path: root/mrbgems/mruby-objectspace/src/mruby_objectspace.c

#include <mruby.h>
#include <mruby/gc.h>
#include <mruby/hash.h>
#include <mruby/class.h>
#include <mruby/object.h>
#include <mruby/numeric.h>
#include <mruby/string.h>
#include <mruby/array.h>
#include <mruby/variable.h>
#include <mruby/proc.h>
#include <mruby/value.h>
#include <mruby/range.h>

struct os_count_struct {
  mrb_int total;
  mrb_int freed;
  mrb_int counts[MRB_TT_MAXDEFINE+1];
};

static int
os_count_object_type(mrb_state *mrb, struct RBasic *obj, void *data)
{
  struct os_count_struct *obj_count;
  obj_count = (struct os_count_struct*)data;

  obj_count->total++;

  if (mrb_object_dead_p(mrb, obj)) {
    obj_count->freed++;
  }
  else {
    obj_count->counts[obj->tt]++;
  }
  return MRB_EACH_OBJ_OK;
}

/*
 *  call-seq:
 *     ObjectSpace.count_objects([result_hash]) -> hash
 *
 *  Counts objects for each type.
 *
 *  It returns a hash, such as:
 *  {
 *    :TOTAL=>10000,
 *    :FREE=>3011,
 *    :T_OBJECT=>6,
 *    :T_CLASS=>404,
 *    # ...
 *  }
 *
 *  If the optional argument +result_hash+ is given,
 *  it is overwritten and returned. This is intended to avoid probe effect.
 *
 */

static mrb_value
os_count_objects(mrb_state *mrb, mrb_value self)
{
  struct os_count_struct obj_count = { 0 };
  mrb_int i;
  mrb_value hash;

  if (mrb_get_args(mrb, "|H", &hash) == 0) {
    hash = mrb_hash_new(mrb);
  }

  if (!mrb_hash_empty_p(mrb, hash)) {
    mrb_hash_clear(mrb, hash);
  }

  mrb_objspace_each_objects(mrb, os_count_object_type, &obj_count);

  mrb_hash_set(mrb, hash, mrb_symbol_value(mrb_intern_lit(mrb, "TOTAL")), mrb_fixnum_value(obj_count.total));
  mrb_hash_set(mrb, hash, mrb_symbol_value(mrb_intern_lit(mrb, "FREE")), mrb_fixnum_value(obj_count.freed));

  for (i = MRB_TT_FALSE; i < MRB_TT_MAXDEFINE; i++) {
    mrb_value type;
    switch (i) {
#define COUNT_TYPE(t) case (MRB_T ## t): type = mrb_symbol_value(mrb_intern_lit(mrb, #t)); break;
      COUNT_TYPE(T_FALSE);
      COUNT_TYPE(T_FREE);
      COUNT_TYPE(T_TRUE);
      COUNT_TYPE(T_FIXNUM);
      COUNT_TYPE(T_SYMBOL);
      COUNT_TYPE(T_UNDEF);
      COUNT_TYPE(T_FLOAT);
      COUNT_TYPE(T_CPTR);
      COUNT_TYPE(T_OBJECT);
      COUNT_TYPE(T_CLASS);
      COUNT_TYPE(T_MODULE);
      COUNT_TYPE(T_ICLASS);
      COUNT_TYPE(T_SCLASS);
      COUNT_TYPE(T_PROC);
      COUNT_TYPE(T_ARRAY);
      COUNT_TYPE(T_HASH);
      COUNT_TYPE(T_STRING);
      COUNT_TYPE(T_RANGE);
      COUNT_TYPE(T_EXCEPTION);
      COUNT_TYPE(T_ENV);
      COUNT_TYPE(T_DATA);
      COUNT_TYPE(T_FIBER);
#undef COUNT_TYPE
    default:
      type = mrb_fixnum_value(i); break;
    }
    if (obj_count.counts[i])
      mrb_hash_set(mrb, hash, type, mrb_fixnum_value(obj_count.counts[i]));
  }

  return hash;
}

struct os_each_object_data {
  mrb_value block;
  struct RClass *target_module;
  mrb_int count;
};

static int
os_each_object_cb(mrb_state *mrb, struct RBasic *obj, void *ud)
{
  struct os_each_object_data *d = (struct os_each_object_data*)ud;

  /* filter dead objects */
  if (mrb_object_dead_p(mrb, obj)) {
    return MRB_EACH_OBJ_OK;
  }

  /* filter internal objects */
  switch (obj->tt) {
  case MRB_TT_ENV:
  case MRB_TT_ICLASS:
    return MRB_EACH_OBJ_OK;
  default:
    break;
  }

  /* filter half baked (or internal) objects */
  if (!obj->c) return MRB_EACH_OBJ_OK;

  /* filter class kind if target module defined */
  if (d->target_module && !mrb_obj_is_kind_of(mrb, mrb_obj_value(obj), d->target_module)) {
    return MRB_EACH_OBJ_OK;
  }

  mrb_yield(mrb, d->block, mrb_obj_value(obj));
  ++d->count;
  return MRB_EACH_OBJ_OK;
}

/*
 *  call-seq:
 *     ObjectSpace.each_object([module]) {|obj| ... } -> fixnum
 *
 *  Calls the block once for each object in this Ruby process.
 *  Returns the number of objects found.
 *  If the optional argument +module+ is given,
 *  calls the block for only those classes or modules
 *  that match (or are a subclass of) +module+.
 *
 *  If no block is given, ArgumentError is raised.
 *
 */

static mrb_value
os_each_object(mrb_state *mrb, mrb_value self)
{
  mrb_value cls = mrb_nil_value();
  struct os_each_object_data d;
  mrb_get_args(mrb, "&!|C", &d.block, &cls);

  d.target_module = mrb_nil_p(cls) ? NULL : mrb_class_ptr(cls);
  d.count = 0;
  mrb_objspace_each_objects(mrb, os_each_object_cb, &d);
  return mrb_fixnum_value(d.count);
}

static void os_memsize_of_object(mrb_state*,mrb_value,mrb_bool,mrb_int*);

static int
os_memsize_ivar_cb(mrb_state *mrb, mrb_sym _name, mrb_value obj, void *data)
{
  mrb_int *cb_data = (mrb_int *)data;
  mrb_int recurse = *(&cb_data[0]);
  mrb_int* total = &cb_data[1];

  os_memsize_of_object(mrb, obj, (mrb_bool)(recurse), total);
  return 0;
}

static void
os_memsize_of_ivars(mrb_state* mrb, mrb_value obj, mrb_bool recurse, mrb_int *t)
{
  /* need iv segment table size */
  if(recurse) {
    mrb_int r = (mrb_int)recurse;
    mrb_int *cb_data[2] = { &r, t };
    mrb_iv_foreach(mrb, obj, os_memsize_ivar_cb, cb_data);
  }
}

static void
os_memsize_of_irep(mrb_state* state, struct mrb_irep *irep, mrb_int* t)
{
  mrb_int i;
  (*t) += (irep->slen * sizeof(mrb_sym)) +
          (irep->plen * sizeof(mrb_code)) +
          (irep->ilen * sizeof(mrb_code));

  for(i = 0; i < irep->rlen; i++) {
    os_memsize_of_irep(state, irep->reps[i], t);
  }
}

static void
os_memsize_of_method(mrb_state* mrb, mrb_value method_obj, mrb_int* t)
{
  mrb_value proc_value = mrb_obj_iv_get(mrb, mrb_obj_ptr(method_obj),
                                        mrb_intern_lit(mrb, "_proc"));
  struct RProc *proc = mrb_proc_ptr(proc_value);

  (*t) += sizeof(struct RProc);
  if(!MRB_PROC_CFUNC_P(proc)) os_memsize_of_irep(mrb, proc->body.irep, t);
}

static void
os_memsize_of_methods(mrb_state* mrb, mrb_value obj, mrb_int* t)
{
  mrb_value method_list;
  mrb_int i;
  if(!mrb_respond_to(mrb, obj, mrb_intern_lit(mrb, "instance_methods"))) return;
  method_list = mrb_funcall(mrb, obj, "instance_methods", 1, mrb_false_value());
  for(i = 0; i < RARRAY_LEN(method_list); i++) {
    mrb_value method = mrb_funcall(mrb, obj, "instance_method", 1,
                                   mrb_ary_ref(mrb, method_list, i));
    os_memsize_of_method(mrb, method, t);
  }
}

static void
os_memsize_of_object(mrb_state* mrb, mrb_value obj, mrb_bool recurse, mrb_int* t)
{
  switch(obj.tt) {
    case MRB_TT_STRING:
      (*t) += RSTRING_LEN(obj);
      break;
    case MRB_TT_CLASS:
    case MRB_TT_MODULE:
    case MRB_TT_EXCEPTION:
    case MRB_TT_SCLASS:
    case MRB_TT_ICLASS:
    case MRB_TT_OBJECT: {
      os_memsize_of_ivars(mrb, obj, recurse, t);
      if(mrb_obj_is_kind_of(mrb, obj, mrb_class_get(mrb, "UnboundMethod"))) {
        os_memsize_of_method(mrb, obj, t);
      }
      else {
        os_memsize_of_methods(mrb, obj, t);
      }
      break;
    }
    case MRB_TT_HASH: {
      /*struct htable* htable = RHASH_TBL(obj);
       * Need htable & segment struct defs */
      break;
    }
    case MRB_TT_ARRAY: {
      mrb_int len, i;
      len = RARRAY_LEN(obj);
      /* Arrays that do not fit within an RArray perform a heap allocation
      *  storing an array of pointers to the original objects*/
      if(len > MRB_ARY_EMBED_LEN_MAX) (*t) += sizeof(mrb_value *) * len;

      if(recurse) {
        for(i = 0; i < len; i++) {
          os_memsize_of_object(mrb, ARY_PTR(mrb_ary_ptr(obj))[i], recurse, t);
        }
      }
      break;
    }
    case MRB_TT_PROC: {
      struct RProc* proc = mrb_proc_ptr(obj);
      (*t) += MRB_ENV_LEN(proc->e.env) * sizeof(mrb_value);
      if(!MRB_PROC_CFUNC_P(proc)) os_memsize_of_irep(mrb, proc->body.irep, t);
      break;
    }
    case MRB_TT_DATA:
      if(mrb_respond_to(mrb, obj, mrb_intern_lit(mrb, "memsize"))) {
        (*t) += mrb_fixnum(mrb_funcall(mrb, obj, "memsize", 0));
      }
      break;
    #ifndef MRB_WITHOUT_FLOAT
    case MRB_TT_FLOAT:
      #ifdef MRB_WORD_BOXING
        (*t) += sizeof(struct RFloat);
      #endif
      break;
    #endif
    case MRB_TT_RANGE:
    #ifndef MRB_RANGE_EMBED
      (*t) += sizeof(struct mrb_range_edges);
    #endif
      break;
    case MRB_TT_FIBER: {
      /*  struct RFiber* fiber = (struct RFiber*)mrb_ptr(obj); */
      (*t) += sizeof(struct mrb_context);
      break;
    }
    /*  zero heap size types.
     *  immediate VM stack values, contained within mrb_state, mrb_heap_page,
     *  or on C stack */
    case MRB_TT_TRUE:
    case MRB_TT_FALSE:
    case MRB_TT_FIXNUM:
    case MRB_TT_BREAK:
    case MRB_TT_CPTR:
    case MRB_TT_SYMBOL:
    case MRB_TT_FREE:
    case MRB_TT_UNDEF:
    case MRB_TT_ENV:
    case MRB_TT_ISTRUCT:
    /* never used, silences compiler warning
     * not having a default: clause lets the compiler tell us when there is a new
     * TT not accounted for */
    case MRB_TT_MAXDEFINE:
      break;
  }
}

/*
 *  call-seq:
 *    ObjectSpace.memsize_of(obj, recurse: false) -> Numeric
 *
 *  Returns the amount of heap memory allocated for object in size_t units.
 *  Not all objects cause additional heap allocations beyond their object pointer
 *  in the heap page and may return 0.
 *
 *  The return value depends on the definition of size_t on that platform,
 *  therefore the value is not comparable across platform types.
 *
 *  Immediate values such as integers, booleans, symbols and unboxed float numbers
 *  return 0. Additionally special objects which are small enough to fit inside an
 *  object *  pointer, termed embedded objects, also return 0. Strings and arrays
 *  below a compile-time defined size may be embedded.
 *
 *  Setting recurse: true descends into instance variables, array members,
 *  and hash values recursively, calculating the child objects and adding to
 *  the final sum.
 *
 */

static mrb_value
os_memsize_of(mrb_state *mrb, mrb_value self)
{
  mrb_int total;
  mrb_value obj;
  mrb_bool recurse;
  const char *kw_names[1] = { "recurse" };
  mrb_value kw_values[1];
  const mrb_kwargs kwargs = { 1, kw_values, kw_names, 0, NULL };

  mrb_get_args(mrb, "o:", &obj, &kwargs);
  recurse = mrb_obj_eq(mrb, kw_values[0], mrb_true_value()) ? TRUE : FALSE;

  total = 0;
  os_memsize_of_object(mrb, obj, recurse, &total);

  return mrb_fixnum_value(total);
}

void
mrb_mruby_objectspace_gem_init(mrb_state *mrb)
{
  struct RClass *os = mrb_define_module(mrb, "ObjectSpace");
  mrb_define_class_method(mrb, os, "count_objects", os_count_objects, MRB_ARGS_OPT(1));
  mrb_define_class_method(mrb, os, "each_object", os_each_object, MRB_ARGS_OPT(1));
  mrb_define_class_method(mrb, os, "memsize_of", os_memsize_of, MRB_ARGS_REQ(1)|MRB_ARGS_OPT(1));
}

void
mrb_mruby_objectspace_gem_final(mrb_state *mrb)
{
}