned and its reference count is 1.

SV*	newSVrv _((SV* rv, char* classname));
newSVsv

Creates a new SV which is an exact duplicate of the original SV.

SV*	newSVsv _((SV* old));
newXS

Used by xsubpp to hook up XSUBs as Perl subs.

newXSproto

Used by xsubpp to hook up XSUBs as Perl subs. Adds Perl prototypes to the subs.

Nullav

Null AV pointer.

Nullch

Null character pointer.

Nullcv

Null CV pointer.

Nullhv

Null HV pointer.

Nullsv

Null SV pointer.

ORIGMARK

The original stack mark for the XSUB. See dORIGMARK.

perl_alloc

Allocates a new Perl interpreter. See perlembed.

perl_call_argv

Performs a callback to the specified Perl sub. See perlcall.

I32	perl_call_argv _((char* subname, I32 flags, char** argv));
perl_call_method

Performs a callback to the specified Perl method. The blessed object must be on the stack. See perlcall.

I32	perl_call_method _((char* methname, I32 flags));
perl_call_pv

Performs a callback to the specified Perl sub. See perlcall.

I32	perl_call_pv _((char* subname, I32 flags));
perl_call_sv

Performs a callback to the Perl sub whose name is in the SV. See perlcall.

I32	perl_call_sv _((SV* sv, I32 flags));
perl_construct

Initializes a new Perl interpreter. See perlembed.

perl_destruct

Shuts down a Perl interpreter. See perlembed.

perl_eval_sv

Tells Perl to eval the string in the SV.

I32	perl_eval_sv _((SV* sv, I32 flags));
perl_eval_pv

Tells Perl to eval the given string and return an SV* result.

SV*	perl_eval_pv _((char* p, I32 croak_on_error));
perl_free

Releases a Perl interpreter. See perlembed.

perl_get_av

Returns the AV of the specified Perl array. If create is set and the Perl variable does not exist then it will be created. If create is not set and the variable does not exist then NULL is returned.

AV*	perl_get_av _((char* name, I32 create));
perl_get_cv

Returns the CV of the specified Perl sub. If create is set and the Perl variable does not exist then it will be created. If create is not set and the variable does not exist then NULL is returned.

CV*	perl_get_cv _((char* name, I32 create));
perl_get_hv

Returns the HV of the specified Perl hash. If create is set and the Perl variable does not exist then it will be created. If create is not set and the variable does not exist then NULL is returned.

HV*	perl_get_hv _((char* name, I32 create));
perl_get_sv

Returns the SV of the specified Perl scalar. If create is set and the Perl variable does not exist then it will be created. If create is not set and the variable does not exist then NULL is returned.

SV*	perl_get_sv _((char* name, I32 create));
perl_parse

Tells a Perl interpreter to parse a Perl script. See perlembed.

perl_require_pv

Tells Perl to require a module.

void	perl_require_pv _((char* pv));
perl_run

Tells a Perl interpreter to run. See perlembed.

POPi

Pops an integer off the stack.

int POPi();
POPl

Pops a long off the stack.

long POPl();
POPp

Pops a string off the stack.

char * POPp();
POPn

Pops a double off the stack.

double POPn();
POPs

Pops an SV off the stack.

SV* POPs();
PUSHMARK

Opening bracket for arguments on a callback. See PUTBACK and perlcall.

PUSHMARK(p)
PUSHi

Push an integer onto the stack. The stack must have room for this element. See XPUSHi.

PUSHi(int d)
PUSHn

Push a double onto the stack. The stack must have room for this element. See XPUSHn.

PUSHn(double d)
PUSHp

Push a string onto the stack. The stack must have room for this element. The len indicates the length of the string. See XPUSHp.

PUSHp(char *c, int len )
PUSHs

Push an SV onto the stack. The stack must have room for this element. See XPUSHs.

PUSHs(sv)
PUTBACK

Closing bracket for XSUB arguments. This is usually handled by xsubpp. See PUSHMARK and perlcall for other uses.

PUTBACK;
Renew

The XSUB-writer's interface to the C realloc function.

void * Renew( void *ptr, int size, type )
Renewc

The XSUB-writer's interface to the C realloc function, with cast.

void * Renewc( void *ptr, int size, type, cast )
RETVAL

Variable which is setup by xsubpp to hold the return value for an XSUB. This is always the proper type for the XSUB. See "The RETVAL Variable" in perlxs.

safefree

The XSUB-writer's interface to the C free function.

safemalloc

The XSUB-writer's interface to the C malloc function.

saferealloc

The XSUB-writer's interface to the C realloc function.

savepv

Copy a string to a safe spot. This does not use an SV.

char*	savepv _((char* sv));
savepvn

Copy a string to a safe spot. The len indicates number of bytes to copy. This does not use an SV.

char*	savepvn _((char* sv, I32 len));
SAVETMPS

Opening bracket for temporaries on a callback. See FREETMPS and perlcall.

SAVETMPS;
SP

Stack pointer. This is usually handled by xsubpp. See dSP and SPAGAIN.

SPAGAIN

Refetch the stack pointer. Used after a callback. See perlcall.

SPAGAIN;
ST

Used to access elements on the XSUB's stack.

SV* ST(int x)
strEQ

Test two strings to see if they are equal. Returns true or false.

int strEQ( char *s1, char *s2 )
strGE

Test two strings to see if the first, s1, is greater than or equal to the second, s2. Returns true or false.

int strGE( char *s1, char *s2 )
strGT

Test two strings to see if the first, s1, is greater than the second, s2. Returns true or false.

int strGT( char *s1, char *s2 )
strLE

Test two strings to see if the first, s1, is less than or equal to the second, s2. Returns true or false.

int strLE( char *s1, char *s2 )
strLT

Test two strings to see if the first, s1, is less than the second, s2. Returns true or false.

int strLT( char *s1, char *s2 )
strNE

Test two strings to see if they are different. Returns true or false.

int strNE( char *s1, char *s2 )
strnEQ

Test two strings to see if they are equal. The len parameter indicates the number of bytes to compare. Returns true or false.

int strnEQ( char *s1, char *s2 )
strnNE

Test two strings to see if they are different. The len parameter indicates the number of bytes to compare. Returns true or false.

int strnNE( char *s1, char *s2, int len )
sv_2mortal

Marks an SV as mortal. The SV will be destroyed when the current context ends.

SV*	sv_2mortal _((SV* sv));
sv_bless

Blesses an SV into a specified package. The SV must be an RV. The package must be designated by its stash (see gv_stashpv()). The reference count of the SV is unaffected.

SV*	sv_bless _((SV* sv, HV* stash));
sv_catpv

Concatenates the string onto the end of the string which is in the SV.

void	sv_catpv _((SV* sv, char* ptr));
sv_catpvn

Concatenates the string onto the end of the string which is in the SV. The len indicates number of bytes to copy.

void	sv_catpvn _((SV* sv, char* ptr, STRLEN len));
sv_catpvf

Processes its arguments like sprintf and appends the formatted output to an SV.

void	sv_catpvf _((SV* sv, const char* pat, ...));
sv_catsv

Concatenates the string from SV ssv onto the end of the string in SV dsv.

void	sv_catsv _((SV* dsv, SV* ssv));
sv_cmp

Compares the strings in two SVs. Returns -1, 0, or 1 indicating whether the string in sv1 is less than, equal to, or greater than the string in sv2.

I32	sv_cmp _((SV* sv1, SV* sv2));
SvCUR

Returns the length of the string which is in the SV. See SvLEN.

int SvCUR (SV* sv)
SvCUR_set

Set the length of the string which is in the SV. See SvCUR.

SvCUR_set (SV* sv, int val )
sv_dec

Auto-decrement of the value in the SV.

void	sv_dec _((SV* sv));
SvEND

Returns a pointer to the last character in the string which is in the SV. See SvCUR. Access the character as

*SvEND(sv)
sv_eq

Returns a boolean indicating whether the strings in the two SVs are identical.

I32	sv_eq _((SV* sv1, SV* sv2));
SvGROW

Expands the character buffer in the SV. Calls sv_grow to perform the expansion if necessary. Returns a pointer to the character buffer.

char * SvGROW( SV* sv, int len )
sv_grow

Expands the character buffer in the SV. This will use sv_unref and will upgrade the SV to SVt_PV. Returns a pointer to the character buffer. Use SvGROW.

sv_inc

Auto-increment of the value in the SV.

void	sv_inc _((SV* sv));
SvIOK

Returns a boolean indicating whether the SV contains an integer.

int SvIOK (SV* SV)
SvIOK_off

Unsets the IV status of an SV.

SvIOK_off (SV* sv)
SvIOK_on

Tells an SV that it is an integer.

SvIOK_on (SV* sv)
SvIOK_only

Tells an SV that it is an integer and disables all other OK bits.

SvIOK_on (SV* sv)
SvIOKp

Returns a boolean indicating whether the SV contains an integer. Checks the private setting. Use SvIOK.

int SvIOKp (SV* SV)
sv_isa

Returns a boolean indicating whether the SV is blessed into the specified class. This does not know how to check for subtype, so it doesn't work in an inheritance relationship.

int	sv_isa _((SV* sv, char* name));
SvIV

Returns the integer which is in the SV.

int SvIV (SV* sv)
sv_isobject

Returns a boolean indicating whether the SV is an RV pointing to a blessed object. If the SV is not an RV, or if the object is not blessed, then this will return false.

int	sv_isobject _((SV* sv));
SvIVX

Returns the integer which is stored in the SV.

int  SvIVX (SV* sv);
SvLEN

Returns the size of the string buffer in the SV. See SvCUR.

int SvLEN (SV* sv)
sv_len

Returns the length of the string in the SV. Use SvCUR.

STRLEN	sv_len _((SV* sv));
sv_magic

Adds magic to an SV.

void	sv_magic _((SV* sv, SV* obj, int how, char* name, I32 namlen));
sv_mortalcopy

Creates a new SV which is a copy of the original SV. The new SV is marked as mortal.

SV*	sv_mortalcopy _((SV* oldsv));
SvOK

Returns a boolean indicating whether the value is an SV.

int SvOK (SV* sv)
sv_newmortal

Creates a new SV which is mortal. The reference count of the SV is set to 1.

SV*	sv_newmortal _((void));
sv_no

This is the false SV. See sv_yes. Always refer to this as &sv_no.

SvNIOK

Returns a boolean indicating whether the SV contains a number, integer or double.

int SvNIOK (SV* SV)
SvNIOK_off

Unsets the NV/IV status of an SV.

SvNIOK_off (SV* sv)
SvNIOKp

Returns a boolean indicating whether the SV contains a number, integer or double. Checks the private setting. Use SvNIOK.

int SvNIOKp (SV* SV)
SvNOK

Returns a boolean indicating whether the SV contains a double.

int SvNOK (SV* SV)
SvNOK_off

Unsets the NV status of an SV.

SvNOK_off (SV* sv)
SvNOK_on

Tells an SV that it is a double.

SvNOK_on (SV* sv)
SvNOK_only

Tells an SV that it is a double and disables all other OK bits.

SvNOK_on (SV* sv)
SvNOKp

Returns a boolean indicating whether the SV contains a double. Checks the private setting. Use SvNOK.

int SvNOKp (SV* SV)
SvNV

Returns the double which is stored in the SV.

double SvNV (SV* sv);
SvNVX

Returns the double which is stored in the SV.

double SvNVX (SV* sv);
SvPOK

Returns a boolean indicating whether the SV contains a character string.

int SvPOK (SV* SV)
SvPOK_off

Unsets the PV status of an SV.

SvPOK_off (SV* sv)
SvPOK_on

Tells an SV that it is a string.

SvPOK_on (SV* sv)
SvPOK_only

Tells an SV that it is a string and disables all other OK bits.

SvPOK_on (SV* sv)
SvPOKp

Returns a boolean indicating whether the SV contains a character string. Checks the private setting. Use SvPOK.

int SvPOKp (SV* SV)
SvPV

Returns a pointer to the string in the SV, or a stringified form of the SV if the SV does not contain a string. If len is na then Perl will handle the length on its own.

char * SvPV (SV* sv, int len )
SvPVX

Returns a pointer to the string in the SV. The SV must contain a string.

char * SvPVX (SV* sv)
SvREFCNT

Returns the value of the object's reference count.

int SvREFCNT (SV* sv);
SvREFCNT_dec

Decrements the reference count of the given SV.

void SvREFCNT_dec (SV* sv)
SvREFCNT_inc

Increments the reference count of the given SV.

void SvREFCNT_inc (SV* sv)
SvROK

Tests if the SV is an RV.

int SvROK (SV* sv)
SvROK_off

Unsets the RV status of an SV.

SvROK_off (SV* sv)
SvROK_on

Tells an SV that it is an RV.

SvROK_on (SV* sv)
SvRV

Dereferences an RV to return the SV.

SV*	SvRV (SV* sv);
sv_setiv

Copies an integer into the given SV.

void	sv_setiv _((SV* sv, IV num));
sv_setnv

Copies a double into the given SV.

void	sv_setnv _((SV* sv, double num));
sv_setpv

Copies a string into an SV. The string must be null-terminated.

void	sv_setpv _((SV* sv, char* ptr));
sv_setpvn

Copies a string into an SV. The len parameter indicates the number of bytes to be copied.

void	sv_setpvn _((SV* sv, char* ptr, STRLEN len));
sv_setpvf

Processes its arguments like sprintf and sets an SV to the formatted output.

void	sv_setpvf _((SV* sv, const char* pat, ...));
sv_setref_iv

Copies an integer into a new SV, optionally blessing the SV. The rv argument will be upgraded to an RV. That RV will be modified to point to the new SV. The classname argument indicates the package for the blessing. Set classname to Nullch to avoid the blessing. The new SV will be returned and will have a reference count of 1.

SV*	sv_setref_iv _((SV *rv, char *classname, IV iv));
sv_setref_nv

Copies a double into a new SV, optionally blessing the SV. The rv argument will be upgraded to an RV. That RV will be modified to point to the new SV. The classname argument indicates the package for the blessing. Set classname to Nullch to avoid the blessing. The new SV will be returned and will have a reference count of 1.

SV*	sv_setref_nv _((SV *rv, char *classname, double nv));
sv_setref_pv

Copies a pointer into a new SV, optionally blessing the SV. The rv argument will be upgraded to an RV. That RV will be modified to point to the new SV. If the pv argument is NULL then sv_undef will be placed into the SV. The classname argument indicates the package for the blessing. Set classname to Nullch to avoid the blessing. The new SV will be returned and will have a reference count of 1.

SV*	sv_setref_pv _((SV *rv, char *classname, void* pv));

Do not use with integral Perl types such as HV, AV, SV, CV, because those objects will become corrupted by the pointer copy process.

Note that sv_setref_pvn copies the string while this copies the pointer.

sv_setref_pvn

Copies a string into a new SV, optionally blessing the SV. The length of the string must be specified with n. The rv argument will be upgraded to an RV. That RV will be modified to point to the new SV. The classname argument indicates the package for the blessing. Set classname to Nullch to avoid the blessing. The new SV will be returned and will have a reference count of 1.

SV*	sv_setref_pvn _((SV *rv, char *classname, char* pv, I32 n));

Note that sv_setref_pv copies the pointer while this copies the string.

sv_setsv

Copies the contents of the source SV ssv into the destination SV dsv. The source SV may be destroyed if it is mortal.

void	sv_setsv _((SV* dsv, SV* ssv));
SvSTASH

Returns the stash of the SV.

HV * SvSTASH (SV* sv)
SVt_IV

Integer type flag for scalars. See svtype.

SVt_PV

Pointer type flag for scalars. See svtype.

SVt_PVAV

Type flag for arrays. See svtype.

SVt_PVCV

Type flag for code refs. See svtype.

SVt_PVHV

Type flag for hashes. See svtype.

SVt_PVMG

Type flag for blessed scalars. See svtype.

SVt_NV

Double type flag for scalars. See svtype.

SvTRUE

Returns a boolean indicating whether Perl would evaluate the SV as true or false, defined or undefined.

int SvTRUE (SV* sv)
SvTYPE

Returns the type of the SV. See svtype.

svtype	SvTYPE (SV* sv)
svtype

An enum of flags for Perl types. These are found in the file sv.h in the svtype enum. Test these flags with the SvTYPE macro.

SvUPGRADE

Used to upgrade an SV to a more complex form. Uses sv_upgrade to perform the upgrade if necessary. See svtype.

bool    SvUPGRADE _((SV* sv, svtype mt));
sv_upgrade

Upgrade an SV to a more complex form. Use SvUPGRADE. See svtype.

sv_undef

This is the undef SV. Always refer to this as &sv_undef.

sv_unref

Unsets the RV status of the SV, and decrements the reference count of whatever was being referenced by the RV. This can almost be thought of as a reversal of newSVrv. See SvROK_off.

void    sv_unref _((SV* sv));
sv_usepvn

Tells an SV to use ptr to find its string value. Normally the string is stored inside the SV but sv_usepvn allows the SV to use an outside string. The ptr should point to memory that was allocated by malloc. The string length, len, must be supplied. This function will realloc the memory pointed to by ptr, so that pointer should not be freed or used by the programmer after giving it to sv_usepvn.

void	sv_usepvn _((SV* sv, char* ptr, STRLEN len));
sv_yes

This is the true SV. See sv_no. Always refer to this as &sv_yes.

THIS

Variable which is setup by xsubpp to designate the object in a C++ XSUB. This is always the proper type for the C++ object. See CLASS and "Using XS With C++" in perlxs.

toLOWER

Converts the specified character to lowercase.

int toLOWER (char c)
toUPPER

Converts the specified character to uppercase.

int toUPPER (char c)
warn

This is the XSUB-writer's interface to Perl's warn function. Use this function the same way you use the C printf function. See croak().

XPUSHi

Push an integer onto the stack, extending the stack if necessary. See PUSHi.

XPUSHi(int d)
XPUSHn

Push a double onto the stack, extending the stack if necessary. See PUSHn.

XPUSHn(double d)
XPUSHp

Push a string onto the stack, extending the stack if necessary. The len indicates the length of the string. See PUSHp.

XPUSHp(char *c, int len)
XPUSHs

Push an SV onto the stack, extending the stack if necessary. See PUSHs.

XPUSHs(sv)
XS

Macro to declare an XSUB and its C parameter list. This is handled by xsubpp.

XSRETURN

Return from XSUB, indicating number of items on the stack. This is usually handled by xsubpp.

XSRETURN(int x);
XSRETURN_EMPTY

Return an empty list from an XSUB immediately.

XSRETURN_EMPTY;
XSRETURN_IV

Return an integer from an XSUB immediately. Uses XST_mIV.

XSRETURN_IV(IV v);
XSRETURN_NO

Return &sv_no from an XSUB immediately. Uses XST_mNO.

XSRETURN_NO;
XSRETURN_NV

Return an double from an XSUB immediately. Uses XST_mNV.

XSRETURN_NV(NV v);
XSRETURN_PV

Return a copy of a string from an XSUB immediately. Uses XST_mPV.

XSRETURN_PV(char *v);
XSRETURN_UNDEF

Return &sv_undef from an XSUB immediately. Uses XST_mUNDEF.

XSRETURN_UNDEF;
XSRETURN_YES

Return &sv_yes from an XSUB immediately. Uses XST_mYES.

XSRETURN_YES;
XST_mIV

Place an integer into the specified position i on the stack. The value is stored in a new mortal SV.

XST_mIV( int i, IV v );
XST_mNV

Place a double into the specified position i on the stack. The value is stored in a new mortal SV.

XST_mNV( int i, NV v );
XST_mNO

Place &sv_no into the specified position i on the stack.

XST_mNO( int i );
XST_mPV

Place a copy of a string into the specified position i on the stack. The value is stored in a new mortal SV.

XST_mPV( int i, char *v );
XST_mUNDEF

Place &sv_undef into the specified position i on the stack.

XST_mUNDEF( int i );
XST_mYES

Place &sv_yes into the specified position i on the stack.

XST_mYES( int i );
XS_VERSION

The version identifier for an XS module. This is usually handled automatically by ExtUtils::MakeMaker. See XS_VERSION_BOOTCHECK.

XS_VERSION_BOOTCHECK

Macro to verify that a PM module's $VERSION variable matches the XS module's XS_VERSION variable. This is usually handled automatically by xsubpp. See "The VERSIONCHECK: Keyword" in perlxs.

Zero

The XSUB-writer's interface to the C memzero function. The d is the destination, n is the number of items, and t is the type.

(void) Zero( d, n, t );

EDITOR

Jeff Okamoto <okamoto@corp.hp.com>

With lots of help and suggestions from Dean Roehrich, Malcolm Beattie, Andreas Koenig, Paul Hudson, Ilya Zakharevich, Paul Marquess, Neil Bowers, Matthew Green, Tim Bunce, Spider Boardman, Ulrich Pfeifer, and Stephen McCamant.

API Listing by Dean Roehrich <roehrich@cray.com>.

DATE

Version 31.8: 1997/5/17