/* Copyright 1995-1998,2000-2001,2004,2006,2010,2012-2016,2018-2019
Free Software Foundation, Inc.
This file is part of Guile.
Guile is free software: you can redistribute it and/or modify it
under the terms of the GNU Lesser General Public License as published
by the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Guile is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
License for more details.
You should have received a copy of the GNU Lesser General Public
License along with Guile. If not, see
. */
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#ifdef HAVE_CONFIG_H
# include
#endif
#include
#include
#include
#include
#include
/* For Windows... */
#ifdef HAVE_IO_H
#include
#endif
#include "async.h"
#include "dynwind.h"
#include "gsubr.h"
#include "list.h"
#include "modules.h"
#include "numbers.h"
#include "pairs.h"
#include "strings.h"
#include "symbols.h"
#include "throw.h"
#include "error.h"
�
/* {Errors and Exceptional Conditions}
*/
/* Scheme interface to scm_error_scm. */
void
scm_error (SCM key, const char *subr, const char *message, SCM args, SCM rest)
{
scm_error_scm
(key,
(subr == NULL) ? SCM_BOOL_F : scm_from_utf8_string (subr),
(message == NULL) ? SCM_BOOL_F : scm_from_utf8_string (message),
args, rest);
}
/* All errors should pass through here. */
SCM_DEFINE (scm_error_scm, "scm-error", 5, 0, 0,
(SCM key, SCM subr, SCM message, SCM args, SCM data),
"Raise an error with key @var{key}. @var{subr} can be a string\n"
"naming the procedure associated with the error, or @code{#f}.\n"
"@var{message} is the error message string, possibly containing\n"
"@code{~S} and @code{~A} escapes. When an error is reported,\n"
"these are replaced by formatting the corresponding members of\n"
"@var{args}: @code{~A} (was @code{%s} in older versions of\n"
"Guile) formats using @code{display} and @code{~S} (was\n"
"@code{%S}) formats using @code{write}. @var{data} is a list or\n"
"@code{#f} depending on @var{key}: if @var{key} is\n"
"@code{system-error} then it should be a list containing the\n"
"Unix @code{errno} value; If @var{key} is @code{signal} then it\n"
"should be a list containing the Unix signal number; If\n"
"@var{key} is @code{out-of-range}, @code{wrong-type-arg},\n"
"or @code{keyword-argument-error}, "
"it is a list containing the bad value; otherwise\n"
"it will usually be @code{#f}.")
#define FUNC_NAME s_scm_error_scm
{
scm_ithrow (key, scm_list_4 (subr, message, args, data), 1);
/* No return, but just in case: */
fprintf (stderr, "Guile scm_ithrow returned!\n");
exit (EXIT_FAILURE);
}
#undef FUNC_NAME
/* strerror may not be thread safe, for instance in glibc (version 2.3.2) an
error number not among the known values results in a string like "Unknown
error 9999" formed in a static buffer, which will be overwritten by a
similar call in another thread. A test program running two threads with
different unknown error numbers can trip this fairly quickly.
Some systems don't do what glibc does, instead just giving a single
"Unknown error" for unrecognised numbers. It doesn't seem worth trying
to tell if that's the case, a mutex is reasonably fast, and strerror
isn't needed very often.
strerror_r (when available) could be used, it might be a touch faster
than a frame and a mutex, though there's probably not much
difference. */
SCM_DEFINE (scm_strerror, "strerror", 1, 0, 0,
(SCM err),
"Return the Unix error message corresponding to @var{err}, which\n"
"must be an integer value.")
#define FUNC_NAME s_scm_strerror
{
SCM ret;
int errnum = scm_to_int (err); /* Must be done outside of the
critical section below, to avoid a
deadlock on errors. */
scm_dynwind_begin (0);
scm_i_dynwind_pthread_mutex_lock (&scm_i_misc_mutex);
ret = scm_from_locale_string (strerror (errnum));
scm_dynwind_end ();
return ret;
}
#undef FUNC_NAME
SCM_GLOBAL_SYMBOL (scm_system_error_key, "system-error");
void
scm_syserror (const char *subr)
{
SCM err = scm_from_int (errno);
/* It could be that we're getting here because the syscall was
interrupted by a signal. In that case a signal handler might have
been queued to run. The signal handler probably throws an
exception.
If we don't try to run the signal handler now, it will run later,
which would result in two exceptions being thrown: this syserror,
and then at some later time the exception thrown by the async
signal handler.
The problem is that we don't know if handling the signal caused an
async to be queued. By this time scmsigs.c:take_signal will have
written a byte on the fd, but we don't know if the signal-handling
thread has read it off and queued an async.
Ideally we need some API like scm_i_ensure_signals_delivered() to
catch up signal delivery. Barring that, we just cross our digits
and pray; it could be that we handle the signal in time, and just
throw once, or it could be that we miss the deadline and throw
twice.
*/
#ifdef EINTR
if (scm_to_int (err) == EINTR)
scm_async_tick ();
#endif
scm_error (scm_system_error_key,
subr,
"~A",
scm_cons (scm_strerror (err), SCM_EOL),
scm_cons (err, SCM_EOL));
}
void
scm_syserror_msg (const char *subr, const char *message, SCM args, int eno)
{
/* See above note about the EINTR signal handling race. */
#ifdef EINTR
if (eno == EINTR)
scm_async_tick ();
#endif
scm_error (scm_system_error_key,
subr,
message,
args,
scm_cons (scm_from_int (eno), SCM_EOL));
}
SCM_GLOBAL_SYMBOL (scm_num_overflow_key, "numerical-overflow");
void
scm_num_overflow (const char *subr)
{
scm_error (scm_num_overflow_key,
subr,
"Numerical overflow",
SCM_BOOL_F,
SCM_BOOL_F);
}
SCM_GLOBAL_SYMBOL (scm_out_of_range_key, "out-of-range");
void
scm_out_of_range (const char *subr, SCM bad_value)
{
scm_error (scm_out_of_range_key,
subr,
"Value out of range: ~S",
scm_list_1 (bad_value),
scm_list_1 (bad_value));
}
void
scm_out_of_range_pos (const char *subr, SCM bad_value, SCM pos)
{
scm_error (scm_out_of_range_key,
subr,
"Argument ~A out of range: ~S",
scm_list_2 (pos, bad_value),
scm_list_1 (bad_value));
}
SCM_GLOBAL_SYMBOL (scm_args_number_key, "wrong-number-of-args");
void
scm_wrong_num_args (SCM proc)
{
scm_error (scm_args_number_key,
NULL,
"Wrong number of arguments to ~A",
scm_list_1 (proc),
SCM_BOOL_F);
}
void
scm_error_num_args_subr (const char *subr)
{
scm_error (scm_args_number_key,
NULL,
"Wrong number of arguments to ~A",
scm_list_1 (scm_from_utf8_string (subr)),
SCM_BOOL_F);
}
SCM_GLOBAL_SYMBOL (scm_arg_type_key, "wrong-type-arg");
void
scm_wrong_type_arg (const char *subr, int pos, SCM bad_value)
{
scm_error (scm_arg_type_key,
subr,
(pos == 0) ? "Wrong type: ~S"
: "Wrong type argument in position ~A: ~S",
(pos == 0) ? scm_list_1 (bad_value)
: scm_list_2 (scm_from_int (pos), bad_value),
scm_list_1 (bad_value));
}
void
scm_i_wrong_type_arg_symbol (SCM symbol, int pos, SCM bad_value)
{
scm_error_scm (scm_arg_type_key,
scm_symbol_to_string (symbol),
(pos == 0) ? scm_from_utf8_string ("Wrong type: ~S")
: scm_from_utf8_string ("Wrong type argument in position ~A: ~S"),
(pos == 0) ? scm_list_1 (bad_value)
: scm_list_2 (scm_from_int (pos), bad_value),
scm_list_1 (bad_value));
scm_remember_upto_here_2 (symbol, bad_value);
}
void
scm_wrong_type_arg_msg (const char *subr, int pos, SCM bad_value, const char *szMessage)
{
SCM msg = scm_from_utf8_string (szMessage);
if (pos == 0)
{
scm_error (scm_arg_type_key,
subr, "Wrong type (expecting ~A): ~S",
scm_list_2 (msg, bad_value),
scm_list_1 (bad_value));
}
else
{
scm_error (scm_arg_type_key,
subr,
"Wrong type argument in position ~A (expecting ~A): ~S",
scm_list_3 (scm_from_int (pos), msg, bad_value),
scm_list_1 (bad_value));
}
}
SCM_GLOBAL_SYMBOL (scm_misc_error_key, "misc-error");
void
scm_misc_error (const char *subr, const char *message, SCM args)
{
scm_error (scm_misc_error_key, subr, message, args, SCM_BOOL_F);
}
void
scm_init_error ()
{
#include "cpp-E.c"
#include "error.x"
}