2020-07-15 17:21:42 +02:00
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---
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title: "Generic Flyweight in C++"
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date: 2020-07-16T14:28:52+02:00
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draft: false # I don't care for draft mode, git has branches for that
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2021-10-20 12:37:19 +02:00
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description: "A no-boilerplate flyweight pattern"
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2020-07-15 17:21:42 +02:00
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tags:
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- design pattern
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- C++
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categories:
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- programming
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series:
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- Generic flyweight
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favorite: false
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---
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The flyweight is a well-known
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[GoF](https://en.wikipedia.org/wiki/Design_Patterns) design pattern.
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2024-06-26 15:44:23 +02:00
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Its intent is to minimize memory usage by reducing the number of instantiations
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2020-07-15 17:21:42 +02:00
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of a given object.
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I will show you how to implement a robust flyweight in C++, as well as a way to
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make it templatable for easy use with no boiler-plate.
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<!--more-->
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## Flyweight
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The [flyweight pattern](https://en.wikipedia.org/wiki/Design_Patterns) minimizes
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memory usage by sharing a maximum amount of memory.
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The classic example, as outlined on Wikipedia, is the representation of glyphs
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in a word processor. Most characters will be instantiated multiple times, it
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would lead to a ludicrous amount of memory usage to instantiate an object with
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its full metadata for each character onscreen.
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What you can do instead is to instantiate the object once when you first
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encounter it, and then each time you need an identical object, you just refer to
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the first copy that you already had.
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### Implementation
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Most tutorials that I have seen online use an `std::vector` with a small amount
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of objects, and each flyweight holds on to an index inside the `vector`.
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```cpp
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class GlyphMetadata { /* implementation */ };
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class FlyweightImpl {
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static inline std::vector<GlyphMetadata> instances_{};
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public:
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static size_t glyphIndex(char c) {
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size_t ret = 0;
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// Linear scan to find the glyph's index if we already have it
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for (const auto& g : instances_)
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if (g.char() == c)
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return ret;
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else
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++ret;
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// We didn't find it, add it at the end
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instances_.emplace_back(c);
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return ret; // Return the newly added element's index
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}
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// Getters etc...
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};
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class Glyph {
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const size_t index_;
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public:
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Glyph(char c) : index_(FlyweightImpl::glyphIndex(c)) // Reference the index
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{}
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/* implementation, using the index to reference metadata */
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};
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// Etc...
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```
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However, this is not a robust solution, a large amount of objects will lead to
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longer checks for equality as you scan the whole length of the array. You
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cannot keep the `vector` sorted to do binary searches and insertion, because
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the flyweights rely on their index inside the vector being stable.
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Instead, I'd recommend you use an `std::set` for the following reasons:
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2020-08-27 17:32:51 +02:00
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2020-07-15 17:21:42 +02:00
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- its semantic implies an ordering relationship, without duplication
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- it has an (asymptotically) efficient insertion.
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- it has stable iterators/pointers on insertion: a flyweight can just refer to
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a pointer to the object contained inside the `std::set`.
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2020-08-27 17:32:51 +02:00
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2020-07-15 17:21:42 +02:00
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That last bullet point is the reason why I'd recommend using a `set` instead of
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a sorted `vector`.
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Here's the same example using this technique:
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```cpp
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// Same GlyphMetadata class
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// No need for a FlyweightImpl class
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class Glyph {
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static inline std::set<GlyphMetadata> instances_{};
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GlyphMetadata* meta_;
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public:
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Glyph(char c) : meta_(&(*instances_.emplace(c))) {}
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};
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```
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The little `&(*instances_.emplace(c))` does all the work for us:
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2020-08-27 17:32:51 +02:00
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2020-07-15 17:21:42 +02:00
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- `instances_.emplace(c)` creates the corresponding metadata only if it isn't in
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the set already.
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- We get an iterator back to the inserted element from this operation
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- We dereference it (`*<IT>`) to get a `GlyphMetadata&`
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- We take the address of that reference for our flyweight (`&(<REF>)`).
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### Templating
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This scheme with an `std::set` is easily templatable: indeed we can imagine a
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class `Unique<T>` which enables us to flyweight *any* `T`.
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```cpp
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// Templated on both the type T and the comparison functor used for total order
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// Most of the time, 'std::less' is good enough
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template <typename T, typename Cmp = std::less<T>>
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class Unique {
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static inline std::set<T, Cmp> instances_{};
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T* instance_;
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// Construct our Unique from a given T
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Unique(T value) : instances_(&(*instances_.emplace(std::move(value)))) {}
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// Other methods, e.g: implicit conversion to T&, copy assignment, etc...
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};
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```
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You can then create new flyweight by simply inheriting from the `Unique` class:
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```cpp
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// A flyweight string, e.g: when we have lots of duplication
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class LightStrings : public Unique<std::string> {
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// Flyweight pattern for free from inherited Unique
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// Implementation...
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};
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```
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## Conclusion
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This is an easy, generic flyweight implementation without any boilerplate. On
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the next post I'll show you how to use the same scheme with a polymorphic base
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class in our flyweight.
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I first discovered this pattern while working on EPITA's [Tiger
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Compiler](https://assignments.lrde.epita.fr/), a full-featured compiler written
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in modern C++, whose goal is to help teach C++ techniques to students and
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illustrate the use of design patterns in a big code base.
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