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- :article_outdated: True
- .. _doc_data_preferences:
- Data preferences
- ================
- Ever wondered whether one should approach problem X with data structure
- Y or Z? This article covers a variety of topics related to these dilemmas.
- .. note::
- This article makes references to "[something]-time" operations. This
- terminology comes from algorithm analysis'
- `Big O Notation <https://rob-bell.net/2009/06/a-beginners-guide-to-big-o-notation/>`_.
- Long-story short, it describes the worst-case scenario of runtime length.
- In laymen's terms:
- "As the size of a problem domain increases, the runtime length of the
- algorithm..."
- - Constant-time, ``O(1)``: "...does not increase."
- - Logarithmic-time, ``O(log n)``: "...increases at a slow rate."
- - Linear-time, ``O(n)``: "...increases at the same rate."
- - Etc.
- Imagine if one had to process 3 million data points within a single frame. It
- would be impossible to craft the feature with a linear-time algorithm since
- the sheer size of the data would increase the runtime far beyond the time allotted.
- In comparison, using a constant-time algorithm could handle the operation without
- issue.
- By and large, developers want to avoid engaging in linear-time operations as
- much as possible. But, if one keeps the scale of a linear-time operation
- small, and if one does not need to perform the operation often, then it may
- be acceptable. Balancing these requirements and choosing the right
- algorithm / data structure for the job is part of what makes programmers'
- skills valuable.
- Array vs. Dictionary vs. Object
- -------------------------------
- Godot stores all variables in the scripting API in the
- :ref:`Variant <doc_variant_class>` class.
- Variants can store Variant-compatible data structures such as
- :ref:`Array <class_Array>` and :ref:`Dictionary <class_Dictionary>` as well
- as :ref:`Objects <class_Object>`.
- Godot implements Array as a ``Vector<Variant>``. The engine stores the Array
- contents in a contiguous section of memory, i.e. they are in a row adjacent
- to each other.
- .. note::
- For those unfamiliar with C++, a Vector is the name of the
- array object in traditional C++ libraries. It is a "templated"
- type, meaning that its records can only contain a particular type (denoted
- by angled brackets). So, for example, a
- :ref:`PackedStringArray <class_PackedStringArray>` would be something like
- a ``Vector<String>``.
- Contiguous memory stores imply the following operation performance:
- - **Iterate:** Fastest. Great for loops.
- - Op: All it does is increment a counter to get to the next record.
- - **Insert, Erase, Move:** Position-dependent. Generally slow.
- - Op: Adding/removing/moving content involves moving the adjacent records
- over (to make room / fill space).
- - Fast add/remove *from the end*.
- - Slow add/remove *from an arbitrary position*.
- - Slowest add/remove *from the front*.
- - If doing many inserts/removals *from the front*, then...
- 1. invert the array.
- 2. do a loop which executes the Array changes *at the end*.
- 3. re-invert the array.
- This makes only 2 copies of the array (still constant time, but slow)
- versus copying roughly 1/2 of the array, on average, N times (linear time).
- - **Get, Set:** Fastest *by position*. E.g. can request 0th, 2nd, 10th record, etc.
- but cannot specify which record you want.
- - Op: 1 addition operation from array start position up to desired index.
- - **Find:** Slowest. Identifies the index/position of a value.
- - Op: Must iterate through array and compare values until one finds a match.
- - Performance is also dependent on whether one needs an exhaustive
- search.
- - If kept ordered, custom search operations can bring it to logarithmic
- time (relatively fast). Laymen users won't be comfortable with this
- though. Done by re-sorting the Array after every edit and writing an
- ordered-aware search algorithm.
- Godot implements Dictionary as an ``OrderedHashMap<Variant, Variant>``. The engine
- stores a small array (initialized to 2^3 or 8 records) of key-value pairs. When
- one attempts to access a value, they provide it a key. It then *hashes* the
- key, i.e. converts it into a number. The "hash" is used to calculate the index
- into the array. As an array, the OHM then has a quick lookup within the "table"
- of keys mapped to values. When the HashMap becomes too full, it increases to
- the next power of 2 (so, 16 records, then 32, etc.) and rebuilds the structure.
- Hashes are to reduce the chance of a key collision. If one occurs, the table
- must recalculate another index for the value that takes the previous position
- into account. In all, this results in constant-time access to all records at
- the expense of memory and some minor operational efficiency.
- 1. Hashing every key an arbitrary number of times.
- - Hash operations are constant-time, so even if an algorithm must do more
- than one, as long as the number of hash calculations doesn't become
- too dependent on the density of the table, things will stay fast.
- Which leads to...
- 2. Maintaining an ever-growing size for the table.
- - HashMaps maintain gaps of unused memory interspersed in the table
- on purpose to reduce hash collisions and maintain the speed of
- accesses. This is why it constantly increases in size exponentially by
- powers of 2.
- As one might be able to tell, Dictionaries specialize in tasks that Arrays
- do not. An overview of their operational details is as follows:
- - **Iterate:** Fast.
- - Op: Iterate over the map's internal vector of hashes. Return each key.
- Afterwards, users then use the key to jump to and return the desired
- value.
- - **Insert, Erase, Move:** Fastest.
- - Op: Hash the given key. Do 1 addition operation to look up the
- appropriate value (array start + offset). Move is two of these
- (one insert, one erase). The map must do some maintenance to preserve
- its capabilities:
- - update ordered List of records.
- - determine if table density mandates a need to expand table capacity.
- - The Dictionary remembers in what
- order users inserted its keys. This enables it to execute reliable iterations.
- - **Get, Set:** Fastest. Same as a lookup *by key*.
- - Op: Same as insert/erase/move.
- - **Find:** Slowest. Identifies the key of a value.
- - Op: Must iterate through records and compare the value until a match is
- found.
- - Note that Godot does not provide this feature out-of-the-box (because
- they aren't meant for this task).
- Godot implements Objects as stupid, but dynamic containers of data content.
- Objects query data sources when posed questions. For example, to answer
- the question, "do you have a property called, 'position'?", it might ask
- its :ref:`script <class_Script>` or the :ref:`ClassDB <class_ClassDB>`.
- One can find more information about what objects are and how they work in
- the :ref:`doc_what_are_godot_classes` article.
- The important detail here is the complexity of the Object's task. Every time
- it performs one of these multi-source queries, it runs through *several*
- iteration loops and HashMap lookups. What's more, the queries are linear-time
- operations dependent on the Object's inheritance hierarchy size. If the class
- the Object queries (its current class) doesn't find anything, the request
- defers to the next base class, all the way up until the original Object class.
- While these are each fast operations in isolation, the fact that it must make
- so many checks is what makes them slower than both of the alternatives for
- looking up data.
- .. note::
- When developers mention how slow the scripting API is, it is this chain
- of queries they refer to. Compared to compiled C++ code where the
- application knows exactly where to go to find anything, it is inevitable
- that scripting API operations will take much longer. They must locate the
- source of any relevant data before they can attempt to access it.
- The reason GDScript is slow is because every operation it performs passes
- through this system.
- C# can process some content at higher speeds via more optimized bytecode.
- But, if the C# script calls into an engine class'
- content or if the script tries to access something external to it, it will
- go through this pipeline.
- NativeScript C++ goes even further and keeps everything internal by default.
- Calls into external structures will go through the scripting API. In
- NativeScript C++, registering methods to expose them to the scripting API is
- a manual task. It is at this point that external, non-C++ classes will use
- the API to locate them.
- So, assuming one extends from Reference to create a data structure, like
- an Array or Dictionary, why choose an Object over the other two options?
- 1. **Control:** With objects comes the ability to create more sophisticated
- structures. One can layer abstractions over the data to ensure the external
- API doesn't change in response to internal data structure changes. What's
- more, Objects can have signals, allowing for reactive behavior.
- 2. **Clarity:** Objects are a reliable data source when it comes to the data
- that scripts and engine classes define for them. Properties may not hold the
- values one expects, but one doesn't need to worry about whether the property
- exists in the first place.
- 3. **Convenience:** If one already has a similar data structure in mind, then
- extending from an existing class makes the task of building the data
- structure much easier. In comparison, Arrays and Dictionaries don't
- fulfill all use cases one might have.
- Objects also give users the opportunity to create even more specialized data
- structures. With it, one can design their own List, Binary Search Tree, Heap,
- Splay Tree, Graph, Disjoint Set, and any host of other options.
- "Why not use Node for tree structures?" one might ask. Well, the Node
- class contains things that won't be relevant to one's custom data structure.
- As such, it can be helpful to construct one's own node type when building
- tree structures.
- .. tabs::
- .. code-tab:: gdscript GDScript
- extends Object
- class_name TreeNode
- var _parent: TreeNode = null
- var _children := []
- func _notification(p_what):
- match p_what:
- NOTIFICATION_PREDELETE:
- # Destructor.
- for a_child in _children:
- a_child.free()
- .. code-tab:: csharp
- using Godot;
- using System.Collections.Generic;
- // Can decide whether to expose getters/setters for properties later
- public partial class TreeNode : GodotObject
- {
- private TreeNode _parent = null;
- private List<TreeNode> _children = new();
- public override void _Notification(int what)
- {
- switch (what)
- {
- case NotificationPredelete:
- foreach (TreeNode child in _children)
- {
- node.Free();
- }
- break;
- }
- }
- }
- From here, one can then create their own structures with specific features,
- limited only by their imagination.
- Enumerations: int vs. string
- ----------------------------
- Most languages offer an enumeration type option. GDScript is no different, but
- unlike most other languages, it allows one to use either integers or strings for
- the enum values (the latter only when using the ``@export_enum`` annotation in GDScript).
- The question then arises, "which should one use?"
- The short answer is, "whichever you are more comfortable with." This
- is a feature specific to GDScript and not Godot scripting in general;
- The languages prioritizes usability over performance.
- On a technical level, integer comparisons (constant-time) will happen
- faster than string comparisons (linear-time). If one wants to keep
- up other languages' conventions though, then one should use integers.
- The primary issue with using integers comes up when one wants to *print*
- an enum value. As integers, attempting to print ``MY_ENUM`` will print
- ``5`` or what-have-you, rather than something like ``"MyEnum"``. To
- print an integer enum, one would have to write a Dictionary that maps the
- corresponding string value for each enum.
- If the primary purpose of using an enum is for printing values and one wishes
- to group them together as related concepts, then it makes sense to use them as
- strings. That way, a separate data structure to execute on the printing is
- unnecessary.
- AnimatedTexture vs. AnimatedSprite2D vs. AnimationPlayer vs. AnimationTree
- --------------------------------------------------------------------------
- Under what circumstances should one use each of Godot's animation classes?
- The answer may not be immediately clear to new Godot users.
- :ref:`AnimatedTexture <class_AnimatedTexture>` is a texture that
- the engine draws as an animated loop rather than a static image.
- Users can manipulate...
- 1. the rate at which it moves across each section of the texture (FPS).
- 2. the number of regions contained within the texture (frames).
- Godot's :ref:`RenderingServer <class_RenderingServer>` then draws
- the regions in sequence at the prescribed rate. The good news is that this
- involves no extra logic on the part of the engine. The bad news is
- that users have very little control.
- Also note that AnimatedTexture is a :ref:`Resource <class_Resource>` unlike
- the other :ref:`Node <class_Node>` objects discussed here. One might create
- a :ref:`Sprite2D <class_Sprite2D>` node that uses AnimatedTexture as its texture.
- Or (something the others can't do) one could add AnimatedTextures as tiles
- in a :ref:`TileSet <class_TileSet>` and integrate it with a
- :ref:`TileMapLayer <class_TileMapLayer>` for many auto-animating backgrounds that
- all render in a single batched draw call.
- The :ref:`AnimatedSprite2D <class_AnimatedSprite2D>` node, in combination with the
- :ref:`SpriteFrames <class_SpriteFrames>` resource, allows one to create a
- variety of animation sequences through spritesheets, flip between animations,
- and control their speed, regional offset, and orientation. This makes them
- well-suited to controlling 2D frame-based animations.
- If one needs to trigger other effects in relation to animation changes (for
- example, create particle effects, call functions, or manipulate other
- peripheral elements besides the frame-based animation), then one will need to use
- an :ref:`AnimationPlayer <class_AnimationPlayer>` node in conjunction with
- the AnimatedSprite2D.
- AnimationPlayers are also the tool one will need to use if they wish to design
- more complex 2D animation systems, such as...
- 1. **Cut-out animations:** editing sprites' transforms at runtime.
- 2. **2D Mesh animations:** defining a region for the sprite's texture and
- rigging a skeleton to it. Then one animates the bones which
- stretch and bend the texture in proportion to the bones' relationships to
- each other.
- 3. A mix of the above.
- While one needs an AnimationPlayer to design each of the individual
- animation sequences for a game, it can also be useful to combine animations
- for blending, i.e. enabling smooth transitions between these animations. There
- may also be a hierarchical structure between animations that one plans out for
- their object. These are the cases where the :ref:`AnimationTree <class_AnimationTree>`
- shines. One can find an in-depth guide on using the AnimationTree
- :ref:`here <doc_animation_tree>`.
|