# License
libco is released under the ISC license.

# Foreword
libco is a cross-platform, permissively licensed implementation of
cooperative-multithreading; a feature that is sorely lacking from the ISO C/C++
standard.

The library is designed for maximum speed and portability, and not for safety or
features. If safety or extra functionality is desired, a wrapper API can easily
be written to encapsulate all library functions.

Behavior of executing operations that are listed as not permitted below result
in undefined behavior. They may work anyway, they may cause undesired / unknown
behavior, or they may crash the program entirely.

The goal of this library was to simplify the base API as much as possible,
implementing only that which cannot be implemented using pure C. Additional
functionality after this would only complicate ports of this library to new
platforms.

# Porting
This document is included as a reference for porting libco. Please submit any
ports you create to me, so that libco can become more useful. Please note that
since libco is permissively licensed, you must submit your code as a work of the
public domain in order for it to be included in the official distribution.

Full credit will be given in the source code of the official release. Please
do not bother submitting code to me under any other license -- including GPL,
LGPL, BSD or CC -- I am not interested in creating a library with multiple
different licenses depending on which targets are used.

Note that there are a variety of compile-time options in `settings.h`,
so if you want to use libco on a platform where it is not supported by default,
you may be able to configure the implementation appropriately without having
to make a whole new port.

# Synopsis
```c
typedef void* cothread_t;

cothread_t co_active();
cothread_t co_create(unsigned int heapsize, void (*coentry)(void));
void       co_delete(cothread_t cothread);
void       co_switch(cothread_t cothread);
```

# Usage
## cothread_t
```c
typedef void* cothread_t;
```
Handle to cothread.

Handle must be of type `void*`.

A value of null (0) indicates an uninitialized or invalid handle, whereas a
non-zero value indicates a valid handle. A valid handle is backed by execution
state to which the execution can be co_switch()ed to.

## co_active
```c
cothread_t co_active();
```
Return handle to current cothread.

Note that the handle is valid even if the function is called from a non-cothread
context. To achieve this, we save the execution state in an internal buffer,
instead of using the user-provided memory. Since this handle is valid, it can
be used to co_switch to this context from another cothread. In multi-threaded
applications, make sure to not switch non-cothread context across CPU cores,
to prevent any possible conflicts with the OS scheduler.

## co_derive
```c
cothread_t co_derive(void* memory,
                     unsigned int heapsize,
                     void (*coentry)(void));
```
Initializes new cothread.

This function is identical to `co_create`, only it attempts to use the provided
memory instead of allocating new memory on the heap. Please note that certain
implementations (currently only Windows Fibers) cannot be created using existing
memory, and as such, this function will fail.

## co_create
```c
cothread_t co_create(unsigned int heapsize,
                     void (*coentry)(void));
```
Create new cothread.

`heapsize` is the amount of memory allocated for the cothread stack, specified
in bytes. This is unfortunately impossible to make fully portable. It is
recommended to specify sizes using `n * sizeof(void*)`. It is better to err
on the side of caution and allocate more memory than will be needed to ensure
compatibility with other platforms, within reason. A typical heapsize for a
32-bit architecture is ~1MB.

When the new cothread is first called, program execution jumps to coentry.
This function does not take any arguments, due to portability issues with
passing function arguments. However, arguments can be simulated by the use
of global variables, which can be set before the first call to each cothread.

`coentry()` must not return, and should end with an appropriate `co_switch()`
statement. Behavior is undefined if entry point returns normally.

Library is responsible for allocating cothread stack memory, to free
the user from needing to allocate special memory capable of being used
as program stack memory on platforms where this is required.

User is always responsible for deleting cothreads with `co_delete()`.

Return value of `null` (0) indicates cothread creation failed.

## co_delete
```c
void co_delete(cothread_t cothread);
```
Delete specified cothread.

`null` (0) or invalid cothread handle is not allowed.

Passing handle of active cothread to this function is not allowed.

Passing handle of primary cothread is not allowed.

## co_serializable

```c
int co_serializable(void);
```

Returns non-zero if the implementation keeps the entire coroutine state in the
buffer passed to `co_derive()`. That is, if `co_serializable()` returns
non-zero, and if your cothread does not modify the heap or any process-wide
state, then you can "snapshot" the cothread's state by taking a copy of the
buffer originally passed to `co_derive()`, and "restore" a previous state
by copying the snapshot back into the buffer it came from.

## co_switch
```c
void co_switch(cothread_t cothread);
```
Switch to specified cothread.

`null` (0) or invalid cothread handle is not allowed.

Passing handle of active cothread to this function is not allowed.