/* Initialize the SPU multi-architecture support target. */
static void
init_spu_ops (void)
{
spu_ops.to_shortname = "spu";
spu_ops.to_longname = "SPU multi-architecture support.";
spu_ops.to_doc = "SPU multi-architecture support.";
spu_ops.to_mourn_inferior = spu_mourn_inferior;
spu_ops.to_fetch_registers = spu_fetch_registers;
spu_ops.to_store_registers = spu_store_registers;
spu_ops.to_xfer_partial = spu_xfer_partial;
spu_ops.to_search_memory = spu_search_memory;
spu_ops.to_region_ok_for_hw_watchpoint = spu_region_ok_for_hw_watchpoint;
spu_ops.to_thread_architecture = spu_thread_architecture;
spu_ops.to_stratum = arch_stratum;
spu_ops.to_magic = OPS_MAGIC;
}
extern void _initialize_spu_multiarch(void); /* -Wmissing-prototypes */
void
_initialize_spu_multiarch(void)
{
/* Install ourselves on the target stack. */
init_spu_ops ();
add_target (&spu_ops);
/* Install observers to watch for SPU objects. */
observer_attach_inferior_created (spu_multiarch_inferior_created);
observer_attach_solib_loaded (spu_multiarch_solib_loaded);
observer_attach_solib_unloaded (spu_multiarch_solib_unloaded);
}
static void *
mi_interpreter_init (int top_level)
{
struct mi_interp *mi = XMALLOC (struct mi_interp);
/* HACK: We need to force stdout/stderr to point at the console. This avoids
any potential side effects caused by legacy code that is still
using the TUI / fputs_unfiltered_hook. So we set up output channels for
this now, and swap them in when we are run. */
raw_stdout = stdio_fileopen (stdout);
/* Create MI channels */
mi->out = mi_console_file_new (raw_stdout, "~", '"');
mi->err = mi_console_file_new (raw_stdout, "&", '"');
mi->log = mi->err;
mi->targ = mi_console_file_new (raw_stdout, "@", '"');
mi->event_channel = mi_console_file_new (raw_stdout, "=", 0);
if (top_level)
{
observer_attach_new_thread (mi_new_thread);
observer_attach_thread_exit (mi_thread_exit);
observer_attach_inferior_added (mi_inferior_added);
observer_attach_inferior_appeared (mi_inferior_appeared);
observer_attach_inferior_exit (mi_inferior_exit);
observer_attach_inferior_removed (mi_inferior_removed);
observer_attach_normal_stop (mi_on_normal_stop);
observer_attach_target_resumed (mi_on_resume);
observer_attach_solib_loaded (mi_solib_loaded);
observer_attach_solib_unloaded (mi_solib_unloaded);
observer_attach_about_to_proceed (mi_about_to_proceed);
/* The initial inferior is created before this function is called, so we
need to report it explicitly. Use iteration in case future version
of GDB creates more than one inferior up-front. */
iterate_over_inferiors (report_initial_inferior, mi);
}
return mi;
}
static void *
mi_interpreter_init (struct interp *interp, int top_level)
{
struct mi_interp *mi = XNEW (struct mi_interp);
const char *name;
int mi_version;
/* Assign the output channel created at startup to its own global,
so that we can create a console channel that encapsulates and
prefixes all gdb_output-type bits coming from the rest of the
debugger. */
raw_stdout = gdb_stdout;
/* Create MI console channels, each with a different prefix so they
can be distinguished. */
mi->out = mi_console_file_new (raw_stdout, "~", '"');
mi->err = mi_console_file_new (raw_stdout, "&", '"');
mi->log = mi->err;
mi->targ = mi_console_file_new (raw_stdout, "@", '"');
mi->event_channel = mi_console_file_new (raw_stdout, "=", 0);
name = interp_name (interp);
/* INTERP_MI selects the most recent released version. "mi2" was
released as part of GDB 6.0. */
if (strcmp (name, INTERP_MI) == 0)
mi_version = 2;
else if (strcmp (name, INTERP_MI1) == 0)
mi_version = 1;
else if (strcmp (name, INTERP_MI2) == 0)
mi_version = 2;
else if (strcmp (name, INTERP_MI3) == 0)
mi_version = 3;
else
gdb_assert_not_reached ("unhandled MI version");
mi->mi_uiout = mi_out_new (mi_version);
mi->cli_uiout = cli_out_new (mi->out);
/* There are installed even if MI is not the top level interpreter.
The callbacks themselves decide whether to be skipped. */
observer_attach_signal_received (mi_on_signal_received);
observer_attach_end_stepping_range (mi_on_end_stepping_range);
observer_attach_signal_exited (mi_on_signal_exited);
observer_attach_exited (mi_on_exited);
observer_attach_no_history (mi_on_no_history);
if (top_level)
{
observer_attach_new_thread (mi_new_thread);
observer_attach_thread_exit (mi_thread_exit);
observer_attach_inferior_added (mi_inferior_added);
observer_attach_inferior_appeared (mi_inferior_appeared);
observer_attach_inferior_exit (mi_inferior_exit);
observer_attach_inferior_removed (mi_inferior_removed);
observer_attach_record_changed (mi_record_changed);
observer_attach_normal_stop (mi_on_normal_stop);
observer_attach_target_resumed (mi_on_resume);
observer_attach_solib_loaded (mi_solib_loaded);
observer_attach_solib_unloaded (mi_solib_unloaded);
observer_attach_about_to_proceed (mi_about_to_proceed);
observer_attach_traceframe_changed (mi_traceframe_changed);
observer_attach_tsv_created (mi_tsv_created);
observer_attach_tsv_deleted (mi_tsv_deleted);
observer_attach_tsv_modified (mi_tsv_modified);
observer_attach_breakpoint_created (mi_breakpoint_created);
observer_attach_breakpoint_deleted (mi_breakpoint_deleted);
observer_attach_breakpoint_modified (mi_breakpoint_modified);
observer_attach_command_param_changed (mi_command_param_changed);
observer_attach_memory_changed (mi_memory_changed);
observer_attach_sync_execution_done (mi_on_sync_execution_done);
/* The initial inferior is created before this function is
called, so we need to report it explicitly. Use iteration in
case future version of GDB creates more than one inferior
up-front. */
iterate_over_inferiors (report_initial_inferior, mi);
}
return mi;
}
