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178 lines
7.1 KiB
Plaintext
178 lines
7.1 KiB
Plaintext
/**
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\addtogroup sys
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@{
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*/
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/**
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\defgroup pt Protothreads
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Protothreads are a type of lightweight stackless threads designed for
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severly memory constrained systems such as deeply embedded systems or
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sensor network nodes. Protothreads provides linear code execution for
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event-driven systems implemented in C. Protothreads can be used with
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or without an RTOS.
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Protothreads are a extremely lightweight, stackless type of threads
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that provides a blocking context on top of an event-driven system,
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without the overhead of per-thread stacks. The purpose of protothreads
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is to implement sequential flow of control without complex state
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machines or full multi-threading. Protothreads provides conditional
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blocking inside C functions.
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The advantage of protothreads over a purely event-driven approach is
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that protothreads provides a sequential code structure that allows for
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blocking functions. In purely event-driven systems, blocking must be
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implemented by manually breaking the function into two pieces - one
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for the piece of code before the blocking call and one for the code
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after the blocking call. This makes it hard to use control structures
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such as if() conditionals and while() loops.
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The advantage of protothreads over ordinary threads is that a
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protothread does not require a separate stack. In memory constrained
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systems, the overhead of allocating multiple stacks can consume large
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amounts of the available memory. In contrast, each protothread only
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requires between two and twelve bytes of state, depending on the
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architecture.
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\note Because protothreads do not save the stack context across a
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blocking call, <b>local variables are not preserved when the
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protothread blocks</b>. This means that local variables should be used
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with utmost care - <b>if in doubt, do not use local variables inside a
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protothread!</b>
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Main features:
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- No machine specific code - the protothreads library is pure C
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- Does not use error-prone functions such as longjmp()
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- Very small RAM overhead - only two bytes per protothread
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- Can be used with or without an OS
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- Provides blocking wait without full multi-threading or
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stack-switching
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Examples applications:
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- Memory constrained systems
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- Event-driven protocol stacks
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- Deeply embedded systems
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- Sensor network nodes
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The protothreads API consists of four basic operations:
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initialization: PT_INIT(), execution: PT_BEGIN(), conditional
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blocking: PT_WAIT_UNTIL() and exit: PT_END(). On top of these, two
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convenience functions are built: reversed condition blocking:
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PT_WAIT_WHILE() and protothread blocking: PT_WAIT_THREAD().
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\sa \ref pt "Protothreads API documentation"
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The protothreads library is released under a BSD-style license that
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allows for both non-commercial and commercial usage. The only
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requirement is that credit is given.
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\section authors Authors
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The protothreads library was written by Adam Dunkels <adam@sics.se>
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with support from Oliver Schmidt <ol.sc@web.de>.
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\section pt-desc Protothreads
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Protothreads are a extremely lightweight, stackless threads that
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provides a blocking context on top of an event-driven system, without
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the overhead of per-thread stacks. The purpose of protothreads is to
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implement sequential flow of control without using complex state
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machines or full multi-threading. Protothreads provides conditional
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blocking inside a C function.
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In memory constrained systems, such as deeply embedded systems,
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traditional multi-threading may have a too large memory overhead. In
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traditional multi-threading, each thread requires its own stack, that
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typically is over-provisioned. The stacks may use large parts of the
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available memory.
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The main advantage of protothreads over ordinary threads is that
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protothreads are very lightweight: a protothread does not require its
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own stack. Rather, all protothreads run on the same stack and context
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switching is done by stack rewinding. This is advantageous in memory
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constrained systems, where a stack for a thread might use a large part
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of the available memory. A protothread only requires only two bytes of
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memory per protothread. Moreover, protothreads are implemented in pure
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C and do not require any machine-specific assembler code.
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A protothread runs within a single C function and cannot span over
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other functions. A protothread may call normal C functions, but cannot
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block inside a called function. Blocking inside nested function calls
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is instead made by spawning a separate protothread for each
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potentially blocking function. The advantage of this approach is that
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blocking is explicit: the programmer knows exactly which functions
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that block that which functions the never blocks.
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Protothreads are similar to asymmetric co-routines. The main
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difference is that co-routines uses a separate stack for each
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co-routine, whereas protothreads are stackless. The most similar
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mechanism to protothreads are Python generators. These are also
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stackless constructs, but have a different purpose. Protothreads
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provides blocking contexts inside a C function, whereas Python
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generators provide multiple exit points from a generator function.
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\section pt-autovars Local variables
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\note
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Because protothreads do not save the stack context across a blocking
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call, local variables are not preserved when the protothread
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blocks. This means that local variables should be used with utmost
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care - if in doubt, do not use local variables inside a protothread!
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\section pt-scheduling Scheduling
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A protothread is driven by repeated calls to the function in which the
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protothread is running. Each time the function is called, the
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protothread will run until it blocks or exits. Thus the scheduling of
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protothreads is done by the application that uses protothreads.
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\section pt-impl Implementation
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Protothreads are implemented using \ref lc "local continuations". A
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local continuation represents the current state of execution at a
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particular place in the program, but does not provide any call history
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or local variables. A local continuation can be set in a specific
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function to capture the state of the function. After a local
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continuation has been set can be resumed in order to restore the state
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of the function at the point where the local continuation was set.
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Local continuations can be implemented in a variety of ways:
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-# by using machine specific assembler code,
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-# by using standard C constructs, or
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-# by using compiler extensions.
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The first way works by saving and restoring the processor state,
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except for stack pointers, and requires between 16 and 32 bytes of
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memory per protothread. The exact amount of memory required depends on
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the architecture.
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The standard C implementation requires only two bytes of state per
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protothread and utilizes the C switch() statement in a non-obvious way
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that is similar to Duff's device. This implementation does, however,
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impose a slight restriction to the code that uses protothreads in that
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the code cannot use switch() statements itself.
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Certain compilers has C extensions that can be used to implement
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protothreads. GCC supports label pointers that can be used for this
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purpose. With this implementation, protothreads require 4 bytes of RAM
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per protothread.
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@{
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*/
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/** @} */
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/** @} */ |