third_party/gofrontend/libgo/runtime/go-cgo.c - llvm-project/llgo - Git at Google

 /* go-cgo.c -- SWIG support routines for libgo.

    Copyright 2011 The Go Authors. All rights reserved.
    Use of this source code is governed by a BSD-style
    license that can be found in the LICENSE file.  */

 #include "runtime.h"
 #include "go-alloc.h"
 #include "interface.h"
 #include "go-panic.h"
 #include "go-type.h"

 extern void __go_receive (ChanType *, Hchan *, byte *);

 /* Prepare to call from code written in Go to code written in C or
    C++.  This takes the current goroutine out of the Go scheduler, as
    though it were making a system call.  Otherwise the program can
    lock up if the C code goes to sleep on a mutex or for some other
    reason.  This idea is to call this function, then immediately call
    the C/C++ function.  After the C/C++ function returns, call
    syscall_cgocalldone.  The usual Go code would look like

        syscall.Cgocall()
        defer syscall.Cgocalldone()
        cfunction()

    */

 /* We let Go code call these via the syscall package.  */
 void syscall_cgocall(void) __asm__ (GOSYM_PREFIX "syscall.Cgocall");
 void syscall_cgocalldone(void) __asm__ (GOSYM_PREFIX "syscall.CgocallDone");
 void syscall_cgocallback(void) __asm__ (GOSYM_PREFIX "syscall.CgocallBack");
 void syscall_cgocallbackdone(void) __asm__ (GOSYM_PREFIX "syscall.CgocallBackDone");

 void
 syscall_cgocall ()
 {
   M* m;
   G* g;

   if (runtime_needextram && runtime_cas (&runtime_needextram, 1, 0))
     runtime_newextram ();

   m = runtime_m ();
   ++m->ncgocall;
   g = runtime_g ();
   ++g->ncgo;
   runtime_entersyscall ();
 }

 /* Prepare to return to Go code from C/C++ code.  */

 void
 syscall_cgocalldone ()
 {
   G* g;

   g = runtime_g ();
   __go_assert (g != NULL);
   --g->ncgo;
   if (g->ncgo == 0)
     {
       /* We are going back to Go, and we are not in a recursive call.
 	 Let the garbage collector clean up any unreferenced
 	 memory.  */
       g->cgomal = NULL;
     }

   /* If we are invoked because the C function called _cgo_panic, then
      _cgo_panic will already have exited syscall mode.  */
   if (g->status == Gsyscall)
     runtime_exitsyscall ();
 }

 /* Call back from C/C++ code to Go code.  */

 void
 syscall_cgocallback ()
 {
   M *mp;

   mp = runtime_m ();
   if (mp == NULL)
     {
       runtime_needm ();
       mp = runtime_m ();
       mp->dropextram = true;
     }

   runtime_exitsyscall ();

   if (runtime_g ()->ncgo == 0)
     {
       /* The C call to Go came from a thread not currently running any
 	 Go.  In the case of -buildmode=c-archive or c-shared, this
 	 call may be coming in before package initialization is
 	 complete.  Wait until it is.  */
       __go_receive (NULL, runtime_main_init_done, NULL);
     }

   mp = runtime_m ();
   if (mp->needextram)
     {
       mp->needextram = 0;
       runtime_newextram ();
     }
 }

 /* Prepare to return to C/C++ code from a callback to Go code.  */

 void
 syscall_cgocallbackdone ()
 {
   M *mp;

   runtime_entersyscall ();
   mp = runtime_m ();
   if (mp->dropextram && runtime_g ()->ncgo == 0)
     {
       mp->dropextram = false;
       runtime_dropm ();
     }
 }

 /* Allocate memory and save it in a list visible to the Go garbage
    collector.  */

 void *
 alloc_saved (size_t n)
 {
   void *ret;
   G *g;
   CgoMal *c;

   ret = __go_alloc (n);

   g = runtime_g ();
   c = (CgoMal *) __go_alloc (sizeof (CgoMal));
   c->next = g->cgomal;
   c->alloc = ret;
   g->cgomal = c;

   return ret;
 }

 /* These are routines used by SWIG.  The gc runtime library provides
    the same routines under the same name, though in that case the code
    is required to import runtime/cgo.  */

 void *
 _cgo_allocate (size_t n)
 {
   void *ret;

   runtime_exitsyscall ();
   ret = alloc_saved (n);
   runtime_entersyscall ();
   return ret;
 }

 extern const struct __go_type_descriptor string_type_descriptor
   __asm__ (GOSYM_PREFIX "__go_tdn_string");

 void
 _cgo_panic (const char *p)
 {
   intgo len;
   unsigned char *data;
   String *ps;
   struct __go_empty_interface e;

   runtime_exitsyscall ();
   len = __builtin_strlen (p);
   data = alloc_saved (len);
   __builtin_memcpy (data, p, len);
   ps = alloc_saved (sizeof *ps);
   ps->str = data;
   ps->len = len;
   e.__type_descriptor = &string_type_descriptor;
   e.__object = ps;

   /* We don't call runtime_entersyscall here, because normally what
      will happen is that we will walk up the stack to a Go deferred
      function that calls recover.  However, this will do the wrong
      thing if this panic is recovered and the stack unwinding is
      caught by a C++ exception handler.  It might be possible to
      handle this by calling runtime_entersyscall in the personality
      function in go-unwind.c.  FIXME.  */

   __go_panic (e);
 }

 /* Used for _cgo_wait_runtime_init_done.  This is based on code in
    runtime/cgo/gcc_libinit.c in the master library.  */

 static pthread_cond_t runtime_init_cond = PTHREAD_COND_INITIALIZER;
 static pthread_mutex_t runtime_init_mu = PTHREAD_MUTEX_INITIALIZER;
 static _Bool runtime_init_done;

 /* This is called by exported cgo functions to ensure that the runtime
    has been initialized before we enter the function.  This is needed
    when building with -buildmode=c-archive or similar.  */

 void
 _cgo_wait_runtime_init_done (void)
 {
   int err;

   if (__atomic_load_n (&runtime_init_done, __ATOMIC_ACQUIRE))
     return;

   err = pthread_mutex_lock (&runtime_init_mu);
   if (err != 0)
     abort ();
   while (!__atomic_load_n (&runtime_init_done, __ATOMIC_ACQUIRE))
     {
       err = pthread_cond_wait (&runtime_init_cond, &runtime_init_mu);
       if (err != 0)
 	abort ();
     }
   err = pthread_mutex_unlock (&runtime_init_mu);
   if (err != 0)
     abort ();
 }

 /* This is called by runtime_main after the Go runtime is
    initialized.  */

 void
 _cgo_notify_runtime_init_done (void)
 {
   int err;

   err = pthread_mutex_lock (&runtime_init_mu);
   if (err != 0)
     abort ();
   __atomic_store_n (&runtime_init_done, 1, __ATOMIC_RELEASE);
   err = pthread_cond_broadcast (&runtime_init_cond);
   if (err != 0)
     abort ();
   err = pthread_mutex_unlock (&runtime_init_mu);
   if (err != 0)
     abort ();
 }

 // runtime_iscgo is set to true if some cgo code is linked in.
 // This is done by a constructor in the cgo generated code.
 _Bool runtime_iscgo;

 // runtime_cgoHasExtraM is set on startup when an extra M is created
 // for cgo.  The extra M must be created before any C/C++ code calls
 // cgocallback.
 _Bool runtime_cgoHasExtraM;
	/* go-cgo.c -- SWIG support routines for libgo.

	Copyright 2011 The Go Authors. All rights reserved.
	Use of this source code is governed by a BSD-style
	license that can be found in the LICENSE file. */

	#include "runtime.h"
	#include "go-alloc.h"
	#include "interface.h"
	#include "go-panic.h"
	#include "go-type.h"

	extern void __go_receive (ChanType , Hchan , byte *);

	/* Prepare to call from code written in Go to code written in C or
	C++. This takes the current goroutine out of the Go scheduler, as
	though it were making a system call. Otherwise the program can
	lock up if the C code goes to sleep on a mutex or for some other
	reason. This idea is to call this function, then immediately call
	the C/C++ function. After the C/C++ function returns, call
	syscall_cgocalldone. The usual Go code would look like

	syscall.Cgocall()
	defer syscall.Cgocalldone()
	cfunction()

	*/

	/* We let Go code call these via the syscall package. */
	void syscall_cgocall(void) __asm__ (GOSYM_PREFIX "syscall.Cgocall");
	void syscall_cgocalldone(void) __asm__ (GOSYM_PREFIX "syscall.CgocallDone");
	void syscall_cgocallback(void) __asm__ (GOSYM_PREFIX "syscall.CgocallBack");
	void syscall_cgocallbackdone(void) __asm__ (GOSYM_PREFIX "syscall.CgocallBackDone");

	void
	syscall_cgocall ()
	{
	M* m;
	G* g;

	if (runtime_needextram && runtime_cas (&runtime_needextram, 1, 0))
	runtime_newextram ();

	m = runtime_m ();
	++m->ncgocall;
	g = runtime_g ();
	++g->ncgo;
	runtime_entersyscall ();
	}

	/* Prepare to return to Go code from C/C++ code. */

	void
	syscall_cgocalldone ()
	{
	G* g;

	g = runtime_g ();
	__go_assert (g != NULL);
	--g->ncgo;
	if (g->ncgo == 0)
	{
	/* We are going back to Go, and we are not in a recursive call.
	Let the garbage collector clean up any unreferenced
	memory. */
	g->cgomal = NULL;
	}

	/* If we are invoked because the C function called _cgo_panic, then
	_cgo_panic will already have exited syscall mode. */
	if (g->status == Gsyscall)
	runtime_exitsyscall ();
	}

	/* Call back from C/C++ code to Go code. */

	void
	syscall_cgocallback ()
	{
	M *mp;

	mp = runtime_m ();
	if (mp == NULL)
	{
	runtime_needm ();
	mp = runtime_m ();
	mp->dropextram = true;
	}

	runtime_exitsyscall ();

	if (runtime_g ()->ncgo == 0)
	{
	/* The C call to Go came from a thread not currently running any
	Go. In the case of -buildmode=c-archive or c-shared, this
	call may be coming in before package initialization is
	complete. Wait until it is. */
	__go_receive (NULL, runtime_main_init_done, NULL);
	}

	mp = runtime_m ();
	if (mp->needextram)
	{
	mp->needextram = 0;
	runtime_newextram ();
	}
	}

	/* Prepare to return to C/C++ code from a callback to Go code. */

	void
	syscall_cgocallbackdone ()
	{
	M *mp;

	runtime_entersyscall ();
	mp = runtime_m ();
	if (mp->dropextram && runtime_g ()->ncgo == 0)
	{
	mp->dropextram = false;
	runtime_dropm ();
	}
	}

	/* Allocate memory and save it in a list visible to the Go garbage
	collector. */

	void *
	alloc_saved (size_t n)
	{
	void *ret;
	G *g;
	CgoMal *c;

	ret = __go_alloc (n);

	g = runtime_g ();
	c = (CgoMal *) __go_alloc (sizeof (CgoMal));
	c->next = g->cgomal;
	c->alloc = ret;
	g->cgomal = c;

	return ret;
	}

	/* These are routines used by SWIG. The gc runtime library provides
	the same routines under the same name, though in that case the code
	is required to import runtime/cgo. */

	void *
	_cgo_allocate (size_t n)
	{
	void *ret;

	runtime_exitsyscall ();
	ret = alloc_saved (n);
	runtime_entersyscall ();
	return ret;
	}

	extern const struct __go_type_descriptor string_type_descriptor
	__asm__ (GOSYM_PREFIX "__go_tdn_string");

	void
	_cgo_panic (const char *p)
	{
	intgo len;
	unsigned char *data;
	String *ps;
	struct __go_empty_interface e;

	runtime_exitsyscall ();
	len = __builtin_strlen (p);
	data = alloc_saved (len);
	__builtin_memcpy (data, p, len);
	ps = alloc_saved (sizeof *ps);
	ps->str = data;
	ps->len = len;
	e.__type_descriptor = &string_type_descriptor;
	e.__object = ps;

	/* We don't call runtime_entersyscall here, because normally what
	will happen is that we will walk up the stack to a Go deferred
	function that calls recover. However, this will do the wrong
	thing if this panic is recovered and the stack unwinding is
	caught by a C++ exception handler. It might be possible to
	handle this by calling runtime_entersyscall in the personality
	function in go-unwind.c. FIXME. */

	__go_panic (e);
	}

	/* Used for _cgo_wait_runtime_init_done. This is based on code in
	runtime/cgo/gcc_libinit.c in the master library. */

	static pthread_cond_t runtime_init_cond = PTHREAD_COND_INITIALIZER;
	static pthread_mutex_t runtime_init_mu = PTHREAD_MUTEX_INITIALIZER;
	static _Bool runtime_init_done;

	/* This is called by exported cgo functions to ensure that the runtime
	has been initialized before we enter the function. This is needed
	when building with -buildmode=c-archive or similar. */

	void
	_cgo_wait_runtime_init_done (void)
	{
	int err;

	if (__atomic_load_n (&runtime_init_done, __ATOMIC_ACQUIRE))
	return;

	err = pthread_mutex_lock (&runtime_init_mu);
	if (err != 0)
	abort ();
	while (!__atomic_load_n (&runtime_init_done, __ATOMIC_ACQUIRE))
	{
	err = pthread_cond_wait (&runtime_init_cond, &runtime_init_mu);
	if (err != 0)
	abort ();
	}
	err = pthread_mutex_unlock (&runtime_init_mu);
	if (err != 0)
	abort ();
	}

	/* This is called by runtime_main after the Go runtime is
	initialized. */

	void
	_cgo_notify_runtime_init_done (void)
	{
	int err;

	err = pthread_mutex_lock (&runtime_init_mu);
	if (err != 0)
	abort ();
	__atomic_store_n (&runtime_init_done, 1, __ATOMIC_RELEASE);
	err = pthread_cond_broadcast (&runtime_init_cond);
	if (err != 0)
	abort ();
	err = pthread_mutex_unlock (&runtime_init_mu);
	if (err != 0)
	abort ();
	}

	// runtime_iscgo is set to true if some cgo code is linked in.
	// This is done by a constructor in the cgo generated code.
	_Bool runtime_iscgo;

	// runtime_cgoHasExtraM is set on startup when an extra M is created
	// for cgo. The extra M must be created before any C/C++ code calls
	// cgocallback.
	_Bool runtime_cgoHasExtraM;