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jerryscript/jerry-core/ecma/base/ecma-helpers.c
Robert Fancsik 48f34adea5 General GC optimizations (#3221) 
- Enable recursive GC marking with a limited recursion count (this option is configurable)
- No need to decrease the reference count of the gray objects anymore
- Bound function object marking is seperated into a helper function

JerryScript-DCO-1.0-Signed-off-by: Robert Fancsik frobert@inf.u-szeged.hu
2019-10-24 14:49:47 +02:00

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/* Copyright JS Foundation and other contributors, http://js.foundation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "ecma-alloc.h"
#include "ecma-gc.h"
#include "ecma-globals.h"
#include "ecma-helpers.h"
#include "ecma-lcache.h"
#include "ecma-property-hashmap.h"
#include "jcontext.h"
#include "jrt-bit-fields.h"
#include "byte-code.h"
#include "re-compiler.h"
#include "ecma-builtins.h"
#if ENABLED (JERRY_DEBUGGER)
#include "debugger.h"
#endif /* ENABLED (JERRY_DEBUGGER) */
/** \addtogroup ecma ECMA
* @{
*
* \addtogroup ecmahelpers Helpers for operations with ECMA data types
* @{
*/
JERRY_STATIC_ASSERT (ECMA_PROPERTY_TYPE_MASK >= ECMA_PROPERTY_TYPE__MAX,
ecma_property_types_must_be_lower_than_the_container_mask);
JERRY_STATIC_ASSERT (ECMA_OBJECT_TYPE_MASK >= ECMA_OBJECT_TYPE__MAX - 1,
ecma_object_types_must_be_lower_than_the_container_mask);
JERRY_STATIC_ASSERT (ECMA_OBJECT_TYPE_MASK >= ECMA_LEXICAL_ENVIRONMENT_TYPE__MAX,
ecma_lexical_environment_types_must_be_lower_than_the_container_mask);
JERRY_STATIC_ASSERT (ECMA_OBJECT_TYPE_MASK + 1 == ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV,
ecma_built_in_flag_must_follow_the_object_type);
JERRY_STATIC_ASSERT (ECMA_OBJECT_FLAG_EXTENSIBLE == (ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV << 1),
ecma_extensible_flag_must_follow_the_built_in_flag);
JERRY_STATIC_ASSERT (ECMA_OBJECT_REF_ONE == (ECMA_OBJECT_FLAG_EXTENSIBLE << 1),
ecma_object_ref_one_must_follow_the_extensible_flag);
JERRY_STATIC_ASSERT (((ECMA_OBJECT_MAX_REF + ECMA_OBJECT_REF_ONE) | (ECMA_OBJECT_REF_ONE - 1)) == UINT16_MAX,
ecma_object_max_ref_does_not_fill_the_remaining_bits);
JERRY_STATIC_ASSERT (ECMA_PROPERTY_TYPE_DELETED == (ECMA_DIRECT_STRING_MAGIC << ECMA_PROPERTY_NAME_TYPE_SHIFT),
ecma_property_type_deleted_must_have_magic_string_name_type);
/**
* Create an object with specified prototype object
* (or NULL prototype if there is not prototype for the object)
* and value of 'Extensible' attribute.
*
* Reference counter's value will be set to one.
*
* @return pointer to the object's descriptor
*/
ecma_object_t *
ecma_create_object (ecma_object_t *prototype_object_p, /**< pointer to prototybe of the object (or NULL) */
size_t ext_object_size, /**< size of extended objects */
ecma_object_type_t type) /**< object type */
{
ecma_object_t *new_object_p;
if (ext_object_size > 0)
{
new_object_p = (ecma_object_t *) ecma_alloc_extended_object (ext_object_size);
}
else
{
new_object_p = ecma_alloc_object ();
}
new_object_p->type_flags_refs = (uint16_t) (type | ECMA_OBJECT_FLAG_EXTENSIBLE);
ecma_init_gc_info (new_object_p);
new_object_p->u1.property_list_cp = JMEM_CP_NULL;
ECMA_SET_POINTER (new_object_p->u2.prototype_cp, prototype_object_p);
return new_object_p;
} /* ecma_create_object */
/**
* Create a declarative lexical environment with specified outer lexical environment
* (or NULL if the environment is not nested).
*
* See also: ECMA-262 v5, 10.2.1.1
*
* Reference counter's value will be set to one.
*
* @return pointer to the descriptor of lexical environment
*/
ecma_object_t *
ecma_create_decl_lex_env (ecma_object_t *outer_lexical_environment_p) /**< outer lexical environment */
{
ecma_object_t *new_lexical_environment_p = ecma_alloc_object ();
uint16_t type = ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV | ECMA_LEXICAL_ENVIRONMENT_DECLARATIVE;
new_lexical_environment_p->type_flags_refs = type;
ecma_init_gc_info (new_lexical_environment_p);
new_lexical_environment_p->u1.property_list_cp = JMEM_CP_NULL;
ECMA_SET_POINTER (new_lexical_environment_p->u2.outer_reference_cp, outer_lexical_environment_p);
return new_lexical_environment_p;
} /* ecma_create_decl_lex_env */
/**
* Create a object lexical environment with specified outer lexical environment
* (or NULL if the environment is not nested), binding object and provided type flag.
*
* See also: ECMA-262 v5, 10.2.1.2
*
* Reference counter's value will be set to one.
*
* @return pointer to the descriptor of lexical environment
*/
ecma_object_t *
ecma_create_object_lex_env (ecma_object_t *outer_lexical_environment_p, /**< outer lexical environment */
ecma_object_t *binding_obj_p, /**< binding object */
ecma_lexical_environment_type_t type) /**< type of the new lexical environment */
{
#if ENABLED (JERRY_ES2015)
JERRY_ASSERT (type == ECMA_LEXICAL_ENVIRONMENT_THIS_OBJECT_BOUND
|| type == ECMA_LEXICAL_ENVIRONMENT_SUPER_OBJECT_BOUND);
#else /* !ENABLED (JERRY_ES2015) */
JERRY_ASSERT (type == ECMA_LEXICAL_ENVIRONMENT_THIS_OBJECT_BOUND);
#endif /* ENABLED (JERRY_ES2015) */
JERRY_ASSERT (binding_obj_p != NULL
&& !ecma_is_lexical_environment (binding_obj_p));
ecma_object_t *new_lexical_environment_p = ecma_alloc_object ();
new_lexical_environment_p->type_flags_refs = (uint16_t) (ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV | type);
ecma_init_gc_info (new_lexical_environment_p);
ECMA_SET_NON_NULL_POINTER (new_lexical_environment_p->u1.bound_object_cp,
binding_obj_p);
ECMA_SET_POINTER (new_lexical_environment_p->u2.outer_reference_cp, outer_lexical_environment_p);
return new_lexical_environment_p;
} /* ecma_create_object_lex_env */
/**
* Check if the object is lexical environment.
*
* @return true - if object is a lexical environment
* false - otherwise
*/
inline bool JERRY_ATTR_PURE
ecma_is_lexical_environment (const ecma_object_t *object_p) /**< object or lexical environment */
{
JERRY_ASSERT (object_p != NULL);
uint32_t full_type = object_p->type_flags_refs & (ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV | ECMA_OBJECT_TYPE_MASK);
return full_type >= (ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV | ECMA_LEXICAL_ENVIRONMENT_TYPE_START);
} /* ecma_is_lexical_environment */
/**
* Get value of [[Extensible]] object's internal property.
*
* @return true - if object is extensible
* false - otherwise
*/
inline bool JERRY_ATTR_PURE
ecma_get_object_extensible (const ecma_object_t *object_p) /**< object */
{
JERRY_ASSERT (object_p != NULL);
JERRY_ASSERT (!ecma_is_lexical_environment (object_p));
return (object_p->type_flags_refs & ECMA_OBJECT_FLAG_EXTENSIBLE) != 0;
} /* ecma_get_object_extensible */
/**
* Set value of [[Extensible]] object's internal property.
*/
inline void
ecma_set_object_extensible (ecma_object_t *object_p, /**< object */
bool is_extensible) /**< value of [[Extensible]] */
{
JERRY_ASSERT (object_p != NULL);
JERRY_ASSERT (!ecma_is_lexical_environment (object_p));
if (is_extensible)
{
object_p->type_flags_refs = (uint16_t) (object_p->type_flags_refs | ECMA_OBJECT_FLAG_EXTENSIBLE);
}
else
{
object_p->type_flags_refs = (uint16_t) (object_p->type_flags_refs & ~ECMA_OBJECT_FLAG_EXTENSIBLE);
}
} /* ecma_set_object_extensible */
/**
* Get object's internal implementation-defined type.
*
* @return type of the object (ecma_object_type_t)
*/
inline ecma_object_type_t JERRY_ATTR_PURE
ecma_get_object_type (const ecma_object_t *object_p) /**< object */
{
JERRY_ASSERT (object_p != NULL);
JERRY_ASSERT (!ecma_is_lexical_environment (object_p));
return (ecma_object_type_t) (object_p->type_flags_refs & ECMA_OBJECT_TYPE_MASK);
} /* ecma_get_object_type */
/**
* Check if the object is a built-in object
*
* @return true - if object is a built-in object
* false - otherwise
*/
inline bool JERRY_ATTR_PURE
ecma_get_object_is_builtin (const ecma_object_t *object_p) /**< object */
{
JERRY_ASSERT (object_p != NULL);
JERRY_ASSERT (!ecma_is_lexical_environment (object_p));
return (object_p->type_flags_refs & ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV) != 0;
} /* ecma_get_object_is_builtin */
/**
* Set flag indicating whether the object is a built-in object
*/
inline void
ecma_set_object_is_builtin (ecma_object_t *object_p) /**< object */
{
JERRY_ASSERT (object_p != NULL);
JERRY_ASSERT (!(object_p->type_flags_refs & ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV));
JERRY_ASSERT ((object_p->type_flags_refs & ECMA_OBJECT_TYPE_MASK) < ECMA_LEXICAL_ENVIRONMENT_TYPE_START);
object_p->type_flags_refs = (uint16_t) (object_p->type_flags_refs | ECMA_OBJECT_FLAG_BUILT_IN_OR_LEXICAL_ENV);
} /* ecma_set_object_is_builtin */
/**
* Get the built-in ID of the object.
* If the object is not builtin, return ECMA_BUILTIN_ID__COUNT
*
* @return the ID of the built-in
*/
inline uint8_t
ecma_get_object_builtin_id (ecma_object_t *object_p) /**< object */
{
if (!ecma_get_object_is_builtin (object_p))
{
return ECMA_BUILTIN_ID__COUNT;
}
ecma_built_in_props_t *built_in_props_p;
ecma_object_type_t object_type = ecma_get_object_type (object_p);
if (object_type == ECMA_OBJECT_TYPE_CLASS || object_type == ECMA_OBJECT_TYPE_ARRAY)
{
built_in_props_p = &((ecma_extended_built_in_object_t *) object_p)->built_in;
}
else
{
built_in_props_p = &((ecma_extended_object_t *) object_p)->u.built_in;
}
return built_in_props_p->id;
} /* ecma_get_object_builtin_id */
/**
* Get type of lexical environment.
*
* @return type of the lexical environment (ecma_lexical_environment_type_t)
*/
inline ecma_lexical_environment_type_t JERRY_ATTR_PURE
ecma_get_lex_env_type (const ecma_object_t *object_p) /**< lexical environment */
{
JERRY_ASSERT (object_p != NULL);
JERRY_ASSERT (ecma_is_lexical_environment (object_p));
return (ecma_lexical_environment_type_t) (object_p->type_flags_refs & ECMA_OBJECT_TYPE_MASK);
} /* ecma_get_lex_env_type */
/**
* Get lexical environment's bound object.
*
* @return pointer to ecma object
*/
inline ecma_object_t *JERRY_ATTR_PURE
ecma_get_lex_env_binding_object (const ecma_object_t *object_p) /**< object-bound lexical environment */
{
JERRY_ASSERT (object_p != NULL);
JERRY_ASSERT (ecma_is_lexical_environment (object_p));
#if ENABLED (JERRY_ES2015)
JERRY_ASSERT (ecma_get_lex_env_type (object_p) == ECMA_LEXICAL_ENVIRONMENT_THIS_OBJECT_BOUND
|| ecma_get_lex_env_type (object_p) == ECMA_LEXICAL_ENVIRONMENT_SUPER_OBJECT_BOUND);
#else /* !ENABLED (JERRY_ES2015) */
JERRY_ASSERT (ecma_get_lex_env_type (object_p) == ECMA_LEXICAL_ENVIRONMENT_THIS_OBJECT_BOUND);
#endif /* ENABLED (JERRY_ES2015) */
return ECMA_GET_NON_NULL_POINTER (ecma_object_t, object_p->u1.bound_object_cp);
} /* ecma_get_lex_env_binding_object */
/**
* Create a property in an object and link it into
* the object's properties' linked-list (at start of the list).
*
* @return pointer to the newly created property value
*/
static ecma_property_value_t *
ecma_create_property (ecma_object_t *object_p, /**< the object */
ecma_string_t *name_p, /**< property name */
uint8_t type_and_flags, /**< type and flags, see ecma_property_info_t */
ecma_property_value_t value, /**< property value */
ecma_property_t **out_prop_p) /**< [out] the property is also returned
* if this field is non-NULL */
{
JERRY_ASSERT (ECMA_PROPERTY_PAIR_ITEM_COUNT == 2);
JERRY_ASSERT (name_p != NULL);
JERRY_ASSERT (object_p != NULL);
jmem_cpointer_t *property_list_head_p = &object_p->u1.property_list_cp;
if (*property_list_head_p != ECMA_NULL_POINTER)
{
/* If the first entry is free (deleted), it is reused. */
ecma_property_header_t *first_property_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
*property_list_head_p);
#if ENABLED (JERRY_PROPRETY_HASHMAP)
bool has_hashmap = false;
if (first_property_p->types[0] == ECMA_PROPERTY_TYPE_HASHMAP)
{
property_list_head_p = &first_property_p->next_property_cp;
first_property_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
*property_list_head_p);
has_hashmap = true;
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
JERRY_ASSERT (ECMA_PROPERTY_IS_PROPERTY_PAIR (first_property_p));
if (first_property_p->types[0] == ECMA_PROPERTY_TYPE_DELETED)
{
ecma_property_pair_t *first_property_pair_p = (ecma_property_pair_t *) first_property_p;
ecma_property_t name_type;
first_property_pair_p->names_cp[0] = ecma_string_to_property_name (name_p,
&name_type);
first_property_p->types[0] = (ecma_property_t) (type_and_flags | name_type);
ecma_property_t *property_p = first_property_p->types + 0;
JERRY_ASSERT (ECMA_PROPERTY_VALUE_PTR (property_p) == first_property_pair_p->values + 0);
if (out_prop_p != NULL)
{
*out_prop_p = property_p;
}
first_property_pair_p->values[0] = value;
#if ENABLED (JERRY_PROPRETY_HASHMAP)
/* The property must be fully initialized before ecma_property_hashmap_insert
* is called, because the insert operation may reallocate the hashmap, and
* that triggers garbage collection which scans all properties of all objects.
* A not fully initialized but queued property may cause a crash. */
if (has_hashmap)
{
ecma_property_hashmap_insert (object_p,
name_p,
first_property_pair_p,
0);
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
return first_property_pair_p->values + 0;
}
}
/* Otherwise we create a new property pair and use its second value. */
ecma_property_pair_t *first_property_pair_p = ecma_alloc_property_pair ();
/* Need to query property_list_head_p again and recheck the existennce
* of property hasmap, because ecma_alloc_property_pair may delete them. */
property_list_head_p = &object_p->u1.property_list_cp;
#if ENABLED (JERRY_PROPRETY_HASHMAP)
bool has_hashmap = false;
if (*property_list_head_p != ECMA_NULL_POINTER)
{
ecma_property_header_t *first_property_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
*property_list_head_p);
if (first_property_p->types[0] == ECMA_PROPERTY_TYPE_HASHMAP)
{
property_list_head_p = &first_property_p->next_property_cp;
has_hashmap = true;
}
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
/* Just copy the previous value (no need to decompress, compress). */
first_property_pair_p->header.next_property_cp = *property_list_head_p;
first_property_pair_p->header.types[0] = ECMA_PROPERTY_TYPE_DELETED;
first_property_pair_p->names_cp[0] = LIT_INTERNAL_MAGIC_STRING_DELETED;
ecma_property_t name_type;
first_property_pair_p->names_cp[1] = ecma_string_to_property_name (name_p,
&name_type);
first_property_pair_p->header.types[1] = (ecma_property_t) (type_and_flags | name_type);
ECMA_SET_NON_NULL_POINTER (*property_list_head_p, &first_property_pair_p->header);
ecma_property_t *property_p = first_property_pair_p->header.types + 1;
JERRY_ASSERT (ECMA_PROPERTY_VALUE_PTR (property_p) == first_property_pair_p->values + 1);
if (out_prop_p != NULL)
{
*out_prop_p = property_p;
}
first_property_pair_p->values[1] = value;
#if ENABLED (JERRY_PROPRETY_HASHMAP)
/* See the comment before the other ecma_property_hashmap_insert above. */
if (has_hashmap)
{
ecma_property_hashmap_insert (object_p,
name_p,
first_property_pair_p,
1);
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
return first_property_pair_p->values + 1;
} /* ecma_create_property */
/**
* Create named data property with given name, attributes and undefined value
* in the specified object.
*
* @return pointer to the newly created property value
*/
ecma_property_value_t *
ecma_create_named_data_property (ecma_object_t *object_p, /**< object */
ecma_string_t *name_p, /**< property name */
uint8_t prop_attributes, /**< property attributes (See: ecma_property_flags_t) */
ecma_property_t **out_prop_p) /**< [out] the property is also returned
* if this field is non-NULL */
{
JERRY_ASSERT (object_p != NULL && name_p != NULL);
JERRY_ASSERT (ecma_is_lexical_environment (object_p)
|| ecma_get_object_type (object_p) != ECMA_OBJECT_TYPE_ARRAY
|| !((ecma_extended_object_t *) object_p)->u.array.is_fast_mode);
JERRY_ASSERT (ecma_find_named_property (object_p, name_p) == NULL);
JERRY_ASSERT ((prop_attributes & ~ECMA_PROPERTY_CONFIGURABLE_ENUMERABLE_WRITABLE) == 0);
uint8_t type_and_flags = ECMA_PROPERTY_TYPE_NAMEDDATA | prop_attributes;
ecma_property_value_t value;
value.value = ECMA_VALUE_UNDEFINED;
return ecma_create_property (object_p, name_p, type_and_flags, value, out_prop_p);
} /* ecma_create_named_data_property */
/**
* Create named accessor property with given name, attributes, getter and setter.
*
* @return pointer to the newly created property value
*/
ecma_property_value_t *
ecma_create_named_accessor_property (ecma_object_t *object_p, /**< object */
ecma_string_t *name_p, /**< property name */
ecma_object_t *get_p, /**< getter */
ecma_object_t *set_p, /**< setter */
uint8_t prop_attributes, /**< property attributes */
ecma_property_t **out_prop_p) /**< [out] the property is also returned
* if this field is non-NULL */
{
JERRY_ASSERT (object_p != NULL && name_p != NULL);
JERRY_ASSERT (ecma_is_lexical_environment (object_p)
|| ecma_get_object_type (object_p) != ECMA_OBJECT_TYPE_ARRAY
|| !((ecma_extended_object_t *) object_p)->u.array.is_fast_mode);
JERRY_ASSERT (ecma_find_named_property (object_p, name_p) == NULL);
JERRY_ASSERT ((prop_attributes & ~ECMA_PROPERTY_CONFIGURABLE_ENUMERABLE) == 0);
uint8_t type_and_flags = ECMA_PROPERTY_TYPE_NAMEDACCESSOR | prop_attributes;
ecma_property_value_t value;
#if ENABLED (JERRY_CPOINTER_32_BIT)
ecma_getter_setter_pointers_t *getter_setter_pair_p;
getter_setter_pair_p = jmem_pools_alloc (sizeof (ecma_getter_setter_pointers_t));
ECMA_SET_POINTER (getter_setter_pair_p->getter_cp, get_p);
ECMA_SET_POINTER (getter_setter_pair_p->setter_cp, set_p);
ECMA_SET_NON_NULL_POINTER (value.getter_setter_pair_cp, getter_setter_pair_p);
#else /* !ENABLED (JERRY_CPOINTER_32_BIT) */
ECMA_SET_POINTER (value.getter_setter_pair.getter_cp, get_p);
ECMA_SET_POINTER (value.getter_setter_pair.setter_cp, set_p);
#endif /* ENABLED (JERRY_CPOINTER_32_BIT) */
return ecma_create_property (object_p, name_p, type_and_flags, value, out_prop_p);
} /* ecma_create_named_accessor_property */
/**
* Find named data property or named access property in specified object.
*
* @return pointer to the property, if it is found,
* NULL - otherwise.
*/
ecma_property_t *
ecma_find_named_property (ecma_object_t *obj_p, /**< object to find property in */
ecma_string_t *name_p) /**< property's name */
{
JERRY_ASSERT (obj_p != NULL);
JERRY_ASSERT (name_p != NULL);
JERRY_ASSERT (ecma_is_lexical_environment (obj_p)
|| ecma_get_object_type (obj_p) != ECMA_OBJECT_TYPE_ARRAY
|| !((ecma_extended_object_t *) obj_p)->u.array.is_fast_mode);
ecma_property_t *property_p = NULL;
#if ENABLED (JERRY_LCACHE)
property_p = ecma_lcache_lookup (obj_p, name_p);
if (property_p != NULL)
{
return property_p;
}
#endif /* ENABLED (JERRY_LCACHE) */
jmem_cpointer_t prop_iter_cp = obj_p->u1.property_list_cp;
#if ENABLED (JERRY_PROPRETY_HASHMAP)
if (prop_iter_cp != JMEM_CP_NULL)
{
ecma_property_header_t *prop_iter_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
prop_iter_cp);
if (prop_iter_p->types[0] == ECMA_PROPERTY_TYPE_HASHMAP)
{
jmem_cpointer_t property_real_name_cp;
property_p = ecma_property_hashmap_find ((ecma_property_hashmap_t *) prop_iter_p,
name_p,
&property_real_name_cp);
#if ENABLED (JERRY_LCACHE)
if (property_p != NULL
&& !ecma_is_property_lcached (property_p))
{
ecma_lcache_insert (obj_p, property_real_name_cp, property_p);
}
#endif /* ENABLED (JERRY_LCACHE) */
return property_p;
}
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
#if ENABLED (JERRY_PROPRETY_HASHMAP)
uint32_t steps = 0;
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
jmem_cpointer_t property_name_cp = ECMA_NULL_POINTER;
if (ECMA_IS_DIRECT_STRING (name_p))
{
ecma_property_t prop_name_type = (ecma_property_t) ECMA_GET_DIRECT_STRING_TYPE (name_p);
property_name_cp = (jmem_cpointer_t) ECMA_GET_DIRECT_STRING_VALUE (name_p);
JERRY_ASSERT (prop_name_type > 0);
while (prop_iter_cp != JMEM_CP_NULL)
{
ecma_property_header_t *prop_iter_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
prop_iter_cp);
JERRY_ASSERT (ECMA_PROPERTY_IS_PROPERTY_PAIR (prop_iter_p));
ecma_property_pair_t *prop_pair_p = (ecma_property_pair_t *) prop_iter_p;
if (prop_pair_p->names_cp[0] == property_name_cp
&& ECMA_PROPERTY_GET_NAME_TYPE (prop_iter_p->types[0]) == prop_name_type)
{
JERRY_ASSERT (ECMA_PROPERTY_IS_NAMED_PROPERTY (prop_iter_p->types[0]));
property_p = prop_iter_p->types + 0;
break;
}
if (prop_pair_p->names_cp[1] == property_name_cp
&& ECMA_PROPERTY_GET_NAME_TYPE (prop_iter_p->types[1]) == prop_name_type)
{
JERRY_ASSERT (ECMA_PROPERTY_IS_NAMED_PROPERTY (prop_iter_p->types[1]));
property_p = prop_iter_p->types + 1;
break;
}
#if ENABLED (JERRY_PROPRETY_HASHMAP)
steps++;
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
prop_iter_cp = prop_iter_p->next_property_cp;
}
}
else
{
while (prop_iter_cp != JMEM_CP_NULL)
{
ecma_property_header_t *prop_iter_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
prop_iter_cp);
JERRY_ASSERT (ECMA_PROPERTY_IS_PROPERTY_PAIR (prop_iter_p));
ecma_property_pair_t *prop_pair_p = (ecma_property_pair_t *) prop_iter_p;
if (ECMA_PROPERTY_GET_NAME_TYPE (prop_iter_p->types[0]) == ECMA_DIRECT_STRING_PTR)
{
property_name_cp = prop_pair_p->names_cp[0];
ecma_string_t *prop_name_p = ECMA_GET_NON_NULL_POINTER (ecma_string_t, property_name_cp);
if (ecma_compare_ecma_non_direct_strings (name_p, prop_name_p))
{
property_p = prop_iter_p->types + 0;
break;
}
}
if (ECMA_PROPERTY_GET_NAME_TYPE (prop_iter_p->types[1]) == ECMA_DIRECT_STRING_PTR)
{
property_name_cp = prop_pair_p->names_cp[1];
ecma_string_t *prop_name_p = ECMA_GET_NON_NULL_POINTER (ecma_string_t, property_name_cp);
if (ecma_compare_ecma_non_direct_strings (name_p, prop_name_p))
{
property_p = prop_iter_p->types + 1;
break;
}
}
#if ENABLED (JERRY_PROPRETY_HASHMAP)
steps++;
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
prop_iter_cp = prop_iter_p->next_property_cp;
}
}
#if ENABLED (JERRY_PROPRETY_HASHMAP)
if (steps >= (ECMA_PROPERTY_HASMAP_MINIMUM_SIZE / 2))
{
ecma_property_hashmap_create (obj_p);
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
#if ENABLED (JERRY_LCACHE)
if (property_p != NULL
&& !ecma_is_property_lcached (property_p))
{
ecma_lcache_insert (obj_p, property_name_cp, property_p);
}
#endif /* ENABLED (JERRY_LCACHE) */
return property_p;
} /* ecma_find_named_property */
/**
* Get named data property or named access property in specified object.
*
* Warning:
* the property must exist
*
* @return pointer to the property, if it is found,
* NULL - otherwise.
*/
ecma_property_value_t *
ecma_get_named_data_property (ecma_object_t *obj_p, /**< object to find property in */
ecma_string_t *name_p) /**< property's name */
{
JERRY_ASSERT (obj_p != NULL);
JERRY_ASSERT (name_p != NULL);
JERRY_ASSERT (ecma_is_lexical_environment (obj_p)
|| ecma_get_object_type (obj_p) != ECMA_OBJECT_TYPE_ARRAY
|| !((ecma_extended_object_t *) obj_p)->u.array.is_fast_mode);
ecma_property_t *property_p = ecma_find_named_property (obj_p, name_p);
JERRY_ASSERT (property_p != NULL
&& ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDDATA);
return ECMA_PROPERTY_VALUE_PTR (property_p);
} /* ecma_get_named_data_property */
/**
* Free property values and change their type to deleted.
*/
void
ecma_free_property (ecma_object_t *object_p, /**< object the property belongs to */
jmem_cpointer_t name_cp, /**< name of the property or ECMA_NULL_POINTER */
ecma_property_t *property_p) /**< property */
{
JERRY_ASSERT (object_p != NULL && property_p != NULL);
switch (ECMA_PROPERTY_GET_TYPE (*property_p))
{
case ECMA_PROPERTY_TYPE_NAMEDDATA:
{
ecma_free_value_if_not_object (ECMA_PROPERTY_VALUE_PTR (property_p)->value);
break;
}
case ECMA_PROPERTY_TYPE_NAMEDACCESSOR:
{
#if ENABLED (JERRY_CPOINTER_32_BIT)
ecma_getter_setter_pointers_t *getter_setter_pair_p;
getter_setter_pair_p = ECMA_GET_NON_NULL_POINTER (ecma_getter_setter_pointers_t,
ECMA_PROPERTY_VALUE_PTR (property_p)->getter_setter_pair_cp);
jmem_pools_free (getter_setter_pair_p, sizeof (ecma_getter_setter_pointers_t));
#endif /* ENABLED (JERRY_CPOINTER_32_BIT) */
break;
}
default:
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_INTERNAL);
/* Must be a native pointer. */
JERRY_ASSERT (ECMA_PROPERTY_GET_NAME_TYPE (*property_p) == ECMA_DIRECT_STRING_MAGIC
&& name_cp >= LIT_FIRST_INTERNAL_MAGIC_STRING);
break;
}
}
#if ENABLED (JERRY_LCACHE)
if (ecma_is_property_lcached (property_p))
{
ecma_lcache_invalidate (object_p, name_cp, property_p);
}
#endif /* ENABLED (JERRY_LCACHE) */
if (ECMA_PROPERTY_GET_NAME_TYPE (*property_p) == ECMA_DIRECT_STRING_PTR)
{
ecma_string_t *prop_name_p = ECMA_GET_NON_NULL_POINTER (ecma_string_t, name_cp);
ecma_deref_ecma_string (prop_name_p);
}
} /* ecma_free_property */
/**
* Delete the object's property referenced by its value pointer.
*
* Note: specified property must be owned by specified object.
*/
void
ecma_delete_property (ecma_object_t *object_p, /**< object */
ecma_property_value_t *prop_value_p) /**< property value reference */
{
jmem_cpointer_t cur_prop_cp = object_p->u1.property_list_cp;
ecma_property_header_t *prev_prop_p = NULL;
#if ENABLED (JERRY_PROPRETY_HASHMAP)
ecma_property_hashmap_delete_status hashmap_status = ECMA_PROPERTY_HASHMAP_DELETE_NO_HASHMAP;
if (cur_prop_cp != JMEM_CP_NULL)
{
ecma_property_header_t *cur_prop_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
cur_prop_cp);
if (cur_prop_p->types[0] == ECMA_PROPERTY_TYPE_HASHMAP)
{
prev_prop_p = cur_prop_p;
cur_prop_cp = cur_prop_p->next_property_cp;
hashmap_status = ECMA_PROPERTY_HASHMAP_DELETE_HAS_HASHMAP;
}
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
while (cur_prop_cp != JMEM_CP_NULL)
{
ecma_property_header_t *cur_prop_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t,
cur_prop_cp);
JERRY_ASSERT (ECMA_PROPERTY_IS_PROPERTY_PAIR (cur_prop_p));
ecma_property_pair_t *prop_pair_p = (ecma_property_pair_t *) cur_prop_p;
for (int i = 0; i < ECMA_PROPERTY_PAIR_ITEM_COUNT; i++)
{
if ((prop_pair_p->values + i) == prop_value_p)
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (cur_prop_p->types[i]) != ECMA_PROPERTY_TYPE_SPECIAL);
#if ENABLED (JERRY_PROPRETY_HASHMAP)
if (hashmap_status == ECMA_PROPERTY_HASHMAP_DELETE_HAS_HASHMAP)
{
hashmap_status = ecma_property_hashmap_delete (object_p,
prop_pair_p->names_cp[i],
cur_prop_p->types + i);
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
ecma_free_property (object_p, prop_pair_p->names_cp[i], cur_prop_p->types + i);
cur_prop_p->types[i] = ECMA_PROPERTY_TYPE_DELETED;
prop_pair_p->names_cp[i] = LIT_INTERNAL_MAGIC_STRING_DELETED;
JERRY_ASSERT (ECMA_PROPERTY_PAIR_ITEM_COUNT == 2);
if (cur_prop_p->types[1 - i] != ECMA_PROPERTY_TYPE_DELETED)
{
#if ENABLED (JERRY_PROPRETY_HASHMAP)
/* The other property is still valid. */
if (hashmap_status == ECMA_PROPERTY_HASHMAP_DELETE_RECREATE_HASHMAP)
{
ecma_property_hashmap_free (object_p);
ecma_property_hashmap_create (object_p);
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
return;
}
JERRY_ASSERT (cur_prop_p->types[i] == ECMA_PROPERTY_TYPE_DELETED);
if (prev_prop_p == NULL)
{
object_p->u1.property_list_cp = cur_prop_p->next_property_cp;
}
else
{
prev_prop_p->next_property_cp = cur_prop_p->next_property_cp;
}
ecma_dealloc_property_pair ((ecma_property_pair_t *) cur_prop_p);
#if ENABLED (JERRY_PROPRETY_HASHMAP)
if (hashmap_status == ECMA_PROPERTY_HASHMAP_DELETE_RECREATE_HASHMAP)
{
ecma_property_hashmap_free (object_p);
ecma_property_hashmap_create (object_p);
}
#endif /* ENABLED (JERRY_PROPRETY_HASHMAP) */
return;
}
}
prev_prop_p = cur_prop_p;
cur_prop_cp = cur_prop_p->next_property_cp;
}
} /* ecma_delete_property */
/**
* Check whether the object contains a property
*/
static void
ecma_assert_object_contains_the_property (const ecma_object_t *object_p, /**< ecma-object */
const ecma_property_value_t *prop_value_p, /**< property value */
ecma_property_types_t type) /**< expected property type */
{
#ifndef JERRY_NDEBUG
jmem_cpointer_t prop_iter_cp = object_p->u1.property_list_cp;
JERRY_ASSERT (prop_iter_cp != JMEM_CP_NULL);
ecma_property_header_t *prop_iter_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t, prop_iter_cp);
if (prop_iter_p->types[0] == ECMA_PROPERTY_TYPE_HASHMAP)
{
prop_iter_cp = prop_iter_p->next_property_cp;
}
while (prop_iter_cp != JMEM_CP_NULL)
{
prop_iter_p = ECMA_GET_NON_NULL_POINTER (ecma_property_header_t, prop_iter_cp);
JERRY_ASSERT (ECMA_PROPERTY_IS_PROPERTY_PAIR (prop_iter_p));
ecma_property_pair_t *prop_pair_p = (ecma_property_pair_t *) prop_iter_p;
for (int i = 0; i < ECMA_PROPERTY_PAIR_ITEM_COUNT; i++)
{
if ((prop_pair_p->values + i) == prop_value_p)
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (prop_pair_p->header.types[i]) == type);
return;
}
}
prop_iter_cp = prop_iter_p->next_property_cp;
}
#else /* JERRY_NDEBUG */
JERRY_UNUSED (object_p);
JERRY_UNUSED (prop_value_p);
JERRY_UNUSED (type);
#endif /* !JERRY_NDEBUG */
} /* ecma_assert_object_contains_the_property */
/**
* Assign value to named data property
*
* Note:
* value previously stored in the property is freed
*/
inline void JERRY_ATTR_ALWAYS_INLINE
ecma_named_data_property_assign_value (ecma_object_t *obj_p, /**< object */
ecma_property_value_t *prop_value_p, /**< property value reference */
ecma_value_t value) /**< value to assign */
{
ecma_assert_object_contains_the_property (obj_p, prop_value_p, ECMA_PROPERTY_TYPE_NAMEDDATA);
ecma_value_assign_value (&prop_value_p->value, value);
} /* ecma_named_data_property_assign_value */
/**
* Get named accessor property getter-setter-pair
*
* @return pointer to object's getter-setter pair
*/
ecma_getter_setter_pointers_t *
ecma_get_named_accessor_property (const ecma_property_value_t *prop_value_p) /**< property value reference */
{
#if ENABLED (JERRY_CPOINTER_32_BIT)
return ECMA_GET_NON_NULL_POINTER (ecma_getter_setter_pointers_t, prop_value_p->getter_setter_pair_cp);
#else /* !ENABLED (JERRY_CPOINTER_32_BIT) */
return (ecma_getter_setter_pointers_t *) &prop_value_p->getter_setter_pair;
#endif /* ENABLED (JERRY_CPOINTER_32_BIT) */
} /* ecma_get_named_accessor_property */
/**
* Set getter of named accessor property
*/
void
ecma_set_named_accessor_property_getter (ecma_object_t *object_p, /**< the property's container */
ecma_property_value_t *prop_value_p, /**< property value reference */
ecma_object_t *getter_p) /**< getter object */
{
ecma_assert_object_contains_the_property (object_p, prop_value_p, ECMA_PROPERTY_TYPE_NAMEDACCESSOR);
#if ENABLED (JERRY_CPOINTER_32_BIT)
ecma_getter_setter_pointers_t *getter_setter_pair_p;
getter_setter_pair_p = ECMA_GET_NON_NULL_POINTER (ecma_getter_setter_pointers_t,
prop_value_p->getter_setter_pair_cp);
ECMA_SET_POINTER (getter_setter_pair_p->getter_cp, getter_p);
#else /* !ENABLED (JERRY_CPOINTER_32_BIT) */
ECMA_SET_POINTER (prop_value_p->getter_setter_pair.getter_cp, getter_p);
#endif /* ENABLED (JERRY_CPOINTER_32_BIT) */
} /* ecma_set_named_accessor_property_getter */
/**
* Set setter of named accessor property
*/
void
ecma_set_named_accessor_property_setter (ecma_object_t *object_p, /**< the property's container */
ecma_property_value_t *prop_value_p, /**< property value reference */
ecma_object_t *setter_p) /**< setter object */
{
ecma_assert_object_contains_the_property (object_p, prop_value_p, ECMA_PROPERTY_TYPE_NAMEDACCESSOR);
#if ENABLED (JERRY_CPOINTER_32_BIT)
ecma_getter_setter_pointers_t *getter_setter_pair_p;
getter_setter_pair_p = ECMA_GET_NON_NULL_POINTER (ecma_getter_setter_pointers_t,
prop_value_p->getter_setter_pair_cp);
ECMA_SET_POINTER (getter_setter_pair_p->setter_cp, setter_p);
#else /* !ENABLED (JERRY_CPOINTER_32_BIT) */
ECMA_SET_POINTER (prop_value_p->getter_setter_pair.setter_cp, setter_p);
#endif /* ENABLED (JERRY_CPOINTER_32_BIT) */
} /* ecma_set_named_accessor_property_setter */
/**
* Get property's 'Writable' attribute value
*
* @return true - property is writable,
* false - otherwise
*/
inline bool JERRY_ATTR_ALWAYS_INLINE
ecma_is_property_writable (ecma_property_t property) /**< property */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_NAMEDDATA
|| ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_VIRTUAL);
return (property & ECMA_PROPERTY_FLAG_WRITABLE) != 0;
} /* ecma_is_property_writable */
/**
* Set property's 'Writable' attribute value
*/
void
ecma_set_property_writable_attr (ecma_property_t *property_p, /**< [in,out] property */
bool is_writable) /**< new value for writable flag */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDDATA);
if (is_writable)
{
*property_p = (uint8_t) (*property_p | ECMA_PROPERTY_FLAG_WRITABLE);
}
else
{
*property_p = (uint8_t) (*property_p & ~ECMA_PROPERTY_FLAG_WRITABLE);
}
} /* ecma_set_property_writable_attr */
/**
* Get property's 'Enumerable' attribute value
*
* @return true - property is enumerable,
* false - otherwise
*/
inline bool JERRY_ATTR_ALWAYS_INLINE
ecma_is_property_enumerable (ecma_property_t property) /**< property */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_NAMEDDATA
|| ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_NAMEDACCESSOR
|| ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_VIRTUAL);
return (property & ECMA_PROPERTY_FLAG_ENUMERABLE) != 0;
} /* ecma_is_property_enumerable */
/**
* Set property's 'Enumerable' attribute value
*/
void
ecma_set_property_enumerable_attr (ecma_property_t *property_p, /**< [in,out] property */
bool is_enumerable) /**< new value for enumerable flag */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDDATA
|| ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDACCESSOR);
if (is_enumerable)
{
*property_p = (uint8_t) (*property_p | ECMA_PROPERTY_FLAG_ENUMERABLE);
}
else
{
*property_p = (uint8_t) (*property_p & ~ECMA_PROPERTY_FLAG_ENUMERABLE);
}
} /* ecma_set_property_enumerable_attr */
/**
* Get property's 'Configurable' attribute value
*
* @return true - property is configurable,
* false - otherwise
*/
inline bool JERRY_ATTR_ALWAYS_INLINE
ecma_is_property_configurable (ecma_property_t property) /**< property */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_NAMEDDATA
|| ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_NAMEDACCESSOR
|| ECMA_PROPERTY_GET_TYPE (property) == ECMA_PROPERTY_TYPE_VIRTUAL);
return (property & ECMA_PROPERTY_FLAG_CONFIGURABLE) != 0;
} /* ecma_is_property_configurable */
/**
* Set property's 'Configurable' attribute value
*/
void
ecma_set_property_configurable_attr (ecma_property_t *property_p, /**< [in,out] property */
bool is_configurable) /**< new value for configurable flag */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDDATA
|| ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDACCESSOR);
if (is_configurable)
{
*property_p = (uint8_t) (*property_p | ECMA_PROPERTY_FLAG_CONFIGURABLE);
}
else
{
*property_p = (uint8_t) (*property_p & ~ECMA_PROPERTY_FLAG_CONFIGURABLE);
}
} /* ecma_set_property_configurable_attr */
#if ENABLED (JERRY_LCACHE)
/**
* Check whether the property is registered in LCache
*
* @return true / false
*/
inline bool JERRY_ATTR_ALWAYS_INLINE
ecma_is_property_lcached (ecma_property_t *property_p) /**< property */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDDATA
|| ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDACCESSOR
|| ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_INTERNAL);
return (*property_p & ECMA_PROPERTY_FLAG_LCACHED) != 0;
} /* ecma_is_property_lcached */
/**
* Set value of flag indicating whether the property is registered in LCache
*/
inline void JERRY_ATTR_ALWAYS_INLINE
ecma_set_property_lcached (ecma_property_t *property_p, /**< property */
bool is_lcached) /**< new value for lcached flag */
{
JERRY_ASSERT (ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDDATA
|| ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_NAMEDACCESSOR
|| ECMA_PROPERTY_GET_TYPE (*property_p) == ECMA_PROPERTY_TYPE_INTERNAL);
if (is_lcached)
{
*property_p = (uint8_t) (*property_p | ECMA_PROPERTY_FLAG_LCACHED);
}
else
{
*property_p = (uint8_t) (*property_p & ~ECMA_PROPERTY_FLAG_LCACHED);
}
} /* ecma_set_property_lcached */
#endif /* ENABLED (JERRY_LCACHE) */
/**
* Construct empty property descriptor, i.e.:
* property descriptor with all is_defined flags set to false and the rest - to default value.
*
* @return empty property descriptor
*/
ecma_property_descriptor_t
ecma_make_empty_property_descriptor (void)
{
ecma_property_descriptor_t prop_desc;
prop_desc.flags = 0;
prop_desc.value = ECMA_VALUE_UNDEFINED;
prop_desc.get_p = NULL;
prop_desc.set_p = NULL;
return prop_desc;
} /* ecma_make_empty_property_descriptor */
/**
* Free values contained in the property descriptor
* and make it empty property descriptor
*/
void
ecma_free_property_descriptor (ecma_property_descriptor_t *prop_desc_p) /**< property descriptor */
{
if (prop_desc_p->flags & ECMA_PROP_IS_VALUE_DEFINED)
{
ecma_free_value (prop_desc_p->value);
}
if ((prop_desc_p->flags & ECMA_PROP_IS_GET_DEFINED)
&& prop_desc_p->get_p != NULL)
{
ecma_deref_object (prop_desc_p->get_p);
}
if ((prop_desc_p->flags & ECMA_PROP_IS_SET_DEFINED)
&& prop_desc_p->set_p != NULL)
{
ecma_deref_object (prop_desc_p->set_p);
}
*prop_desc_p = ecma_make_empty_property_descriptor ();
} /* ecma_free_property_descriptor */
/**
* The size of error reference must be 8 bytes to use jmem_pools_alloc().
*/
JERRY_STATIC_ASSERT (sizeof (ecma_error_reference_t) == 8,
ecma_error_reference_size_must_be_8_bytes);
/**
* Create an error reference from a given value.
*
* Note:
* Reference of the value is taken.
*
* @return error reference value
*/
ecma_value_t
ecma_create_error_reference (ecma_value_t value, /**< referenced value */
bool is_exception) /**< error reference is an exception */
{
ecma_error_reference_t *error_ref_p = (ecma_error_reference_t *) jmem_pools_alloc (sizeof (ecma_error_reference_t));
error_ref_p->refs_and_flags = ECMA_ERROR_REF_ONE | (is_exception ? 0 : ECMA_ERROR_REF_ABORT);
error_ref_p->value = value;
return ecma_make_error_reference_value (error_ref_p);
} /* ecma_create_error_reference */
/**
* Create an error reference from the currently thrown error value.
*
* @return error reference value
*/
ecma_value_t
ecma_create_error_reference_from_context (void)
{
return ecma_create_error_reference (JERRY_CONTEXT (error_value),
(JERRY_CONTEXT (status_flags) & ECMA_STATUS_EXCEPTION) != 0);
} /* ecma_create_error_reference_from_context */
/**
* Create an error reference from a given object.
*
* Note:
* Reference of the value is taken.
*
* @return error reference value
*/
inline ecma_value_t JERRY_ATTR_ALWAYS_INLINE
ecma_create_error_object_reference (ecma_object_t *object_p) /**< referenced object */
{
return ecma_create_error_reference (ecma_make_object_value (object_p), true);
} /* ecma_create_error_object_reference */
/**
* Increase ref count of an error reference.
*/
void
ecma_ref_error_reference (ecma_error_reference_t *error_ref_p) /**< error reference */
{
if (JERRY_LIKELY (error_ref_p->refs_and_flags < ECMA_ERROR_MAX_REF))
{
error_ref_p->refs_and_flags += ECMA_ERROR_REF_ONE;
}
else
{
jerry_fatal (ERR_REF_COUNT_LIMIT);
}
} /* ecma_ref_error_reference */
/**
* Decrease ref count of an error reference.
*/
void
ecma_deref_error_reference (ecma_error_reference_t *error_ref_p) /**< error reference */
{
JERRY_ASSERT (error_ref_p->refs_and_flags >= ECMA_ERROR_REF_ONE);
error_ref_p->refs_and_flags -= ECMA_ERROR_REF_ONE;
if (error_ref_p->refs_and_flags < ECMA_ERROR_REF_ONE)
{
ecma_free_value (error_ref_p->value);
jmem_pools_free (error_ref_p, sizeof (ecma_error_reference_t));
}
} /* ecma_deref_error_reference */
/**
* Clears error reference, and returns with the value.
*
* @return value referenced by the error
*/
ecma_value_t
ecma_clear_error_reference (ecma_value_t value, /**< error reference */
bool set_abort_flag) /**< set abort flag */
{
ecma_error_reference_t *error_ref_p = ecma_get_error_reference_from_value (value);
if (set_abort_flag)
{
if (error_ref_p->refs_and_flags & ECMA_ERROR_REF_ABORT)
{
JERRY_CONTEXT (status_flags) &= (uint32_t) ~ECMA_STATUS_EXCEPTION;
}
else
{
JERRY_CONTEXT (status_flags) |= ECMA_STATUS_EXCEPTION;
}
}
JERRY_ASSERT (error_ref_p->refs_and_flags >= ECMA_ERROR_REF_ONE);
if (error_ref_p->refs_and_flags >= 2 * ECMA_ERROR_REF_ONE)
{
error_ref_p->refs_and_flags -= ECMA_ERROR_REF_ONE;
return ecma_copy_value (error_ref_p->value);
}
ecma_value_t referenced_value = error_ref_p->value;
jmem_pools_free (error_ref_p, sizeof (ecma_error_reference_t));
return referenced_value;
} /* ecma_clear_error_reference */
/**
* Increase reference counter of Compact
* Byte Code or regexp byte code.
*/
void
ecma_bytecode_ref (ecma_compiled_code_t *bytecode_p) /**< byte code pointer */
{
/* Abort program if maximum reference number is reached. */
if (bytecode_p->refs >= UINT16_MAX)
{
jerry_fatal (ERR_REF_COUNT_LIMIT);
}
bytecode_p->refs++;
} /* ecma_bytecode_ref */
/**
* Decrease reference counter of Compact
* Byte Code or regexp byte code.
*/
void
ecma_bytecode_deref (ecma_compiled_code_t *bytecode_p) /**< byte code pointer */
{
JERRY_ASSERT (bytecode_p->refs > 0);
JERRY_ASSERT (!(bytecode_p->status_flags & CBC_CODE_FLAGS_STATIC_FUNCTION));
bytecode_p->refs--;
if (bytecode_p->refs > 0)
{
/* Non-zero reference counter. */
return;
}
if (bytecode_p->status_flags & CBC_CODE_FLAGS_FUNCTION)
{
ecma_value_t *literal_start_p = NULL;
uint32_t literal_end;
uint32_t const_literal_end;
if (bytecode_p->status_flags & CBC_CODE_FLAGS_UINT16_ARGUMENTS)
{
cbc_uint16_arguments_t *args_p = (cbc_uint16_arguments_t *) bytecode_p;
literal_end = args_p->literal_end;
const_literal_end = args_p->const_literal_end;
literal_start_p = (ecma_value_t *) ((uint8_t *) bytecode_p + sizeof (cbc_uint16_arguments_t));
literal_start_p -= args_p->register_end;
}
else
{
cbc_uint8_arguments_t *args_p = (cbc_uint8_arguments_t *) bytecode_p;
literal_end = args_p->literal_end;
const_literal_end = args_p->const_literal_end;
literal_start_p = (ecma_value_t *) ((uint8_t *) bytecode_p + sizeof (cbc_uint8_arguments_t));
literal_start_p -= args_p->register_end;
}
for (uint32_t i = const_literal_end; i < literal_end; i++)
{
ecma_compiled_code_t *bytecode_literal_p = ECMA_GET_INTERNAL_VALUE_POINTER (ecma_compiled_code_t,
literal_start_p[i]);
/* Self references are ignored. */
if (bytecode_literal_p != bytecode_p)
{
ecma_bytecode_deref (bytecode_literal_p);
}
}
#if ENABLED (JERRY_DEBUGGER)
if ((JERRY_CONTEXT (debugger_flags) & JERRY_DEBUGGER_CONNECTED)
&& !(bytecode_p->status_flags & CBC_CODE_FLAGS_DEBUGGER_IGNORE)
&& jerry_debugger_send_function_cp (JERRY_DEBUGGER_RELEASE_BYTE_CODE_CP, bytecode_p))
{
/* Delay the byte code free until the debugger client is notified.
* If the connection is aborted the pointer is still freed by
* jerry_debugger_close_connection(). */
jerry_debugger_byte_code_free_t *byte_code_free_p = (jerry_debugger_byte_code_free_t *) bytecode_p;
jmem_cpointer_t byte_code_free_head = JERRY_CONTEXT (debugger_byte_code_free_head);
byte_code_free_p->prev_cp = ECMA_NULL_POINTER;
jmem_cpointer_t byte_code_free_cp;
JMEM_CP_SET_NON_NULL_POINTER (byte_code_free_cp, byte_code_free_p);
if (byte_code_free_head == ECMA_NULL_POINTER)
{
JERRY_CONTEXT (debugger_byte_code_free_tail) = byte_code_free_cp;
}
else
{
jerry_debugger_byte_code_free_t *first_byte_code_free_p;
first_byte_code_free_p = JMEM_CP_GET_NON_NULL_POINTER (jerry_debugger_byte_code_free_t,
byte_code_free_head);
first_byte_code_free_p->prev_cp = byte_code_free_cp;
}
JERRY_CONTEXT (debugger_byte_code_free_head) = byte_code_free_cp;
return;
}
#endif /* ENABLED (JERRY_DEBUGGER) */
#if ENABLED (JERRY_MEM_STATS)
jmem_stats_free_byte_code_bytes (((size_t) bytecode_p->size) << JMEM_ALIGNMENT_LOG);
#endif /* ENABLED (JERRY_MEM_STATS) */
}
else
{
#if ENABLED (JERRY_BUILTIN_REGEXP)
re_compiled_code_t *re_bytecode_p = (re_compiled_code_t *) bytecode_p;
ecma_deref_ecma_string (ecma_get_string_from_value (re_bytecode_p->source));
#endif /* ENABLED (JERRY_BUILTIN_REGEXP) */
}
jmem_heap_free_block (bytecode_p,
((size_t) bytecode_p->size) << JMEM_ALIGNMENT_LOG);
} /* ecma_bytecode_deref */
#if (JERRY_STACK_LIMIT != 0)
/**
* Check the current stack usage by calculating the difference from the initial stack base.
*
* @return current stack usage in bytes
*/
uintptr_t JERRY_ATTR_NOINLINE
ecma_get_current_stack_usage (void)
{
volatile int __sp;
return (uintptr_t) (JERRY_CONTEXT (stack_base) - (uintptr_t)&__sp);
} /* ecma_get_current_stack_usage */
#endif /* (JERRY_STACK_LIMIT != 0) */
/**
* @}
* @}
*/
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