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2531 lines
103 KiB
2531 lines
103 KiB
===========
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duk_hobject
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===========
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Overview
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========
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The ``duk_hobject`` type represents an object with key-value properties,
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and is the most important type from an implementation point of view.
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It provides objects for various purposes:
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* Objects with E5 normal object semantics
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* Objects with E5 array object exotic behavior
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* Objects with E5 string object exotic behavior
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* Objects with E5 arguments object exotic behavior
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* Objects with no E5 semantics, for internal use
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This document discusses the ``duk_hobject`` object in detail, including:
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* Requirements overview
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* Features of Ecmascript E5 objects
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* Internal data structure and algorithms
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* Enumeration guarantees
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* Ecmascript property behavior (default and exotic)
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* Design notes, future work
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The details of property-related algorithms in E5 are pretty intricate
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and are described separately in ``hobject-algorithms.rst``.
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The following parts of Ecmascript E5 are useful background:
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+-----------+-------------------------------------------------------------+
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| Section | Description |
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+===========+=============================================================+
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| 8.6 | Object type, internal properties, property attributes |
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+-----------+-------------------------------------------------------------+
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| 8.10 | Property descriptors |
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+-----------+-------------------------------------------------------------+
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| 8.12 | Default property access methods |
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+-----------+-------------------------------------------------------------+
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| 10.6 | Arguments object exotic behavior |
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+-----------+-------------------------------------------------------------+
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| 15.4.5.1 | Array object exotic behavior |
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+-----------+-------------------------------------------------------------+
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| 15.5.5.2 | String object exotic behavior |
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+-----------+-------------------------------------------------------------+
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See also the following documentation:
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* ``hobject-algorithms.rst``: detailed derivation of object algorithms
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* ``hobject-enumeration.rst``: more discussion on enumeration
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* ``error-objects.rst``: error object properties
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* ``function-objects.rst``: function template and instance properties
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Requirements overview
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=====================
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Ecmascript object compatibility requires:
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* Properties with a string key and a value that is either a plain data
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value or an accessor (getter/setter)
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* Property attributes which control the behavior of individual properties
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(e.g. enumerability and writability)
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* Object extensibility flag which controls addition of new properties
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* Prototype-based inheritance of properties along a loop-free prototype chain
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* Some very basic enumeration guarantees for both mutating and non-mutating
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enumeration
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* Object internal properties (at a conceptual level)
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Additional practical requirements include:
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* Additional enumeration guarantees (e.g. enumeration order matches key
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insertion order); see separate discussion on enumeration
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* Minimal memory footprint, especially for objects with few properties
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which dominate common use
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* Near constant property lookup performance, even for large objects
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* Near constant amortized property insert performance, even for large objects
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* Fast read/write access for array entries, in particular avoiding string
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interning whenever possible
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* Sparse array support (e.g. ``var x=[]; x[0]=1; x[1000000]=2;``): must be
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compliant, shouldn't allocate megabytes of memory, but does not have to
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be fast
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* Support long-lived objects with an arbitrary number of key insertions
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and deletions (implies "compaction" of keys / ordering structure)
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There are unavoidable trade-offs involved, the current trade-off preferences
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are roughly as follows (most important to least important):
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#. Compliance
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#. Compactness
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#. Performance
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#. Low complexity
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Compliance is a must-have goal for all object features. Performance is only
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really relevant for common idioms. Rare cases need to be compliant but not
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especially compact or performant: for instance, sparse arrays don't perform
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very well but are still compliant.
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Object features
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===============
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Named and internal properties
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-----------------------------
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An Ecmascript object consists of:
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* A set of externally visible *named properties*
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* A set of (conceptual) *internal properties*
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The externally visible named properties are characterized by:
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* A string key
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+ 16-bit characters (any 16-bit unsigned integer codepoints may be used)
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+ Even array indices are strings, e.g. ``x[0]`` really means ``x["0"]``
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* A property value which may be:
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+ A *data property*, a plain Ecmascript value
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+ An *accessor property*, a setter/getter function pair invoked
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for property accesses
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* Property attributes which control property accesses:
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+ For data properties:
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- ``[[Configurable]]``
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- ``[[Enumerable]]``
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- ``[[Value]]``
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- ``[[Writable]]``
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+ For accessor properties:
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- ``[[Configurable]]``
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- ``[[Enumerable]]``
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- ``[[Get]]``
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- ``[[Set]]``
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* The ``[[Extensible]]`` internal property determines whether new (own) keys
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can be added to an object. Many other internal properties exist.
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Internal properties are used in E5 to specify required behavior; the
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concrete property implementation is implementation specific. The
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current implementation for internal properties is covered in more
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detail below.
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Property attributes and descriptors
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-----------------------------------
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Property attributes affect property access algorithms internally. They are
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also externally visible and can be manipulated through built-in methods.
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The property attributes are:
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* ``[[Configurable]]``
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* ``[[Enumerable]]``
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* ``[[Value]]``
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* ``[[Writable]]``
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* ``[[Get]]``
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* ``[[Set]]``
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New properties added to objects by an assignment are by default data
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properties with the following attributes: ``[[Writable]]=true``,
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``[[Enumerable]]=true``, ``[[Configurable]]=true``. This is implicit
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in the ``[[Put]]`` algorithm (E5 Section 8.12.5, step 6). Note that
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these defaults differ from the "official default values" (all attributes
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``false``) in E5 Section 8.6.1 which are used for e.g.
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``[[DefineOwnProperty]]``.
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User code can deviate from the defaults for assignments by defining or
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modifying properties using ``Object.defineProperty()``. This is not
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very common, so almost all user properties have default attributes.
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Built-in objects often have properties with non-default attributes, though.
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A *property descriptor* contains zero or more property attributes,
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and is used both internally and externally to describe or modify
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property attributes. Property descriptors are used internally in the E5
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specification with the following notation::
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{ ``[[Value]]``: 42, ``[[Writable]]``: true }
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The same property descriptor would be represented as an external Ecmascript
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value::
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{ "value": 42, "writable": true }
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The internal and external property descriptors are converted through the
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internal ``FromPropertyDescriptor()`` and ``ToPropertyDescriptor()``
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methods.
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Property descriptors are classified into several categories based on
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what keys they contain:
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* Data property descriptor: contains ``[[Value]]`` or ``[[Writable]]``
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* Accessor property descriptor: contains ``[[Set]]`` or ``[[Get]]``
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* Generic property descriptor: a descriptor which is neither a data nor
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an accessor property descriptor, i.e. does not contain
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``[[Value]]``, ``[[Writable]]``, ``[[Set]]``, or ``[[Get]]``
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Although a property descriptor can technically be both a data property
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descriptor and an accessor property descriptor at the same time, such
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descriptors are rejected whenever they are encountered. The
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``[[Configurable]]`` and ``[[Enumerable]]`` attributes can be in any
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kind of a descriptor.
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A property descriptor is *fully populated* if it contains all the keys of
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its type, i.e.:
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* A fully populated data descriptor contains all of the following:
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``[[Configurable]]``, ``[[Enumerable]]``, ``[[Value]]``, ``[[Writable]]``
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* A fully populated accessor descriptor contains all of the following:
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``[[Configurable]]``, ``[[Enumerable]]``, ``[[Get]]``, ``[[Set]]``
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The property attributes stored in the object for a certain property always
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form a fully populated property descriptor. Any missing values are always
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filled in with defaults when a property is first inserted, and although
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attribute values can be changed after insertion, the attributes themselves
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cannot be removed.
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Partially populated property descriptors are used internally in the
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specification for describing property modifications. They can also be
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used externally (for similar purposes) through ``Object.defineProperty()``.
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Consider the following example, which illustrates how properties and
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their attributes can be defined in various ways::
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// array initializer
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var o = [ "one", "two" ]; // also sets "length" to 2
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// add "foo" (writable, enumerable, configurable)
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o.foo = 1;
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// modify attributes after insertion
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Object.defineProperty(o, "foo", {
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writable: false
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});
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// insert an accessor, with [[DefineOwnProperty]] default
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// attributes (non-enumerable, non-configurable)
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Object.defineProperty(o, "bar", {
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"get": function() { return "bar"; },
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"set": function(x) { throw new Error("cannot write bar"); }
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});
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The object would have the following internal state (represented as
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external property descriptors)::
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"0" --> { "configurable": true,
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"enumerable": true,
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"writable": true,
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"value": 'one' }
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"1" --> { "configurable": true,
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"enumerable": true,
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"writable": true,
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"value": 'two' }
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// non-default attributes (E5 Section 15.4.5.2)
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"length" --> { "configurable": false,
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"enumerable": false,
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"writable": true,
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"value": 2 }
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"foo" --> { "configurable": true,
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"enumerable": true,
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"writable": false,
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"value": 1 }
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// [[DefineOwnProperty]] defaults for new properties
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// differ from [[Put]] (defaults to false)
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"bar" --> { "configurable": false,
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"enumerable": false,
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"get": <function reference>,
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"set": <function reference> }
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Property descriptors can also be read back from user code through
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``Object.getOwnPropertyDescriptor()``. Example using NodeJS / V8::
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var o = {
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foo: 1,
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get bar() { return "bar"; },
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set bar(x) { throw new Error("cannot write bar"); }
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};
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// Prints:
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// { value: 1,
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// writable: true,
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// enumerable: true,
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// configurable: true }
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console.log(Object.getOwnPropertyDescriptor(o, "foo"));
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// Prints:
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// { get: [Function: bar],
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// set: [Function: bar],
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// enumerable: true,
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// configurable: true }
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console.log(Object.getOwnPropertyDescriptor(o, "bar"));
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The visibility of property attributes to user code poses some implementation
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challenges. Ordinary property access occurs through the ``[[Get]]``,
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``[[Put]]``, and ``[[Delete]]`` algorithms, hiding some of the internal
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complexity regarding property attributes etc. However, the built-in method
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``Object.defineProperty()`` exposes the internal ``[[DefineOwnProperty]]``
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in all its complexity to user code.
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The current implementation manages to use fully populated descriptors
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internally, and expose partial descriptors only through
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``Object.defineProperty()``.
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Prototype chain
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---------------
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Each object has a non-mutable *internal prototype* established at
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object creation (``[[Prototype]]`` internal property). The value of
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the internal prototype must be another object or null. Since the
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prototype object may also have an internal prototype (and so on), the
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objects form a non-mutable *prototype chain* terminating at an object
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whose internal prototype is ``null``.
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The prototype chain affects most property access algorithms with the
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general principle that if a property is not found in a certain object,
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the prototype chain is then searched in ascending order. To simplify:
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* Property read operations return the value found in the first object
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in the prototype chain containing the property. If an accessor
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property is found, the getter is called.
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* Property write operations first check the prototype chain to see
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whether the property exists. If so, the property may prevent the
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write (if a non-writable data property), cause a setter call (if an
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accessor property), or allow the write. The write is allowed and
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not captured by a setter, the property is added to the *original target
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object* (instead of an object possibly higher up in the prototype chain).
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* Property delete operations do not consult the prototype chain and
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only have an effect on the target object.
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The non-mutability of the prototype chain is not very explicit in the
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specification (nor does the current implementation assume or take
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advantage of its non-mutability). The requirement is stated in a
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footnote in E5 Section 8.6.2:
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NOTE This specification defines no ECMAScript language operators or
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built-in functions that permit a program to modify an object's
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``[[Class]]`` or ``[[Prototype]]`` internal properties or to change
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the value of [[Extensible]] from false to true.
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The prototype chain is required to be loop-free; it is required to
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terminate in a null reference (again, in E5 Section 8.6.2):
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Every ``[[Prototype]]`` chain must have finite length (that is, starting
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from any object, recursively accessing the [[Prototype]] internal
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property must eventually lead to a null value).
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The current implementation makes no specific effort to ensure this because
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plain Ecmascript code cannot create prototype loops (though C code can
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easily do so). To see why this is the case, assume that the current set of
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objects have no prototype loops and a new object is created. The internal
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prototype of the created object is either set to ``null`` or one of the
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existing objects during its creation. Since the prototypes of the existing
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objects cannot be updated, the result is a new set of objects without
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prototype loops. Even so, all prototype walking loops in the implementation
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contain a sanity limit for prototype chain length to break out should a
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loop be somehow created.
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Valid array index and length
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----------------------------
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The E5 specification has very specific definitions for *valid array index*
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property names and *valid array length* property values. Only these trigger
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the ``Array`` specific ``[[DefineOwnProperty]]`` behavior in E5 Section
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15.4.5.1 steps 3 and 4.
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Note that these requirements do not simply specify a minimum length for
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supported arrays: they also specify a maximum length for arrays at least
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with respect to how ``length`` behaves. It would be nice to be able to
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support larger arrays as a build option, but there are probably no realistic
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cases with arrays larger than 4G elements which would still be relevant for
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embedding Duktape.
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Array index
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:::::::::::
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Ecmascript E5 Section 15.4 states:
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A property name ``P`` (in the form of a String value) is an *array index*
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if and only if ``ToString(ToUint32(P))`` is equal to ``P`` and
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``ToUint32(P)`` is not equal to 2^32-1 (0xffffffff).
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This implies that the maximum array length is 2**32-1 (0xffffffff) and
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the maximum array index is one less, 2**32-2 (0xfffffffe). All valid
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array index and length values can be represented with unsigned 32-bit
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values. Because 0xffffffff is not a valid array index, it is used internally
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as a convenient "no array index" marker (``DUK_HSTRING_NO_ARRAY_INDEX``).
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For instance, a coercion call can return the marker to indicate that an input
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was not a valid array index.
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Because Ecmascript object property keys are strings, all array indices
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encountered in property access expressions are conceptually first coerced
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to a string form using ``ToString()`` and then checked whether they are
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valid array indexes (this is unlike array ``length`` values, which can
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have any type, see below). (Obviously, this explicit coercion should be
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avoided whenever possible.)
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The following table lists the possible coercions:
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+---------------+-----------------+---------------------------------------+
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| Property name | ``ToString`` | Valid array index? |
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+===============+=================+=======================================+
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| ``undefined`` | ``"undefined"`` | no |
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+---------------+-----------------+---------------------------------------+
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| ``null`` | ``"null"`` | no |
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+---------------+-----------------+---------------------------------------+
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| ``false`` | ``"false"`` | no |
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+---------------+-----------------+---------------------------------------+
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| ``true`` | ``"true"`` | no |
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+---------------+-----------------+---------------------------------------+
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| a number | various | yes, if a whole number in the range |
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| | | [0,2**32-2] |
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+---------------+-----------------+---------------------------------------+
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| a string | same | yes, if a "canonical" representation |
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| | | for a whole number in the range |
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| | | [0,2**32-2] (``"2"`` is valid, while |
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| | | ``"0.2e1"`` is not) |
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+---------------+-----------------+---------------------------------------+
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| an object | various | depends on coerced string value |
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+---------------+-----------------+---------------------------------------+
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Note that for instance ``"0.2e1"`` which numerically represents 2 is not
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a valid array index: ``ToString(ToUint32("0.2e1"))`` produces ``"2"``, but
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this is not equal to the original string ``"0.2e1"`` (which is required).
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Array length
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::::::::::::
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The requirements for a valid *array length* are a bit different, because
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array length is assigned as an arbitrary property value and is not therefore
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automatically coerced to a string first.
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The requirements for a valid array length are implicit in E5 Section 15.4.5.1,
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steps 3.c to 3.d:
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* Step 3.c: Let ``newLen`` be ``ToUint32(Desc.[[Value]])``.
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* Step 3.d: If ``newLen`` is not equal to ``ToNumber(Desc.[[Value]])``, throw
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a ``RangeError`` exception
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The requirements boils down to (for input value ``X``):
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* ``ToUint32(X)`` == ``ToNumber(X)``
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The requirements are seemingly similar to the array index requirements, but
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in fact allow a wider set of values, such as:
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* ``true`` represents array length ``1``, but is not a valid array index
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* ``"0.2e1"`` represents array length ``2``, but is not a valid array index
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* ``0xffffffff`` represents array length 2**32-1, but is not a valid array index
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A potential ``length`` value ``X`` is treated as follows (see E5 Sections
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9.3 and 9.6 for definitions of the coercions ``ToNumber`` and ``ToUint32``):
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+----------------+--------------+--------------+--------------------------+
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| Property value | ``ToNumber`` | ``ToUint32`` | Valid array length? |
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+================+==============+==============+==========================+
|
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| ``undefined`` | ``NaN`` | ``+0`` | no |
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+----------------+--------------+--------------+--------------------------+
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| ``null`` | ``+0`` | ``+0`` | yes, length ``0`` |
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+----------------+--------------+--------------+--------------------------+
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| ``false`` | ``+0`` | ``+0`` | yes, length ``0`` |
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+----------------+--------------+--------------+--------------------------+
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| ``true`` | ``1`` | ``1`` | yes, length ``1`` |
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+----------------+--------------+--------------+--------------------------+
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| a number | various | various | yes, if whole number in |
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| | | | the range [0,2**32-1] |
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+----------------+--------------+--------------+--------------------------+
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| a string | various | various | yes, if representation of|
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| | | | a whole number in the |
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| | | | range [0,2**32-1] (does |
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| | | | not need to be canonical,|
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| | | | e.g. ``"2"``, ``"2.0"``, |
|
|
| | | | ``"0.2e1"`` are all |
|
|
| | | | acceptable |
|
|
+----------------+--------------+--------------+--------------------------+
|
|
| an object | various | various | depends on coerced |
|
|
| | | | values |
|
|
+----------------+--------------+--------------+--------------------------+
|
|
|
|
As an example of using a non-number as Array length::
|
|
|
|
duk> var a = [ 'foo', 'bar', 'quux' ]; a
|
|
= foo,bar,quux
|
|
duk> a.length = true; // same as a.length = 1
|
|
= true
|
|
duk> a
|
|
= foo
|
|
duk> a.length
|
|
= 1
|
|
|
|
Enumeration requirements
|
|
------------------------
|
|
|
|
Enumeration requirements are discussed in a separate section below,
|
|
together with the current implementation for enumerating object keys.
|
|
|
|
.. raw:: LaTeX
|
|
|
|
\newpage
|
|
|
|
Structure overview
|
|
==================
|
|
|
|
The memory layout of an ``duk_hobject`` is illustrated below::
|
|
|
|
duk_hobject property allocation
|
|
(fixed allocation) (dynamic allocation)
|
|
|
|
+------------------------+ +---------------------------+
|
|
| duk_heaphdr (flags) | .---->| entry part keys |
|
|
+========================+ | | (e_size x duk_hstring *) |
|
|
| duk_u8 *p -------------+--' +---------------------------+
|
|
| duk_u32 e_size | .->| entry part values |
|
|
| duk_u32 e_next | : | (e_size x duk_propvalue) |
|
|
| duk_u32 a_size | : +---------------------------+
|
|
| duk_u32 h_size | +->| entry part flags |
|
|
| duk_hobject *prototype | : | (e_size x duk_u8) |
|
|
+------------------------+ : +---------------------------+
|
|
: duk_hcompfunc : +->| array part values |
|
|
: duk_hnatfunc : : | (a_size x duk_tval) |
|
|
: duk_hthread : : +---------------------------+
|
|
: ... : +->| hash part indices |
|
|
: (extended structures) : : | (h_size x duk_u32) |
|
|
+------------------------+ : +---------------------------+
|
|
:
|
|
'p' is NULL if no property `- these pointers are computed
|
|
allocation exists on-the-fly using e_size and
|
|
a_size
|
|
|
|
There are multiple memory layouts for the property allocation part,
|
|
each containing the same parts but in a different order. The different
|
|
layouts are used to best suit the target platform's alignment needs.
|
|
The layout is automatically selected by Duktape during compilation
|
|
(feature detection).
|
|
|
|
The heap header structure ``duk_heaphdr`` contains:
|
|
|
|
* flags with both heap level flags (``DUK_HEAPHDR_FLAG_*`` in
|
|
``duk_heaphdr.h``) and object specific flags (``DUK_HOBJECT_FLAG_*``
|
|
in ``duk_hobject.h``)
|
|
* heap allocated list linkage
|
|
* reference counter field
|
|
|
|
The object specific part of ``duk_hobject`` contains:
|
|
|
|
* property allocation: A data structure for storing properties
|
|
|
|
* internal prototype field for fast prototype chain walking;
|
|
other internal properties are stored in the property allocation
|
|
|
|
Some ``duk_hobject`` sub-types share the beginning of the ``duk_hobject``
|
|
struct but have additional fields. These sub-types include: ``duk_harray``,
|
|
``duk_hcompfunc``, ``duk_hnatfunc``, ``duk_hthread``, and ``duk_hbufobj``.
|
|
|
|
The property allocation part is a single memory allocation containing all
|
|
the object properties, both external and internal. It is subdivided
|
|
internally into the following parts:
|
|
|
|
* *Entry part* stores ordered key-value properties with arbitrary
|
|
property attributes (flags), and supports accessor properties
|
|
(getter/setter properties), i.e., full E5 semantics
|
|
|
|
* *Array part* (optional) stores plain values with default property
|
|
attributes (writable, enumerable, configurable) for valid array indices
|
|
(``"0"``, ``"1"``, ..., ``"4294967294"``); does not support accessor
|
|
properties
|
|
|
|
* *Hash part* (optional) provides accelerated key lookups for the
|
|
entry part, mapping a key into an entry part index
|
|
|
|
Internal properties are stored in the entry part, and are only distinguished
|
|
from normal properties in that their keys are invalid UTF-8 sequences which
|
|
cannot be generated (and thus not accessed) from Ecmascript code. Internal
|
|
properties should never be enumerable or visible in other ways. See separate
|
|
discussion of internal properties later in the document.
|
|
|
|
The ``duk_hobject`` allocation is fixed and its address never changes after
|
|
initialization. The property allocation part is allocated on demand, and
|
|
its address may change when the object is resized; this currently always
|
|
happens because there is no in-place resizing. The resizing process is
|
|
described in a separate section below. The property allocation part can also
|
|
be missing, the ``p`` pointer is NULL in this case.
|
|
|
|
To avoid storing multiple pointers/offsets pointing to the individual sections
|
|
of the property allocation, the different parts are reached with run-time
|
|
pointer computations. There are a lot of convenience accessor macros in
|
|
``duk_hobject.h`` to access the various parts and elements within the parts.
|
|
**Always** use these macros to manipulate object properties so that changing
|
|
the layout is contained to a small section of code.
|
|
|
|
Notes:
|
|
|
|
* For a newly allocated object with no properties, there is no property
|
|
allocation, and the ``p`` pointer is ``NULL``. It may also become
|
|
``NULL`` later if all object properties are deleted and the object is
|
|
then compacted.
|
|
|
|
* The array part is assumed to be comprehensive, i.e. if the array part
|
|
exists, all valid array index keys must reside in the array part. If
|
|
this invariant would need to be violated, the array part is abandoned
|
|
and its entries moved into the entry part.
|
|
|
|
* The array part entries are assumed to have default property attributes
|
|
(writable, configurable, enumerable). If this invariant would need to
|
|
be violated, the array part is also abandoned.
|
|
|
|
* The array part is also abandoned if the array part would become too
|
|
sparse, i.e. it would take too much memory compared to the number of
|
|
entries actually present. This behavior is not compliance related.
|
|
|
|
* A certain key can be present at most once (in either the entry or array
|
|
part). This invariant must be enforced when adding new keys into the
|
|
object. Other implementation code can simply assume it.
|
|
|
|
* The default attributes for new properties depend on how they are inserted:
|
|
|
|
+ For ordinary assignment, the defaults are defined in the ``[[Put]]``
|
|
algorithm (E5 Section 8.12.5, step 6): writable, enumerable, configurable.
|
|
Note that these differ from the official default values defined in
|
|
E5 Section 8.6.2.
|
|
|
|
+ For ``[[DefineOwnProperty]]`` the defaults are defined in E5 Section
|
|
8.12.9 step 4, which refers to the official "default attribute values"
|
|
in E5 Section 8.6.2: non-writable, non-enumerable, non-configurable.
|
|
|
|
Entry and hash part
|
|
===================
|
|
|
|
The entry part contains ordered key-value pairs, and supports full Ecmascript
|
|
E5 semantics: property values can be plain *data properties* or *accessor
|
|
properties*, and can have any property attributes, stored in property flags.
|
|
Internal properties, identified with a special key prefix, can also be stored.
|
|
|
|
The hash part is optional, and allows faster lookups into the entry part.
|
|
It is only used for objects with at least ``DUK_HOBJECT_E_USE_HASH_LIMIT``
|
|
properties in the entry part.
|
|
|
|
.. raw:: LaTeX
|
|
|
|
\newpage
|
|
|
|
Layout
|
|
------
|
|
|
|
The entry part consists of three separate arrays arranged sequentially:
|
|
keys, values, flags. An optional hash part may exist to speed up key
|
|
lookups::
|
|
|
|
+---------+
|
|
| key 0 | entry part keys
|
|
| NULL | (duk_hstring *)
|
|
.->| key 2 |
|
|
| | / / / / |
|
|
| | / / / / |
|
|
| +---------+
|
|
| | value 0 | entry part values
|
|
| | / / / / | (duk_propvalue)
|
|
+->| value 2 |
|
|
| | / / / / |
|
|
| | / / / / |
|
|
| +---------+
|
|
| | flags 0 | entry part flags
|
|
| | / / / / | (duk_u8)
|
|
+->| flags 2 |
|
|
| | / / / / |
|
|
| | / / / / | / / / / Denotes uninitialized data
|
|
| +---------+ which is not reachable from
|
|
| : : a GC perspective
|
|
| : array :
|
|
| : part :
|
|
| : :
|
|
| +---------+
|
|
| | UNUSED | hash part
|
|
`--| 2 | (duk_u32)
|
|
| DELETED |
|
|
| UNUSED | UNUSED = DUK_HOBJECT_HASHIDX_UNUSED
|
|
| 0 | = 0xffffffffU
|
|
| UNUSED |
|
|
| UNUSED | DELETED = DUK_HOBJECT_HASHIDX_DELETED
|
|
| UNUSED | = 0xfffffffeU
|
|
+---------+
|
|
DELETED entries don't terminate hash
|
|
probe sequences, UNUSED entries do.
|
|
|
|
Here, e_size = 5, e_next = 3, h_size = 8.
|
|
|
|
.. FIXME for some unknown reason the illustration breaks with pandoc
|
|
|
|
Each array in the entry part contains ``e_size`` allocated entries.
|
|
The entries at indices [0,\ ``e_next``\ [ are currently in use, and any
|
|
entries above that are uninitialized (garbage) data, and not reachable
|
|
from a GC perspective.
|
|
|
|
New keys are always appended to the current ``e_next`` position (with the
|
|
entry part resized if it is already full). Existing entries are deleted
|
|
by marking a key as ``NULL``; they are not reused for new properties to
|
|
avoid disrupting the key enumeration order (which should match insertion
|
|
order). NULL entries are removed (compacted) whenever the property
|
|
allocation is resized. If a key entry is ``NULL``, the corresponding value
|
|
and flag fields MUST NOT be interpreted, and are not considered reachable
|
|
from a GC perspective. Thus, the property value must be decref'd when the
|
|
key is set to NULL. If a key entry is non-\ ``NULL``, it is considered
|
|
reachable and must be incref'd on insertion.
|
|
|
|
Flags are represented by an ``duk_u8`` field, with flags defined in
|
|
``duk_hobject.h``. The current flags are:
|
|
|
|
* ``DUK_PROPDESC_FLAG_WRITABLE``
|
|
|
|
* ``DUK_PROPDESC_FLAG_ENUMERABLE``
|
|
|
|
* ``DUK_PROPDESC_FLAG_CONFIGURABLE``
|
|
|
|
* ``DUK_PROPDESC_FLAG_ACCESSOR``
|
|
|
|
The value field is a union of (1) a plain value, and (2) an accessor value
|
|
which contains ``get`` and ``set`` function pointers. The interpretation
|
|
of the union depends on the ``DUK_PROPDESC_FLAG_ACCESSOR``; if set, the
|
|
value is treated as the accessor part of the union, otherwise it is treated
|
|
as the value part of the union. This interpretation must be done everywhere
|
|
where the value is accessed, otherwise garbage values will be read.
|
|
In particular, the reference count and garbage collection code must always
|
|
interpret the union correctly based on the current entry flags.
|
|
|
|
The hash part (if it exists) maps an ``duk_hstring`` key ``K`` to an index
|
|
``I`` of the current entries part, or indicates that the key does not exist
|
|
in the object. The hash index structure has no bearing on garbage
|
|
collection; in particular, the index references from the hash part to the
|
|
entry part are not considered counted references.
|
|
|
|
If the hash part exists, it is always kept up-to-date with the entry part
|
|
so that both structures always contain the same keys. Deleted entries
|
|
in the hash data structure are explicitly marked DELETED. Such entries
|
|
don't terminate hash probe sequences but act otherwise as UNUSED entries;
|
|
see more detailed discussion below. DELETED entries are eliminated
|
|
(converted to UNUSED) when the property allocation is resized, improving
|
|
hash part performance.
|
|
|
|
Notes:
|
|
|
|
* This layout of three separate arrays has been chosen so that a linear key
|
|
scan is efficient, e.g. works nicely with cache lines and prefetches,
|
|
which is important because "small" objects don't have a hash part at all.
|
|
Linear scan is more space efficient and often also faster than a
|
|
hash lookup, which does one or more random accesses to the hash part when
|
|
going through the probe sequence.
|
|
|
|
* Objects in dynamic languages often don't guarantee a key enumeration
|
|
order, which allows objects to be implemented with easy and efficient
|
|
"pure" hash tables. Although Ecmascript E5 does not require a particular
|
|
key ordering for enumeration, a practical implementation must provide
|
|
some ordering guarantees to be compatible with existing code base. Such
|
|
guarantees include enumerating keys in their insertion order; see the
|
|
section on enumeration for details. This has a big impact on the viable
|
|
data structure alternatives; the current entry and hash part model is a
|
|
relatively simple approach to satisfy the practical requirements.
|
|
|
|
Hash part details
|
|
-----------------
|
|
|
|
The hash part maps a key ``K`` to an index ``I`` of the entry part or
|
|
indicates that ``K`` does not exist. The hash part uses a `closed hash
|
|
table`__, i.e. the hash table has a fixed size and a certain key has
|
|
multiple possible locations in a *probe sequence*.
|
|
|
|
__ http://en.wikipedia.org/wiki/Hash_table#Open_addressing
|
|
|
|
.. note:: The current hash algorithm does not perform especially well,
|
|
and it is future work to make it work better especially with
|
|
high load factors.
|
|
|
|
The hash part is an array of ``h_size`` ``duk_u32`` values. Each value
|
|
is either an index to the entry part, or one of two markers:
|
|
|
|
* ``UNUSED``: entry is currently unused
|
|
|
|
* ``DELETED``: entry has been deleted
|
|
|
|
Hash table size (``h_size``) is selected relative to the maximum number
|
|
of inserted elements ``N`` (equal to ``e_size`` in practice) in two steps:
|
|
|
|
#. Find lowest N so that ``2 ** N >= e_size``.
|
|
|
|
#. Use ``2 ** (N + 1)`` as hash size. This guarantees load factor is
|
|
lower than 0.5 after resize.
|
|
|
|
The probe sequence for a certain key is guaranteed to walk through every
|
|
hash table entry. Currently the probe sequence is simply:
|
|
|
|
* ``(X + i) % h_size`` where i=0,1,...,h_size-1.
|
|
|
|
This isn't ideal for avoiding clustering (double hashing would be better)
|
|
but is cache friendly and works well enough with low load factors.
|
|
|
|
When looking up an element from the hash table, we walk through the probe
|
|
sequence looking at the hash table entries. If a UNUSED entry is found, the
|
|
probe sequence is terminated, and we determine that the entry cannot be in
|
|
the hash (and thus, not in the entry part). If a DELETED entry is found,
|
|
we continue with the probe sequence. This is necessary to handle deletions
|
|
correctly.
|
|
|
|
When inserting an element to the hash table, we must first ensure it does
|
|
not already exist. The probe sequence must be verified up to the first
|
|
UNUSED entry (but not beyond). The element is then inserted to the first
|
|
UNUSED *or* DELETED entry. DELETED entries can thus be reused, but they
|
|
can never be marked UNUSED, otherwise probe sequences would be "broken".
|
|
|
|
When an element is deleted, it is first located by following the probe
|
|
sequence, and if found, is then replaced with a DELETED marker.
|
|
|
|
If the hash part is full, the probe sequence eventually comes back to the
|
|
initial entry and is thus in an infinite loop. An explicit loop check
|
|
would be an unnecessary cost: it suffices to ensure there is at least one
|
|
UNUSED entry in the hash part. As the probe sequence is guaranteed to
|
|
cover every hash entry, it will eventually hit the UNUSED entry and
|
|
terminate.
|
|
|
|
DELETED entries don't terminate hash probe sequences. If they did, existing
|
|
hash chains could be broken as a side effect of deletions. Since the hash
|
|
must contain at least one UNUSED entry, DELETED entries must be "purged" from
|
|
time to time: if all entries were either occupied or marked DELETED, probe
|
|
sequences would never terminate. Currently DELETED entries are only removed
|
|
during property allocation resizing, which always rehashes all entries,
|
|
purging any DELETED entries as a side effect. The handling of key insertion
|
|
and deletion in the entry part actually guarantees that a rehashing occurs
|
|
before the hash part fills up with DELETED entries as follows.
|
|
|
|
Because all new entries are appended to the existing entry part key array
|
|
(deleted entry part keys are marked ``NULL`` but not reused until a resize
|
|
happens), the hash part contains exactly ``e_next`` used and DELETED entries
|
|
combined, and exactly ``h_size - e_next`` UNUSED entries. As long as the hash
|
|
part is larger than the entry part (``h_size > e_size``) the hash is thus
|
|
guaranteed to contain at least one UNUSED entry. When an insertion is
|
|
attempted to a full entry part (``e_next = e_size``), a property allocation
|
|
resize is triggered which also resizes and rehashes the hash part, purging
|
|
any ``DELETED`` entries.
|
|
|
|
.. raw:: LaTeX
|
|
|
|
\newpage
|
|
|
|
Array part
|
|
==========
|
|
|
|
Layout
|
|
------
|
|
|
|
The array part simply contains a sequence of tagged values::
|
|
|
|
values
|
|
(duk_tval)
|
|
|
|
+---------+
|
|
| value 0 | Represents the array:
|
|
| UNUSED | { "0": (value 0), "2": (value 2) }
|
|
| value 2 |
|
|
| UNUSED | UNUSED = duk_tval 'unused' marker value
|
|
| UNUSED | (DUK_TVAL_IS_UNUSED(tv))
|
|
+---------+
|
|
|
|
Here, a_size = 5.
|
|
|
|
The array part stores all properties whose string key is a *valid
|
|
array index*, a canonical string representation of a whole number in
|
|
the range [0,0xfffffffe] (discussed in more detail above). The array
|
|
part is *comprehensive*, which means that if an object has an array part,
|
|
any string key which is a valid array index *must* reside in the array
|
|
part (it can never be in the entry part). (Because 0xffffffff is not a
|
|
valid array index, it is used internally as a convenient "no array index"
|
|
marker, ``DUK_HSTRING_NO_ARRAY_INDEX``.)
|
|
|
|
The array part does not store any property attribute flags: all entries
|
|
are implicity assumed to be data properties with the default ``[[Put]]``
|
|
property attributes: writable, enumerable, configurable. This assumption is
|
|
true for almost all real world code. If a property insertion or modification
|
|
were to violate this assumption, the entire array part needs to be abandoned
|
|
and moved to the entry part to maintain E5 semantics.
|
|
|
|
All array entries are always reachable from a GC perspective, up to
|
|
the allocated size, ``a_size``. Unused values are marked with the special
|
|
"unused" value, set using the ``DUK_TVAL_SET_UNUSED`` macro. Any other
|
|
entries, including "undefined" values, set using the ``DUK_TVAL_SET_UNDEFINED``
|
|
macro, are considered to be in use, and their corresponding key is
|
|
considered to exist in the object, and they are thus visible to enumeration.
|
|
In the illustration above, values at indices "0" and "2" are considered used,
|
|
so an attempt to enumerate the array part would result in ``["0", "2"]``, also
|
|
e.g. ``2 in obj`` would be true while ``3 in obj`` would be false.
|
|
|
|
Notes:
|
|
|
|
* The array part is an optimized structure for reading and writing
|
|
array indexed properties efficiently. It can be used for *any* object,
|
|
not just the Ecmascript ``Array`` object, and Ecmascript ``Array``
|
|
exotic behaviors are unrelated to the array part's existence.
|
|
|
|
* A non-\ ``Array`` object with an array part does not get the ``Array``
|
|
related exotic behaviors (like automatic interaction between array
|
|
indexed elements and the ``length`` property).
|
|
|
|
* An ``Array`` object may be created without an array part, or may have its
|
|
array part abandoned. The ``Array`` exotic behaviors must keep on
|
|
working even if the ``Array`` object has no array part.
|
|
|
|
* The ``Array`` ``length`` property is stored as an ordinary property in
|
|
the entries part, and has no relation with array part size (``a_size``).
|
|
|
|
Abandoning the array part
|
|
-------------------------
|
|
|
|
The array entries are assumed to be data properties with default
|
|
attributes (writable, configurable, enumerable). This has the
|
|
following implications:
|
|
|
|
* When a new property with an array index outside the currently allocated
|
|
array part is being added (e.g. as part of a property write), we must
|
|
either:
|
|
|
|
#. extend the array allocation to cover the new entry; or
|
|
|
|
#. abandon the entire array part, moving all array part entries to the
|
|
entry part.
|
|
|
|
The first option may not be viable if the array were to become very
|
|
sparse (e.g. when executing: ``var a = []; a[1000000000] = 1``).
|
|
|
|
* When a property in the array part would become an accessor property
|
|
(getter/setter) or would need to have incompatible attributes, the entire
|
|
array part must be abandoned.
|
|
|
|
Note that the property cannot be stored in the entry part while keeping
|
|
the array part, because the array part is assumed to be comprehensive.
|
|
|
|
When an array part is abandoned, its entries are all moved into the entries
|
|
part as ordinary key-value properties with string keys. If an array part
|
|
is abandoned for a certain object it is currently never reinstated. The
|
|
current implementation performs array abandonment only as part of a property
|
|
allocation resize; the need to abandon the array thus triggers a resize with
|
|
the side effect of doing key compaction, rehashing, etc.
|
|
|
|
The enumeration ordering of keys is preserved for existing array index
|
|
keys by adding them first to the resized entry part, before non-array-index
|
|
keys. However, key ordering behavior for new array indexed entries after
|
|
the resize (which abandons the array part) differs from an object with an
|
|
array part: array index keys are appended to the entry part as ordinary keys.
|
|
This implementation specific behavior is illustrated below::
|
|
|
|
// two example arrays
|
|
var a = [1,2,3]; a.foo = "bar";
|
|
var b = [1,2,3]; b.foo = "bar";
|
|
|
|
// force 'a' to abandon array part
|
|
a[1000000] = 4; // array part abandoned
|
|
a.length = 3; // array part not reinstated
|
|
|
|
// arrays 'a' and 'b' have the same enumeration
|
|
// ordering at this point: [ "0", "1", "2", "foo" ].
|
|
|
|
a[4] = 5;
|
|
a[3] = 4;
|
|
b[4] = 5;
|
|
b[3] = 4;
|
|
|
|
// enumeration ordering differs here:
|
|
print(Object.keys(a)); // -> 0,1,2,foo,4,3
|
|
print(Object.keys(b)); // -> 0,1,2,3,4,foo
|
|
|
|
Note that Ecmascript implementation behavior differs greatly when it comes
|
|
to "sparse arrays". For instance, the above example has varying results
|
|
with existing Ecmascript implementations::
|
|
|
|
// Rhino (Rhino 1.7 release 3 2012 02 13)
|
|
// (behavior matches example above)
|
|
[...]
|
|
0,1,2,foo,4,3
|
|
0,1,2,3,4,foo
|
|
|
|
// smjs (JavaScript-C 1.8.5+ 2011-04-16)
|
|
// (enumerates based purely on insertion order
|
|
// for both objects)
|
|
[...]
|
|
0,1,2,foo,4,3
|
|
0,1,2,foo,4,3
|
|
|
|
// V8 (nodejs v0.4.12)
|
|
// (enumerates array indices before other keys
|
|
// for both objects)
|
|
print = console.log;
|
|
[...]
|
|
[ '0', '1', '2', '3', '4', 'foo' ]
|
|
[ '0', '1', '2', '3', '4', 'foo' ]
|
|
|
|
Fast array access
|
|
-----------------
|
|
|
|
The reason why a separate array part exists is to:
|
|
|
|
* Store normal array structures compactly: normal arrays are dense and
|
|
have default properties
|
|
|
|
* Provide relatively fast access to array elements: avoid entry or hash
|
|
part lookup
|
|
|
|
* Avoid string interning of array index keys for numeric indices
|
|
|
|
Ecmascript array indices are always strings, so conceptually arrays
|
|
map string indices of the form "0", "1", etc to arbitrary values.
|
|
Non-string keys for property accesses are coerced to strings at run time.
|
|
For instance::
|
|
|
|
var a = [1,2];
|
|
print(a[0]); // 0 coerced to "0" before access
|
|
print(a["0"]); // equivalent access
|
|
|
|
var i = 1;
|
|
print(a[i]); // equivalent to a["1"]
|
|
|
|
If the property access key happens to be a number which is also a valid
|
|
array index (whole number in the range [0,2**32-1[) and the target array
|
|
happens to have an array part, we can avoid the string interning and
|
|
look up the entry directly. The same applies to assignments to array
|
|
index properties.
|
|
|
|
This is not trivial to implement in practice because of the prototype
|
|
chain, the details of property access algorithms etc. Currently the
|
|
"fast path" behavior applies to a very narrow set of circumstances.
|
|
See the following functions in ``duk_hobject_props.c``:
|
|
|
|
* ``duk_hobject_get_value_u32()``
|
|
|
|
* ``duk_hobject_get_value_tval()``
|
|
|
|
* ``duk_hobject_has_property_u32()``
|
|
|
|
* ``duk_hobject_has_property_tval()``
|
|
|
|
There is currently no fast path for array writes, which means the key is
|
|
temporarily interned for the duration of the array write. The array write
|
|
fast path is a bit tricky: if the element does not already exist, a property
|
|
higher up in the prototype chain may block or capture the write, and currently
|
|
the prototype chain lookup is only possible with a string key. See future
|
|
work.
|
|
|
|
Resizing the property allocation
|
|
================================
|
|
|
|
The property allocation resizing algorithm handles: growing and shrinking
|
|
of the entry, array, and hash parts; abandoning the array part, key compaction
|
|
(elimination of ``NULL`` keys); and rehashing (elimination of ``DELETED``
|
|
entries). Only one resizing algorithm is used; all parts of the property
|
|
allocation are always processed during resizing. Multiple resizing
|
|
algorithms would be useful (e.g. to just resize one part, perhaps in-place),
|
|
but would increase code size. The current resize algorithm is
|
|
``realloc_props()`` in ``duk_hobject_props.c``.
|
|
|
|
The property allocation is currently resized e.g. when:
|
|
|
|
* The entry part runs out during insertion of a new property.
|
|
|
|
* The array part needs to be extended during insertion of a new
|
|
property.
|
|
|
|
* The array part needs to be abandoned due to:
|
|
|
|
+ a property insert which would result in a too sparse array part;
|
|
|
|
+ a property insert incompatible with the array part assumptions; or
|
|
|
|
+ a property modification incompatible with the array part assumptions.
|
|
|
|
* The object is compacted, i.e. its active entry and array part properies
|
|
are counted, and an optimal (small) new size is allocated.
|
|
|
|
The resizing algorithm:
|
|
|
|
* Allocates a new memory area for properties (in-place resizing is not
|
|
supported). This may trigger a garbage colleciton, and may fail.
|
|
|
|
* If array abandoning is requested, existing array properties are first
|
|
moved into the beginning of the new entry part to keep the enumeration
|
|
ordering identical to that before abandonding (array indices are normally
|
|
enumerated before other entry keys). The array abandoning process is a
|
|
bit tricky because it requires string interning which may trigger garbage
|
|
collection and may also fail. Any temporary values must thus be reachable
|
|
and correctly referenced counted for every intern call.
|
|
|
|
* Existing entry part properties are moved into the new entry part. Any
|
|
``NULL`` keys are skipped, so that the entry part keys are "compacted".
|
|
|
|
* If the new allocation has a hash part, the new entry part keys are
|
|
hashed into the new hash part. Note that an existing hash part (of
|
|
the current allocation) is irrelevant and is ignored here; in any case,
|
|
the new hash part contains no ``DELETED`` entries.
|
|
|
|
If the array part is not abandoned, reference counts for the object as a
|
|
whole remain constant: the reachable keys and values are exactly the same.
|
|
If the array part is abandoned, the newly interned array index string keys
|
|
(e.g. ``"0"``) will be newly reachable and need to be incref'd.
|
|
|
|
Some complications:
|
|
|
|
* The tricky reachability issues related to array abandoning are handled by
|
|
using the current thread's value stack as a place to store temporaries;
|
|
the value stack has an existing process for cleanup if an error occurs.
|
|
This is not the whole story, though; see code for details.
|
|
|
|
* The allocation calls required during resizing (for the new memory area,
|
|
string interning, and value stack resizing) may cause a garbage collection.
|
|
The garbage collection may attempt to resize any object as part of an
|
|
"emergency GC" compaction. This needs to be prevented for the current
|
|
object (or in general, for any object being concurrently resized).
|
|
|
|
The current solution is to prevent finalizers from running (which prevents
|
|
attempts to add, remove, or modify properties in the middle of a resize)
|
|
and to prevent object compaction (so that a certain object won't be resized
|
|
when it is already being resized).
|
|
|
|
Enumeration
|
|
===========
|
|
|
|
Enumeration poses a lot of problems for implementing the Ecmascript
|
|
object/array semantics efficiently.
|
|
|
|
Below, the relevant parts of the specification are first discussed
|
|
(and quoted for easy reference), followed by some useful additional
|
|
requirements and features. Some implementation pitfalls are then
|
|
discussed. Finally, the current enumeration mechanism is discussed
|
|
in some detail.
|
|
|
|
The current implementation can be found in ``duk_hobject_enum.c``.
|
|
|
|
Ecmascript specification requirements
|
|
-------------------------------------
|
|
|
|
E5 Section 12.6.4: "The for-in statement" contains the main requirements
|
|
for enumeration in the E5 specification:
|
|
|
|
* The mechanics and order of enumerating the properties [...] is
|
|
not specified.
|
|
|
|
* Properties of the object being enumerated may be deleted during
|
|
enumeration. If a property that has not yet been visited during
|
|
enumeration is deleted, then it will not be visited.
|
|
|
|
* If new properties are added to the object being enumerated during
|
|
enumeration, the newly added properties are not guaranteed to be
|
|
visited in the active enumeration.
|
|
|
|
* Enumerating the properties of an object includes enumerating
|
|
properties of its prototype, and the prototype of the prototype,
|
|
and so on, recursively; but a property of a prototype is not
|
|
enumerated if it is "shadowed" because some previous object in
|
|
the prototype chain has a property with the same name.
|
|
|
|
E5 Section 15.2.3.7: "Object.defineProperties ( O, Properties )"
|
|
requires that when multiple properties are defined with
|
|
``Object.defineProperties()``, the order should be kept:
|
|
|
|
* If an implementation defines a specific order of enumeration
|
|
for the for-in statement, that same enumeration order must be
|
|
used to order the list elements in step 3 of this algorithm.
|
|
|
|
E5 Section 15.2.3.14: "Object.keys ( O )" requires that the "for-in"
|
|
enumeration order should also be used for ``Object.keys()``:
|
|
|
|
* If an implementation defines a specific order of enumeration
|
|
for the for-in statement, that same enumeration order must be
|
|
used in step 5 of this algorithm.
|
|
|
|
Practical enumeration requirements
|
|
----------------------------------
|
|
|
|
The E5 requirements for enumeration are rather loose; for instance, there
|
|
is no requirement that object keys are enumerated in their insertion order
|
|
or even that array indexes are enumerated in an ascending order. However,
|
|
real world code sometimes makes such assumptions.
|
|
|
|
For instance, it is a common idiom to assume that the following works::
|
|
|
|
var a = [ "foo", "bar", "quux" ];
|
|
for (var i in a) {
|
|
print(i, a[i]);
|
|
}
|
|
|
|
Many programmers expect this to print::
|
|
|
|
0 foo
|
|
1 bar
|
|
2 quux
|
|
|
|
where it might just as well, while being fully E5 compliant, print::
|
|
|
|
2 quux
|
|
0 foo
|
|
1 bar
|
|
|
|
Similarly, much existing code assumes that properties are enumerated
|
|
in the order they were inserted. See, for instance:
|
|
|
|
* http://code.google.com/p/chromium/issues/detail?id=2605
|
|
|
|
* http://ejohn.org/blog/javascript-in-chrome/
|
|
|
|
"However, specification is quite different from implementation.
|
|
All modern implementations of ECMAScript iterate through object
|
|
properties in the order in which they were defined. Because of
|
|
this the Chrome team has deemed this to be a bug and will be fixing it."
|
|
|
|
* ``hobject-enumeration.rst`` for practical testing results with
|
|
actual implementations.
|
|
|
|
We impose the following additional requirements for compatibility:
|
|
|
|
* Non-array-index keys should be enumerated in their insertion order.
|
|
|
|
* The keys for ``Array`` elements should be enumerated in an
|
|
ascending order, and before non-array-index keys.
|
|
|
|
+ This is currently provided for all objects with an array part.
|
|
Ecmascript ``Array`` instances should thus always have an array
|
|
part (at least when they are created).
|
|
|
|
+ If an object has an array part which is abandoned, e.g. because
|
|
the array becomes too sparse, the enumeration ordering reverts
|
|
to enumerating entries in insertion order (regardless of whether
|
|
the property is a valid array index or not).
|
|
|
|
* All keys of a certain object should be enumerated (including both
|
|
array index and non-array-index keys) before proceeding to the
|
|
prototype. Keys already enumerated must not be repeated during
|
|
enumeration even if they occur again in the prototype chain.
|
|
|
|
* If an entry is deleted during enumeration before it has appeared
|
|
in the enumeration sequence, it must not turn up later in the
|
|
enumeration.
|
|
|
|
* A certain key must never appear twice in the enumeration sequence,
|
|
despite any mutation.
|
|
|
|
* A key which was present during the "initialization" of the enumeration
|
|
(before the first key was enumerated) must not be omitted from the
|
|
enumeration sequence, if they are not deleted during enumeration
|
|
(before they have appeared in the enumeration sequence).
|
|
|
|
Note the following *non-requirements*:
|
|
|
|
* New entries added during enumeration are not required to show up
|
|
during the enumeration in progress.
|
|
|
|
+ The current implementation will *never* enumerate such keys.
|
|
This is not desirable as such, but is a side effect of the
|
|
(simplistic) implementation strategy.
|
|
|
|
+ The same behavior seems to apply to smjs, Rhino, and V8 at the
|
|
time of writing.
|
|
|
|
Implementation issues
|
|
---------------------
|
|
|
|
It is tempting to implement enumeration with sort of enumerator state
|
|
which maintains some iteration pointers or indices to the target object
|
|
and steps through object properties and the (immutable) prototype chain
|
|
on request. However, this approach has many practical difficulties:
|
|
|
|
* Object mutation may cause the internal structure of the target object
|
|
(or any object in its prototype chain) to change.
|
|
|
|
+ This poses a problem for any approach based on maintaining an index
|
|
to the array/entry part, as an index may be invalidated by internal
|
|
data structure maintenance such as compaction of keys.
|
|
|
|
+ This problem can be avoided if the object is "frozen" for enumeration,
|
|
but this requires awkward book-keeping, which must work even if errors
|
|
are thrown, threads yield (and perhaps never resume, or are garbage
|
|
collected) etc.
|
|
|
|
* Any keys may be deleted during enumeration.
|
|
|
|
+ This poses a problem for any approach based on maintaining a key
|
|
based state, e.g. "current key". The key in question may be
|
|
deleted; how can one then find the next key in the sequence?
|
|
|
|
Current enumeration mechanism
|
|
-----------------------------
|
|
|
|
The current enumeration approach is based on creating an internal
|
|
enumeration object (enumerator) when enumeration is initialized, before
|
|
any keys are needed. The entire list of enumerated keys is generated
|
|
during initialization and stored in the enumerator. This avoids any
|
|
issues with mutation, because no user code runs while the enumerator
|
|
is being initialized. This step is memory intensive; in particular,
|
|
all enumerated array index keys are interned.
|
|
|
|
The enumerator is then used to generate a sequence of keys on demand.
|
|
When a new key is requested, the enumerator advances to the next key
|
|
in its internal sequence. The key is then checked to ensure it has
|
|
not been deleted during enumeration; if it has, we skip and try the
|
|
next key in the sequence.
|
|
|
|
Note that the key may be deleted and still found in an ancestor (and
|
|
should still be enumerated)::
|
|
|
|
function F() {};
|
|
F.prototype = { "foo": "inherited" };
|
|
|
|
var a = new F();
|
|
a.bar = "skip";
|
|
a.foo = "own";
|
|
|
|
// enumeration order: "bar", "foo"
|
|
for (var i in a) {
|
|
delete a.foo; // only affects 'a', not F.prototype
|
|
print(i, a[i]);
|
|
}
|
|
|
|
This is expected to print::
|
|
|
|
bar skip
|
|
foo inherited
|
|
|
|
However, behavior seems to differ across implementations: V8 and Smjs
|
|
work as above, while Rhino does not enumerate ``"foo"``. Rhino *will*
|
|
enumerate ``foo`` if the for-loop is executed twice. There are other
|
|
corner cases in enumeration too, see test cases.
|
|
|
|
Suppose the enumeration target is::
|
|
|
|
x = [ "foo", "bar", "quux" ];
|
|
x.foo = "bar";
|
|
|
|
After initialization, the internal enumerator object would contain
|
|
the following::
|
|
|
|
e = {
|
|
// internal control properties first
|
|
"_Target": (target object),
|
|
"_Next": (numeric index),
|
|
|
|
// followed by enumeration keys
|
|
// (as properties, not array entries)
|
|
"0": true,
|
|
"1": true,
|
|
"2": true,
|
|
"foo": true
|
|
}
|
|
|
|
The enumerator object takes advantage of two features:
|
|
|
|
#. Keys inserted into an object maintain their order in the entry part
|
|
(even during resizes). Thus, we can insert keys into the enumerator
|
|
and trust that their order is maintained. The entry part is always
|
|
gap-free, i.e. there are no NULL keys in the sequence.
|
|
|
|
#. Inserting enumerated keys as properties instead of array entries
|
|
allows duplicate keys to be handled correctly. Duplicate keys
|
|
may occur when the prototype chain is walked. The first occurrence
|
|
is recorded in its correct position, and any later occurrences are
|
|
ignored.
|
|
|
|
The ``_Next`` internal property is a numeric index which indicates
|
|
where to find the next potential key. It is an index to the *entry
|
|
part* of the enumerator, and it's initialized to the value 2 because
|
|
positions 0 and 1 are taken by ``_Target`` and ``_Next`` properties,
|
|
respectively. Entry index 2 in the example above is the "0" key. This
|
|
needs to be managed carefully as the indexing model depends on the entry
|
|
part having a very specific, unchanged form.
|
|
|
|
Note that the enumerator is not mutated after its creation, so this
|
|
entry part index approach is reliable. It is reliable even if the
|
|
enumerator is resized, as long as properties are not deleted; that
|
|
would cause problems in a resize, when the entry part was compacted.
|
|
|
|
Notes
|
|
-----
|
|
|
|
The current implementation has some nice qualities:
|
|
|
|
* It is very simple and robust, and avoids any issues with mutation
|
|
(except that keys added during mutation are never enumerated, which
|
|
is not nice but a common feature in other implementations, too).
|
|
|
|
* It has small code space.
|
|
|
|
* It has minimal impact on anything else, e.g. it requires no co-operation
|
|
from the object, such as avoiding key compaction until enumeration is
|
|
over.
|
|
|
|
However, it has many drawbacks:
|
|
|
|
* It has a relatively large memory footprint for the enumerator. Because
|
|
the keys are stored as key-value properties (not as array entries), each
|
|
enumerated key takes about 13 bytes on a typical 32-bit architecture
|
|
(4 bytes for key, 8 bytes for value, 1 byte for flags).
|
|
|
|
+ This footprint could be reduced somewhat by using the property-based
|
|
approach to generate the enumeration sequence (eliminating duplicate
|
|
keys etc), and then converting that to an array; array entries typically
|
|
take 8 bytes. But this would temporarily increase memory footprint
|
|
even more.
|
|
|
|
* Numeric key indices of an array part or the virtual numeric key indices
|
|
of a ``String`` object are interned and are reachable simultaneously
|
|
during enumeration.
|
|
|
|
* Execution of program code stops while the enumerator is initially
|
|
created. This probably has little impact in most cases, but it might
|
|
be an issue if a very large object is being enumerated (consider for
|
|
instance enumerating a very large array).
|
|
|
|
As a concrete illustration of some of the drawbacks, consider the
|
|
following::
|
|
|
|
var a = [... large array of 1 million elements ...];
|
|
for (var i in a) {
|
|
print(i, a[i]);
|
|
}
|
|
|
|
The enumerator created in this example would contain a million interned
|
|
keys for "0", "1", and so on. *All* of these keys would remain reachable
|
|
for the entire duration of the enumeration. The following code would
|
|
perform *much* better (and would be more portable, as it makes no
|
|
assumptions on enumeration order)::
|
|
|
|
var a = [... large array of 1 million elements ...];
|
|
var n = a.length;
|
|
for (var i = 0; i < n; i++) {
|
|
print(i, a[i]);
|
|
}
|
|
|
|
This problem could be alleviated a bit by deleting any already-enumerated
|
|
keys from the enumerator as enumeration proceeds. Care would then have
|
|
to be taken to avoid any possibility of a resize of the object to avoid
|
|
mixing up the key order (due to key compaction). This might not be easy
|
|
to arrange, if GC is allowed to opportunistically compact objects
|
|
(at least in "emergency GC" mode). A much easier approach would be to
|
|
replace enumeration entry keys with a fixed string (like the empty string)
|
|
instead of deleting them. This would still free the string resources but
|
|
keep the object property key list intact. However, it would lead to
|
|
duplicate keys in the entry part, which needs careful consideration to work
|
|
correctly.
|
|
|
|
Internal properties
|
|
===================
|
|
|
|
Duktape implements E5 internal properties in differing ways, depending
|
|
on the property in question:
|
|
|
|
* concretely stored internal properties
|
|
|
|
* ``duk_hobject`` header flags
|
|
|
|
* ``duk_hobject`` structure fields (only internal prototype currently)
|
|
* implicit behaviors in specification algorithms based on e.g.
|
|
object flags, type, or class
|
|
|
|
The current approach for storing internal properties which are not visible
|
|
to ordinary program code and never overlap with externally visible named
|
|
properties is simple: since all standard keys encode into valid UTF-8
|
|
sequences (valid CESU-8 sequences to be exact) in memory, internal properties
|
|
are prefixed with an invalid UTF-8 sequence which standard Ecmascript code
|
|
cannot generate and thus cannot access. The current prefix is a single
|
|
``0x82`` byte. The prefix is denoted with an underscore in this document;
|
|
e.g. ``_Map`` would be represented as the byte sequence: ``0x82`` ``'M'``
|
|
``'a'`` ``'p'`` in memory. User C code can also use internal properties for
|
|
its own purposes, as long as the property names don't conflict with Duktape's
|
|
internal properties.
|
|
|
|
To avoid complications:
|
|
|
|
* Internal properties MUST NOT be enumerable
|
|
|
|
- Duktape prevents enumeration of internal properties regardless of their
|
|
``[[Enumerable]]`` attribute. This makes it easier for user code to
|
|
read/write internal properties as ordinary put/get primitives can be
|
|
used.
|
|
|
|
* Internal properties MUST NOT be visible in any other way either, e.g.
|
|
through ``Object.getOwnPropertyNames()`` which outputs also
|
|
non-enumerable properties
|
|
|
|
- Duktape prevents this in each relevant built-in function.
|
|
|
|
* User Ecmascript code should not be given references to internal strings,
|
|
i.e. strings other than valid UTF-8/CESU-8 encodings
|
|
|
|
* Untrusted Ecmascript code should have no access to buffer values or
|
|
buffer constructors because it's easy to create an internal property
|
|
name with buffers
|
|
|
|
User C code can access internal properties; C code has full memory access
|
|
anyway so it must be trustworthy in any case. User code should never access
|
|
Duktape's internal properties as the internal properties may change arbitrarily
|
|
between versions.
|
|
|
|
Internal property names use a bit of shorthand and often the same internal
|
|
key is reused in many contexts. This is simply to save a bit of memory with
|
|
minimal impact on readability.
|
|
|
|
The following table summarizes the internal properties specified in E5,
|
|
and how they are mapped to the ``duk_hobject`` implementation. The
|
|
double brackets are omitted from the specification property names
|
|
(e.g. ``[[Class]]`` is listed as "Class").
|
|
|
|
+-------------------+------------------------------------------------------+
|
|
| Property | Implementation |
|
|
+===================+======================================================+
|
|
| Prototype | ``duk_hobject`` struct ``prototype`` field. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Class | ``duk_hobject`` flags field, encoded as a number. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Extensible | ``duk_hobject`` flag ``DUK_HOBJECT_FLAG_EXTENSIBLE``.|
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Get | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| GetOwnProperty | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| GetProperty | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Put | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| CanPut | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| HasProperty | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Delete | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| DefaultValue | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| DefineOwnProperty | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| PrimitiveValue | Internal property ``_Value``. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Construct | Not stored, implicit in algorithms. ``duk_hobject`` |
|
|
| | flag ``DUK_HOBJECT_FLAG_CONSTRUCTABLE`` indicates |
|
|
| | whether the object is a constructor, i.e. |
|
|
| | conceptually implements the internal |
|
|
| | ``[[Construct]]`` function. Note that all callable |
|
|
| | objects are not constructable. |
|
|
+-------------------+------------------------------------------------------+
|
|
| Call | Not stored, implicit in algorithms. ``duk_hobject`` |
|
|
| | macro ``DUK_HOBJECT_IS_CALLABLE`` determines whether |
|
|
| | the object is callable, i.e. conceptually implements |
|
|
| | the internal ``[[Call]]`` function. The check is |
|
|
| | made using (other) object type flags, there is no |
|
|
| | dedicated "callable" flag. |
|
|
+-------------------+------------------------------------------------------+
|
|
| HasInstance | Not stored, implicit in algorithms. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Scope | Internal ``duk_hcompfunc`` fields ``lex_env`` and |
|
|
| | ``var_env``. Unlike E5, global and eval code are |
|
|
| | also compiled into functions, hence two scope fields |
|
|
| | are needed.) |
|
|
+-------------------+------------------------------------------------------+
|
|
| FormalParameters | Internal property ``_Formals``. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
| Code | An Ecmascript function (``duk_hcompfunc``) has |
|
|
| | a pointer to compiled bytecode and associated |
|
|
| | data (such as constants), see ``duk_hcompfunc.h``. |
|
|
| | A C function (``duk_hnatfunc``) has a pointer to a |
|
|
| | a C function and some related control data, see |
|
|
| | ``duk_hnatfunc.h``. Lightfunc C function pointer is |
|
|
| | embedded in the tagged ``duk_tval`` directly.
|
|
+-------------------+------------------------------------------------------+
|
|
| TargetFunction | ``duk_hobject`` flag ``DUK_HOBJECT_FLAG_BOUND`` is |
|
|
| | set, and the internal property ``_Target`` is set |
|
|
| | to the target function. |
|
|
+-------------------+------------------------------------------------------+
|
|
| BoundThis | ``duk_hobject`` flag ``DUK_HOBJECT_FLAG_BOUND`` is |
|
|
| | set and the internal property ``_This`` is set |
|
|
| | to the ``this`` binding. |
|
|
+-------------------+------------------------------------------------------+
|
|
| BoundArguments | ``duk_hobject`` flag ``DUK_HOBJECT_FLAG_BOUND`` is |
|
|
| | set and the internal property ``_Args`` is set |
|
|
| | to a list of bound arguments. |
|
|
+-------------------+------------------------------------------------------+
|
|
| Match | Not stored, implicit in algorithms. Object type |
|
|
| | (class number is DUK_HOBJECT_CLASS_REGEXP) determines|
|
|
| | whether ``[[Match]]`` is conceptually supported. |
|
|
| | The compiled regexp and its flags are stored as the |
|
|
| | ``_Bytecode`` internal property, whose value is an |
|
|
| | internal string. |
|
|
+-------------------+------------------------------------------------------+
|
|
| ParameterMap | Internal property ``_Map``. |
|
|
| | |
|
|
+-------------------+------------------------------------------------------+
|
|
|
|
Exotic behavior and virtual properties
|
|
======================================
|
|
|
|
Terminology
|
|
-----------
|
|
|
|
The E5 specification defines default property access algorithms like
|
|
``[[GetProperty]]`` and ``[[DefineOwnProperty]]`` in E5 Section 8.12.
|
|
Some objects have behavior which differs from default behavior; we call
|
|
these *exotic properties* (or properties with *exotic behavior*), as
|
|
opposed to *normal properties* (or properties with *normal behavior* or
|
|
*default behavior*).
|
|
|
|
Conceptually each object has a number of algorithms "stored" in its
|
|
internal properties (E5 Section 8.6.2), including all the property access
|
|
algorithms. The current implementation of property access is completely
|
|
different: there are fixed algorithms for property access, which change
|
|
their behavior based on object type and flags. The exotic behaviors are
|
|
thus "inlined" into a single algorithm.
|
|
|
|
From a purely implementation viewpoint some properties are stored in a data
|
|
structure as concrete key-value pairs, while others are computed
|
|
on-the-fly. The former are called *concrete properties* and the latter
|
|
*virtual properties*. Whether a property is concrete or virtual should
|
|
have no externally visible impact with respect to compliance.
|
|
Note that these two concepts ("being exotic" and "being virtual") are
|
|
indepedent: a exotic property can be implemented with a concrete property
|
|
storing its value, and a normal property can be implemented as a virtual
|
|
property.
|
|
|
|
Exotic behaviors in E5 specification
|
|
------------------------------------
|
|
|
|
Exotic behaviors are discussed at least in the following places in the E5
|
|
specification (page numbers refer to page numbers on the page contents, not
|
|
the "PDF page number").
|
|
|
|
Section 8.6.2, pages 32-33 summarizes exotic behavior and refers to:
|
|
|
|
* Array objects: ``[[DefineOwnProperty]]``, E5 Section 15.4.5.1
|
|
|
|
* String objects: ``[[GetOwnProperty]]``, E5 Section 15.5.5.2
|
|
|
|
* Arguments objects: ``[[Get]]``, ``[[GetOwnProperty]]``,
|
|
``[DefineOwnProperty]]``, ``[[Delete]]``, E5 Section 10.6
|
|
(the exotic behavior of a non-strict arguments object is pretty
|
|
intricate and is discussed separately in ``arguments-object.rst``)
|
|
|
|
* Function objects: ``[[Get]]``, E5 Section 15.3
|
|
|
|
Exotic behavior for ``[[Get]]``:
|
|
|
|
* The ``arguments`` object: E5 Section 10.5
|
|
|
|
+ If ``arguments.caller`` has a value, which is a strict function object,
|
|
the ``[[Get]]`` operation fails after standard lookup is complete.
|
|
|
|
+ Note that the exotic behavior occurs at the level of ``[[Get]]`` and
|
|
is *not* visible through property descriptors, e.g. through
|
|
``[[GetProperty]]`` or ``[[GetOwnProperty]]``.
|
|
|
|
+ Exotic behavior only applies to non-strict arguments objects.
|
|
|
|
* The ``Function`` object: E5 Section 15.3.5.4
|
|
|
|
+ Same exotic behavior for ``caller`` property as for ``arguments``
|
|
object.
|
|
|
|
Exotic behavior for ``[[GetOwnProperty]]``:
|
|
|
|
* ``String`` object array-index properties: E5 Section 15.5.5.2
|
|
|
|
+ Covers properties which are valid array indexes as specified in E5
|
|
Section 15.4, i.e. P for which ``ToString(ToUint32(P)) == P`` and
|
|
``ToUint32(P) != 0xffffffff``.
|
|
|
|
+ Ecmascript E5.1 extended behavior to all number-like properties,
|
|
and thus allows strings longer than 4G characters.
|
|
|
|
* ``Array`` ``length`` property: E5 Section 15.4.5
|
|
|
|
+ May be implemented as a concrete property or as a virtual property.
|
|
Currently implemented as a concrete property.
|
|
|
|
* The ``arguments`` object: E5 Section 10.5
|
|
|
|
+ The ``[[Value]]`` of a property descriptor may be overridden for
|
|
"magically bound" properties (some numeric indices).
|
|
|
|
+ Exotic behavior only applies to non-strict arguments objects.
|
|
|
|
Exotic behavior for ``[[DefineOwnProperty]]``:
|
|
|
|
* ``Array`` ``length`` property: E5 Section 15.4.5.1
|
|
|
|
+ Has side effects on array elements (deleting elements above newly
|
|
written length).
|
|
|
|
* ``Array`` index properties: E5 Section 15.4.5.1
|
|
|
|
+ Has the side effect of automatically updating array ``length``.
|
|
|
|
* The ``arguments`` object: E5 Section 10.6
|
|
|
|
+ Automatic interaction with "magically bound" variables (some
|
|
numeric indices). May also remove magic binding.
|
|
|
|
+ Exotic behavior only applies to non-strict arguments objects.
|
|
|
|
Exotic behavior for ``[[Delete]]``:
|
|
|
|
* The ``arguments`` object: E5 Section 10.6
|
|
|
|
+ Automatic interaction with "magically" bound variables (some
|
|
numeric indices), may remove magic binding.
|
|
|
|
+ Exotic behavior only applies to non-strict arguments objects.
|
|
|
|
When implementing exotic or virtual properties, property attributes must
|
|
be respected normally. Exotic or virtual properties may have specific
|
|
initial attributes, but these are not fixed and may be changed later by
|
|
user code. The *only* properties which are "truly fixed" are:
|
|
|
|
* Non-configurable, non-writable data properties
|
|
|
|
* Non-configurable accessor properties
|
|
|
|
In particular, a data property which is non-configurable but writable
|
|
*can* be changed to non-writable (see E5 Section, step 10). The property
|
|
cannot be changed back to writable after that. This has the practical
|
|
implication that only "truly fixed" properties can be easily implemented
|
|
as stateless virtual properties.
|
|
|
|
Summary of exotic properties
|
|
----------------------------
|
|
|
|
The following table summarizes exotic properties defined in the E5
|
|
specification, along with their (initial) property attributes in the
|
|
columns W(ritable), E(numerable), and C(onfigurable):
|
|
``y`` means "true", ``n`` means "false", ``a`` means "any":
|
|
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| Object | Property | W | E | C | Notes |
|
|
+============+============+===+===+===+===================================+
|
|
| ``Array`` | ``length`` | y | n | n | Write may affect array elements |
|
|
| instance | | | | | (indices above new length are |
|
|
| | | | | | deleted) |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| ``Array`` | array | a | a | a | Write may affect array |
|
|
| instance | indices | | | | ``length`` (if new index is above |
|
|
| | | | | | existing length) |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| ``String`` | ``length`` | n | n | n | No exotic behavior as such, but |
|
|
| instance | | | | | easy to implement as a virtual |
|
|
| | | | | | property because not writable |
|
|
| | | | | | or configurable. |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| ``String`` | array | n | y | n | No exotic behavior as such, but |
|
|
| instance | indices | | | | maps individual characters to |
|
|
| | inside | | | | indicates; affects enumeration. |
|
|
| | string | | | | |
|
|
| | length | | | | |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| plain | ``length`` | n | n | n | See notes below. |
|
|
| string | | | | | |
|
|
| value | | | | | |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| plain | array | n | y | n | See notes below. |
|
|
| string | indices | | | | |
|
|
| value | inside | | | | |
|
|
| | string | | | | |
|
|
| | length | | | | |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| Arguments | some | y | y | y | Some numeric indices of an |
|
|
| object, | numeric | | | | arguments object "magically bind" |
|
|
| non-strict | indices | | | | to formal arguments. Only affects|
|
|
| | | | | | a non-strict arguments object. |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
| Arguments | ``caller`` | a | a | a | If *value* of ``caller`` property |
|
|
| object, | | | | | is a strict function, ``[[Get]]`` |
|
|
| non-strict | | | | | fails (but ``[[GetOwnProperty]]`` |
|
|
| | | | | | does not!). Only affects a |
|
|
| | | | | | non-strict arguments object. |
|
|
+------------+------------+---+---+---+-----------------------------------+
|
|
|
|
Notes:
|
|
|
|
* The exotic properties for ``String`` instances (which are objects) also
|
|
apply in practice to plain strings, because properties of plain strings
|
|
can also be accessed (the string is automatically promoted to a temporary
|
|
object; the implementation handles this without an actual temporary object
|
|
being created).
|
|
|
|
* The ``caller`` property of a non-strict arguments object is curious: it has
|
|
exotic behavior but no such property is established for non-strict argument
|
|
objects. (This is why its property attributes are listed as "any" above.)
|
|
|
|
* The only exotic properties which are easy to implement as fully virtual,
|
|
stateless properties are the ``String`` instance ``length`` and
|
|
array index properties, because they are non-configurable and non-writable.
|
|
They are enumerable, though, which must be taken into account in enumeration.
|
|
|
|
* The array ``length`` property has an initial value which is a valid array
|
|
length (32-bit unsigned integer). The exotic behavior of the property
|
|
ensures that whatever values are assigned to it, they are either rejected
|
|
or coerced into a valid array length (32-bit unsigned integer).
|
|
|
|
Implementation of exotic properties
|
|
-----------------------------------
|
|
|
|
The following table summarizes the implementation of exotic properties at
|
|
the moment.
|
|
|
|
+------------+------------+-----------------------------------------------+
|
|
| Object | Property | Description |
|
|
+============+============+===============================================+
|
|
| ``Array`` | ``length`` | Stored as a concrete property. |
|
|
| instance | | ``DUK_HOBJECT_FLAG_EXOTIC_ARRAY`` enables |
|
|
| | | exotic behavior in: |
|
|
| | | ``duk_hobject_put_value()``, |
|
|
| | | ``duk_hobject_object_define_property()``. |
|
|
+------------+------------+-----------------------------------------------+
|
|
| ``Array`` | array | Stored as conrete properties in array part |
|
|
| instance | indices | or entry part (if array part abandoned). |
|
|
| | | ``DUK_HOBJECT_FLAG_EXOTIC_ARRAY`` enables |
|
|
| | | exotic behavior in: |
|
|
| | | ``duk_hobject_put_value()``, |
|
|
| | | ``duk_hobject_object_define_property()``. |
|
|
+------------+------------+-----------------------------------------------+
|
|
| ``String`` | ``length`` | Virtual property computed from the string |
|
|
| instance | | length of the internal ``_Value`` property. |
|
|
| | | ``DUK_HOBJECT_FLAG_EXOTIC_STRINGOBJ`` enables |
|
|
| | | exotic behavior in: |
|
|
| | | ``get_own_property_desc()``. |
|
|
+------------+------------+-----------------------------------------------+
|
|
| ``String`` | array | Virtual properties computed by looking up |
|
|
| instance | indices | characters of the internal ``_Value`` |
|
|
| | inside | property. |
|
|
| | string | ``DUK_HOBJECT_FLAG_EXOTIC_STRINGOBJ`` enables |
|
|
| | length | exotic behavior in: |
|
|
| | | ``get_own_property_desc()``. |
|
|
+------------+------------+-----------------------------------------------+
|
|
| plain | ``length`` | Exotic handling in property access code, |
|
|
| string | | return string character length without |
|
|
| value | | promoting the plain string value to a |
|
|
| | | temporary ``String`` instance. |
|
|
+------------+------------+-----------------------------------------------+
|
|
| plain | array | Exotic handling in property access code, |
|
|
| string | indices | return individual character value without |
|
|
| value | inside | promoting the plain string value to a |
|
|
| | string | temporary ``String`` instance. |
|
|
| | length | |
|
|
+------------+------------+-----------------------------------------------+
|
|
| Arguments | some | Stored as concrete property values. |
|
|
| object, | numeric | ``DUK_HOBJECT_FLAG_EXOTIC_ARGUMENTS`` enables |
|
|
| non-strict | indices | exotic behavior in: |
|
|
| | | ``get_own_property_desc()``, |
|
|
| | | ``duk_hobject_get_value()``, |
|
|
| | | ``duk_hobject_put_value()``, |
|
|
| | | ``duk_hobject_delete_property()``, |
|
|
| | | ``duk_hobject_object_define_property()``. |
|
|
+------------+------------+-----------------------------------------------+
|
|
| Arguments | ``caller`` | Stored as a concrete property. |
|
|
| object, | | ``DUK_HOBJECT_FLAG_EXOTIC_ARGUMENTS`` enables |
|
|
| non-strict | | exotic behavior in: |
|
|
| | | ``duk_hobject_get_value()``. |
|
|
| | | This exotic behavior only affects |
|
|
| | | ``[[Get]]``, it is not visible through e.g. |
|
|
| | | property descriptors or |
|
|
| | | ``[[GetOwnProperty]]``. |
|
|
+------------+------------+-----------------------------------------------+
|
|
|
|
Notes:
|
|
|
|
* The only virtual properties are ``String`` object ``length`` and array
|
|
index properties. These are easy to implement as virtual properties
|
|
because they are non-configurable and non-writable. However, they *are*
|
|
enumerable which affects enumeration handling.
|
|
|
|
* If array ``length`` becomes non-writable, the exotic behavior ensures
|
|
no elements above the specified length can ever be inserted. The array
|
|
part could thus be compacted without risk of it being extended afterwards.
|
|
|
|
Notes on array length and array indices
|
|
---------------------------------------
|
|
|
|
The exotic array semantics only apply to valid array indices. Nothing
|
|
prevents user code from writing to numeric array indices higher than the
|
|
maximum valid array index, but such writes will get no exotic behavior::
|
|
|
|
var x = [];
|
|
x["4294967294"] = 1; // has array semantics, updates length
|
|
print(x.length); // length is 4294967295
|
|
|
|
x["9999999999"] = 2; // no array semantics
|
|
print(x.length); // length is still 4294967295
|
|
|
|
print(x[4294967294]); // coerced to string -> value "1"
|
|
print(x[9999999999]); // like above -> value "2"
|
|
|
|
print(Object.keys(x)); // -> ["4294967294", "999999999"]
|
|
|
|
x.length = 0; // deletes valid array indices
|
|
print(x[4294967294]); // undefined
|
|
print(x[9999999999]); // value still "2", not auto-deleted
|
|
|
|
Note that assigning an ``undefined`` value extends the array length, as
|
|
it is a valid value::
|
|
|
|
var x = [];
|
|
print(x.length); // -> 0
|
|
x[10] = undefined;
|
|
print(x.length); // -> 11
|
|
|
|
print(Object.keys(x)); // -> [ "10" ]
|
|
|
|
Internal objects
|
|
================
|
|
|
|
The following internal objects are currently used:
|
|
|
|
* Function templates which are "instantiated" into concrete closures
|
|
|
|
* A declarative environment record
|
|
|
|
* An object environment record
|
|
|
|
* Function formals name list
|
|
|
|
* Function variable map
|
|
|
|
Internal objects don't always need Ecmascript properties like:
|
|
|
|
* Enumeration order
|
|
|
|
* Property attributes
|
|
|
|
* Prototype chain
|
|
|
|
The current implementation does not take advantage of these: internal
|
|
objects are handled just like Ecmascript objects.
|
|
|
|
Function instances
|
|
==================
|
|
|
|
The creation of function instances is described in E5 Section 13.2.
|
|
Each function instance (each closure created from a function
|
|
expression or declaration) has the following properties:
|
|
|
|
* ``length``
|
|
|
|
* ``prototype``: points to a fresh object which has a ``constructor``
|
|
property pointing back to the function
|
|
|
|
* ``caller``: thrower (strict functions only)
|
|
|
|
* ``arguments``: thrower (strict functions only)
|
|
|
|
There is considerable variance in practical implementations:
|
|
|
|
* smjs::
|
|
|
|
// the "name" property is non-standard; "arguments" and "caller" are
|
|
// present for a non-strict function
|
|
|
|
js> f = function foo() {}
|
|
(function () {})
|
|
js> Object.getOwnPropertyNames(f)
|
|
["prototype", "length", "name", "arguments", "caller"]
|
|
|
|
// for strict mode, the same properties are present.
|
|
|
|
js> f = function foo() { "use strict"; }
|
|
(function foo() {"use strict";})
|
|
js> Object.getOwnPropertyNames(f);
|
|
["prototype", "length", "name", "arguments", "caller"]
|
|
|
|
// the "name" property contains the function expression name
|
|
|
|
js> f.name
|
|
"foo"
|
|
|
|
// "name" is non-writable, non-configurable (and non-enumerable)
|
|
// -> works as a reliable "internal" property too
|
|
|
|
js> Object.getOwnPropertyDescriptor(f, 'name')
|
|
({configurable:false, enumerable:false, value:"foo", writable:false})
|
|
|
|
* nodejs (v8)::
|
|
|
|
// "name" is non-standard; "arguments" and "caller" are present
|
|
// for even a non-strict function
|
|
|
|
> f = function foo() {}
|
|
[Function: foo]
|
|
> Object.getOwnPropertyNames(f)
|
|
[ 'length',
|
|
'caller',
|
|
'arguments',
|
|
'name',
|
|
'prototype' ]
|
|
> f.name
|
|
'foo'
|
|
|
|
// strict mode is the same
|
|
|
|
> f = function foo() { "use strict"; }
|
|
[Function: foo]
|
|
> Object.getOwnPropertyNames(f)
|
|
[ 'name',
|
|
'length',
|
|
'arguments',
|
|
'prototype',
|
|
'caller' ]
|
|
|
|
// 'name' is writable but not configurable/enumerable
|
|
|
|
> f.name
|
|
'foo'
|
|
> Object.getOwnPropertyDescriptor(f, 'name')
|
|
{ value: 'foo',
|
|
writable: true,
|
|
enumerable: false,
|
|
configurable: false }
|
|
|
|
* rhino::
|
|
|
|
// "name" is non-standard, "arity" is non-standard, "arguments"
|
|
// is present (but "caller" is not)
|
|
|
|
js> f = function foo() {}
|
|
[...]
|
|
js> Object.getOwnPropertyNames(f)
|
|
arguments,prototype,name,arity,length
|
|
|
|
// name is non-writable, non-enumerable, non-configurable
|
|
|
|
js> pd = Object.getOwnPropertyDescriptor(f, 'name')
|
|
[object Object]
|
|
js> pd.writable
|
|
false
|
|
js> pd.enumerable
|
|
false
|
|
js> pd.configurable
|
|
false
|
|
|
|
// strict mode functions are similar
|
|
|
|
See ``function-objects.rst`` for more discussion.
|
|
|
|
Built-in functions
|
|
------------------
|
|
|
|
The properties of built-in functions are a special case, because
|
|
they are not created with the algorithm in E5 Section 13.2;
|
|
instead, their properties are described explicitly in E5 Section 15.
|
|
|
|
There is considerable variance between implementations on what
|
|
properties built-in functions get.
|
|
|
|
Design notes and future work
|
|
============================
|
|
|
|
ES2015 Proxy objects or Lua-like metatables
|
|
-------------------------------------------
|
|
|
|
It would be nice to have a Lua metatable like mechanism for creating
|
|
custom object behavior extensions and full object virtualization,
|
|
see http://www.lua.org/pil/13.html for a description of Lua metatables.
|
|
There is a similar mechanism in Ecmascript 6 called "Proxy object":
|
|
|
|
* http://www.ecma-international.org/ecma-262/6.0/index.html#sec-proxy-object-internal-methods-and-internal-slots
|
|
|
|
The ES2015 Proxy object is of course a natural target for implementation,
|
|
but it's not clear what the underlying mechanism should be: should the
|
|
Proxy object mechanism be the internal mechanism, or should there be some
|
|
other implementation specific mechanism underneath which is used to provide
|
|
the Proxy object implementation but also provide non-standard additional
|
|
features?
|
|
|
|
Nice-to-have features:
|
|
|
|
* Sufficient for creating arbitrary "host objects"
|
|
|
|
* Sufficient for providing array-like access to byte buffers
|
|
|
|
* Allow "full virtualization" of E5 semantics
|
|
|
|
Some notes:
|
|
|
|
* Should interact reasonably with the E5 object model, e.g. property
|
|
descriptors.
|
|
|
|
* Should metatable behavior only affect non-existent properties (as in
|
|
Lua)? To apply it to all properties, simply use an empty table.
|
|
|
|
* May require raw access functions for dealing with the underlying
|
|
properties.
|
|
|
|
* What's the best level for capturing operations?
|
|
|
|
a. Concrete, exposed operations like getprop, putprop, hasprop, delprop,
|
|
Object.getOwnPropertyDescriptor(), Object.defineProperty(), etc?
|
|
|
|
b. Specification functions like ``[[GetOwnProperty]]``,
|
|
``[[DefineProperty]]`` etc?
|
|
|
|
* In addition, should cover:
|
|
|
|
+ Enumeration
|
|
+ Getting object ``[[Class]]``
|
|
+ Garbage collection => finalizer
|
|
|
|
ES2015 features
|
|
---------------
|
|
|
|
There are many ES2015 features which may need changes to the basic object model.
|
|
|
|
For instance, there are keyed collections:
|
|
|
|
* http://www.ecma-international.org/ecma-262/6.0/index.html#sec-keyed-collection
|
|
|
|
The ``Map`` object provides an arbitrary collection of key/value pairs,
|
|
where keys and values can be arbitrary Ecmascript objects. This is very
|
|
useful compared to the standard Ecmascript object whose keys can only be
|
|
strings.
|
|
|
|
How to implement this? One could extend the basic model to provide enough
|
|
functionality to implement ``Map`` values. One could also implement them
|
|
entirely separate from the basic object model. The trouble is, the ``Map``
|
|
keys and values must be GC reachable so they have to reside either in basic
|
|
objects or there needs to be additional native structure for them.
|
|
|
|
Array-like access to underlying byte buffers
|
|
--------------------------------------------
|
|
|
|
There are various proposals for typed access to an underlying buffer.
|
|
For instance:
|
|
|
|
* http://www.khronos.org/registry/typedarray/specs/latest/
|
|
* http://nodejs.org/docs/v0.4.7/api/buffers.html
|
|
|
|
See ``buffers.txt``.
|
|
|
|
WindowProxy
|
|
-----------
|
|
|
|
The HTML5 WindowProxy object seems to require behavior outside E5.
|
|
|
|
See: http://www.w3.org/TR/html5/browsers.html#windowproxy.
|
|
|
|
The ES2015 Proxy object probably addresses this.
|
|
|
|
Script origin for security checks
|
|
---------------------------------
|
|
|
|
HTML5 web storage, as an example, uses 'script origin' to do required
|
|
security checks on property access.
|
|
|
|
Possible implementation e.g. through: a metatable-like mechanism for
|
|
capturing accesses, and some way to introspect the current caller or
|
|
call chain to check script origin.
|
|
|
|
It would be nice to be able to determine an origin for every function,
|
|
mapped to an Ecmascript object with a bunch of propeties like URI,
|
|
load time.
|
|
|
|
Alternatives to current entry part
|
|
----------------------------------
|
|
|
|
Are there better alternatives to the current entry part model?
|
|
|
|
The pointer computations have a run-time performance cost and also a
|
|
code footprint cost. Is it worth it? This depends on the number of
|
|
objects. For instance, if there are 1000 objects and a pointer to the
|
|
array part and hash part are added to ``duk_hobject``, this would have
|
|
a footprint of 8000 extra bytes on a 32-bit platform.
|
|
|
|
Hash algorithm notes
|
|
--------------------
|
|
|
|
Some hash algorithm goals:
|
|
|
|
* Minimal memory allocation
|
|
|
|
* High load factor (minimizes memory use)
|
|
|
|
* Small code space
|
|
|
|
Closed hashing (open addressing) provides fixed allocation, but requires a
|
|
"probe sequence" to deal with hash collisions. Options for dealing with
|
|
collisions include:
|
|
|
|
* http://en.wikipedia.org/wiki/Linear_probing
|
|
|
|
* http://en.wikipedia.org/wiki/Quadratic_probing
|
|
|
|
* http://en.wikipedia.org/wiki/Double_hashing
|
|
|
|
* http://en.wikipedia.org/wiki/Cuckoo_hashing
|
|
|
|
Notes on current solution:
|
|
|
|
* Linear probing is more cache efficient but requires a lower load (= higher
|
|
allocated size relative to used size) to avoid 'clustering' issues.
|
|
Current approach prefers compact object size over cache efficiency.
|
|
|
|
* Slightly better probe would be: ``probe_steps[(hash >> 16) % 32]``.
|
|
This could possibly correlate less with the initial hash value, but
|
|
requires an extra shift operation. Most likely not worth it.
|
|
|
|
* The current algorithm is not very good, as it requires the load factor
|
|
to be relatively low (around 70-80%) to be efficient. Much better
|
|
results are possible. This is definite future work.
|
|
|
|
Property key ordering
|
|
---------------------
|
|
|
|
Because of the practical enumeration requirements, a data structure for
|
|
object keys must both maintain keys in their insertion order, and also
|
|
support some form of indexed access (e.g. a hash table) to work efficiently
|
|
with large objects.
|
|
|
|
One such approach is to use an "ordered hash table" which maintains
|
|
entries both in the hash structure and a linked list for order.
|
|
|
|
The current approach is to maintain a simple, ordered entry part, and
|
|
then provide an optional hash table on top of that. This has some
|
|
nice properties:
|
|
|
|
* The entry part maintains key ordering trivially.
|
|
|
|
* The hash part is optional, which minimizes object size. For small
|
|
objects a linear scan of keys is also relatively efficient because
|
|
the keys are adjacent in memory (being in the own "sub array").
|
|
|
|
* The hash part is non-critical. For instance, it could be dumped in an
|
|
emergency out of memory situation without losing any information.
|
|
|
|
* It would be relatively straightforward to support multiple hash
|
|
algorithms for e.g. different object sizes. In particular, it might
|
|
be useful to have a variant for medium size objects, where entry part
|
|
indices could be 8-bit or 16-bit values (instead of 32-bit).
|
|
|
|
What are the practical alternatives?
|
|
|
|
Separate object type for internal objects
|
|
-----------------------------------------
|
|
|
|
There used to be a separate object type for internal objects.
|
|
|
|
The differences to standard objects include: no need to support
|
|
array part, no property attributes, no accessor properties,
|
|
no need to preserve property ordering, no exotic behaviors, etc.
|
|
|
|
However, the extra cost of having another object data structure
|
|
does not seem worth it. The effects are:
|
|
|
|
* Code size is increased by several kilobytes.
|
|
|
|
* Internal objects data size decreases slightly (no need to track
|
|
property attributes, for instance).
|
|
|
|
* Internal object property lookup is slightly more performant.
|
|
|
|
Currently it seems to make more sense to use the same object
|
|
abstraction but to provide "short cut" raw property accessors
|
|
for faster / simpler accessing, if necessary.
|
|
|
|
Array part "freezing" vs abandoning
|
|
-----------------------------------
|
|
|
|
The current policy is that the array part is either actively used and contains
|
|
all array indexed properties, or it is abandoned entirely and all entries
|
|
moved to the entry part. An alternative design would allow some array entries
|
|
to be in the array part and others in the entry part.
|
|
|
|
For instance, the array part could be "frozen" and entries above the
|
|
allocated size could reside in the entry part. This is an easy and
|
|
relatively straightforward policy too:
|
|
|
|
* If the "frozen" flag is set, never resize the array part (except perhaps
|
|
to abandon it entirely).
|
|
|
|
* If an array index key is not found from the array part, and the "frozen"
|
|
flag is *not* set, no need to look at the entry part (this would be the
|
|
common case). If the "frozen" flag is set, need to look at the entry
|
|
part, too.
|
|
|
|
This policy has the nice side effect that there is no need to necessarily
|
|
support array abandoning at all. However, without array abandoning the
|
|
frozen array part could be left arbitrarily sparse after deletions.
|
|
|
|
Array size management improvements
|
|
----------------------------------
|
|
|
|
* When to do compaction checks (e.g. property deletion)?
|
|
|
|
* Periodic actual density checks (relative to e_size + a_size to keep
|
|
average cost limited)?
|
|
|
|
* Triggered density checks?
|
|
|
|
More fast paths for array indexing
|
|
----------------------------------
|
|
|
|
It would be nice to have more fast paths (intern free accesses) for the
|
|
array part. In particular, it would be very nice to have a fast path for
|
|
``[[Put]]``, at least for the very common case of a plain Array value
|
|
inheriting from ``Array.prototype`` with no array indexes entries anywhere
|
|
in the prototype chain.
|
|
|
|
How to do the prototype chain check required by ``[[Put]]`` efficiently?
|
|
In other hands, how to the check *without interning the index* that:
|
|
|
|
* The property does not exist in any ancestor.
|
|
|
|
* Or if it exists in an ancestor, the write is not prevented by a
|
|
non-writable property or "captured" by an accessor property.
|
|
|
|
Some approaches:
|
|
|
|
* Rework the property lookup to do lazy interning in general.
|
|
|
|
* Add an object flag ``DUK_HOBJECT_FLAG_NO_ARRIDX_PROPS``.
|
|
|
|
+ If set, the flag guarantees that the object has no concrete or virtual
|
|
array indexed properties.
|
|
|
|
+ The prototype walking check can then simply check that no object in the
|
|
prototype chain has this flag cleared. The flag must be cleared for e.g.
|
|
``String`` objects which have virtual array indexed properties.
|
|
|
|
+ Unfortunately the ``Array`` prototype is itself an array, see E5 Section
|
|
15.4.4. However, it normally has no array elements, so it could have the
|
|
flag set initially, and if someone set an array index to the prototype
|
|
(which does not really make sense) the flag would be cleared, wrecking
|
|
performance.
|
|
|
|
+ Whenever adding a new property (by whichever means) and the key is an
|
|
array index, the flag must be cleared for the target object.
|
|
|
|
Note that the fast path really only needs to work for ``Array`` instances
|
|
in practice. Their prototype chain is::
|
|
|
|
null
|
|
^
|
|
|
|
|
Object prototype (E5 Section 15.2.4)
|
|
^
|
|
|
|
|
Array prototype (E5 Section 15.4.4)
|
|
^
|
|
|
|
|
Array instance (see E5 Section 15.4.2)
|
|
|
|
The exotic flag based approach would work if the object and array prototypes
|
|
have no array indexed keys.
|
|
|
|
Existing Ecmascript implementations do not seem to implement the
|
|
official ``[[Put]]`` algorithm accurately, especially for checking the
|
|
ancestor properties for protection. For instance, NodeJS / V8::
|
|
|
|
> var p = Array.prototype;
|
|
> Object.defineProperty(p, '0', { 'value': 'inherited', 'writable': false });
|
|
[]
|
|
> var a = [];
|
|
> a[0] = 'own'; // should fail
|
|
'own'
|
|
> console.log(a[0]); // but does not
|
|
own
|
|
|
|
NodeJS / V8 doesn't seem to respect ``[[Put]]`` for normal objects either::
|
|
|
|
> var p = Object.prototype;
|
|
> Object.defineProperty(p, 'foo', { 'value': 'inherited', 'writable': false });
|
|
{}
|
|
> var o = {};
|
|
> o.foo = 'own'; // should fail
|
|
'own'
|
|
> console.log(o.foo); // but does not
|
|
own
|
|
|
|
Rhino respects the algorithm in both cases::
|
|
|
|
Rhino 1.7 release 3 2012 02 13
|
|
js> var p = Array.prototype;
|
|
js> Object.defineProperty(p, '0', { 'value': 'inherited', 'writable': false });
|
|
inherited
|
|
js> var a = [];
|
|
js> a[0] = 'own'; // should fail
|
|
own
|
|
js> print(a[0]);
|
|
inherited
|
|
|
|
and::
|
|
|
|
Rhino 1.7 release 3 2012 02 13
|
|
js> var p = Object.prototype;
|
|
js> Object.defineProperty(p, 'foo', { 'value': 'inherited', 'writable': false });
|
|
[object Object]
|
|
js> var o = {};
|
|
js> o.foo = 'own'; // should fail
|
|
own
|
|
js> print(o.foo);
|
|
inherited
|
|
|
|
Similarly for Smjs::
|
|
|
|
js> var p = Array.prototype;
|
|
js> Object.defineProperty(p, '0', { 'value': 'inherited', 'writable': false });
|
|
["inherited"]
|
|
js> var a = [];
|
|
js> a[0] = 'own'; // should fail
|
|
"own"
|
|
js> print(a[0]);
|
|
inherited
|
|
|
|
and::
|
|
|
|
js> var p = Object.prototype;
|
|
js> Object.defineProperty(p, 'foo', { 'value': 'inherited', 'writable': false });
|
|
({})
|
|
js> var o = {};
|
|
js> o.foo = 'own';
|
|
"own"
|
|
js> print(o.foo);
|
|
inherited
|
|
|
|
Delete keys from enumerator state during enumeration
|
|
----------------------------------------------------
|
|
|
|
It would be nice to delete keys from enumerator state once the keys have
|
|
been enumerated. This would reduce memory pressure as quickly as it is
|
|
currently possible. Care must be taken to avoid a resize and key compaction
|
|
while enumeration is running.
|
|
|
|
A more practical alternative is to replace the already enumerated keys with
|
|
a fixed string (e.g. the empty string). This would allow the enumerated keys
|
|
to be freed as the enumeration progresses. However, this would create duplicate
|
|
keys in the entry part, something which is not currently allowed and would thus
|
|
need careful consideration.
|
|
|
|
Enumeration ordering vs. mutation
|
|
---------------------------------
|
|
|
|
Enumeration vs. mutation causes a lot of implementation headache, as no
|
|
internal reorganizations (hash part resizing, array part reallocation or
|
|
dropping, compactions) can cause enumeration to fail. There are at least
|
|
three basic approaches to manage these:
|
|
|
|
#. Freeze the object when one or more enumerations are in progress.
|
|
However, to do this, enumerations must be tracked which complicates
|
|
execution.
|
|
|
|
#. Design the data structures to work with enumeration (especially mutation
|
|
during enumeration) so that the object does not need to know that
|
|
enumerations are in progress. This is difficult.
|
|
|
|
#. Create a snapshot of keys to-be-enumerated when the enumerator is
|
|
created. This wastes memory but is guaranteed to work - although newly
|
|
added keys will not show up in the enumeration (which is compliant
|
|
behavior).
|
|
|
|
The current approach is to create a snapshot of keys and then re-check them
|
|
to see whether they've been deleted during enumeration.
|
|
|
|
More modular virtual/exotic properties
|
|
---------------------------------------
|
|
|
|
More modular (but still compact) way of implementing virtual and exotic
|
|
properties?
|
|
|
|
Test cases
|
|
----------
|
|
|
|
Black box and white box test cases.
|
|
|