setcontext
setcontext is one of a family of C library functions (the others being getcontext, makecontext and swapcontext) used for context control. The setcontext
family allows the implementation in C of advanced control flow patterns such as iterators, fibers, and coroutines. They may be viewed as an advanced version of setjmp/longjmp; whereas the latter allows only a single non-local jump up the stack, setcontext
allows the creation of multiple cooperative threads of control, each with its own stack.
Specification
setcontext
is specified in POSIX.1-2001 and the Single Unix Specification, version 2, but not all Unix-like operating systems provide them. Citing portability concerns, POSIX.1-2004 obsoleted these functions, and in POSIX.1-2008 they were removed, and POSIX Threads recommended. The functions and associated types are defined in the ucontext.h
system header file. This includes the ucontext_t
type, with which all four functions operate:
typedef struct ucontext {
struct ucontext *uc_link;
sigset_t uc_sigmask;
stack_t uc_stack;
mcontext_t uc_mcontext;
...
} ucontext_t;
uc_link
points to the context which will be resumed when the current context exits, if the context was created with makecontext
(a secondary context). uc_sigmask
is used to store the set of signals blocked in the context, and uc_stack
is the stack used by the context. uc_mcontext
stores execution state, including all registers and CPU flags, the instruction pointer, and the stack pointer; mcontext_t
is an opaque type.
The functions are:
-
int setcontext(const ucontext_t *ucp)
- This function transfers control to the context in
ucp
. Execution continues from the point at which the context was stored inucp
.setcontext
does not return.
-
int getcontext(ucontext_t *ucp)
- Saves current context into
ucp
. This function returns in two possible cases: after the initial call, or when a thread switches to the context inucp
viasetcontext
orswapcontext
. Thegetcontext
function does not provide a return value to distinguish the cases (its return value is used solely to signal error), so the programmer must use an explicit flag variable, which must not be a register variable and must be declared volatile to avoid constant propagation or other compiler optimisations.
-
void makecontext(ucontext_t *ucp, void *func(), int argc, ...)
- The
makecontext
function sets up an alternate thread of control inucp
, which has previously been initialised usinggetcontext
. Theucp.uc_stack
member should be pointed to an appropriately sized stack; the constantSIGSTKSZ
is commonly used. Whenucp
is jumped to usingsetcontext
orswapcontext
, execution will begin at the entry point to the function pointed to byfunc
, withargc
arguments as specified. Whenfunc
terminates, control is returned toucp.uc_link
.
-
int swapcontext(ucontext_t *oucp, ucontext_t *ucp)
- Transfers control to
ucp
and saves the current execution state intooucp
.
Example
The example below demonstrates an iterator using setcontext
. This form of example is unlikely to be widely seen; as setcontext
is somewhat cumbersome to use effectively, programmers writing cooperatively multitasked applications often choose to use a wrapper library such as GNU Portable Threads. Most code using setcontext
appears in such wrapper libraries, in high-level programming language implementations, or in emulators.
#include <stdio.h>
#include <stdlib.h>
#include <ucontext.h>
/* The three contexts:
* (1) main_context1 : The point in main to which loop will return.
* (2) main_context2 : The point in main to which control from loop will
* flow by switching contexts.
* (3) loop_context : The point in loop to which control from main will
* flow by switching contexts. */
ucontext_t main_context1, main_context2, loop_context;
/* The iterator return value. */
volatile int i_from_iterator;
/* This is the iterator function. It is entered on the first call to
* swapcontext, and loops from 0 to 9. Each value is saved in i_from_iterator,
* and then swapcontext used to return to the main loop. The main loop prints
* the value and calls swapcontext to swap back into the function. When the end
* of the loop is reached, the function exits, and execution switches to the
* context pointed to by main_context1. */
void loop(
ucontext_t *loop_context,
ucontext_t *other_context,
int *i_from_iterator)
{
int i;
for (i=0; i < 10; ++i) {
/* Write the loop counter into the iterator return location. */
*i_from_iterator = i;
/* Save the loop context (this point in the code) into ''loop_context'',
* and switch to other_context. */
swapcontext(loop_context, other_context);
}
/* The function falls through to the calling context with an implicit
* ''setcontext(&loop_context->uc_link);'' */
}
int main(void)
{
/* The stack for the iterator function. */
char iterator_stack[SIGSTKSZ];
/* Flag indicating that the iterator has completed. */
volatile int iterator_finished;
getcontext(&loop_context);
/* Initialise the iterator context. uc_link points to main_context1, the
* point to return to when the iterator finishes. */
loop_context.uc_link = &main_context1;
loop_context.uc_stack.ss_sp = iterator_stack;
loop_context.uc_stack.ss_size = sizeof(iterator_stack);
/* Fill in loop_context so that it makes swapcontext start loop. The
* (void (*)(void)) typecast is to avoid a compiler warning but it is
* not relevant to the behaviour of the function. */
makecontext(&loop_context, (void (*)(void)) loop,
3, &loop_context, &main_context2, &i_from_iterator);
/* Clear the finished flag. */
iterator_finished = 0;
/* Save the current context into main_context1. When loop is finished,
* control flow will return to this point. */
getcontext(&main_context1);
if (!iterator_finished) {
/* Set iterator_finished so that when the previous getcontext is
* returned to via uc_link, the above if condition is false and the
* iterator is not restarted. */
iterator_finished = 1;
while (1) {
/* Save this point into main_context2 and switch into the iterator.
* The first call will begin loop. Subsequent calls will switch to
* the swapcontext in loop. */
swapcontext(&main_context2, &loop_context);
printf("%d\n", i_from_iterator);
}
}
return 0;
}
NOTE: this example is not consistent with the manual page or the specification.[1] The function makecontext
requires additional parameters to be type int
, but the example passes pointers. Thus, the example may fail on 64-bit machines (specifically LP64-architectures, where sizeof(void*) > sizeof(int)
). This problem can be worked around by breaking up and reconstructing 64-bit values, but that introduces a performance penalty.
"On architectures where int and pointer types are the same size (e.g., x86-32, where both types are 32 bits), you may be able to get away with passing pointers as arguments to makecontext() following argc. However, doing this is not guaranteed to be portable, is undefined according to the standards, and won't work on architectures where pointers are larger than ints. Nevertheless, starting with version 2.8, glibc makes some changes to makecontext(3), to permit this on some 64-bit architectures (e.g., x86-64)."
For get and set context, a smaller context can be handy:
#include <stdio.h>
#include <ucontext.h>
#include <unistd.h>
int main(int argc, const char *argv[]){
ucontext_t context;
getcontext(&context);
puts("Hello world");
sleep(1);
setcontext(&context);
return 0;
}
This makes an infinite loop because context holds the program counter.
References
- ↑ The Open Group Base Specifications Issue 6 IEEE Std 1003.1, 2004 Edition
External links
- System V Contexts - The GNU C Library Manual
- : get/set current user context – Linux Programmer's Manual – Library Functions
- setcontext - get/set current user context FreeBSD man page.