parrotinterpreter.pmc

/*
Copyright (C) 2001-2008, The Perl Foundation.
$Id$

=head1 NAME

src/pmc/parrotinterpreter.pmc - Parrot Interpreter

=head1 DESCRIPTION

These are the vtable functions for the ParrotInterpreter base class

   getinterp P0
   set P1, P0[.IGLOBALS_*]  # access interpreter globals
   set I0, P0[x]            # interpinfo I0, x
   set I0, P0[-1]           # get interpreter flags
   set P0[-1], x            # set flags on interpreter
                            # NOTE: this doesn't restart

=head2 Functions

=over 4

=cut

*/

#include "parrot/parrot.h"
#include "parrot/embed.h"
#include "parrot/dynext.h"
#include "pmc_class.h"

/*

=item C<void
clone_interpreter(Parrot_Interp dest, const Parrot_Interp source, INTVAL flags)>

Clones the interpreter as specified by the flags.

=cut

*/

void
clone_interpreter(Parrot_Interp d, Parrot_Interp s, INTVAL flags)
{
    /* we block DOD runs while cloning since C<d> is not yet running */
    Parrot_block_GC_mark(d);

    /* create as constant to avoid order-of-destruction errors, RT #60622 */
    d->scheduler = constant_pmc_new(d, enum_class_Scheduler);
    d->scheduler = VTABLE_share_ro(d, d->scheduler);

    if (flags & PARROT_CLONE_RUNOPS)
        d->run_core = s->run_core;

    if (flags & PARROT_CLONE_INTERP_FLAGS) {
        /* XXX setting of IS_THREAD? */
        d->flags       = s->flags;
        d->debug_flags = s->debug_flags;
    }

    if (flags & PARROT_CLONE_HLL) {
        /* we'd like to share the HLL data. Give it a PMC_sync structure
           if it doesn't have one already */
        add_pmc_sync(s, s->HLL_info);
        d->HLL_info = s->HLL_info;
        Parrot_regenerate_HLL_namespaces(d);
    }

    if (flags & (PARROT_CLONE_LIBRARIES | PARROT_CLONE_CLASSES)) {
        INTVAL i, last_remove;
        const INTVAL start = d->n_vtable_max;

        /* copy type registrations to keep type numbers the same */
        d->class_hash   = Parrot_clone(d, s->class_hash);
        d->n_vtable_max = s->n_vtable_max;

        if (d->n_vtable_max > d->n_vtable_alloced)
            parrot_realloc_vtables(d);

        last_remove = s->n_vtable_max;

        for (i = s->n_vtable_max - 1; i >= start; --i) {
            if (s->vtables[i] && s->vtables[i]->pmc_class &&
                PObj_is_class_TEST(s->vtables[i]->pmc_class)) {
                STRING * const class_name =
                    VTABLE_get_string(s, s->vtables[i]->pmc_class);
                PARROT_ASSERT(VTABLE_exists_keyed_str(d,
                    d->class_hash, class_name));

                VTABLE_delete_keyed_str(d, d->class_hash, class_name);

                if (last_remove == i + 1) {
                    --d->n_vtable_max;
                    last_remove = i;
                }
            }
        }
    }

    if (flags & PARROT_CLONE_LIBRARIES) {
        PMC   * const libs     = VTABLE_get_pmc_keyed_int(s, s->iglobals,
            IGLOBALS_DYN_LIBS);
        PMC   * const lib_iter = VTABLE_get_iter(s, libs);
        const INTVAL n         = VTABLE_elements(s, libs);
        INTVAL i;

        for (i = 0; i < n; ++i) {
            STRING * const key     = VTABLE_shift_string(s, lib_iter);
            PMC    * const lib_pmc = VTABLE_get_pmc_keyed_str(s, libs, key);
            PMC    * const ignored = Parrot_clone_lib_into(d, s, lib_pmc);
            UNUSED(ignored);
        }
    }

    if (flags & PARROT_CLONE_CLASSES) {
        INTVAL i;
        for (i = 0; i < s->n_vtable_max; ++i) {
            if (s->vtables[i] && s->vtables[i]->pmc_class &&
                    PObj_is_class_TEST(s->vtables[i]->pmc_class)) {
                /* Cloning the class into the new interpreter ought
                 * to be sufficient to instantiate the class.  */
                 PMC          *source       = s->vtables[i]->pmc_class;
                 PMC          *dest         = Parrot_clone(d, source);
                 Parrot_Class_attributes *source_class = PARROT_CLASS(source);
                 Parrot_Class_attributes *dest_class   = PARROT_CLASS(dest);
                 dest_class->name           = string_copy(d, source_class->name);
                 dest_class->_namespace     = VTABLE_clone(d, source_class->_namespace);
            }
        }
    }

    if (flags & PARROT_CLONE_CODE)
        pt_clone_code(d, s);

    if (flags & PARROT_CLONE_GLOBALS)
        pt_clone_globals(d, s);

    Parrot_unblock_GC_sweep(d);
}


/*

=item C<static void
create_interp(PMC *self, Parrot_Interp parent)>

Creates a new child interpreter of C<parent>.

=cut

*/

static void
create_interp(PMC *self, Parrot_Interp parent)
{
    Interp_flags flag  = PARROT_NO_FLAGS;
    Parrot_Interp new_interp;

    if (self->vtable->base_type == enum_class_ParrotThread)
        flag = PARROT_IS_THREAD;

    new_interp     = make_interpreter(parent, (INTVAL)flag);
    PMC_data(self) = new_interp;

    VTABLE_set_pmc_keyed_int(new_interp, new_interp->iglobals,
        (INTVAL) IGLOBALS_INTERPRETER, self);

    new_interp->current_cont = NEED_CONTINUATION;
}

static int
recursion_limit(Parrot_Interp interp, PMC *self, int l)
{
    const int ret           = interp->recursion_limit;
    interp->recursion_limit = l;
    return ret;
}

pmclass ParrotInterpreter need_ext no_ro {

/*

=back

=head2 Methods

=over 4

=item C<void class_init()>

Class initialization.

=cut

*/

    void class_init() {
        const int typ = enum_class_ParrotInterpreter;

        if (pass) {
            /* TODO unify and fix signatures */
            register_nci_method(INTERP, typ,
                    F2DPTR(pt_thread_yield), "yield", "v");

            /* misc functions */
            register_nci_method(INTERP, typ,
                    F2DPTR(recursion_limit), "recursion_limit", "iJOi");
        }
    }

/*

=item C<void init()>

Initializes the interpreter.

=cut

*/

    VTABLE void init() {
        /*
         * init/init_pmc may be called internally (from thread creation in
         * ParrotThread::init_pmc() or stand-alone
         * so we check, if the interpreter is already setup
         */
        if (!PMC_data(SELF)) {
            create_interp(SELF, INTERP);
            PARROT_ASSERT(PMC_data(SELF));
        }

        PMC_struct_val(SELF) = NULL;
        PMC_pmc_val(SELF)    = NULL;
    }

/*

=item C<void init_pmc(PMC *parent)>

Initializes a child interpreter with C<*parent> if C<parent> is
a ParrotInterpreter instance. Otherwise takes the thread ID from
C<parent> and uses that thread.

=cut

*/

    VTABLE void init_pmc(PMC *parent) {
        Parrot_Interp p = PMC_data_typed(parent, Parrot_Interp);

        if (!PMC_data(SELF))
            create_interp(SELF, p);

        PMC_struct_val(SELF) = NULL;
    }

/*

=item C<void set_pointer(void *value)>

Sets C<struct_val> to C<*value>.

=cut

*/

    VTABLE void set_pointer(void *value) {
        PMC_struct_val(SELF) = value;
    }

/*

=item C<void *get_pointer()>

Returns C<struct_val>.

=cut

*/

    VTABLE void *get_pointer() {
        return PMC_struct_val(SELF);
    }

/*

=item C<INTVAL get_integer()>

Returns the thread id of the interpreter.

=cut

*/

    VTABLE INTVAL get_integer() {
        const Parrot_Interp i = PMC_data_typed(SELF, Parrot_Interp);
        return (INTVAL)i->thread_data->tid;
    }

/*

=item C<opcode_t *invoke(void *next)>

Runs the interpreter's byte code.

=cut

*/

    VTABLE opcode_t *invoke(void *next) {
        Interp * const new_interp = PMC_data_typed(SELF, Interp *);

        /* setup code */
        pt_thread_prepare_for_run(new_interp, interp);

        /* TODO pass arguments from parent (interp) to child (new_interp) by
         * possibly clone of share the arguments r/o args can be passed as is */

        /* calculate offset and run */
        runops(new_interp, (size_t)((opcode_t *)PMC_struct_val(SELF) -
            (opcode_t *)interp->code->base.data));

        return (opcode_t *)next;
    }

/*

=item C<PMC *get_pmc_keyed_int(INTVAL key)>

Returns the PMC global value for C<key>.

=cut

*/

    VTABLE PMC *get_pmc_keyed_int(INTVAL key) {
        Interp * const new_interp = PMC_data_typed(SELF, Interp *);

        if (key >= 0 && key < IGLOBALS_SIZE)
            return VTABLE_get_pmc_keyed_int(new_interp,
                new_interp->iglobals, key);

        /* quick hack to get the global stash */
        if (key == -1)
            return new_interp->root_namespace;

        return PMCNULL;
    }

/*

=item C<PMC *get_pmc_keyed(PMC *key)>

Introspection interface. C<key> can be:

  "sub"                     ... return Sub object of this subroutine
  "continuation"            ... return Continuation PMC
  "lexpad"                  ... return lexpad PMC for this sub
  "namespace"               ... return namespace PMC for this sub
  "outer"                   ... return outer sub of this closure
  "<item>"; level           ... same for caller <level>
  "outer"; "<item>"         ... same for outer level 1
  "outer"; "<item>"; level  ... same for outer <level>
  "globals"                 ... return global stash

=cut

*/

    VTABLE PMC *get_pmc_keyed(PMC *key) {
        PMC    *nextkey, *cont;
        STRING *outer = NULL;
        STRING *item  = key_string(interp, key);
        STRING *s     = CONST_STRING(interp, "globals");
        int     level = 0;

        Parrot_Context *ctx;

        if (string_equal(interp, item, s) == 0)
            return interp->root_namespace;

        s     = CONST_STRING(interp, "outer");

        if (string_equal(interp, item, s) == 0) {
            outer   = item;
            nextkey = key_next(INTERP, key);

            if (nextkey && (PObj_get_FLAGS(nextkey) & KEY_string_FLAG)) {
                key  = nextkey;
                item = VTABLE_get_string(interp, key);
            }
        }

        nextkey = key_next(INTERP, key);

        if (nextkey)
            level = key_integer(interp, nextkey);
        else if (outer)
            level = 1;

        if (level < 0)
            Parrot_ex_throw_from_c_args(interp, NULL, CONTROL_ERROR,
                "No such caller depth");

        ctx = CONTEXT(interp);

        if (outer) {
            for (; level; --level) {
                ctx = ctx->outer_ctx;
                if (!ctx)
                    Parrot_ex_throw_from_c_args(interp, NULL,
                        CONTROL_ERROR, "No such outer depth");
            }
        }
        else {
            for (; level; --level) {
                cont = ctx->current_cont;

                if (PMC_IS_NULL(cont) || !PMC_cont(cont)->seg)
                    Parrot_ex_throw_from_c_args(interp, NULL,
                        CONTROL_ERROR, "No such caller depth");

                ctx = PMC_cont(cont)->to_ctx;

                if (!ctx->current_sub)
                    Parrot_ex_throw_from_c_args(interp, NULL,
                        CONTROL_ERROR, "No such caller depth");
            }
        }

        if (item == outer)
            return ctx->current_sub;

        s = CONST_STRING(interp, "sub");

        if (string_equal(interp, item, s) == 0)
            return ctx->current_sub;

        s = CONST_STRING(interp, "lexpad");

        if (string_equal(interp, item, s) == 0)
            return ctx->lex_pad;

        s = CONST_STRING(interp, "namespace");

        if (string_equal(interp, item, s) == 0)
            return ctx->current_namespace;

        s = CONST_STRING(interp, "continuation");

        if (string_equal(interp, item, s) == 0)
            return VTABLE_clone(interp, ctx->current_cont);

        Parrot_ex_throw_from_c_args(interp, NULL, EXCEPTION_ATTRIB_NOT_FOUND,
                "No such item %Ss", item);
    }

/*

=item C<INTVAL get_integer_keyed_int(INTVAL key)>

Returns the interpreter info for C<key>.

=cut

*/

    VTABLE INTVAL get_integer_keyed_int(INTVAL key) {
        Interp * const new_interp = PMC_data_typed(SELF, Interp *);

        if (key == -1)
            return (INTVAL)new_interp->flags;

        return interpinfo(new_interp, key);
    }

/*

=item C<void set_integer_keyed_int(INTVAL key, INTVAL val)>

Sets the interpreter info for C<key> to C<val>.

=cut

*/

    VTABLE void set_integer_keyed_int(INTVAL key, INTVAL val) {
        Interp * const new_interp = PMC_data_typed(SELF, Interp *);

        /* set interpreter flags */
        if (key == -1) {
            const INTVAL allowed = PARROT_BOUNDS_FLAG | PARROT_PROFILE_FLAG |
                             PARROT_GC_DEBUG_FLAG;
            Parrot_clear_flag(new_interp, allowed);
            Parrot_set_flag(new_interp, val & allowed);
        }
    }

/*

=item C<PMC *clone()>

First attempt to make things running, and to see, where problems may
arise. Only minimal items are done yet.

XXX this should of course call C<Parrot_clone()> and use freeze/thaw.

=cut

*/

    VTABLE PMC *clone() {
        PMC * const dest = pmc_new(INTERP, SELF->vtable->base_type);

        clone_interpreter((Parrot_Interp)PMC_data(dest),
                          (Parrot_Interp)PMC_data(SELF), PARROT_CLONE_DEFAULT);

        return dest;
    }

/*

=item C<INTVAL is_equal(PMC *val)>

Returns whether the interpreter is equal to C<*val>.

Two interpreters (threads) are equal if both are non-threaded or they
have the same thread id.

=cut

*/

    VTABLE INTVAL is_equal(PMC *val) {
        Parrot_Interp self  = PMC_data_typed(SELF, Parrot_Interp);
        Parrot_Interp other = PMC_data_typed(val, Parrot_Interp);

        if (!self->thread_data && !other->thread_data)
            return 1;

        if (self->thread_data && other->thread_data &&
            self->thread_data->tid == other->thread_data->tid)
            return 1;

        return 0;
    }

/*

=item C<void visit(visit_info *info)>

This is used by freeze/thaw to visit the contents of the interpreter.

C<*info> is the visit info, (see F<include/parrot/pmc_freeze.h>).

=item C<void freeze(visit_info *info)>

Used to archive the interpreter. Actually not the whole interpreter is
frozen but the state of the interpreter, which includes everything that
has changes since creating an empty interpreter.

=item C<void thaw(visit_info *info)>

Used to unarchive the interpreter. This merges the changes into this
interpreter instance.

=item C<void thawfinish(visit_info *info)>

Finish thawing.

=cut

*/

    VTABLE void visit(visit_info *info) {
        PMC **pos;
        /*
         * the information frozen here is part of all PBCs
         * we probably need to freeze all dynamic extensible
         * mappings (or at least the dynamic part)
         * e.g.
         *    charsets   idx - name
         *    encodings  idx - name
         *    pmc types  idx - name
         *    dynamic oplibs    opcode nr - opname
         *
         * The machine thawing this info still needs to load
         * these extensions, but the order of loading could be
         * relaxed.
         *
         * creating all these info as standard PMCs would vastly
         * simplify this process
         *
         * thaw would then need a merge operation:
         *  - compare existing for sanity
         *  - extend new
         */

        /*  HLL_info */
        if (info->what == VISIT_THAW_NORMAL ||
                info->what == VISIT_THAW_CONSTANTS) {
            pos = &PMC_pmc_val(SELF);
        }
        else
            pos = &INTERP->HLL_info;

        info->thaw_ptr = pos;
        (info->visit_pmc_now)(INTERP, *pos, info);
    }

    VTABLE void thaw(visit_info *info) {
        if (info->extra_flags == EXTRA_IS_PROP_HASH) {
            SUPER(info);
        }
        else if (info->extra_flags == EXTRA_IS_NULL) {
            PMC_data(SELF) = INTERP;
            info->what     = VISIT_THAW_CONSTANTS;
        }
    }

    void thawfinish(visit_info *info) {
        PMC * const new_info = PMC_pmc_val(SELF);
        const INTVAL  m      = VTABLE_elements(INTERP, new_info);
        INTVAL  i;

        PMC_pmc_val(SELF) = NULL;

        /* merge new_info */
        /* TODO compare old entries */

        for (i = 0; i < m; ++i) {
            PMC * const entry    = VTABLE_get_pmc_keyed_int(INTERP, new_info, i);
            PMC * const lib_pmc  = VTABLE_get_pmc_keyed_int(INTERP, entry, e_HLL_lib);
            PMC * const name_pmc = VTABLE_get_pmc_keyed_int(INTERP, entry, e_HLL_name);
            PMC * const typemap  = VTABLE_get_pmc_keyed_int(INTERP, entry, e_HLL_typemap);
            INTVAL hll_id = - 1;

            if (!PMC_IS_NULL(name_pmc)) {
                STRING * const hll_name = VTABLE_get_string(INTERP, name_pmc);

                hll_id           = Parrot_register_HLL(INTERP, hll_name);
            }

            if (!PMC_IS_NULL(lib_pmc)) {
                STRING *lib_name = VTABLE_get_string(INTERP, lib_pmc);
                PMC    *ignored;

                if (!STRING_IS_EMPTY(lib_name)) {
                    INTVAL id;
                    ignored      = Parrot_load_lib(INTERP, lib_name, NULL);
                    id           = Parrot_register_HLL_lib(INTERP, lib_name);
                    UNUSED(id);
                }

                UNUSED(ignored);
            }

            if (hll_id >= 0 && !PMC_IS_NULL(typemap)) {
                PMC   *iter = VTABLE_get_iter(INTERP, typemap);
                INTVAL e    = VTABLE_get_integer(INTERP, typemap);
                INTVAL i;

                for (i = 0; i < e; ++i) {
                    PMC * const key        = VTABLE_shift_pmc(INTERP, iter);
                    const INTVAL core_type = VTABLE_get_integer(INTERP, key);
                    const INTVAL hll_type  =
                        VTABLE_get_integer_keyed_int(INTERP, typemap, core_type);

                    Parrot_register_HLL_type(INTERP, hll_id,
                        core_type, hll_type);
                }
            }
        }
    }

    METHOD run_gc() {
        Parrot_do_dod_run(PMC_data_typed(SELF, Parrot_Interp), 0);
    }
/*

=item METHOD hll_map(PMC core_type,PMC hll_type)

Finish thawing.

=cut

*/

    METHOD hll_map(PMC *core_type, PMC *hll_type) {
        INTVAL core_type_id = VTABLE_type(INTERP, core_type);
        INTVAL hll_type_id  = VTABLE_type(INTERP, hll_type);
        INTVAL hll_id       = CONTEXT(interp)->current_HLL;
        Parrot_register_HLL_type(INTERP, hll_id, core_type_id, hll_type_id);
    }


}

/*

=back

=cut

*/

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