| @node Non-Local Exits, Signal Handling, Resource Usage And Limitation, Top |
| @c %MENU% Jumping out of nested function calls |
| @chapter Non-Local Exits |
| @cindex non-local exits |
| @cindex long jumps |
| |
| Sometimes when your program detects an unusual situation inside a deeply |
| nested set of function calls, you would like to be able to immediately |
| return to an outer level of control. This section describes how you can |
| do such @dfn{non-local exits} using the @code{setjmp} and @code{longjmp} |
| functions. |
| |
| @menu |
| * Intro: Non-Local Intro. When and how to use these facilities. |
| * Details: Non-Local Details. Functions for non-local exits. |
| * Non-Local Exits and Signals:: Portability issues. |
| * System V contexts:: Complete context control a la System V. |
| @end menu |
| |
| @node Non-Local Intro, Non-Local Details, , Non-Local Exits |
| @section Introduction to Non-Local Exits |
| |
| As an example of a situation where a non-local exit can be useful, |
| suppose you have an interactive program that has a ``main loop'' that |
| prompts for and executes commands. Suppose the ``read'' command reads |
| input from a file, doing some lexical analysis and parsing of the input |
| while processing it. If a low-level input error is detected, it would |
| be useful to be able to return immediately to the ``main loop'' instead |
| of having to make each of the lexical analysis, parsing, and processing |
| phases all have to explicitly deal with error situations initially |
| detected by nested calls. |
| |
| (On the other hand, if each of these phases has to do a substantial |
| amount of cleanup when it exits---such as closing files, deallocating |
| buffers or other data structures, and the like---then it can be more |
| appropriate to do a normal return and have each phase do its own |
| cleanup, because a non-local exit would bypass the intervening phases and |
| their associated cleanup code entirely. Alternatively, you could use a |
| non-local exit but do the cleanup explicitly either before or after |
| returning to the ``main loop''.) |
| |
| In some ways, a non-local exit is similar to using the @samp{return} |
| statement to return from a function. But while @samp{return} abandons |
| only a single function call, transferring control back to the point at |
| which it was called, a non-local exit can potentially abandon many |
| levels of nested function calls. |
| |
| You identify return points for non-local exits by calling the function |
| @code{setjmp}. This function saves information about the execution |
| environment in which the call to @code{setjmp} appears in an object of |
| type @code{jmp_buf}. Execution of the program continues normally after |
| the call to @code{setjmp}, but if an exit is later made to this return |
| point by calling @code{longjmp} with the corresponding @w{@code{jmp_buf}} |
| object, control is transferred back to the point where @code{setjmp} was |
| called. The return value from @code{setjmp} is used to distinguish |
| between an ordinary return and a return made by a call to |
| @code{longjmp}, so calls to @code{setjmp} usually appear in an @samp{if} |
| statement. |
| |
| Here is how the example program described above might be set up: |
| |
| @smallexample |
| @include setjmp.c.texi |
| @end smallexample |
| |
| The function @code{abort_to_main_loop} causes an immediate transfer of |
| control back to the main loop of the program, no matter where it is |
| called from. |
| |
| The flow of control inside the @code{main} function may appear a little |
| mysterious at first, but it is actually a common idiom with |
| @code{setjmp}. A normal call to @code{setjmp} returns zero, so the |
| ``else'' clause of the conditional is executed. If |
| @code{abort_to_main_loop} is called somewhere within the execution of |
| @code{do_command}, then it actually appears as if the @emph{same} call |
| to @code{setjmp} in @code{main} were returning a second time with a value |
| of @code{-1}. |
| |
| @need 250 |
| So, the general pattern for using @code{setjmp} looks something like: |
| |
| @smallexample |
| if (setjmp (@var{buffer})) |
| /* @r{Code to clean up after premature return.} */ |
| @dots{} |
| else |
| /* @r{Code to be executed normally after setting up the return point.} */ |
| @dots{} |
| @end smallexample |
| |
| @node Non-Local Details, Non-Local Exits and Signals, Non-Local Intro, Non-Local Exits |
| @section Details of Non-Local Exits |
| |
| Here are the details on the functions and data structures used for |
| performing non-local exits. These facilities are declared in |
| @file{setjmp.h}. |
| @pindex setjmp.h |
| |
| @deftp {Data Type} jmp_buf |
| @standards{ISO, setjmp.h} |
| Objects of type @code{jmp_buf} hold the state information to |
| be restored by a non-local exit. The contents of a @code{jmp_buf} |
| identify a specific place to return to. |
| @end deftp |
| |
| @deftypefn Macro int setjmp (jmp_buf @var{state}) |
| @standards{ISO, setjmp.h} |
| @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}} |
| @c _setjmp ok |
| @c __sigsetjmp(!savemask) ok |
| @c __sigjmp_save(!savemask) ok, does not call sigprocmask |
| When called normally, @code{setjmp} stores information about the |
| execution state of the program in @var{state} and returns zero. If |
| @code{longjmp} is later used to perform a non-local exit to this |
| @var{state}, @code{setjmp} returns a nonzero value. |
| @end deftypefn |
| |
| @deftypefun void longjmp (jmp_buf @var{state}, int @var{value}) |
| @standards{ISO, setjmp.h} |
| @safety{@prelim{}@mtsafe{}@asunsafe{@ascuplugin{} @asucorrupt{} @asulock{/hurd}}@acunsafe{@acucorrupt{} @aculock{/hurd}}} |
| @c __libc_siglongjmp @ascuplugin @asucorrupt @asulock/hurd @acucorrupt @aculock/hurd |
| @c _longjmp_unwind @ascuplugin @asucorrupt @acucorrupt |
| @c __pthread_cleanup_upto @ascuplugin @asucorrupt @acucorrupt |
| @c plugins may be unsafe themselves, but even if they weren't, this |
| @c function isn't robust WRT async signals and cancellation: |
| @c cleanups aren't taken off the stack right away, only after all |
| @c cleanups have been run. This means that async-cancelling |
| @c longjmp, or interrupting longjmp with an async signal handler |
| @c that calls longjmp may run the same cleanups multiple times. |
| @c _JMPBUF_UNWINDS_ADJ ok |
| @c *cleanup_buf->__routine @ascuplugin |
| @c sigprocmask(SIG_SETMASK) dup @asulock/hurd @aculock/hurd |
| @c __longjmp ok |
| This function restores current execution to the state saved in |
| @var{state}, and continues execution from the call to @code{setjmp} that |
| established that return point. Returning from @code{setjmp} by means of |
| @code{longjmp} returns the @var{value} argument that was passed to |
| @code{longjmp}, rather than @code{0}. (But if @var{value} is given as |
| @code{0}, @code{setjmp} returns @code{1}).@refill |
| @end deftypefun |
| |
| There are a lot of obscure but important restrictions on the use of |
| @code{setjmp} and @code{longjmp}. Most of these restrictions are |
| present because non-local exits require a fair amount of magic on the |
| part of the C compiler and can interact with other parts of the language |
| in strange ways. |
| |
| The @code{setjmp} function is actually a macro without an actual |
| function definition, so you shouldn't try to @samp{#undef} it or take |
| its address. In addition, calls to @code{setjmp} are safe in only the |
| following contexts: |
| |
| @itemize @bullet |
| @item |
| As the test expression of a selection or iteration |
| statement (such as @samp{if}, @samp{switch}, or @samp{while}). |
| |
| @item |
| As one operand of an equality or comparison operator that appears as the |
| test expression of a selection or iteration statement. The other |
| operand must be an integer constant expression. |
| |
| @item |
| As the operand of a unary @samp{!} operator, that appears as the |
| test expression of a selection or iteration statement. |
| |
| @item |
| By itself as an expression statement. |
| @end itemize |
| |
| Return points are valid only during the dynamic extent of the function |
| that called @code{setjmp} to establish them. If you @code{longjmp} to |
| a return point that was established in a function that has already |
| returned, unpredictable and disastrous things are likely to happen. |
| |
| You should use a nonzero @var{value} argument to @code{longjmp}. While |
| @code{longjmp} refuses to pass back a zero argument as the return value |
| from @code{setjmp}, this is intended as a safety net against accidental |
| misuse and is not really good programming style. |
| |
| When you perform a non-local exit, accessible objects generally retain |
| whatever values they had at the time @code{longjmp} was called. The |
| exception is that the values of automatic variables local to the |
| function containing the @code{setjmp} call that have been changed since |
| the call to @code{setjmp} are indeterminate, unless you have declared |
| them @code{volatile}. |
| |
| @node Non-Local Exits and Signals, System V contexts, Non-Local Details, Non-Local Exits |
| @section Non-Local Exits and Signals |
| |
| In BSD Unix systems, @code{setjmp} and @code{longjmp} also save and |
| restore the set of blocked signals; see @ref{Blocking Signals}. However, |
| the POSIX.1 standard requires @code{setjmp} and @code{longjmp} not to |
| change the set of blocked signals, and provides an additional pair of |
| functions (@code{sigsetjmp} and @code{siglongjmp}) to get the BSD |
| behavior. |
| |
| The behavior of @code{setjmp} and @code{longjmp} in @theglibc{} is |
| controlled by feature test macros; see @ref{Feature Test Macros}. The |
| default in @theglibc{} is the POSIX.1 behavior rather than the BSD |
| behavior. |
| |
| The facilities in this section are declared in the header file |
| @file{setjmp.h}. |
| @pindex setjmp.h |
| |
| @deftp {Data Type} sigjmp_buf |
| @standards{POSIX.1, setjmp.h} |
| This is similar to @code{jmp_buf}, except that it can also store state |
| information about the set of blocked signals. |
| @end deftp |
| |
| @deftypefun int sigsetjmp (sigjmp_buf @var{state}, int @var{savesigs}) |
| @standards{POSIX.1, setjmp.h} |
| @safety{@prelim{}@mtsafe{}@asunsafe{@asulock{/hurd}}@acunsafe{@aculock{/hurd}}} |
| @c sigsetjmp @asulock/hurd @aculock/hurd |
| @c __sigsetjmp(savemask) @asulock/hurd @aculock/hurd |
| @c __sigjmp_save(savemask) @asulock/hurd @aculock/hurd |
| @c sigprocmask(SIG_BLOCK probe) dup @asulock/hurd @aculock/hurd |
| This is similar to @code{setjmp}. If @var{savesigs} is nonzero, the set |
| of blocked signals is saved in @var{state} and will be restored if a |
| @code{siglongjmp} is later performed with this @var{state}. |
| @end deftypefun |
| |
| @deftypefun void siglongjmp (sigjmp_buf @var{state}, int @var{value}) |
| @standards{POSIX.1, setjmp.h} |
| @safety{@prelim{}@mtsafe{}@asunsafe{@ascuplugin{} @asucorrupt{} @asulock{/hurd}}@acunsafe{@acucorrupt{} @aculock{/hurd}}} |
| @c Alias to longjmp. |
| This is similar to @code{longjmp} except for the type of its @var{state} |
| argument. If the @code{sigsetjmp} call that set this @var{state} used a |
| nonzero @var{savesigs} flag, @code{siglongjmp} also restores the set of |
| blocked signals. |
| @end deftypefun |
| |
| @node System V contexts,, Non-Local Exits and Signals, Non-Local Exits |
| @section Complete Context Control |
| |
| The Unix standard provides one more set of functions to control the |
| execution path and these functions are more powerful than those |
| discussed in this chapter so far. These functions were part of the |
| original @w{System V} API and by this route were added to the Unix |
| API. Besides on branded Unix implementations these interfaces are not |
| widely available. Not all platforms and/or architectures @theglibc{} |
| is available on provide this interface. Use @file{configure} to |
| detect the availability. |
| |
| Similar to the @code{jmp_buf} and @code{sigjmp_buf} types used for the |
| variables to contain the state of the @code{longjmp} functions the |
| interfaces of interest here have an appropriate type as well. Objects |
| of this type are normally much larger since more information is |
| contained. The type is also used in a few more places as we will see. |
| The types and functions described in this section are all defined and |
| declared respectively in the @file{ucontext.h} header file. |
| |
| @deftp {Data Type} ucontext_t |
| @standards{SVID, ucontext.h} |
| |
| The @code{ucontext_t} type is defined as a structure with at least the |
| following elements: |
| |
| @table @code |
| @item ucontext_t *uc_link |
| This is a pointer to the next context structure which is used if the |
| context described in the current structure returns. |
| |
| @item sigset_t uc_sigmask |
| Set of signals which are blocked when this context is used. |
| |
| @item stack_t uc_stack |
| Stack used for this context. The value need not be (and normally is |
| not) the stack pointer. @xref{Signal Stack}. |
| |
| @item mcontext_t uc_mcontext |
| This element contains the actual state of the process. The |
| @code{mcontext_t} type is also defined in this header but the definition |
| should be treated as opaque. Any use of knowledge of the type makes |
| applications less portable. |
| |
| @end table |
| @end deftp |
| |
| Objects of this type have to be created by the user. The initialization |
| and modification happens through one of the following functions: |
| |
| @deftypefun int getcontext (ucontext_t *@var{ucp}) |
| @standards{SVID, ucontext.h} |
| @safety{@prelim{}@mtsafe{@mtsrace{:ucp}}@assafe{}@acsafe{}} |
| @c Linux-only implementations in assembly, including sigprocmask |
| @c syscall. A few cases call the sigprocmask function, but that's safe |
| @c too. The ppc case is implemented in terms of a swapcontext syscall. |
| The @code{getcontext} function initializes the variable pointed to by |
| @var{ucp} with the context of the calling thread. The context contains |
| the content of the registers, the signal mask, and the current stack. |
| Executing the contents would start at the point where the |
| @code{getcontext} call just returned. |
| |
| @strong{Compatibility Note:} Depending on the operating system, |
| information about the current context's stack may be in the |
| @code{uc_stack} field of @var{ucp}, or it may instead be in |
| architecture-specific subfields of the @code{uc_mcontext} field. |
| |
| The function returns @code{0} if successful. Otherwise it returns |
| @code{-1} and sets @var{errno} accordingly. |
| @end deftypefun |
| |
| The @code{getcontext} function is similar to @code{setjmp} but it does |
| not provide an indication of whether @code{getcontext} is returning for |
| the first time or whether an initialized context has just been restored. |
| If this is necessary the user has to determine this herself. This must |
| be done carefully since the context contains registers which might contain |
| register variables. This is a good situation to define variables with |
| @code{volatile}. |
| |
| Once the context variable is initialized it can be used as is or it can |
| be modified using the @code{makecontext} function. The latter is normally |
| done when implementing co-routines or similar constructs. |
| |
| @deftypefun void makecontext (ucontext_t *@var{ucp}, void (*@var{func}) (void), int @var{argc}, @dots{}) |
| @standards{SVID, ucontext.h} |
| @safety{@prelim{}@mtsafe{@mtsrace{:ucp}}@assafe{}@acsafe{}} |
| @c Linux-only implementations mostly in assembly, nothing unsafe. |
| |
| The @var{ucp} parameter passed to @code{makecontext} shall be |
| initialized by a call to @code{getcontext}. The context will be |
| modified in a way such that if the context is resumed it will start by |
| calling the function @code{func} which gets @var{argc} integer arguments |
| passed. The integer arguments which are to be passed should follow the |
| @var{argc} parameter in the call to @code{makecontext}. |
| |
| Before the call to this function the @code{uc_stack} and @code{uc_link} |
| element of the @var{ucp} structure should be initialized. The |
| @code{uc_stack} element describes the stack which is used for this |
| context. No two contexts which are used at the same time should use the |
| same memory region for a stack. |
| |
| The @code{uc_link} element of the object pointed to by @var{ucp} should |
| be a pointer to the context to be executed when the function @var{func} |
| returns or it should be a null pointer. See @code{setcontext} for more |
| information about the exact use. |
| @end deftypefun |
| |
| While allocating the memory for the stack one has to be careful. Most |
| modern processors keep track of whether a certain memory region is |
| allowed to contain code which is executed or not. Data segments and |
| heap memory are normally not tagged to allow this. The result is that |
| programs would fail. Examples for such code include the calling |
| sequences the GNU C compiler generates for calls to nested functions. |
| Safe ways to allocate stacks correctly include using memory on the |
| original thread's stack or explicitly allocating memory tagged for |
| execution using (@pxref{Memory-mapped I/O}). |
| |
| @strong{Compatibility note}: The current Unix standard is very imprecise |
| about the way the stack is allocated. All implementations seem to agree |
| that the @code{uc_stack} element must be used but the values stored in |
| the elements of the @code{stack_t} value are unclear. @Theglibc{} |
| and most other Unix implementations require the @code{ss_sp} value of |
| the @code{uc_stack} element to point to the base of the memory region |
| allocated for the stack and the size of the memory region is stored in |
| @code{ss_size}. There are implementations out there which require |
| @code{ss_sp} to be set to the value the stack pointer will have (which |
| can, depending on the direction the stack grows, be different). This |
| difference makes the @code{makecontext} function hard to use and it |
| requires detection of the platform at compile time. |
| |
| @deftypefun int setcontext (const ucontext_t *@var{ucp}) |
| @standards{SVID, ucontext.h} |
| @safety{@prelim{}@mtsafe{@mtsrace{:ucp}}@asunsafe{@asucorrupt{}}@acunsafe{@acucorrupt{}}} |
| @c Linux-only implementations mostly in assembly. Some ports use |
| @c sigreturn or swapcontext syscalls; others restore the signal mask |
| @c first and then proceed restore other registers in userland, which |
| @c leaves a window for cancellation or async signals with misaligned or |
| @c otherwise corrupt stack. ??? Switching to a different stack, or even |
| @c to an earlier state on the same stack, may conflict with pthread |
| @c cleanups. This is not quite MT-Unsafe, it's a different kind of |
| @c safety issue. |
| |
| The @code{setcontext} function restores the context described by |
| @var{ucp}. The context is not modified and can be reused as often as |
| wanted. |
| |
| If the context was created by @code{getcontext} execution resumes with |
| the registers filled with the same values and the same stack as if the |
| @code{getcontext} call just returned. |
| |
| If the context was modified with a call to @code{makecontext} execution |
| continues with the function passed to @code{makecontext} which gets the |
| specified parameters passed. If this function returns execution is |
| resumed in the context which was referenced by the @code{uc_link} |
| element of the context structure passed to @code{makecontext} at the |
| time of the call. If @code{uc_link} was a null pointer the application |
| terminates normally with an exit status value of @code{EXIT_SUCCESS} |
| (@pxref{Program Termination}). |
| |
| If the context was created by a call to a signal handler or from any |
| other source then the behaviour of @code{setcontext} is unspecified. |
| |
| Since the context contains information about the stack no two threads |
| should use the same context at the same time. The result in most cases |
| would be disastrous. |
| |
| The @code{setcontext} function does not return unless an error occurred |
| in which case it returns @code{-1}. |
| @end deftypefun |
| |
| The @code{setcontext} function simply replaces the current context with |
| the one described by the @var{ucp} parameter. This is often useful but |
| there are situations where the current context has to be preserved. |
| |
| @deftypefun int swapcontext (ucontext_t *restrict @var{oucp}, const ucontext_t *restrict @var{ucp}) |
| @standards{SVID, ucontext.h} |
| @safety{@prelim{}@mtsafe{@mtsrace{:oucp} @mtsrace{:ucp}}@asunsafe{@asucorrupt{}}@acunsafe{@acucorrupt{}}} |
| @c Linux-only implementations mostly in assembly. Some ports call or |
| @c inline getcontext and/or setcontext, adjusting the saved context in |
| @c between, so we inherit the potential issues of both. |
| |
| The @code{swapcontext} function is similar to @code{setcontext} but |
| instead of just replacing the current context the latter is first saved |
| in the object pointed to by @var{oucp} as if this was a call to |
| @code{getcontext}. The saved context would resume after the call to |
| @code{swapcontext}. |
| |
| Once the current context is saved the context described in @var{ucp} is |
| installed and execution continues as described in this context. |
| |
| If @code{swapcontext} succeeds the function does not return unless the |
| context @var{oucp} is used without prior modification by |
| @code{makecontext}. The return value in this case is @code{0}. If the |
| function fails it returns @code{-1} and sets @var{errno} accordingly. |
| @end deftypefun |
| |
| @heading Example for SVID Context Handling |
| |
| The easiest way to use the context handling functions is as a |
| replacement for @code{setjmp} and @code{longjmp}. The context contains |
| on most platforms more information which may lead to fewer surprises |
| but this also means using these functions is more expensive (besides |
| being less portable). |
| |
| @smallexample |
| int |
| random_search (int n, int (*fp) (int, ucontext_t *)) |
| @{ |
| volatile int cnt = 0; |
| ucontext_t uc; |
| |
| /* @r{Safe current context.} */ |
| if (getcontext (&uc) < 0) |
| return -1; |
| |
| /* @r{If we have not tried @var{n} times try again.} */ |
| if (cnt++ < n) |
| /* @r{Call the function with a new random number} |
| @r{and the context}. */ |
| if (fp (rand (), &uc) != 0) |
| /* @r{We found what we were looking for.} */ |
| return 1; |
| |
| /* @r{Not found.} */ |
| return 0; |
| @} |
| @end smallexample |
| |
| Using contexts in such a way enables emulating exception handling. The |
| search functions passed in the @var{fp} parameter could be very large, |
| nested, and complex which would make it complicated (or at least would |
| require a lot of code) to leave the function with an error value which |
| has to be passed down to the caller. By using the context it is |
| possible to leave the search function in one step and allow restarting |
| the search which also has the nice side effect that it can be |
| significantly faster. |
| |
| Something which is harder to implement with @code{setjmp} and |
| @code{longjmp} is to switch temporarily to a different execution path |
| and then resume where execution was stopped. |
| |
| @smallexample |
| @include swapcontext.c.texi |
| @end smallexample |
| |
| This an example how the context functions can be used to implement |
| co-routines or cooperative multi-threading. All that has to be done is |
| to call every once in a while @code{swapcontext} to continue running a |
| different context. It is not recommended to do the context switching from |
| the signal handler directly since leaving the signal handler via |
| @code{setcontext} if the signal was delivered during code that was not |
| asynchronous signal safe could lead to problems. Setting a variable in |
| the signal handler and checking it in the body of the functions which |
| are executed is a safer approach. Since @code{swapcontext} is saving the |
| current context it is possible to have multiple different scheduling points |
| in the code. Execution will always resume where it was left. |