pmc.c

/*
Copyright (C) 2001-2011, Parrot Foundation.

=head1 NAME

src/pmc.c

=head1 DESCRIPTION

The base vtable calling functions

=head1 FUNCTIONS

=over 4

=cut

*/

#include "parrot/parrot.h"
#include "pmc.str"
#include "pmc/pmc_class.h"
#include "pmc/pmc_integer.h"
#include "pmc/pmc_callcontext.h"

/* HEADERIZER HFILE: include/parrot/pmc.h */

/* HEADERIZER BEGIN: static */
/* Don't modify between HEADERIZER BEGIN / HEADERIZER END.  Your changes will be lost. */

PARROT_WARN_UNUSED_RESULT
PARROT_CAN_RETURN_NULL
static PMC* check_get_std_props(PARROT_INTERP,
    ARGIN(const PMC *self),
    ARGIN(const STRING *key))
        __attribute__nonnull__(1)
        __attribute__nonnull__(2)
        __attribute__nonnull__(3);

static void check_pmc_reuse_flags(PARROT_INTERP,
    UINTVAL srcflags,
    UINTVAL destflags)
        __attribute__nonnull__(1);

PARROT_WARN_UNUSED_RESULT
static INTVAL check_set_std_props(PARROT_INTERP,
    ARGMOD(PMC *pmc),
    ARGIN(const STRING *key),
    ARGMOD(PMC *value))
        __attribute__nonnull__(1)
        __attribute__nonnull__(2)
        __attribute__nonnull__(3)
        __attribute__nonnull__(4)
        FUNC_MODIFIES(*pmc)
        FUNC_MODIFIES(*value);

PARROT_WARN_UNUSED_RESULT
PARROT_CANNOT_RETURN_NULL
static PMC * create_class_pmc(PARROT_INTERP, INTVAL type)
        __attribute__nonnull__(1);

PARROT_WARN_UNUSED_RESULT
PARROT_CANNOT_RETURN_NULL
static PMC * get_new_pmc_header(PARROT_INTERP,
    INTVAL base_type,
    UINTVAL flags)
        __attribute__nonnull__(1);

PARROT_WARN_UNUSED_RESULT
static INTVAL has_pending_std_props(ARGIN(const PMC *self))
        __attribute__nonnull__(1);

PARROT_CANNOT_RETURN_NULL
PARROT_WARN_UNUSED_RESULT
static PMC* make_prop_hash(PARROT_INTERP, ARGMOD(PMC *self))
        __attribute__nonnull__(1)
        __attribute__nonnull__(2)
        FUNC_MODIFIES(*self);

PARROT_CANNOT_RETURN_NULL
PARROT_WARN_UNUSED_RESULT
static PMC* Parrot_pmc_reuse_noinit(PARROT_INTERP,
    ARGMOD(PMC *pmc),
    INTVAL new_type)
        __attribute__nonnull__(1)
        __attribute__nonnull__(2)
        FUNC_MODIFIES(*pmc);

static void propagate_std_props(PARROT_INTERP,
    ARGIN(PMC *self),
    ARGIN(PMC *prop_hash))
        __attribute__nonnull__(1)
        __attribute__nonnull__(2)
        __attribute__nonnull__(3);

#define ASSERT_ARGS_check_get_std_props __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp) \
    , PARROT_ASSERT_ARG(self) \
    , PARROT_ASSERT_ARG(key))
#define ASSERT_ARGS_check_pmc_reuse_flags __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp))
#define ASSERT_ARGS_check_set_std_props __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp) \
    , PARROT_ASSERT_ARG(pmc) \
    , PARROT_ASSERT_ARG(key) \
    , PARROT_ASSERT_ARG(value))
#define ASSERT_ARGS_create_class_pmc __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp))
#define ASSERT_ARGS_get_new_pmc_header __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp))
#define ASSERT_ARGS_has_pending_std_props __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(self))
#define ASSERT_ARGS_make_prop_hash __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp) \
    , PARROT_ASSERT_ARG(self))
#define ASSERT_ARGS_Parrot_pmc_reuse_noinit __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp) \
    , PARROT_ASSERT_ARG(pmc))
#define ASSERT_ARGS_propagate_std_props __attribute__unused__ int _ASSERT_ARGS_CHECK = (\
       PARROT_ASSERT_ARG(interp) \
    , PARROT_ASSERT_ARG(self) \
    , PARROT_ASSERT_ARG(prop_hash))
/* Don't modify between HEADERIZER BEGIN / HEADERIZER END.  Your changes will be lost. */
/* HEADERIZER END: static */


PMC * PMCNULL;

/*

=item C<INTVAL Parrot_pmc_is_null(PARROT_INTERP, const PMC *pmc)>

Tests if the given pmc is null.

=cut

*/

PARROT_EXPORT
PARROT_PURE_FUNCTION
PARROT_WARN_UNUSED_RESULT
PARROT_HOT
INTVAL
Parrot_pmc_is_null(SHIM_INTERP, ARGIN_NULLOK(const PMC *pmc))
{
    ASSERT_ARGS(Parrot_pmc_is_null)
    return (pmc == PMCNULL) || (pmc == NULL);
}

/*

=item C<void Parrot_pmc_destroy(PARROT_INTERP, PMC *pmc)>

Destroy a PMC. Call his destroy vtable function if needed, and deallocate
his attributes if they are automatically allocated.

For internal usage of the PMC handling functions and garbage collection
subsystem.

=cut

*/

PARROT_EXPORT
void
Parrot_pmc_destroy(PARROT_INTERP, ARGMOD(PMC *pmc))
{
    ASSERT_ARGS(Parrot_pmc_destroy)

    if (PObj_custom_destroy_TEST(pmc))
        VTABLE_destroy(interp, pmc);

    PObj_gc_CLEAR(pmc);

    if (pmc->vtable->attr_size && PMC_data(pmc))
        Parrot_gc_free_pmc_attributes(interp, pmc);
    else
        PMC_data(pmc) = NULL;

#ifndef NDEBUG

    pmc->data = (DPOINTER *)0xdeadbeef;

#endif

}

/*

=item C<PMC * Parrot_pmc_new(PARROT_INTERP, INTVAL base_type)>

Creates a new PMC of type C<base_type> (which is an index into the list of PMC
types declared in C<vtables> in F<include/parrot/pmc.h>). Once the PMC has been
successfully created and its vtable pointer initialized, we call its C<init>
method to perform any other necessary initialization.

=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PARROT_WARN_UNUSED_RESULT
PMC *
Parrot_pmc_new(PARROT_INTERP, INTVAL base_type)
{
    ASSERT_ARGS(Parrot_pmc_new)
    PARROT_ASSERT(interp->n_vtable_max > base_type);
    PARROT_ASSERT(interp->vtables[base_type]);
    {
        PMC *const classobj = interp->vtables[base_type]->pmc_class;

        if (!PMC_IS_NULL(classobj) && PObj_is_class_TEST(classobj))
            return VTABLE_instantiate(interp, classobj, PMCNULL);
        else {
            PMC * const pmc = get_new_pmc_header(interp, base_type, 0);
            VTABLE_init(interp, pmc);
            return pmc;
        }
    }
}

/*

=item C<PMC * Parrot_pmc_new_from_type(PARROT_INTERP, PMC *key)>

Creates a new PMC of type C<key>. You probably do not want this function as
it is only used by a few experimental opcodes. See C<Parrot_pmc_new()> instead.

=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PARROT_WARN_UNUSED_RESULT
PMC *
Parrot_pmc_new_from_type(PARROT_INTERP, ARGIN(PMC *key))
{
    ASSERT_ARGS(Parrot_pmc_new_from_type)

    PMC *pmc;
    PMC *const classobj = Parrot_oo_get_class(interp, key);

    if (!PMC_IS_NULL(classobj))
        pmc = VTABLE_instantiate(interp, classobj, PMCNULL);
    else {
        const INTVAL type = Parrot_pmc_get_type(interp, key);

        if (type <= 0) {
            Parrot_ex_throw_from_c_args(interp, NULL,
                EXCEPTION_NO_CLASS, "Class '%Ss' not found",
                VTABLE_get_repr(interp, key));
        }

        pmc = Parrot_pmc_new(interp, type);
    }

    return pmc;
}

/*

=item C<PMC * Parrot_pmc_reuse(PARROT_INTERP, PMC *pmc, INTVAL new_type, UINTVAL
flags)>

Reuse an existing PMC, turning it into an empty PMC of the new type. Any
required internal structure will be put in place (such as the extension area)
and the PMC will be ready to go.

Cannot currently handle converting a non-Object PMC into an Object. Use
C<pmc_reuse_by_class> for that.


=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PARROT_IGNORABLE_RESULT
PMC *
Parrot_pmc_reuse(PARROT_INTERP, ARGMOD(PMC *pmc), INTVAL new_type, SHIM(UINTVAL flags))
{
    ASSERT_ARGS(Parrot_pmc_reuse)
    pmc = Parrot_pmc_reuse_noinit(interp, pmc, new_type);

    /* Call the base init for the redone pmc. Warning, this should not
       be called on Object PMCs. */
    VTABLE_init(interp, pmc);

    return pmc;
}

/*

=item C<PMC * Parrot_pmc_reuse_init(PARROT_INTERP, PMC *pmc, INTVAL new_type,
PMC *init, UINTVAL flags)>

Reuse an existing PMC, turning it into an PMC of the new type. Any
required internal structure will be put in place (such as the extension area)
and the PMC will be inited.

Cannot currently handle converting a non-Object PMC into an Object. Use
C<pmc_reuse_by_class> for that.


=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PARROT_IGNORABLE_RESULT
PMC *
Parrot_pmc_reuse_init(PARROT_INTERP, ARGMOD(PMC *pmc), INTVAL new_type, ARGIN(PMC *init),
          SHIM(UINTVAL flags))
{
    ASSERT_ARGS(Parrot_pmc_reuse_init)
    pmc = Parrot_pmc_reuse_noinit(interp, pmc, new_type);

    /* Call the base init for the redone pmc. Warning, this should not
       be called on Object PMCs. */
    VTABLE_init_pmc(interp, pmc, init);

    return pmc;
}

/*

=item C<static PMC* Parrot_pmc_reuse_noinit(PARROT_INTERP, PMC *pmc, INTVAL
new_type)>

Prepare pmc for reuse. Do all scuffolding except initing.

=cut

*/

PARROT_CANNOT_RETURN_NULL
PARROT_WARN_UNUSED_RESULT
static PMC*
Parrot_pmc_reuse_noinit(PARROT_INTERP, ARGMOD(PMC *pmc), INTVAL new_type)
{
    ASSERT_ARGS(Parrot_pmc_reuse_noinit)

    if (pmc->vtable->base_type != new_type) {
        const Parrot_UInt gc_flags = pmc->flags & PObj_GC_all_FLAGS;
        VTABLE * const new_vtable  = interp->vtables[new_type];

        /* Singleton/const PMCs/types are not eligible */
        check_pmc_reuse_flags(interp, pmc->vtable->flags, new_vtable->flags);

        /* Free the old PMC resources. */
        Parrot_pmc_destroy(interp, pmc);

        /*
         * We can reuse PMC from older generation. Preserve and soil it.
         *
         * FIXME It's abstraction leak. And it's really strange idea of reusing
         * PMCs...
         */
        PObj_flags_SETTO(pmc, PObj_is_PMC_FLAG | gc_flags);
        PARROT_GC_WRITE_BARRIER(interp, pmc);

        /* Set the right vtable */
        pmc->vtable = new_vtable;

        if (new_vtable->attr_size)
            Parrot_gc_allocate_pmc_attributes(interp, pmc);
        else
            PMC_data(pmc) = NULL;
    }

    return pmc;
}

/*

=item C<PMC * Parrot_pmc_reuse_by_class(PARROT_INTERP, PMC *pmc, PMC *class_,
UINTVAL flags)>

Reuse an existing PMC. Convert it to the type specified by the given Class
PMC. At the moment, this means we can only use this function to reuse PMCs
into types with Classes (not built-in PMCs). Use C<pmc_reuse> if you need
to convert to a built-in PMC type.

=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PARROT_IGNORABLE_RESULT
PMC *
Parrot_pmc_reuse_by_class(PARROT_INTERP, ARGMOD(PMC *pmc), ARGIN(PMC *class_), UINTVAL flags)
{
    ASSERT_ARGS(Parrot_pmc_reuse_by_class)
    const INTVAL   new_type   = PARROT_CLASS(class_)->id;

    if (pmc->vtable->base_type != new_type) {
        VTABLE * const new_vtable = interp->vtables[new_type];

        /* Singleton/const PMCs/types are not eligible */
        check_pmc_reuse_flags(interp, pmc->vtable->flags, new_vtable->flags);

        Parrot_pmc_destroy(interp, pmc);

        PObj_flags_SETTO(pmc, PObj_is_PMC_FLAG | flags);

        /* Set the right vtable */
        pmc->vtable = new_vtable;

        if (new_vtable->attr_size)
            Parrot_gc_allocate_pmc_attributes(interp, pmc);
        else
            PMC_data(pmc) = NULL;
    }

    return pmc;
}

/*

=item C<Parrot_PMC Parrot_pmc_null(void)>

Returns the special C<NULL> PMC.

=cut

*/

PARROT_EXPORT
PARROT_PURE_FUNCTION
PARROT_CAN_RETURN_NULL
Parrot_PMC
Parrot_pmc_null(void)
{
    ASSERT_ARGS(Parrot_pmc_null)
    return PMCNULL;
}

/*

=item C<static void check_pmc_reuse_flags(PARROT_INTERP, UINTVAL srcflags,
UINTVAL destflags)>

We're converting one PMC type to another, either in C<pmc_reuse> or
C<pmc_reuse_by_class>. Check to make sure that neither the existing PMC
or the intended target PMC type are singletons or constants. We throw an
exception if we are attempting an illegal operation.

=cut

*/

static void
check_pmc_reuse_flags(PARROT_INTERP, UINTVAL srcflags, UINTVAL destflags)
{
    ASSERT_ARGS(check_pmc_reuse_flags)
    if ((srcflags | destflags) & (VTABLE_PMC_IS_SINGLETON | VTABLE_IS_CONST_FLAG))
    {
        /* First, is the destination a singleton? No joy for us there */
        if (destflags & VTABLE_PMC_IS_SINGLETON)
            Parrot_ex_throw_from_c_args(interp, NULL,
                EXCEPTION_ALLOCATION_ERROR,
                "Parrot VM: Can't turn to a singleton type!\n");

        /* Is the destination a constant? No joy for us there */
        if (destflags & VTABLE_IS_CONST_FLAG)
            Parrot_ex_throw_from_c_args(interp, NULL,
                EXCEPTION_ALLOCATION_ERROR,
                "Parrot VM: Can't turn to a constant type!\n");

        /* Is the source a singleton? */
        if (srcflags & VTABLE_PMC_IS_SINGLETON)
            Parrot_ex_throw_from_c_args(interp, NULL,
                EXCEPTION_ALLOCATION_ERROR,
                "Parrot VM: Can't modify a singleton\n");

        /* Is the source constant? */
        if (srcflags & VTABLE_IS_CONST_FLAG)
            Parrot_ex_throw_from_c_args(interp, NULL,
                EXCEPTION_ALLOCATION_ERROR,
                "Parrot VM: Can't modify a constant\n");
    }
}

/*

=item C<static PMC * get_new_pmc_header(PARROT_INTERP, INTVAL base_type, UINTVAL
flags)>

Gets a new PMC header of the given integer type. Initialize the pmc if
necessary. In the case of singleton PMC types, get the existing singleton
instead of allocating a new one.

=cut

*/

PARROT_WARN_UNUSED_RESULT
PARROT_CANNOT_RETURN_NULL
static PMC *
get_new_pmc_header(PARROT_INTERP, INTVAL base_type, UINTVAL flags)
{
    ASSERT_ARGS(get_new_pmc_header)
    PMC    *newpmc;
    VTABLE *vtable = interp->vtables[base_type];
    UINTVAL vtable_flags;

    /* This is usually because you either didn't call init_world early enough,
     * you added a new PMC class without adding Parrot_(classname)_class_init
     * to init_world, or you forgot to run 'make realclean' after adding a new
     * PMC class.  */
    if (!vtable)
        PANIC(interp, "Null vtable used; did you add a new PMC?");

    vtable_flags = vtable->flags;

    /* we only have one global Env object, living in the interp */
    if (vtable_flags & VTABLE_PMC_IS_SINGLETON) {
        /*
         * singletons (monadic objects) exist only once
         * the interface * with the class is:
         * - get_pointer: return NULL or a pointer to the single instance
         * - set_pointer: set the only instance once
         *
         * - singletons are created in the constant pmc pool
         */
        PMC *pmc = (PMC *)(vtable->get_pointer)(interp, NULL);

        /* LOCK */
        if (!pmc) {
            pmc = Parrot_gc_new_pmc_header(interp, PObj_constant_FLAG);
            PARROT_ASSERT(pmc);

            pmc->vtable    = vtable;
            VTABLE_set_pointer(interp, pmc, pmc);
        }

        return pmc;
    }

    if (vtable_flags & VTABLE_IS_CONST_PMC_FLAG)
        flags |= PObj_constant_FLAG;
    else if (vtable_flags & VTABLE_IS_CONST_FLAG) {
        /* put the normal vtable in, so that the pmc can be initialized first
         * parrot or user code has to set the _ro property then,
         * to morph the PMC to the const variant
         * This assumes that a constant PMC enum is one bigger then
         * the normal one.
         */

        /*
         * XXX not yet we can't assure that all contents in the
         * const PMC is const too
         * see e.g. t/pmc/sarray_13.pir
         */
        --base_type;
        vtable = interp->vtables[base_type];
    }

    if (vtable_flags & VTABLE_IS_SHARED_FLAG)
        flags |= PObj_is_PMC_shared_FLAG;

    newpmc         = Parrot_gc_new_pmc_header(interp, flags);
    newpmc->vtable = vtable;

    if (vtable->attr_size)
        Parrot_gc_allocate_pmc_attributes(interp, newpmc);

    return newpmc;
}


/*

=item C<PMC * Parrot_pmc_new_noinit(PARROT_INTERP, INTVAL base_type)>

Creates a new PMC of type C<base_type> (which is an index into the list of PMC
types declared in C<vtables> in F<include/parrot/pmc.h>). Unlike C<Parrot_pmc_new()>,
C<Parrot_pmc_new_noinit()> does not call its C<init> method.  This allows separate
allocation and initialization for continuations.

=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PMC *
Parrot_pmc_new_noinit(PARROT_INTERP, INTVAL base_type)
{
    ASSERT_ARGS(Parrot_pmc_new_noinit)
    PMC *const classobj = interp->vtables[base_type]->pmc_class;

    if (!PMC_IS_NULL(classobj) && PObj_is_class_TEST(classobj))
        return VTABLE_instantiate(interp, classobj, PMCNULL);

    return get_new_pmc_header(interp, base_type, 0);
}


/*

=item C<PMC * Parrot_pmc_new_init(PARROT_INTERP, INTVAL base_type, PMC *init)>

As C<Parrot_pmc_new()>, but passes C<init> to the PMC's C<init_pmc()> vtable entry.

=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PMC *
Parrot_pmc_new_init(PARROT_INTERP, INTVAL base_type, ARGOUT(PMC *init))
{
    ASSERT_ARGS(Parrot_pmc_new_init)
    PMC *const classobj = interp->vtables[base_type]->pmc_class;

    if (!PMC_IS_NULL(classobj) && PObj_is_class_TEST(classobj))
        return VTABLE_instantiate(interp, classobj, init);
    else {
        PMC * const pmc = get_new_pmc_header(interp, base_type, 0);
        VTABLE_init_pmc(interp, pmc, init);
        return pmc;
    }
}


/*

=item C<PMC * Parrot_pmc_new_init_int(PARROT_INTERP, INTVAL base_type, INTVAL
init)>

As C<Parrot_pmc_new()>, but passes C<init> to the PMC's C<init_int()> vtable entry.

=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PMC *
Parrot_pmc_new_init_int(PARROT_INTERP, INTVAL base_type, INTVAL init)
{
    ASSERT_ARGS(Parrot_pmc_new_init_int)
    PMC *const classobj = interp->vtables[base_type]->pmc_class;

    if (!PMC_IS_NULL(classobj) && PObj_is_class_TEST(classobj)) {
        PMC * const obj = VTABLE_instantiate(interp, classobj, PMCNULL);
        VTABLE_set_integer_native(interp, obj, init);
        return obj;
    }
    else {
        PMC * const pmc = get_new_pmc_header(interp, base_type, 0);
        VTABLE_init_int(interp, pmc, init);
        return pmc;
    }
}


/*

=item C<PMC * Parrot_pmc_new_temporary(PARROT_INTERP, INTVAL base_type)>

Creates a new temporary PMC of type C<base_type>, then call C<init>. Cannot
be used to create PMC Objects which have been defined from PIR.

B<You> are responsible for freeing this PMC when it goes out of scope with
C<Parrot_pmc_free_temporary()>.  B<Do not> store this PMC in any other PMCs, or
allow it to be stored.  B<Do not> store any regular PMC in this PMC, or
allow the storage of any regular PMC in this PMC. Temporary PMCs do not
participate in garbage collection, and mixing them with PMCs that are
garbage-collected will cause bugs.

If you don't know what this means, or you can't tell if either case
will happen as the result of any call you make on or with this PMC,
B<DO NOT> use this function, lest you cause weird crashes and memory errors.
Use C<Parrot_pmc_new()> instead.

(Why do these functions even exist?  Used judiciously, they can reduce GC
pressure in hotspots tremendously.  If you haven't audited the code carefully
-- including profiling and benchmarking -- then use C<Parrot_pmc_new()> instead, and
never B<ever> add C<PARROT_EXPORT> to either function.)

=cut

*/

PARROT_CANNOT_RETURN_NULL
PMC *
Parrot_pmc_new_temporary(PARROT_INTERP, INTVAL base_type)
{
    ASSERT_ARGS(Parrot_pmc_new_temporary)
    PMC * const pmc = get_new_pmc_header(interp, base_type, PObj_constant_FLAG);
    VTABLE_init(interp, pmc);
    return pmc;
}


/*

=item C<void Parrot_pmc_free_temporary(PARROT_INTERP, PMC *pmc)>

Frees a new temporary PMC created by C<temporary_Parrot_pmc_new()>.  Do not call
this with any other type of PMC.  Do not forget to call this (or you'll leak
PMCs). Read and I<understand> the warnings for C<temporary_Parrot_pmc_new()> before
you're tempted to use this.

=cut

*/

void
Parrot_pmc_free_temporary(PARROT_INTERP, ARGMOD(PMC *pmc))
{
    ASSERT_ARGS(Parrot_pmc_free_temporary)
    Parrot_gc_free_pmc_header(interp, pmc);
}


/*

=item C<INTVAL Parrot_pmc_get_new_vtable_index(PARROT_INTERP)>

Get a new unique identifier number and allocate a new vtable structure for a
new PMC type.

=cut

*/

INTVAL
Parrot_pmc_get_new_vtable_index(PARROT_INTERP)
{
    ASSERT_ARGS(Parrot_pmc_get_new_vtable_index)
    const INTVAL type_id = interp->n_vtable_max++;

    /* Have we overflowed the table? */
    if (type_id >= interp->n_vtable_alloced)
        Parrot_vtbl_realloc_vtables(interp);

    return type_id;
}

/*

=item C<INTVAL Parrot_pmc_register_new_type(PARROT_INTERP, STRING *name)>

Registers the name of a new PMC type with Parrot, returning the INTVAL
representing that type.

=cut

*/

PARROT_EXPORT
INTVAL
Parrot_pmc_register_new_type(PARROT_INTERP, ARGIN(STRING *name))
{
    ASSERT_ARGS(Parrot_pmc_register_new_type)
    /* If they're looking to register an existing class, return that
       class' type number */
    INTVAL type = Parrot_pmc_get_type_str(interp, name);

    if (type > enum_type_undef)
        return type;

    if (type < enum_type_undef)
        Parrot_ex_throw_from_c_args(interp, NULL, 1,
            "undefined type already exists - can't register PMC");

    type = Parrot_pmc_get_new_vtable_index(interp);

    /* set entry in name->type hash */
    VTABLE_set_integer_keyed_str(interp, interp->class_hash, name, type);

    return type;
}


/*

=item C<INTVAL Parrot_pmc_get_type_str(PARROT_INTERP, STRING *name)>

Returns the PMC type for C<name>.

=cut

*/

PARROT_EXPORT
PARROT_WARN_UNUSED_RESULT
INTVAL
Parrot_pmc_get_type_str(PARROT_INTERP, ARGIN_NULLOK(STRING *name))
{
    ASSERT_ARGS(Parrot_pmc_get_type_str)
    if (STRING_IS_NULL(name))
        return enum_type_undef;
    else {
        PMC * const classname_hash = interp->class_hash;
        PMC * const item           =
            (PMC *)VTABLE_get_pointer_keyed_str(interp, classname_hash, name);

        if (!PMC_IS_NULL(item)) {
            /* nested namespace with same name */
            if (PMC_IS_TYPE(item, NameSpace))
                return enum_type_undef;
            else
                return PARROT_INTEGER(item)->iv;
        }
        else
            return -Parrot_dt_get_datatype_enum(interp, name);
    }
}


/*

=item C<PMC * Parrot_pmc_box_string(PARROT_INTERP, STRING *string)>

Boxes a STRING C<string> into a String PMC.

=cut

*/

PARROT_EXPORT
PARROT_HOT
PARROT_CANNOT_RETURN_NULL
PMC *
Parrot_pmc_box_string(PARROT_INTERP, ARGIN_NULLOK(STRING *string))
{
    ASSERT_ARGS(Parrot_pmc_box_string)
    PMC * const ret = Parrot_pmc_new(interp,
                        Parrot_hll_get_ctx_HLL_type(interp, enum_class_String));
    VTABLE_set_string_native(interp, ret, string);

    return ret;
}


/*

=item C<PMC* Parrot_pmc_box_number(PARROT_INTERP, FLOATVAL value)>

Lookup the PMC type which is used for floating point numbers.

=cut

*/

PARROT_EXPORT
PARROT_HOT
PARROT_CANNOT_RETURN_NULL
PMC*
Parrot_pmc_box_number(PARROT_INTERP, FLOATVAL value)
{
    ASSERT_ARGS(Parrot_pmc_box_number)
    PMC * const ret = Parrot_pmc_new(interp,
                                     Parrot_hll_get_ctx_HLL_type(interp, enum_class_Float));
    VTABLE_set_number_native(interp, ret, value);
    return ret;
}


/*

=item C<PMC* Parrot_pmc_box_integer(PARROT_INTERP, INTVAL value)>

Lookup the PMC type which is used for storing native integers.

=cut

*/

PARROT_EXPORT
PARROT_HOT
PARROT_CANNOT_RETURN_NULL
PMC*
Parrot_pmc_box_integer(PARROT_INTERP, INTVAL value)
{
    ASSERT_ARGS(Parrot_pmc_box_integer)
    PMC * const ret = Parrot_pmc_new(interp,
                                     Parrot_hll_get_ctx_HLL_type(interp, enum_class_Integer));
    VTABLE_set_integer_native(interp, ret, value);
    return ret;
}

/*

=item C<PMC * Parrot_pmc_box_c_string_array(PARROT_INTERP, int count, const char
**s)>

Take a C string array and a count, and box it into a string array PMC

=cut

*/

PARROT_EXPORT
PARROT_CANNOT_RETURN_NULL
PMC *
Parrot_pmc_box_c_string_array(PARROT_INTERP, int count, ARGIN(const char **s))
{
    ASSERT_ARGS(Parrot_pmc_box_c_string_array)
    PMC * const s_pmc = Parrot_pmc_new(interp, enum_class_ResizableStringArray);

    if (s != NULL && count > 0) {
        Parrot_Int i = 0;
        for (; i < count; ++i) {
            /* Run through argv, adding everything to the array */
            STRING * const item = Parrot_str_from_platform_cstring(interp, s[i]);
            VTABLE_push_string(interp, s_pmc, item);
        }
    }
    return s_pmc;
}


/*

=item C<INTVAL Parrot_pmc_get_type(PARROT_INTERP, PMC *name)>

Returns the PMC type for C<name>.

=cut

*/

PARROT_EXPORT
INTVAL
Parrot_pmc_get_type(PARROT_INTERP, ARGIN(PMC *name))
{
    ASSERT_ARGS(Parrot_pmc_get_type)
    PMC * const classname_hash = interp->class_hash;
    PMC * const item = (PMC *)VTABLE_get_pointer_keyed(interp, classname_hash, name);

    if (!PMC_IS_NULL(item))
        return VTABLE_get_integer(interp, item);

    return 0;
}


/*

=item C<static PMC * create_class_pmc(PARROT_INTERP, INTVAL type)>

Create a class object for this interpreter.  Takes an interpreter name and type
as arguments.  Returns a pointer to the class object.

=cut

*/

PARROT_WARN_UNUSED_RESULT
PARROT_CANNOT_RETURN_NULL
static PMC *
create_class_pmc(PARROT_INTERP, INTVAL type)
{
    ASSERT_ARGS(create_class_pmc)
    /*
     * class interface - a PMC is its own class
     * put an instance of this PMC into class
     *
     * create a constant PMC
     */
    PMC * const _class = get_new_pmc_header(interp, type,
                                           PObj_constant_FLAG);

    /* If we are a second thread, we may get the same object as the
     * original because we have a singleton. Just set the singleton to
     * be our class object, but don't mess with its vtable.  */
    if ((interp->vtables[type]->flags & VTABLE_PMC_IS_SINGLETON)
    &&  (_class == _class->vtable->pmc_class))
        interp->vtables[type]->pmc_class = _class;
    else {
        PObj_is_PMC_shared_CLEAR(_class);
        interp->vtables[type]->pmc_class = _class;
    }

    return _class;
}


/*

=item C<void Parrot_pmc_create_mro(PARROT_INTERP, INTVAL type)>

Create the MRO (method resolution order) array for this type.

=cut

*/

PARROT_EXPORT
void
Parrot_pmc_create_mro(PARROT_INTERP, INTVAL type)
{
    ASSERT_ARGS(Parrot_pmc_create_mro)
    PMC    *mro;
    VTABLE *vtable   = interp->vtables[type];
    PMC    * const mro_list = vtable->mro;
    INTVAL  i, count;

    /* this should never be PMCNULL */
    PARROT_ASSERT(!PMC_IS_NULL(mro_list));

    /* multithreaded: has already mro */
    if (mro_list->vtable->base_type != enum_class_ResizableStringArray)
        return;

    mro         = Parrot_pmc_new(interp, enum_class_ResizablePMCArray);
    vtable->mro = mro;

    if (vtable->ro_variant_vtable)
        vtable->ro_variant_vtable->mro = mro;

    count = VTABLE_elements(interp, mro_list);

    for (i = 0; i < count; ++i) {
        STRING * const class_name = VTABLE_get_string_keyed_int(interp, mro_list, i);
        const INTVAL parent_type  = Parrot_pmc_get_type_str(interp, class_name);
        PMC *_class;

        /* abstract classes don't have a vtable */
        if (!parent_type)
            break;

        vtable = interp->vtables[parent_type];

        if (!vtable->_namespace) {
            /* need a namespace Hash, anchor at parent, name it */
            PMC * const ns     = Parrot_pmc_new(interp,
                    Parrot_hll_get_ctx_HLL_type(interp, enum_class_NameSpace));
            vtable->_namespace = ns;

            /* anchor at parent, aka current_namespace, that is 'parrot' */
            VTABLE_set_pmc_keyed_str(interp,
                    Parrot_pcc_get_namespace(interp, CURRENT_CONTEXT(interp)), class_name, ns);
        }

        _class = vtable->pmc_class;
        if (!_class)
            _class = create_class_pmc(interp, parent_type);

        VTABLE_push_pmc(interp, mro, _class);
    }
}


/*

=back

=head2 GC registry interface

=over 4

=item C<void Parrot_pmc_gc_register(PARROT_INTERP, PMC *pmc)>

Registers the PMC with the interpreter's GC registry.

=cut

*/

PARROT_EXPORT
void
Parrot_pmc_gc_register(PARROT_INTERP, ARGIN(PMC *pmc))
{
    ASSERT_ARGS(Parrot_pmc_gc_register)
    /* Better not trigger a GC run with a potentially unanchored PMC */
    Parrot_block_GC_mark(interp);

    PARROT_ASSERT(interp->gc_registry);

    VTABLE_set_pmc_keyed(interp, interp->gc_registry, pmc, PMCNULL);
    Parrot_unblock_GC_mark(interp);
}

/*

=item C<void Parrot_pmc_gc_unregister(PARROT_INTERP, PMC *pmc)>

Unregisters the PMC from the interpreter's GC registry.

=cut

*/

PARROT_EXPORT
void
Parrot_pmc_gc_unregister(PARROT_INTERP, ARGIN(PMC *pmc))
{
    ASSERT_ARGS(Parrot_pmc_gc_unregister)
    PARROT_ASSERT(interp->gc_registry);

    VTABLE_delete_keyed(interp, interp->gc_registry, pmc);
}

/*

=item C<INTVAL Parrot_pmc_type_does(PARROT_INTERP, const STRING *role, INTVAL
type)>

Checks to see if PMCs of the given type does the given role. Checks
C<<vtable->provides_str>> to find a match.
Returns true (1) if B<role> is found, false (0) otherwise.

=cut

*/

INTVAL
Parrot_pmc_type_does(PARROT_INTERP, ARGIN(const STRING *role), INTVAL type)
{
    ASSERT_ARGS(Parrot_pmc_type_does)

    INTVAL pos = 0;
    STRING * const what = interp->vtables[type]->provides_str;
    INTVAL length = Parrot_str_byte_length(interp, what);

    do {
        INTVAL len;
        const INTVAL idx = STRING_index(interp, what, role, pos);

        if ((idx < 0) || (idx >= length))
            return 0;

        pos = idx;
        len = Parrot_str_byte_length(interp, role);

        if (pos && (STRING_ord(interp, what, pos - 1) != 32)) {
            pos += len;
            continue;
        }

        if (pos + len < length) {
            pos += len;
            if (STRING_ord(interp, what, pos) != 32)
                continue;
        }

        return 1;
    } while (1);
}


/*

=item C<PMC * Parrot_pmc_getprop(PARROT_INTERP, PMC *pmc, STRING *key)>

Returns the property for C<*key>. If no property is defined then the
NULL PMC is returned.

=cut

*/

PARROT_EXPORT
PARROT_CAN_RETURN_NULL
PMC *
Parrot_pmc_getprop(PARROT_INTERP, ARGIN(PMC *pmc), ARGIN(STRING *key))
{
    ASSERT_ARGS(Parrot_pmc_getprop)
    if (PMC_IS_NULL(PMC_metadata(pmc)))
        return check_get_std_props(interp, pmc, key);
    else
        return VTABLE_get_pmc_keyed_str(interp, PMC_metadata(pmc), key);
}

/*

=item C<void Parrot_pmc_setprop(PARROT_INTERP, PMC *pmc, STRING *key, PMC
*value)>

Sets the property for C<*key> to C<*value>.

=cut

*/

PARROT_EXPORT
void
Parrot_pmc_setprop(PARROT_INTERP, ARGIN(PMC *pmc), ARGIN(STRING *key), ARGIN(PMC *value))
{
    ASSERT_ARGS(Parrot_pmc_setprop)
    if (check_set_std_props(interp, pmc, key, value))
        return;

    if (PMC_IS_NULL(PMC_metadata(pmc)))
        PMC_metadata(pmc) = make_prop_hash(interp, pmc);

    VTABLE_set_pmc_keyed_str(interp, PMC_metadata(pmc), key, value);
}

/*

=item C<void Parrot_pmc_delprop(PARROT_INTERP, PMC *pmc, STRING *key)>

Deletes the property for C<*key>.

=cut

*/

PARROT_EXPORT
void
Parrot_pmc_delprop(PARROT_INTERP, ARGIN(PMC *pmc), ARGIN(STRING *key))
{
    ASSERT_ARGS(Parrot_pmc_delprop)
    if (!PMC_IS_NULL(PMC_metadata(pmc)))
        VTABLE_delete_keyed_str(interp, PMC_metadata(pmc), key);
}

/*

=item C<PMC * Parrot_pmc_getprops(PARROT_INTERP, PMC *pmc)>

Returns the PMC's properties or the NULL PMC if no properties exist.

=cut

*/

PARROT_EXPORT
PARROT_CAN_RETURN_NULL
PMC *
Parrot_pmc_getprops(PARROT_INTERP, ARGIN(PMC *pmc))
{
    ASSERT_ARGS(Parrot_pmc_getprops)
    if (PMC_IS_NULL(PMC_metadata(pmc))) {
        if (has_pending_std_props(pmc))
            PMC_metadata(pmc) = make_prop_hash(interp, pmc);
        else
            return PMCNULL;
    }

    return PMC_metadata(pmc);
}

/*

=item C<static INTVAL check_set_std_props(PARROT_INTERP, PMC *pmc, const STRING
*key, PMC *value)>

Called from C<setprop()>.

Returns a true value if C<setprop()> can avoid actually setting a property
in the prophash. If it returns true, the property setting will be reflected
in a future call to C<propagate_std_props()>

=cut

*/

PARROT_WARN_UNUSED_RESULT
static INTVAL
check_set_std_props(PARROT_INTERP, ARGMOD(PMC *pmc), ARGIN(const STRING *key), ARGMOD(PMC *value))
{
    ASSERT_ARGS(check_set_std_props)

    /*
     * s2 in STRING_equal is freed here
     */
    if (STRING_equal(interp, key, CONST_STRING(interp, "_ro"))) {
        /* pmc should set/clear readonly */
        const INTVAL on = VTABLE_get_bool(interp, value);

        /* morph to Const/normal class or readonly class */
        if (on && (pmc->vtable->flags & VTABLE_HAS_CONST_TOO))
            pmc->vtable = interp->vtables[pmc->vtable->base_type + 1];
        else if (!on && (pmc->vtable->flags & (VTABLE_IS_CONST_FLAG)))
            VTABLE_morph(interp, pmc, interp->vtables[pmc->vtable->base_type - 1]->pmc_class);
        else if (on && (pmc->vtable->flags & VTABLE_HAS_READONLY_FLAG))
            pmc->vtable = pmc->vtable->ro_variant_vtable;
        else if (!on && (pmc->vtable->flags & VTABLE_IS_READONLY_FLAG)
                && pmc->vtable->ro_variant_vtable)
            pmc->vtable = pmc->vtable->ro_variant_vtable;
        else
            return 0;

        return 1;
    }

    return 0;
}

/*

=item C<static void propagate_std_props(PARROT_INTERP, PMC *self, PMC
*prop_hash)>

Set pending standard properties in C<prop_hash>.

=cut

*/

static void
propagate_std_props(PARROT_INTERP, ARGIN(PMC *self), ARGIN(PMC *prop_hash))
{
    ASSERT_ARGS(propagate_std_props)

    if (self->vtable->flags & (VTABLE_IS_CONST_FLAG | VTABLE_IS_READONLY_FLAG)){
        PMC * const pmc_true  = Parrot_pmc_new_init_int(interp,
                enum_class_Integer, 1);
        VTABLE_set_pmc_keyed_str(interp, prop_hash, CONST_STRING(interp, "_ro"), pmc_true);
    }
}

/*

=item C<static INTVAL has_pending_std_props(const PMC *self)>

Returns true if propagate_std_props() would create a non-empty prophash.

=cut

*/

PARROT_WARN_UNUSED_RESULT
static INTVAL
has_pending_std_props(ARGIN(const PMC *self))
{
    ASSERT_ARGS(has_pending_std_props)

    if (self->vtable->flags & (VTABLE_IS_CONST_FLAG | VTABLE_IS_READONLY_FLAG))
        return 1;
    else
        return 0;
}


/*

=item C<static PMC* check_get_std_props(PARROT_INTERP, const PMC *self, const
STRING *key)>

Checks if we can infer the value of C<key> property from C<self> without
looking at its prophash. Returns C<PMCNULL> if not, returns the value otherwise.

=cut
*/

PARROT_WARN_UNUSED_RESULT
PARROT_CAN_RETURN_NULL
static PMC*
check_get_std_props(PARROT_INTERP, ARGIN(const PMC *self), ARGIN(const STRING *key))
{
    ASSERT_ARGS(check_get_std_props)

    if ((self->vtable->flags & (VTABLE_IS_CONST_FLAG | VTABLE_IS_READONLY_FLAG))
       && STRING_equal(interp, key, CONST_STRING(interp, "_ro"))) {
        PMC * const ret_val = Parrot_pmc_new_init_int(interp,
                enum_class_Integer, 1);
        return ret_val;
    }
    else
        return PMCNULL;
}

/*

=item C<static PMC* make_prop_hash(PARROT_INTERP, PMC *self)>

Create a property hash for C<self>. Returns the created hash. Inferred
properties will be added to the hash.

=cut

*/

PARROT_CANNOT_RETURN_NULL
PARROT_WARN_UNUSED_RESULT
static PMC*
make_prop_hash(PARROT_INTERP, ARGMOD(PMC *self))
{
    ASSERT_ARGS(make_prop_hash)

    PMC * const prop = Parrot_pmc_new(interp, enum_class_Hash);

    propagate_std_props(interp, self, prop);
    PARROT_GC_WRITE_BARRIER(interp, self);
    return prop;
}

/*

=back

=head1 SEE ALSO

F<include/parrot/pmc.h>, F<include/parrot/vtable.h>,
L<http://www.nntp.perl.org/group/perl.perl6.internals/2001/10/msg5516.html>

=cut

*/

/*
 * Local variables:
 *   c-file-style: "parrot"
 * End:
 * vim: expandtab shiftwidth=4 cinoptions='\:2=2' :
 */