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#![feature(alloc)]
#![feature(allocator_api)]
#![recursion_limit = "256"]
#![feature(test)]
#![feature(specialization)]
#![feature(attr_literals)]
/*!
This is the documentation for `savefile`

# Introduction

Savefile is a rust library to conveniently, quickly and correctly
serialize and deserialize arbitrary rust struct and enums into
an efficient and compact binary version controlled format.

The design use case is any application that needs to save large
amounts of data to disk, and support loading files from previous
versions of the program (but not from later versions!).


# Example

```
extern crate savefile;
use savefile::prelude::*;

#[macro_use]
extern crate savefile_derive;


#[derive(Savefile)]
struct Player {
    name : String,
    strength : u32,
    inventory : Vec<String>,
}

fn save_player(player:&Player) {
    save_file("save.bin", 0, player).unwrap();
}

fn load_player() -> Player {
    load_file("save.bin", 0).unwrap()
}

fn main() {
    save_player(&Player { name: "Steve".to_string(), strength: 42,
        inventory: vec!(
            "wallet".to_string(),
            "car keys".to_string(),
            "glasses".to_string())});
    assert_eq!(load_player().name,"Steve".to_string());

}

```

# Handling old versions

Let's expand the above example, by creating a 2nd version of the Player struct. Let's say
you decide that your game mechanics doesn't really need to track the skill of the player. But
you do wish to have a set of skills per player as well as the inventory.

Mark the struct like so:


```
extern crate savefile;
use savefile::prelude::*;

#[macro_use]
extern crate savefile_derive;


#[derive(Savefile)]
struct Player {
    name : String,
    #[versions="0..0"] //Only version 0 had this field
    strength : Removed<u32>,
    inventory : Vec<String>,
    #[versions="1.."] //Only versions 1 and later have this field
    skills : Vec<String>,
}

fn save_player(file:&'static str, player:&Player) {
	// Save version 1 of file.
    save_file(file, 1, player).unwrap();
}

fn load_player(file:&'static str) -> Player {
	// The '1' means we have version 1 in memory,
	// but we can still load any older version.
    load_file(file, 1).unwrap()
}

fn main() {
	let mut player = load_player("save.bin"); //Load from previous save
	assert_eq!("Steve",&player.name); //The name from the previous version saved will remain
	assert_eq!(0,player.skills.len()); //Skills didn't exist when this was saved
	player.skills.push("Whistling".to_string());	
	save_player("newsave.bin", &player); //The version saved here will the vec of skills
}
```


# Behind the scenes

For Savefile to be able to load an save a type T, that type must implement traits 
`WithSchema`, `Serialize` and `Deserialize` . The custom derive macro Savefile derives
all of these.

You can also implement these traits manually. Manual implementation can be good for:

1: Complex types for which the Savefile custom derive function does not work. For
example, trait objects or objects containing pointers.
2: Objects for which not all fields should be serialized, or which need complex
initialization (like running arbitrary code during deserialization).

## WithSchema

The `WithSchema` trait represents a type which knows which data layout it will have
when saved. 

## Serialize

The `Serialize`trait represents a type which knows how to write instances of itself to
a `Serializer`.

## Deserialize

The `Deserialize`trait represents a type which knows how to read instances of itself from a `Deserializer`.


# Speeding things up

Now, let's say we want to add a list of all positions that our player have visited,
so that we can provide a instant-replay function to our game. The list can become
really long, so we want to make sure that the overhead when serializing this is
as low as possible.

Savefile has an unsafe trait `ReprC` that you can implement for a type T. This instructs
Savefile to optimize serialization of Vec<T> into being just a very fast memory copy.

This is dangerous. You, as implementor of the `ReprR` trait take full responsibility
that all the following rules are upheld:

 * The type T is Copy
 * The type T is a struct. Using it on enums will probably lead to silent data corruption.
 * The type is represented in memory in an ordered, packed representation. Savefile is not
 clever enough to inspect the actual memory layout and adapt to this, so the memory representation
 has to be all the types of the struct fields in a consecutive sequence without any gaps. Note
 that the #[repr(C)] trait does not do this - it will include padding if needed for alignment
 reasons. You should not use #[repr(packed)], since that may lead to unaligned struct fields.
 If you really want the performance boost of the Savefile `ReprC`-trait, you should instead
 add manual padding, if necessary.

For example, don't do:
```
struct Bad {
	f1 : u8,
	f2 : u32,
}
``` 
Since the compiler is likely to insert 3 bytes of padding after f1, to ensure that f2 is aligned to 4 bytes.

Instead, do this:

```
struct Good {
	f1 : u8,
	pad1 :u8,
	pad2 :u8,
	pad3 :u8,
	f2 : u32,
}
```

And simpy don't use the pad1, pad2 and pad3 fields. Note, at time of writing, Savefile requires that the struct 
be free of all padding. Even padding at the end is not allowed. This means that the following does not work:

```
struct Bad2 {
	f1 : u32,
	f2 : u8,
}
``` 
This restriction may be lifted at a later time.

Note that having a struct with bad alignment will be detected, at runtime, for debug-builds. It may not be
detected in release builds. Serializing or deserializing each `ReprC` struct at least once somewhere in your test suite
is recommended.


```
extern crate savefile;
use savefile::prelude::*;

#[macro_use]
extern crate savefile_derive;

#[derive(ReprC, Clone, Copy, Savefile)]
#[repr(C)]
struct Position {
	x : u32,
	y : u32,
}

#[derive(Savefile)]
struct Player {
    name : String,
    #[versions="0..0"] //Only version 0 had this field
    strength : Removed<u32>,
    inventory : Vec<String>,
    #[versions="1.."] //Only versions 1 and later have this field
    skills : Vec<String>,
    #[versions="2.."] //Only versions 2 and later have this field
    history : Vec<Position>
}

fn save_player(file:&'static str, player:&Player) {
	// Save version 1 of file.
    save_file(file, 2, player).unwrap();
}

fn load_player(file:&'static str) -> Player {
	// The '1' means we have version 1 in memory,
	// but we can still load any older version.
    load_file(file, 2).unwrap()
}

fn main() {
	let mut player = load_player("newsave.bin"); //Load from previous save
	player.history.push(Position{x:1,y:1});
	player.history.push(Position{x:2,y:1});
	player.history.push(Position{x:2,y:2});
	save_player("newersave.bin", &player);
}
```

*/

#[macro_use] 
extern crate failure;

pub mod prelude;
mod savefile;