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|
/* MI Command Set.
Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005 Free Software
Foundation, Inc.
Contributed by Cygnus Solutions (a Red Hat company).
This file is part of GDB.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program 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 General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301, USA. */
/* Work in progress */
#include "defs.h"
#include "target.h"
#include "inferior.h"
#include "gdb_string.h"
#include "exceptions.h"
#include "top.h"
#include "gdbthread.h"
#include "mi-cmds.h"
#include "mi-parse.h"
#include "mi-getopt.h"
#include "mi-console.h"
#include "ui-out.h"
#include "mi-out.h"
#include "interps.h"
#include "event-loop.h"
#include "event-top.h"
#include "gdbcore.h" /* for write_memory() */
#include "value.h" /* for deprecated_write_register_bytes() */
#include "regcache.h"
#include "gdb.h"
#include "frame.h"
#include "mi-main.h"
#include <ctype.h>
#include <sys/time.h>
enum
{
FROM_TTY = 0
};
/* Enumerations of the actions that may result from calling
captured_mi_execute_command */
enum captured_mi_execute_command_actions
{
EXECUTE_COMMAND_DISPLAY_PROMPT,
EXECUTE_COMMAND_SUPRESS_PROMPT
};
/* This structure is used to pass information from captured_mi_execute_command
to mi_execute_command. */
struct captured_mi_execute_command_args
{
/* This return result of the MI command (output) */
enum mi_cmd_result rc;
/* What action to perform when the call is finished (output) */
enum captured_mi_execute_command_actions action;
/* The command context to be executed (input) */
struct mi_parse *command;
};
int mi_debug_p;
struct ui_file *raw_stdout;
/* The token of the last asynchronous command */
static char *last_async_command;
static char *previous_async_command;
char *mi_error_message;
static char *old_regs;
extern void _initialize_mi_main (void);
static enum mi_cmd_result mi_cmd_execute (struct mi_parse *parse);
static void mi_execute_cli_command (const char *cmd, int args_p,
const char *args);
static enum mi_cmd_result mi_execute_async_cli_command (char *mi, char *args, int from_tty);
static void mi_exec_async_cli_cmd_continuation (struct continuation_arg *arg);
static int register_changed_p (int regnum);
static int get_register (int regnum, int format);
/* Command implementations. FIXME: Is this libgdb? No. This is the MI
layer that calls libgdb. Any operation used in the below should be
formalized. */
enum mi_cmd_result
mi_cmd_gdb_exit (char *command, char **argv, int argc)
{
/* We have to print everything right here because we never return */
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("^exit\n", raw_stdout);
mi_out_put (uiout, raw_stdout);
/* FIXME: The function called is not yet a formal libgdb function */
quit_force (NULL, FROM_TTY);
return MI_CMD_DONE;
}
enum mi_cmd_result
mi_cmd_exec_run (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("run", args, from_tty);
}
enum mi_cmd_result
mi_cmd_exec_next (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("next", args, from_tty);
}
enum mi_cmd_result
mi_cmd_exec_next_instruction (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("nexti", args, from_tty);
}
enum mi_cmd_result
mi_cmd_exec_step (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("step", args, from_tty);
}
enum mi_cmd_result
mi_cmd_exec_step_instruction (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("stepi", args, from_tty);
}
enum mi_cmd_result
mi_cmd_exec_finish (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("finish", args, from_tty);
}
enum mi_cmd_result
mi_cmd_exec_until (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("until", args, from_tty);
}
enum mi_cmd_result
mi_cmd_exec_return (char *args, int from_tty)
{
/* This command doesn't really execute the target, it just pops the
specified number of frames. */
if (*args)
/* Call return_command with from_tty argument equal to 0 so as to
avoid being queried. */
return_command (args, 0);
else
/* Call return_command with from_tty argument equal to 0 so as to
avoid being queried. */
return_command (NULL, 0);
/* Because we have called return_command with from_tty = 0, we need
to print the frame here. */
print_stack_frame (get_selected_frame (NULL), 1, LOC_AND_ADDRESS);
return MI_CMD_DONE;
}
enum mi_cmd_result
mi_cmd_exec_continue (char *args, int from_tty)
{
/* FIXME: Should call a libgdb function, not a cli wrapper */
return mi_execute_async_cli_command ("continue", args, from_tty);
}
/* Interrupt the execution of the target. Note how we must play around
with the token varialbes, in order to display the current token in
the result of the interrupt command, and the previous execution
token when the target finally stops. See comments in
mi_cmd_execute. */
enum mi_cmd_result
mi_cmd_exec_interrupt (char *args, int from_tty)
{
if (!target_executing)
{
mi_error_message = xstrprintf ("mi_cmd_exec_interrupt: Inferior not executing.");
return MI_CMD_ERROR;
}
interrupt_target_command (args, from_tty);
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("^done", raw_stdout);
xfree (last_async_command);
if (previous_async_command)
last_async_command = xstrdup (previous_async_command);
xfree (previous_async_command);
previous_async_command = NULL;
mi_out_put (uiout, raw_stdout);
mi_out_rewind (uiout);
fputs_unfiltered ("\n", raw_stdout);
return MI_CMD_QUIET;
}
enum mi_cmd_result
mi_cmd_thread_select (char *command, char **argv, int argc)
{
enum gdb_rc rc;
if (argc != 1)
{
mi_error_message = xstrprintf ("mi_cmd_thread_select: USAGE: threadnum.");
return MI_CMD_ERROR;
}
else
rc = gdb_thread_select (uiout, argv[0], &mi_error_message);
/* RC is enum gdb_rc if it is successful (>=0)
enum return_reason if not (<0). */
if ((int) rc < 0 && (enum return_reason) rc == RETURN_ERROR)
return MI_CMD_ERROR;
else if ((int) rc >= 0 && rc == GDB_RC_FAIL)
return MI_CMD_ERROR;
else
return MI_CMD_DONE;
}
enum mi_cmd_result
mi_cmd_thread_list_ids (char *command, char **argv, int argc)
{
enum gdb_rc rc = MI_CMD_DONE;
if (argc != 0)
{
mi_error_message = xstrprintf ("mi_cmd_thread_list_ids: No arguments required.");
return MI_CMD_ERROR;
}
else
rc = gdb_list_thread_ids (uiout, &mi_error_message);
if (rc == GDB_RC_FAIL)
return MI_CMD_ERROR;
else
return MI_CMD_DONE;
}
enum mi_cmd_result
mi_cmd_data_list_register_names (char *command, char **argv, int argc)
{
int regnum, numregs;
int i;
struct cleanup *cleanup;
/* Note that the test for a valid register must include checking the
REGISTER_NAME because NUM_REGS may be allocated for the union of
the register sets within a family of related processors. In this
case, some entries of REGISTER_NAME will change depending upon
the particular processor being debugged. */
numregs = NUM_REGS + NUM_PSEUDO_REGS;
cleanup = make_cleanup_ui_out_list_begin_end (uiout, "register-names");
if (argc == 0) /* No args, just do all the regs */
{
for (regnum = 0;
regnum < numregs;
regnum++)
{
if (REGISTER_NAME (regnum) == NULL
|| *(REGISTER_NAME (regnum)) == '\0')
ui_out_field_string (uiout, NULL, "");
else
ui_out_field_string (uiout, NULL, REGISTER_NAME (regnum));
}
}
/* Else, list of register #s, just do listed regs */
for (i = 0; i < argc; i++)
{
regnum = atoi (argv[i]);
if (regnum < 0 || regnum >= numregs)
{
do_cleanups (cleanup);
mi_error_message = xstrprintf ("bad register number");
return MI_CMD_ERROR;
}
if (REGISTER_NAME (regnum) == NULL
|| *(REGISTER_NAME (regnum)) == '\0')
ui_out_field_string (uiout, NULL, "");
else
ui_out_field_string (uiout, NULL, REGISTER_NAME (regnum));
}
do_cleanups (cleanup);
return MI_CMD_DONE;
}
enum mi_cmd_result
mi_cmd_data_list_changed_registers (char *command, char **argv, int argc)
{
int regnum, numregs, changed;
int i;
struct cleanup *cleanup;
/* Note that the test for a valid register must include checking the
REGISTER_NAME because NUM_REGS may be allocated for the union of
the register sets within a family of related processors. In this
case, some entries of REGISTER_NAME will change depending upon
the particular processor being debugged. */
numregs = NUM_REGS + NUM_PSEUDO_REGS;
cleanup = make_cleanup_ui_out_list_begin_end (uiout, "changed-registers");
if (argc == 0) /* No args, just do all the regs */
{
for (regnum = 0;
regnum < numregs;
regnum++)
{
if (REGISTER_NAME (regnum) == NULL
|| *(REGISTER_NAME (regnum)) == '\0')
continue;
changed = register_changed_p (regnum);
if (changed < 0)
{
do_cleanups (cleanup);
mi_error_message = xstrprintf ("mi_cmd_data_list_changed_registers: Unable to read register contents.");
return MI_CMD_ERROR;
}
else if (changed)
ui_out_field_int (uiout, NULL, regnum);
}
}
/* Else, list of register #s, just do listed regs */
for (i = 0; i < argc; i++)
{
regnum = atoi (argv[i]);
if (regnum >= 0
&& regnum < numregs
&& REGISTER_NAME (regnum) != NULL
&& *REGISTER_NAME (regnum) != '\000')
{
changed = register_changed_p (regnum);
if (changed < 0)
{
do_cleanups (cleanup);
mi_error_message = xstrprintf ("mi_cmd_data_list_register_change: Unable to read register contents.");
return MI_CMD_ERROR;
}
else if (changed)
ui_out_field_int (uiout, NULL, regnum);
}
else
{
do_cleanups (cleanup);
mi_error_message = xstrprintf ("bad register number");
return MI_CMD_ERROR;
}
}
do_cleanups (cleanup);
return MI_CMD_DONE;
}
static int
register_changed_p (int regnum)
{
gdb_byte raw_buffer[MAX_REGISTER_SIZE];
if (! frame_register_read (get_selected_frame (NULL), regnum, raw_buffer))
return -1;
if (memcmp (&old_regs[DEPRECATED_REGISTER_BYTE (regnum)], raw_buffer,
register_size (current_gdbarch, regnum)) == 0)
return 0;
/* Found a changed register. Return 1. */
memcpy (&old_regs[DEPRECATED_REGISTER_BYTE (regnum)], raw_buffer,
register_size (current_gdbarch, regnum));
return 1;
}
/* Return a list of register number and value pairs. The valid
arguments expected are: a letter indicating the format in which to
display the registers contents. This can be one of: x (hexadecimal), d
(decimal), N (natural), t (binary), o (octal), r (raw). After the
format argumetn there can be a sequence of numbers, indicating which
registers to fetch the content of. If the format is the only argument,
a list of all the registers with their values is returned. */
enum mi_cmd_result
mi_cmd_data_list_register_values (char *command, char **argv, int argc)
{
int regnum, numregs, format, result;
int i;
struct cleanup *list_cleanup, *tuple_cleanup;
/* Note that the test for a valid register must include checking the
REGISTER_NAME because NUM_REGS may be allocated for the union of
the register sets within a family of related processors. In this
case, some entries of REGISTER_NAME will change depending upon
the particular processor being debugged. */
numregs = NUM_REGS + NUM_PSEUDO_REGS;
if (argc == 0)
{
mi_error_message = xstrprintf ("mi_cmd_data_list_register_values: Usage: -data-list-register-values <format> [<regnum1>...<regnumN>]");
return MI_CMD_ERROR;
}
format = (int) argv[0][0];
list_cleanup = make_cleanup_ui_out_list_begin_end (uiout, "register-values");
if (argc == 1) /* No args, beside the format: do all the regs */
{
for (regnum = 0;
regnum < numregs;
regnum++)
{
if (REGISTER_NAME (regnum) == NULL
|| *(REGISTER_NAME (regnum)) == '\0')
continue;
tuple_cleanup = make_cleanup_ui_out_tuple_begin_end (uiout, NULL);
ui_out_field_int (uiout, "number", regnum);
result = get_register (regnum, format);
if (result == -1)
{
do_cleanups (list_cleanup);
return MI_CMD_ERROR;
}
do_cleanups (tuple_cleanup);
}
}
/* Else, list of register #s, just do listed regs */
for (i = 1; i < argc; i++)
{
regnum = atoi (argv[i]);
if (regnum >= 0
&& regnum < numregs
&& REGISTER_NAME (regnum) != NULL
&& *REGISTER_NAME (regnum) != '\000')
{
tuple_cleanup = make_cleanup_ui_out_tuple_begin_end (uiout, NULL);
ui_out_field_int (uiout, "number", regnum);
result = get_register (regnum, format);
if (result == -1)
{
do_cleanups (list_cleanup);
return MI_CMD_ERROR;
}
do_cleanups (tuple_cleanup);
}
else
{
do_cleanups (list_cleanup);
mi_error_message = xstrprintf ("bad register number");
return MI_CMD_ERROR;
}
}
do_cleanups (list_cleanup);
return MI_CMD_DONE;
}
/* Output one register's contents in the desired format. */
static int
get_register (int regnum, int format)
{
gdb_byte buffer[MAX_REGISTER_SIZE];
int optim;
int realnum;
CORE_ADDR addr;
enum lval_type lval;
static struct ui_stream *stb = NULL;
stb = ui_out_stream_new (uiout);
if (format == 'N')
format = 0;
frame_register (get_selected_frame (NULL), regnum, &optim, &lval, &addr,
&realnum, buffer);
if (optim)
{
mi_error_message = xstrprintf ("Optimized out");
return -1;
}
if (format == 'r')
{
int j;
char *ptr, buf[1024];
strcpy (buf, "0x");
ptr = buf + 2;
for (j = 0; j < register_size (current_gdbarch, regnum); j++)
{
int idx = TARGET_BYTE_ORDER == BFD_ENDIAN_BIG ? j
: register_size (current_gdbarch, regnum) - 1 - j;
sprintf (ptr, "%02x", (unsigned char) buffer[idx]);
ptr += 2;
}
ui_out_field_string (uiout, "value", buf);
/*fputs_filtered (buf, gdb_stdout); */
}
else
{
val_print (register_type (current_gdbarch, regnum), buffer, 0, 0,
stb->stream, format, 1, 0, Val_pretty_default);
ui_out_field_stream (uiout, "value", stb);
ui_out_stream_delete (stb);
}
return 1;
}
/* Write given values into registers. The registers and values are
given as pairs. The corresponding MI command is
-data-write-register-values <format> [<regnum1> <value1>...<regnumN> <valueN>]*/
enum mi_cmd_result
mi_cmd_data_write_register_values (char *command, char **argv, int argc)
{
int regnum;
int i;
int numregs;
LONGEST value;
char format;
/* Note that the test for a valid register must include checking the
REGISTER_NAME because NUM_REGS may be allocated for the union of
the register sets within a family of related processors. In this
case, some entries of REGISTER_NAME will change depending upon
the particular processor being debugged. */
numregs = NUM_REGS + NUM_PSEUDO_REGS;
if (argc == 0)
{
mi_error_message = xstrprintf ("mi_cmd_data_write_register_values: Usage: -data-write-register-values <format> [<regnum1> <value1>...<regnumN> <valueN>]");
return MI_CMD_ERROR;
}
format = (int) argv[0][0];
if (!target_has_registers)
{
mi_error_message = xstrprintf ("mi_cmd_data_write_register_values: No registers.");
return MI_CMD_ERROR;
}
if (!(argc - 1))
{
mi_error_message = xstrprintf ("mi_cmd_data_write_register_values: No regs and values specified.");
return MI_CMD_ERROR;
}
if ((argc - 1) % 2)
{
mi_error_message = xstrprintf ("mi_cmd_data_write_register_values: Regs and vals are not in pairs.");
return MI_CMD_ERROR;
}
for (i = 1; i < argc; i = i + 2)
{
regnum = atoi (argv[i]);
if (regnum >= 0
&& regnum < numregs
&& REGISTER_NAME (regnum) != NULL
&& *REGISTER_NAME (regnum) != '\000')
{
void *buffer;
struct cleanup *old_chain;
/* Get the value as a number */
value = parse_and_eval_address (argv[i + 1]);
/* Get the value into an array */
buffer = xmalloc (DEPRECATED_REGISTER_SIZE);
old_chain = make_cleanup (xfree, buffer);
store_signed_integer (buffer, DEPRECATED_REGISTER_SIZE, value);
/* Write it down */
deprecated_write_register_bytes (DEPRECATED_REGISTER_BYTE (regnum), buffer, register_size (current_gdbarch, regnum));
/* Free the buffer. */
do_cleanups (old_chain);
}
else
{
mi_error_message = xstrprintf ("bad register number");
return MI_CMD_ERROR;
}
}
return MI_CMD_DONE;
}
#if 0
/*This is commented out because we decided it was not useful. I leave
it, just in case. ezannoni:1999-12-08 */
/* Assign a value to a variable. The expression argument must be in
the form A=2 or "A = 2" (I.e. if there are spaces it needs to be
quoted. */
enum mi_cmd_result
mi_cmd_data_assign (char *command, char **argv, int argc)
{
struct expression *expr;
struct cleanup *old_chain;
if (argc != 1)
{
mi_error_message = xstrprintf ("mi_cmd_data_assign: Usage: -data-assign expression");
return MI_CMD_ERROR;
}
/* NOTE what follows is a clone of set_command(). FIXME: ezannoni
01-12-1999: Need to decide what to do with this for libgdb purposes. */
expr = parse_expression (argv[0]);
old_chain = make_cleanup (free_current_contents, &expr);
evaluate_expression (expr);
do_cleanups (old_chain);
return MI_CMD_DONE;
}
#endif
/* Evaluate the value of the argument. The argument is an
expression. If the expression contains spaces it needs to be
included in double quotes. */
enum mi_cmd_result
mi_cmd_data_evaluate_expression (char *command, char **argv, int argc)
{
struct expression *expr;
struct cleanup *old_chain = NULL;
struct value *val;
struct ui_stream *stb = NULL;
stb = ui_out_stream_new (uiout);
if (argc != 1)
{
mi_error_message = xstrprintf ("mi_cmd_data_evaluate_expression: Usage: -data-evaluate-expression expression");
return MI_CMD_ERROR;
}
expr = parse_expression (argv[0]);
old_chain = make_cleanup (free_current_contents, &expr);
val = evaluate_expression (expr);
/* Print the result of the expression evaluation. */
val_print (value_type (val), value_contents (val),
value_embedded_offset (val), VALUE_ADDRESS (val),
stb->stream, 0, 0, 0, 0);
ui_out_field_stream (uiout, "value", stb);
ui_out_stream_delete (stb);
do_cleanups (old_chain);
return MI_CMD_DONE;
}
enum mi_cmd_result
mi_cmd_target_download (char *args, int from_tty)
{
char *run;
struct cleanup *old_cleanups = NULL;
run = xstrprintf ("load %s", args);
old_cleanups = make_cleanup (xfree, run);
execute_command (run, from_tty);
do_cleanups (old_cleanups);
return MI_CMD_DONE;
}
/* Connect to the remote target. */
enum mi_cmd_result
mi_cmd_target_select (char *args, int from_tty)
{
char *run;
struct cleanup *old_cleanups = NULL;
run = xstrprintf ("target %s", args);
old_cleanups = make_cleanup (xfree, run);
/* target-select is always synchronous. once the call has returned
we know that we are connected. */
/* NOTE: At present all targets that are connected are also
(implicitly) talking to a halted target. In the future this may
change. */
execute_command (run, from_tty);
do_cleanups (old_cleanups);
/* Issue the completion message here. */
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("^connected", raw_stdout);
mi_out_put (uiout, raw_stdout);
mi_out_rewind (uiout);
fputs_unfiltered ("\n", raw_stdout);
do_exec_cleanups (ALL_CLEANUPS);
return MI_CMD_QUIET;
}
/* DATA-MEMORY-READ:
ADDR: start address of data to be dumped.
WORD-FORMAT: a char indicating format for the ``word''. See
the ``x'' command.
WORD-SIZE: size of each ``word''; 1,2,4, or 8 bytes
NR_ROW: Number of rows.
NR_COL: The number of colums (words per row).
ASCHAR: (OPTIONAL) Append an ascii character dump to each row. Use
ASCHAR for unprintable characters.
Reads SIZE*NR_ROW*NR_COL bytes starting at ADDR from memory and
displayes them. Returns:
{addr="...",rowN={wordN="..." ,... [,ascii="..."]}, ...}
Returns:
The number of bytes read is SIZE*ROW*COL. */
enum mi_cmd_result
mi_cmd_data_read_memory (char *command, char **argv, int argc)
{
struct cleanup *cleanups = make_cleanup (null_cleanup, NULL);
CORE_ADDR addr;
long total_bytes;
long nr_cols;
long nr_rows;
char word_format;
struct type *word_type;
long word_size;
char word_asize;
char aschar;
gdb_byte *mbuf;
int nr_bytes;
long offset = 0;
int optind = 0;
char *optarg;
enum opt
{
OFFSET_OPT
};
static struct mi_opt opts[] =
{
{"o", OFFSET_OPT, 1},
0
};
while (1)
{
int opt = mi_getopt ("mi_cmd_data_read_memory", argc, argv, opts,
&optind, &optarg);
if (opt < 0)
break;
switch ((enum opt) opt)
{
case OFFSET_OPT:
offset = atol (optarg);
break;
}
}
argv += optind;
argc -= optind;
if (argc < 5 || argc > 6)
{
mi_error_message = xstrprintf ("mi_cmd_data_read_memory: Usage: ADDR WORD-FORMAT WORD-SIZE NR-ROWS NR-COLS [ASCHAR].");
return MI_CMD_ERROR;
}
/* Extract all the arguments. */
/* Start address of the memory dump. */
addr = parse_and_eval_address (argv[0]) + offset;
/* The format character to use when displaying a memory word. See
the ``x'' command. */
word_format = argv[1][0];
/* The size of the memory word. */
word_size = atol (argv[2]);
switch (word_size)
{
case 1:
word_type = builtin_type_int8;
word_asize = 'b';
break;
case 2:
word_type = builtin_type_int16;
word_asize = 'h';
break;
case 4:
word_type = builtin_type_int32;
word_asize = 'w';
break;
case 8:
word_type = builtin_type_int64;
word_asize = 'g';
break;
default:
word_type = builtin_type_int8;
word_asize = 'b';
}
/* The number of rows */
nr_rows = atol (argv[3]);
if (nr_rows <= 0)
{
mi_error_message = xstrprintf ("mi_cmd_data_read_memory: invalid number of rows.");
return MI_CMD_ERROR;
}
/* number of bytes per row. */
nr_cols = atol (argv[4]);
if (nr_cols <= 0)
{
mi_error_message = xstrprintf ("mi_cmd_data_read_memory: invalid number of columns.");
return MI_CMD_ERROR;
}
/* The un-printable character when printing ascii. */
if (argc == 6)
aschar = *argv[5];
else
aschar = 0;
/* create a buffer and read it in. */
total_bytes = word_size * nr_rows * nr_cols;
mbuf = xcalloc (total_bytes, 1);
make_cleanup (xfree, mbuf);
nr_bytes = 0;
while (nr_bytes < total_bytes)
{
int error;
long num = target_read_memory_partial (addr + nr_bytes, mbuf + nr_bytes,
total_bytes - nr_bytes,
&error);
if (num <= 0)
break;
nr_bytes += num;
}
/* output the header information. */
ui_out_field_core_addr (uiout, "addr", addr);
ui_out_field_int (uiout, "nr-bytes", nr_bytes);
ui_out_field_int (uiout, "total-bytes", total_bytes);
ui_out_field_core_addr (uiout, "next-row", addr + word_size * nr_cols);
ui_out_field_core_addr (uiout, "prev-row", addr - word_size * nr_cols);
ui_out_field_core_addr (uiout, "next-page", addr + total_bytes);
ui_out_field_core_addr (uiout, "prev-page", addr - total_bytes);
/* Build the result as a two dimentional table. */
{
struct ui_stream *stream = ui_out_stream_new (uiout);
struct cleanup *cleanup_list_memory;
int row;
int row_byte;
cleanup_list_memory = make_cleanup_ui_out_list_begin_end (uiout, "memory");
for (row = 0, row_byte = 0;
row < nr_rows;
row++, row_byte += nr_cols * word_size)
{
int col;
int col_byte;
struct cleanup *cleanup_tuple;
struct cleanup *cleanup_list_data;
cleanup_tuple = make_cleanup_ui_out_tuple_begin_end (uiout, NULL);
ui_out_field_core_addr (uiout, "addr", addr + row_byte);
/* ui_out_field_core_addr_symbolic (uiout, "saddr", addr + row_byte); */
cleanup_list_data = make_cleanup_ui_out_list_begin_end (uiout, "data");
for (col = 0, col_byte = row_byte;
col < nr_cols;
col++, col_byte += word_size)
{
if (col_byte + word_size > nr_bytes)
{
ui_out_field_string (uiout, NULL, "N/A");
}
else
{
ui_file_rewind (stream->stream);
print_scalar_formatted (mbuf + col_byte, word_type, word_format,
word_asize, stream->stream);
ui_out_field_stream (uiout, NULL, stream);
}
}
do_cleanups (cleanup_list_data);
if (aschar)
{
int byte;
ui_file_rewind (stream->stream);
for (byte = row_byte; byte < row_byte + word_size * nr_cols; byte++)
{
if (byte >= nr_bytes)
{
fputc_unfiltered ('X', stream->stream);
}
else if (mbuf[byte] < 32 || mbuf[byte] > 126)
{
fputc_unfiltered (aschar, stream->stream);
}
else
fputc_unfiltered (mbuf[byte], stream->stream);
}
ui_out_field_stream (uiout, "ascii", stream);
}
do_cleanups (cleanup_tuple);
}
ui_out_stream_delete (stream);
do_cleanups (cleanup_list_memory);
}
do_cleanups (cleanups);
return MI_CMD_DONE;
}
/* DATA-MEMORY-WRITE:
COLUMN_OFFSET: optional argument. Must be preceeded by '-o'. The
offset from the beginning of the memory grid row where the cell to
be written is.
ADDR: start address of the row in the memory grid where the memory
cell is, if OFFSET_COLUMN is specified. Otherwise, the address of
the location to write to.
FORMAT: a char indicating format for the ``word''. See
the ``x'' command.
WORD_SIZE: size of each ``word''; 1,2,4, or 8 bytes
VALUE: value to be written into the memory address.
Writes VALUE into ADDR + (COLUMN_OFFSET * WORD_SIZE).
Prints nothing. */
enum mi_cmd_result
mi_cmd_data_write_memory (char *command, char **argv, int argc)
{
CORE_ADDR addr;
char word_format;
long word_size;
/* FIXME: ezannoni 2000-02-17 LONGEST could possibly not be big
enough when using a compiler other than GCC. */
LONGEST value;
void *buffer;
struct cleanup *old_chain;
long offset = 0;
int optind = 0;
char *optarg;
enum opt
{
OFFSET_OPT
};
static struct mi_opt opts[] =
{
{"o", OFFSET_OPT, 1},
0
};
while (1)
{
int opt = mi_getopt ("mi_cmd_data_write_memory", argc, argv, opts,
&optind, &optarg);
if (opt < 0)
break;
switch ((enum opt) opt)
{
case OFFSET_OPT:
offset = atol (optarg);
break;
}
}
argv += optind;
argc -= optind;
if (argc != 4)
{
mi_error_message = xstrprintf ("mi_cmd_data_write_memory: Usage: [-o COLUMN_OFFSET] ADDR FORMAT WORD-SIZE VALUE.");
return MI_CMD_ERROR;
}
/* Extract all the arguments. */
/* Start address of the memory dump. */
addr = parse_and_eval_address (argv[0]);
/* The format character to use when displaying a memory word. See
the ``x'' command. */
word_format = argv[1][0];
/* The size of the memory word. */
word_size = atol (argv[2]);
/* Calculate the real address of the write destination. */
addr += (offset * word_size);
/* Get the value as a number */
value = parse_and_eval_address (argv[3]);
/* Get the value into an array */
buffer = xmalloc (word_size);
old_chain = make_cleanup (xfree, buffer);
store_signed_integer (buffer, word_size, value);
/* Write it down to memory */
write_memory (addr, buffer, word_size);
/* Free the buffer. */
do_cleanups (old_chain);
return MI_CMD_DONE;
}
/* Execute a command within a safe environment.
Return <0 for error; >=0 for ok.
args->action will tell mi_execute_command what action
to perfrom after the given command has executed (display/supress
prompt, display error). */
static void
captured_mi_execute_command (struct ui_out *uiout, void *data)
{
struct captured_mi_execute_command_args *args =
(struct captured_mi_execute_command_args *) data;
struct mi_parse *context = args->command;
switch (context->op)
{
case MI_COMMAND:
/* A MI command was read from the input stream */
if (mi_debug_p)
/* FIXME: gdb_???? */
fprintf_unfiltered (raw_stdout, " token=`%s' command=`%s' args=`%s'\n",
context->token, context->command, context->args);
/* FIXME: cagney/1999-09-25: Rather than this convoluted
condition expression, each function should return an
indication of what action is required and then switch on
that. */
args->action = EXECUTE_COMMAND_DISPLAY_PROMPT;
args->rc = mi_cmd_execute (context);
if (!target_can_async_p () || !target_executing)
{
/* print the result if there were no errors
Remember that on the way out of executing a command, you have
to directly use the mi_interp's uiout, since the command could
have reset the interpreter, in which case the current uiout
will most likely crash in the mi_out_* routines. */
if (args->rc == MI_CMD_DONE)
{
fputs_unfiltered (context->token, raw_stdout);
fputs_unfiltered ("^done", raw_stdout);
mi_out_put (uiout, raw_stdout);
mi_out_rewind (uiout);
fputs_unfiltered ("\n", raw_stdout);
}
else if (args->rc == MI_CMD_ERROR)
{
if (mi_error_message)
{
fputs_unfiltered (context->token, raw_stdout);
fputs_unfiltered ("^error,msg=\"", raw_stdout);
fputstr_unfiltered (mi_error_message, '"', raw_stdout);
xfree (mi_error_message);
fputs_unfiltered ("\"\n", raw_stdout);
}
mi_out_rewind (uiout);
}
else
mi_out_rewind (uiout);
}
else if (sync_execution)
{
/* Don't print the prompt. We are executing the target in
synchronous mode. */
args->action = EXECUTE_COMMAND_SUPRESS_PROMPT;
return;
}
break;
case CLI_COMMAND:
{
char *argv[2];
/* A CLI command was read from the input stream. */
/* This "feature" will be removed as soon as we have a
complete set of mi commands. */
/* Echo the command on the console. */
fprintf_unfiltered (gdb_stdlog, "%s\n", context->command);
/* Call the "console" interpreter. */
argv[0] = "console";
argv[1] = context->command;
args->rc = mi_cmd_interpreter_exec ("-interpreter-exec", argv, 2);
/* If we changed interpreters, DON'T print out anything. */
if (current_interp_named_p (INTERP_MI)
|| current_interp_named_p (INTERP_MI1)
|| current_interp_named_p (INTERP_MI2)
|| current_interp_named_p (INTERP_MI3))
{
if (args->rc == MI_CMD_DONE)
{
fputs_unfiltered (context->token, raw_stdout);
fputs_unfiltered ("^done", raw_stdout);
mi_out_put (uiout, raw_stdout);
mi_out_rewind (uiout);
fputs_unfiltered ("\n", raw_stdout);
args->action = EXECUTE_COMMAND_DISPLAY_PROMPT;
}
else if (args->rc == MI_CMD_ERROR)
{
if (mi_error_message)
{
fputs_unfiltered (context->token, raw_stdout);
fputs_unfiltered ("^error,msg=\"", raw_stdout);
fputstr_unfiltered (mi_error_message, '"', raw_stdout);
xfree (mi_error_message);
fputs_unfiltered ("\"\n", raw_stdout);
}
mi_out_rewind (uiout);
}
else
mi_out_rewind (uiout);
}
break;
}
}
return;
}
void
mi_execute_command (char *cmd, int from_tty)
{
struct mi_parse *command;
struct captured_mi_execute_command_args args;
struct ui_out *saved_uiout = uiout;
/* This is to handle EOF (^D). We just quit gdb. */
/* FIXME: we should call some API function here. */
if (cmd == 0)
quit_force (NULL, from_tty);
command = mi_parse (cmd);
if (command != NULL)
{
struct gdb_exception result;
/* FIXME: cagney/1999-11-04: Can this use of catch_exceptions either
be pushed even further down or even eliminated? */
args.command = command;
result = catch_exception (uiout, captured_mi_execute_command, &args,
RETURN_MASK_ALL);
exception_print (gdb_stderr, result);
if (args.action == EXECUTE_COMMAND_SUPRESS_PROMPT)
{
/* The command is executing synchronously. Bail out early
suppressing the finished prompt. */
mi_parse_free (command);
return;
}
if (result.reason < 0)
{
/* The command execution failed and error() was called
somewhere. */
fputs_unfiltered (command->token, raw_stdout);
fputs_unfiltered ("^error,msg=\"", raw_stdout);
fputstr_unfiltered (result.message, '"', raw_stdout);
fputs_unfiltered ("\"\n", raw_stdout);
mi_out_rewind (uiout);
}
mi_parse_free (command);
}
fputs_unfiltered ("(gdb) \n", raw_stdout);
gdb_flush (raw_stdout);
/* print any buffered hook code */
/* ..... */
}
static enum mi_cmd_result
mi_cmd_execute (struct mi_parse *parse)
{
if (parse->cmd->argv_func != NULL
|| parse->cmd->args_func != NULL)
{
/* FIXME: We need to save the token because the command executed
may be asynchronous and need to print the token again.
In the future we can pass the token down to the func
and get rid of the last_async_command */
/* The problem here is to keep the token around when we launch
the target, and we want to interrupt it later on. The
interrupt command will have its own token, but when the
target stops, we must display the token corresponding to the
last execution command given. So we have another string where
we copy the token (previous_async_command), if this was
indeed the token of an execution command, and when we stop we
print that one. This is possible because the interrupt
command, when over, will copy that token back into the
default token string (last_async_command). */
if (target_executing)
{
if (!previous_async_command)
previous_async_command = xstrdup (last_async_command);
if (strcmp (parse->command, "exec-interrupt"))
{
fputs_unfiltered (parse->token, raw_stdout);
fputs_unfiltered ("^error,msg=\"", raw_stdout);
fputs_unfiltered ("Cannot execute command ", raw_stdout);
fputstr_unfiltered (parse->command, '"', raw_stdout);
fputs_unfiltered (" while target running", raw_stdout);
fputs_unfiltered ("\"\n", raw_stdout);
return MI_CMD_ERROR;
}
}
last_async_command = xstrdup (parse->token);
make_exec_cleanup (free_current_contents, &last_async_command);
/* FIXME: DELETE THIS! */
if (parse->cmd->args_func != NULL)
return parse->cmd->args_func (parse->args, 0 /*from_tty */ );
return parse->cmd->argv_func (parse->command, parse->argv, parse->argc);
}
else if (parse->cmd->cli.cmd != 0)
{
/* FIXME: DELETE THIS. */
/* The operation is still implemented by a cli command */
/* Must be a synchronous one */
mi_execute_cli_command (parse->cmd->cli.cmd, parse->cmd->cli.args_p,
parse->args);
return MI_CMD_DONE;
}
else
{
/* FIXME: DELETE THIS. */
fputs_unfiltered (parse->token, raw_stdout);
fputs_unfiltered ("^error,msg=\"", raw_stdout);
fputs_unfiltered ("Undefined mi command: ", raw_stdout);
fputstr_unfiltered (parse->command, '"', raw_stdout);
fputs_unfiltered (" (missing implementation)", raw_stdout);
fputs_unfiltered ("\"\n", raw_stdout);
return MI_CMD_ERROR;
}
}
/* FIXME: This is just a hack so we can get some extra commands going.
We don't want to channel things through the CLI, but call libgdb directly */
/* Use only for synchronous commands */
void
mi_execute_cli_command (const char *cmd, int args_p, const char *args)
{
if (cmd != 0)
{
struct cleanup *old_cleanups;
char *run;
if (args_p)
run = xstrprintf ("%s %s", cmd, args);
else
run = xstrdup (cmd);
if (mi_debug_p)
/* FIXME: gdb_???? */
fprintf_unfiltered (gdb_stdout, "cli=%s run=%s\n",
cmd, run);
old_cleanups = make_cleanup (xfree, run);
execute_command ( /*ui */ run, 0 /*from_tty */ );
do_cleanups (old_cleanups);
return;
}
}
enum mi_cmd_result
mi_execute_async_cli_command (char *mi, char *args, int from_tty)
{
struct cleanup *old_cleanups;
char *run;
char *async_args;
if (target_can_async_p ())
{
async_args = (char *) xmalloc (strlen (args) + 2);
make_exec_cleanup (free, async_args);
strcpy (async_args, args);
strcat (async_args, "&");
run = xstrprintf ("%s %s", mi, async_args);
make_exec_cleanup (free, run);
add_continuation (mi_exec_async_cli_cmd_continuation, NULL);
old_cleanups = NULL;
}
else
{
run = xstrprintf ("%s %s", mi, args);
old_cleanups = make_cleanup (xfree, run);
}
if (!target_can_async_p ())
{
/* NOTE: For synchronous targets asynchronous behavour is faked by
printing out the GDB prompt before we even try to execute the
command. */
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("^running\n", raw_stdout);
fputs_unfiltered ("(gdb) \n", raw_stdout);
gdb_flush (raw_stdout);
}
else
{
/* FIXME: cagney/1999-11-29: Printing this message before
calling execute_command is wrong. It should only be printed
once gdb has confirmed that it really has managed to send a
run command to the target. */
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("^running\n", raw_stdout);
}
execute_command ( /*ui */ run, 0 /*from_tty */ );
if (!target_can_async_p ())
{
/* Do this before doing any printing. It would appear that some
print code leaves garbage around in the buffer. */
do_cleanups (old_cleanups);
/* If the target was doing the operation synchronously we fake
the stopped message. */
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("*stopped", raw_stdout);
mi_out_put (uiout, raw_stdout);
mi_out_rewind (uiout);
fputs_unfiltered ("\n", raw_stdout);
return MI_CMD_QUIET;
}
return MI_CMD_DONE;
}
void
mi_exec_async_cli_cmd_continuation (struct continuation_arg *arg)
{
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("*stopped", raw_stdout);
mi_out_put (uiout, raw_stdout);
fputs_unfiltered ("\n", raw_stdout);
fputs_unfiltered ("(gdb) \n", raw_stdout);
gdb_flush (raw_stdout);
do_exec_cleanups (ALL_CLEANUPS);
}
void
mi_load_progress (const char *section_name,
unsigned long sent_so_far,
unsigned long total_section,
unsigned long total_sent,
unsigned long grand_total)
{
struct timeval time_now, delta, update_threshold;
static struct timeval last_update;
static char *previous_sect_name = NULL;
int new_section;
struct ui_out *saved_uiout;
/* This function is called through deprecated_show_load_progress
which means uiout may not be correct. Fix it for the duration
of this function. */
saved_uiout = uiout;
if (current_interp_named_p (INTERP_MI))
uiout = mi_out_new (2);
else if (current_interp_named_p (INTERP_MI1))
uiout = mi_out_new (1);
else
return;
update_threshold.tv_sec = 0;
update_threshold.tv_usec = 500000;
gettimeofday (&time_now, NULL);
delta.tv_usec = time_now.tv_usec - last_update.tv_usec;
delta.tv_sec = time_now.tv_sec - last_update.tv_sec;
if (delta.tv_usec < 0)
{
delta.tv_sec -= 1;
delta.tv_usec += 1000000;
}
new_section = (previous_sect_name ?
strcmp (previous_sect_name, section_name) : 1);
if (new_section)
{
struct cleanup *cleanup_tuple;
xfree (previous_sect_name);
previous_sect_name = xstrdup (section_name);
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("+download", raw_stdout);
cleanup_tuple = make_cleanup_ui_out_tuple_begin_end (uiout, NULL);
ui_out_field_string (uiout, "section", section_name);
ui_out_field_int (uiout, "section-size", total_section);
ui_out_field_int (uiout, "total-size", grand_total);
do_cleanups (cleanup_tuple);
mi_out_put (uiout, raw_stdout);
fputs_unfiltered ("\n", raw_stdout);
gdb_flush (raw_stdout);
}
if (delta.tv_sec >= update_threshold.tv_sec &&
delta.tv_usec >= update_threshold.tv_usec)
{
struct cleanup *cleanup_tuple;
last_update.tv_sec = time_now.tv_sec;
last_update.tv_usec = time_now.tv_usec;
if (last_async_command)
fputs_unfiltered (last_async_command, raw_stdout);
fputs_unfiltered ("+download", raw_stdout);
cleanup_tuple = make_cleanup_ui_out_tuple_begin_end (uiout, NULL);
ui_out_field_string (uiout, "section", section_name);
ui_out_field_int (uiout, "section-sent", sent_so_far);
ui_out_field_int (uiout, "section-size", total_section);
ui_out_field_int (uiout, "total-sent", total_sent);
ui_out_field_int (uiout, "total-size", grand_total);
do_cleanups (cleanup_tuple);
mi_out_put (uiout, raw_stdout);
fputs_unfiltered ("\n", raw_stdout);
gdb_flush (raw_stdout);
}
xfree (uiout);
uiout = saved_uiout;
}
void
mi_setup_architecture_data (void)
{
old_regs = xmalloc ((NUM_REGS + NUM_PSEUDO_REGS) * MAX_REGISTER_SIZE + 1);
memset (old_regs, 0, (NUM_REGS + NUM_PSEUDO_REGS) * MAX_REGISTER_SIZE + 1);
}
void
_initialize_mi_main (void)
{
DEPRECATED_REGISTER_GDBARCH_SWAP (old_regs);
deprecated_register_gdbarch_swap (NULL, 0, mi_setup_architecture_data);
}
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