mirror of
https://github.com/0intro/libtask
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252 lines
7.9 KiB
Plaintext
252 lines
7.9 KiB
Plaintext
Libtask is a simple coroutine library. It runs on Linux (ARM, MIPS, and x86),
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FreeBSD (x86), OS X (PowerPC x86, and x86-64), and SunOS Solaris (Sparc),
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and is easy to port to other systems.
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Libtask gives the programmer the illusion of threads, but
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the operating system sees only a single kernel thread.
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For clarity, we refer to the coroutines as "tasks," not threads.
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Scheduling is cooperative. Only one task runs at a time,
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and it cannot be rescheduled without explicitly giving up
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the CPU. Most of the functions provided in task.h do have
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the possibility of going to sleep. Programs using the task
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functions should #include <task.h>.
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--- Basic task manipulation
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int taskcreate(void (*f)(void *arg), void *arg, unsigned int stacksize);
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Create a new task running f(arg) on a stack of size stacksize.
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void tasksystem(void);
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Mark the current task as a "system" task. These are ignored
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for the purposes of deciding the program is done running
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(see taskexit next).
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void taskexit(int status);
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Exit the current task. If this is the last non-system task,
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exit the entire program using the given exit status.
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void taskexitall(int status);
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Exit the entire program, using the given exit status.
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void taskmain(int argc, char *argv[]);
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Write this function instead of main. Libtask provides its own main.
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int taskyield(void);
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Explicitly give up the CPU. The current task will be scheduled
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again once all the other currently-ready tasks have a chance
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to run. Returns the number of other tasks that ran while the
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current task was waiting. (Zero means there are no other tasks
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trying to run.)
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int taskdelay(unsigned int ms)
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Explicitly give up the CPU for at least ms milliseconds.
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Other tasks continue to run during this time.
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void** taskdata(void);
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Return a pointer to a single per-task void* pointer.
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You can use this as a per-task storage place.
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void needstack(int n);
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Tell the task library that you need at least n bytes left
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on the stack. If you don't have it, the task library will call abort.
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(It's hard to figure out how big stacks should be. I usually make
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them really big (say 32768) and then don't worry about it.)
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void taskname(char*, ...);
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Takes an argument list like printf. Sets the current task's name.
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char* taskgetname(void);
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Returns the current task's name. Is the actual buffer; do not free.
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void taskstate(char*, ...);
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char* taskgetstate(void);
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Like taskname and taskgetname but for the task state.
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When you send a tasked program a SIGQUIT (or SIGINFO, on BSD)
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it will print a list of all its tasks and their names and states.
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This is useful for debugging why your program isn't doing anything!
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unsigned int taskid(void);
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Return the unique task id for the current task.
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--- Non-blocking I/O
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There is a small amount of runtime support for non-blocking I/O
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on file descriptors.
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int fdnoblock(int fd);
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Sets I/O on the given fd to be non-blocking. Should be
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called before any of the other fd routines.
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int fdread(int, void*, int);
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Like regular read(), but puts task to sleep while waiting for
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data instead of blocking the whole program.
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int fdreadn(int, void*, int);
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Like fdread(), but does successive read calls until n bytes have
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been read, or a read system call returns a non-positive count.
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int fdwrite(int, void*, int);
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Like regular write(), but puts task to sleep while waiting to
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write data instead of blocking the whole program.
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void fdwait(int fd, int rw);
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Low-level call sitting underneath fdread and fdwrite.
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Puts task to sleep while waiting for I/O to be possible on fd.
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Rw specifies type of I/O: 'r' means read, 'w' means write,
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anything else means just exceptional conditions (hang up, etc.)
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The 'r' and 'w' also wake up for exceptional conditions.
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--- Network I/O
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These are convenient packaging of the ugly Unix socket routines.
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They can all put the current task to sleep during the call.
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int netannounce(int proto, char *address, int port)
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Start a network listener running on address and port of protocol.
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Proto is either TCP or UDP. Port is a port number. Address is a
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string version of a host name or IP address. If address is null,
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then announce binds to the given port on all available interfaces.
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Returns a fd to use with netaccept.
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Examples: netannounce(TCP, "localhost", 80) or
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netannounce(TCP, "127.0.0.1", 80) or netannounce(TCP, 0, 80).
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int netaccept(int fd, char *server, int *port)
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Get the next connection that comes in to the listener fd.
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Returns a fd to use to talk to the guy who just connected.
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If server is not null, it must point at a buffer of at least
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46 bytes that is filled in with the remote IP address.
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If port is not null, it is filled in with the report port.
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Example:
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char server[46];
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int port;
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if(netaccept(fd, server, &port) >= 0)
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printf("connect from %s:%d", server, port);
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int netdial(int proto, char *name, int port)
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Create a new (outgoing) connection to a particular host.
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Name can be an ip address or a domain name. If it's a domain name,
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the entire program will block while the name is resolved
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(the DNS library does not provide a nice non-blocking interface).
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Example: netdial(TCP, "www.google.com", 80)
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or netdial(TCP, "18.26.4.9", 80)
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--- Time
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unsigned int taskdelay(unsigned int ms)
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Put the current task to sleep for approximately ms milliseconds.
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Return the actual amount of time slept, in milliseconds.
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--- Example programs
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In this directory, tcpproxy.c is a simple TCP proxy that illustrates
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most of the above. You can run
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tcpproxy 1234 www.google.com 80
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and then you should be able to visit http://localhost:1234/ and see Google.
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Other examples are:
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primes.c - simple prime sieve
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httpload.c - simple HTTP load generator
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testdelay.c - test taskdelay()
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--- Building
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To build, run make. You can run make install to copy task.h and
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libtask.a to the appropriate places in /usr/local. Then you
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should be able to just link with -ltask in your programs
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that use it.
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On SunOS Solaris machines, run makesun instead of just make.
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--- Contact Info
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Please email me with questions or problems.
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Russ Cox
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rsc@swtch.com
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--- Stuff you probably won't use at first ---
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--- but might want to know about eventually ---
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void tasksleep(Rendez*);
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int taskwakeup(Rendez*);
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int taskwakeupall(Rendez*);
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A Rendez is a condition variable. You can declare a new one by
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just allocating memory for it (or putting it in another structure)
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and then zeroing the memory. Tasksleep(r) 'sleeps on r', giving
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up the CPU. Multiple tasks can sleep on a single Rendez.
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When another task comes along and calls taskwakeup(r),
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the first task sleeping on r (if any) will be woken up.
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Taskwakeupall(r) wakes up all the tasks sleeping on r.
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They both return the actual number of tasks awakened.
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void qlock(QLock*);
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int canqlock(QLock*);
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void qunlock(QLock*);
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You probably won't need locks because of the cooperative
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scheduling, but if you do, here are some. You can make a new
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QLock by just declaring it and zeroing the memory.
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Calling qlock will give up the CPU if the lock is held by someone else.
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Calling qunlock will not give up the CPU.
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Calling canqlock tries to lock the lock, but will not give up the CPU.
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It returns 1 if the lock was acquired, 0 if it cannot be at this time.
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void rlock(RWLock*);
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int canrlock(RWLock*);
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void runlock(RWLock*);
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void wlock(RWLock*);
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int canwlock(RWLock*);
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void wunlock(RWLock*);
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RWLocks are reader-writer locks. Any number of readers
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can lock them at once, but only one writer at a time.
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If a writer is holding it, there can't be any readers.
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Channel *chancreate(int, int);
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etc.
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Channels are buffered communication pipes you can
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use to send messages between tasks. Some people like
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doing most of the inter-task communication using channels.
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For details on channels see the description of channels in
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http://swtch.com/usr/local/plan9/man/man3/thread.html and
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http://swtch.com/~rsc/thread/
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and also the example program primes.c, which implements
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a concurrent prime sieve.
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