/* * Copyright (c) 2001-2012,2015 Marc Alexander Lehmann * * Redistribution and use in source and binary forms, with or without modifica- * tion, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MER- * CHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO * EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPE- * CIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTH- * ERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. * * Alternatively, the contents of this file may be used under the terms of * the GNU General Public License ("GPL") version 2 or any later version, * in which case the provisions of the GPL are applicable instead of * the above. If you wish to allow the use of your version of this file * only under the terms of the GPL and not to allow others to use your * version of this file under the BSD license, indicate your decision * by deleting the provisions above and replace them with the notice * and other provisions required by the GPL. If you do not delete the * provisions above, a recipient may use your version of this file under * either the BSD or the GPL. * * This library is modelled strictly after Ralf S. Engelschalls article at * http://www.gnu.org/software/pth/rse-pmt.ps. So most of the credit must * go to Ralf S. Engelschall . * * This coroutine library is very much stripped down. You should either * build your own process abstraction using it or - better - just use GNU * Portable Threads, http://www.gnu.org/software/pth/. * */ /* * 2006-10-26 Include stddef.h on OS X to work around one of its bugs. * Reported by Michael_G_Schwern. * 2006-11-26 Use _setjmp instead of setjmp on GNU/Linux. * 2007-04-27 Set unwind frame info if gcc 3+ and ELF is detected. * Use _setjmp instead of setjmp on _XOPEN_SOURCE >= 600. * 2007-05-02 Add assembly versions for x86 and amd64 (to avoid reliance * on SIGUSR2 and sigaltstack in Crossfire). * 2008-01-21 Disable CFI usage on anything but GNU/Linux. * 2008-03-02 Switched to 2-clause BSD license with GPL exception. * 2008-04-04 New (but highly unrecommended) pthreads backend. * 2008-04-24 Reinstate CORO_LOSER (had wrong stack adjustments). * 2008-10-30 Support assembly method on x86 with and without frame pointer. * 2008-11-03 Use a global asm statement for CORO_ASM, idea by pippijn. * 2008-11-05 Hopefully fix misaligned stacks with CORO_ASM/SETJMP. * 2008-11-07 rbp wasn't saved in CORO_ASM on x86_64. * introduce coro_destroy, which is a nop except for pthreads. * speed up CORO_PTHREAD. Do no longer leak threads either. * coro_create now allows one to create source coro_contexts. * do not rely on makecontext passing a void * correctly. * try harder to get _setjmp/_longjmp. * major code cleanup/restructuring. * 2008-11-10 the .cfi hacks are no longer needed. * 2008-11-16 work around a freebsd pthread bug. * 2008-11-19 define coro_*jmp symbols for easier porting. * 2009-06-23 tentative win32-backend support for mingw32 (Yasuhiro Matsumoto). * 2010-12-03 tentative support for uclibc (which lacks all sorts of things). * 2011-05-30 set initial callee-saved-registers to zero with CORO_ASM. * use .cfi_undefined rip on linux-amd64 for better backtraces. * 2011-06-08 maybe properly implement weird windows amd64 calling conventions. * 2011-07-03 rely on __GCC_HAVE_DWARF2_CFI_ASM for cfi detection. * 2011-08-08 cygwin trashes stacks, use pthreads with double stack on cygwin. * 2012-12-04 reduce misprediction penalty for x86/amd64 assembly switcher. * 2012-12-05 experimental fiber backend (allocates stack twice). * 2012-12-07 API version 3 - add coro_stack_alloc/coro_stack_free. * 2012-12-21 valgrind stack registering was broken. * 2015-12-05 experimental asm be for arm7, based on a patch by Nick Zavaritsky. * use __name__ for predefined symbols, as in libecb. * enable guard pages on arm, aarch64 and mips. */ #ifndef CORO_H #define CORO_H #if __cplusplus extern "C" { #endif /* * This library consists of only three files * coro.h, coro.c and LICENSE (and optionally README) * * It implements what is known as coroutines, in a hopefully * portable way. * * All compiletime symbols must be defined both when including coro.h * (using libcoro) as well as when compiling coro.c (the implementation). * * You can manually specify which flavour you want. If you don't define * any of these, libcoro tries to choose a safe and fast default: * * -DCORO_UCONTEXT * * This flavour uses SUSv2's get/set/swap/makecontext functions that * unfortunately only some unices support, and is quite slow. * * -DCORO_SJLJ * * This flavour uses SUSv2's setjmp/longjmp and sigaltstack functions to * do it's job. Coroutine creation is much slower than UCONTEXT, but * context switching is a bit cheaper. It should work on almost all unices. * * -DCORO_LINUX * * CORO_SJLJ variant. * Old GNU/Linux systems (<= glibc-2.1) only work with this implementation * (it is very fast and therefore recommended over other methods, but * doesn't work with anything newer). * * -DCORO_LOSER * * CORO_SJLJ variant. * Microsoft's highly proprietary platform doesn't support sigaltstack, and * this selects a suitable workaround for this platform. It might not work * with your compiler though - it has only been tested with MSVC 6. * * -DCORO_FIBER * * Slower, but probably more portable variant for the Microsoft operating * system, using fibers. Ignores the passed stack and allocates it internally. * Also, due to bugs in cygwin, this does not work with cygwin. * * -DCORO_IRIX * * CORO_SJLJ variant. * For SGI's version of Microsoft's NT ;) * * -DCORO_ASM * * Hand coded assembly, known to work only on a few architectures/ABI: * GCC + arm7/x86/IA32/amd64/x86_64 + GNU/Linux and a few BSDs. Fastest * choice, if it works. * * -DCORO_PTHREAD * * Use the pthread API. You have to provide and -lpthread. * This is likely the slowest backend, and it also does not support fork(), * so avoid it at all costs. * * If you define neither of these symbols, coro.h will try to autodetect * the best/safest model. To help with the autodetection, you should check * (e.g. using autoconf) and define the following symbols: HAVE_UCONTEXT_H * / HAVE_SETJMP_H / HAVE_SIGALTSTACK. */ /* * Changes when the API changes incompatibly. * This is ONLY the API version - there is no ABI compatibility between releases. * * Changes in API version 2: * replaced bogus -DCORO_LOOSE with grammatically more correct -DCORO_LOSER * Changes in API version 3: * introduced stack management (CORO_STACKALLOC) */ #define CORO_VERSION 3 #include /* * This is the type for the initialization function of a new coroutine. */ typedef void (*coro_func)(void *); /* * A coroutine state is saved in the following structure. Treat it as an * opaque type. errno and sigmask might be saved, but don't rely on it, * implement your own switching primitive if you need that. */ typedef struct coro_context coro_context; /* * This function creates a new coroutine. Apart from a pointer to an * uninitialised coro_context, it expects a pointer to the entry function * and the single pointer value that is given to it as argument. * * Allocating/deallocating the stack is your own responsibility. * * As a special case, if coro, arg, sptr and ssze are all zero, * then an "empty" coro_context will be created that is suitable * as an initial source for coro_transfer. * * This function is not reentrant, but putting a mutex around it * will work. */ void coro_create (coro_context *ctx, /* an uninitialised coro_context */ coro_func coro, /* the coroutine code to be executed */ void *arg, /* a single pointer passed to the coro */ void *sptr, /* start of stack area */ size_t ssze); /* size of stack area in bytes */ /* * The following prototype defines the coroutine switching function. It is * sometimes implemented as a macro, so watch out. * * This function is thread-safe and reentrant. */ #if 0 void coro_transfer (coro_context *prev, coro_context *next); #endif /* * The following prototype defines the coroutine destroy function. It * is sometimes implemented as a macro, so watch out. It also serves no * purpose unless you want to use the CORO_PTHREAD backend, where it is * used to clean up the thread. You are responsible for freeing the stack * and the context itself. * * This function is thread-safe and reentrant. */ #if 0 void coro_destroy (coro_context *ctx); #endif /*****************************************************************************/ /* optional stack management */ /*****************************************************************************/ /* * You can disable all of the stack management functions by * defining CORO_STACKALLOC to 0. Otherwise, they are enabled by default. * * If stack management is enabled, you can influence the implementation via these * symbols: * * -DCORO_USE_VALGRIND * * If defined, then libcoro will include valgrind/valgrind.h and register * and unregister stacks with valgrind. * * -DCORO_GUARDPAGES=n * * libcoro will try to use the specified number of guard pages to protect against * stack overflow. If n is 0, then the feature will be disabled. If it isn't * defined, then libcoro will choose a suitable default. If guardpages are not * supported on the platform, then the feature will be silently disabled. */ #ifndef CORO_STACKALLOC # define CORO_STACKALLOC 1 #endif #if CORO_STACKALLOC /* * The only allowed operations on these struct members is to read the * "sptr" and "ssze" members to pass it to coro_create, to read the "sptr" * member to see if it is false, in which case the stack isn't allocated, * and to set the "sptr" member to 0, to indicate to coro_stack_free to * not actually do anything. */ struct coro_stack { void *sptr; size_t ssze; #if CORO_USE_VALGRIND int valgrind_id; #endif }; /* * Try to allocate a stack of at least the given size and return true if * successful, or false otherwise. * * The size is *NOT* specified in bytes, but in units of sizeof (void *), * i.e. the stack is typically 4(8) times larger on 32 bit(64 bit) platforms * then the size passed in. * * If size is 0, then a "suitable" stack size is chosen (usually 1-2MB). */ int coro_stack_alloc (struct coro_stack *stack, unsigned int size); /* * Free the stack allocated by coro_stack_alloc again. It is safe to * call this function on the coro_stack structure even if coro_stack_alloc * failed. */ void coro_stack_free (struct coro_stack *stack); #endif /* * That was it. No other user-serviceable parts below here. */ /*****************************************************************************/ #if !defined CORO_LOSER && !defined CORO_UCONTEXT \ && !defined CORO_SJLJ && !defined CORO_LINUX \ && !defined CORO_IRIX && !defined CORO_ASM \ && !defined CORO_PTHREAD && !defined CORO_FIBER # if defined WINDOWS && (defined __i386__ || (__x86_64__ || defined _M_IX86 || defined _M_AMD64)) # define CORO_ASM 1 # elif defined WINDOWS || defined _WIN32 # define CORO_LOSER 1 /* you don't win with windoze */ # elif __linux && (__i386__ || (__x86_64__ && !__ILP32__) || (__arm__ && __ARCH_ARCH == 7)) # define CORO_ASM 1 # elif defined HAVE_UCONTEXT_H # define CORO_UCONTEXT 1 # elif defined HAVE_SETJMP_H && defined HAVE_SIGALTSTACK # define CORO_SJLJ 1 # else error unknown or unsupported architecture # endif #endif /*****************************************************************************/ #if CORO_UCONTEXT # include struct coro_context { ucontext_t uc; }; # define coro_transfer(p,n) swapcontext (&((p)->uc), &((n)->uc)) # define coro_destroy(ctx) (void *)(ctx) #elif CORO_SJLJ || CORO_LOSER || CORO_LINUX || CORO_IRIX # if defined(CORO_LINUX) && !defined(_GNU_SOURCE) # define _GNU_SOURCE /* for glibc */ # endif # if !CORO_LOSER # include # endif /* solaris is hopelessly borked, it expands _XOPEN_UNIX to nothing */ # if __sun # undef _XOPEN_UNIX # define _XOPEN_UNIX 1 # endif # include # if _XOPEN_UNIX > 0 || defined (_setjmp) # define coro_jmp_buf jmp_buf # define coro_setjmp(env) _setjmp (env) # define coro_longjmp(env) _longjmp ((env), 1) # elif CORO_LOSER # define coro_jmp_buf jmp_buf # define coro_setjmp(env) setjmp (env) # define coro_longjmp(env) longjmp ((env), 1) # else # define coro_jmp_buf sigjmp_buf # define coro_setjmp(env) sigsetjmp (env, 0) # define coro_longjmp(env) siglongjmp ((env), 1) # endif struct coro_context { coro_jmp_buf env; }; # define coro_transfer(p,n) do { if (!coro_setjmp ((p)->env)) coro_longjmp ((n)->env); } while (0) # define coro_destroy(ctx) (void *)(ctx) #elif CORO_ASM struct coro_context { void **sp; /* must be at offset 0 */ }; #if __i386__ || __x86_64__ void __attribute__ ((__noinline__, __regparm__(2))) #else void __attribute__ ((__noinline__)) #endif coro_transfer (coro_context *prev, coro_context *next); # define coro_destroy(ctx) (void *)(ctx) #elif CORO_PTHREAD # include extern pthread_mutex_t coro_mutex; struct coro_context { pthread_cond_t cv; pthread_t id; }; void coro_transfer (coro_context *prev, coro_context *next); void coro_destroy (coro_context *ctx); #elif CORO_FIBER struct coro_context { void *fiber; /* only used for initialisation */ coro_func coro; void *arg; }; void coro_transfer (coro_context *prev, coro_context *next); void coro_destroy (coro_context *ctx); #endif #if __cplusplus } #endif #endif