Bochs/bochs/debug/dbg_main.cc

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/////////////////////////////////////////////////////////////////////////
// $Id: dbg_main.cc,v 1.47 2002-08-05 16:35:08 vruppert Exp $
/////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2001 MandrakeSoft S.A.
//
// MandrakeSoft S.A.
// 43, rue d'Aboukir
// 75002 Paris - France
// http://www.linux-mandrake.com/
// http://www.mandrakesoft.com/
//
// This library 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 2 of the License, or (at your option) any later version.
//
// This library 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 this library; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
// define shortcuts to get register from the default CPU
#define EBP (BX_CPU(dbg_cpu)->gen_reg[5].erx)
#define EIP (BX_CPU(dbg_cpu)->eip)
#define ESP (BX_CPU(dbg_cpu)->gen_reg[4].erx)
#define SP (BX_CPU(dbg_cpu)->gen_reg[4].word.rx)
extern "C" {
#include <signal.h>
}
#include "bochs.h"
#define LOG_THIS genlog->
#if HAVE_LIBREADLINE
extern "C" {
#include <stdio.h>
#include <readline/readline.h>
#if HAVE_READLINE_HISTORY_H
#include <readline/history.h>
#endif
}
#endif
static unsigned doit = 0;
#define SIM_NAME0 "bochs"
#ifndef SIM_NAME1_STR
#define SIM_NAME1_STR "sim1"
#endif
#define SIM_NAME(x) ((x == 0) ? SIM_NAME0 : SIM_NAME1_STR)
// default CPU in the debugger. For commands like "dump_cpu" it will
// use the default instead of always dumping all cpus.
Bit32u dbg_cpu = 0;
static void bx_dbg_usage(void);
static char bx_debug_rc_fname[BX_MAX_PATH];
static char tmp_buf[512];
static char *tmp_buf_ptr;
static char *argv0 = NULL;
#if BX_NUM_SIMULATORS >= 2
#define BX_DBG_IO_JOURNAL_SIZE 1024
#define BX_DBG_UCMEM_JOURNAL_SIZE 1024
#define BX_DBG_ASYNC_JOURNAL_SIZE 1024
#define BX_DBG_MASTER_MODE 10
#define BX_DBG_SLAVE_MODE 11
// #define BX_DBG_DEFAULT_ICOUNT_QUANTUM 50
#define BX_DBG_DEFAULT_ICOUNT_QUANTUM 3 /* mch */
static unsigned bx_dbg_cosimulateN(bx_dbg_icount_t count);
static int bx_dbg_compare_sim_iaddr(void);
static Boolean bx_dbg_compare_sim_cpu(void);
static Boolean bx_dbg_compare_sim_memory(void);
static void bx_dbg_journal_a20_event(unsigned val);
#endif
static struct {
#if BX_NUM_SIMULATORS >= 2
// some fields used only for cosimulation
unsigned icount_quantum;
unsigned master_slave_mode;
unsigned master, slave;
struct {
struct {
Bit8u op;
Bit8u len;
Bit16u addr;
Bit32u value;
} element[BX_DBG_IO_JOURNAL_SIZE];
unsigned size;
unsigned head, tail;
} IO_journal;
struct {
struct {
Bit8u op;
Bit8u len;
Bit32u addr;
Bit32u value;
} element[BX_DBG_UCMEM_JOURNAL_SIZE];
unsigned size;
unsigned head, tail;
} UCmem_journal;
// need to handle DMA stuff in here...
#define BX_DBG_ASYNC_JOURNAL_NONE 0
#define BX_DBG_ASYNC_JOURNAL_A20 1
#define BX_DBG_ASYNC_JOURNAL_IAC 2
#define BX_DBG_ASYNC_JOURNAL_NMI 3
#define BX_DBG_ASYNC_JOURNAL_RESET 4
// Asynchronous events at the boundaries they are *taken* by the master simulator.
// These are replayed back to the slave at the same boundaries.
struct {
struct {
unsigned what; // A20, INTR, NMI, RESET, IAC, ...
bx_dbg_icount_t icount;
union {
struct {
unsigned val;
} a20, nmi, reset, iac;
// perhaps other more complex types here
} u;
} element[BX_DBG_ASYNC_JOURNAL_SIZE];
unsigned size;
unsigned head, tail;
} async_journal;
struct {
Boolean iaddr;
Boolean cpu;
Boolean memory;
} compare_at_sync;
Boolean fast_forward_mode;
#endif // #if BX_NUM_SIMULATORS >= 2
// some fields used for single CPU debugger
Boolean auto_disassemble;
unsigned disassemble_size;
char default_display_format;
char default_unit_size;
Bit32u default_addr;
unsigned next_bpoint_id;
// last icount known to be in sync
#if BX_DBG_ICOUNT_SIZE == 32
Bit32u last_sync_icount;
#else // BX_DBG_ICOUNT_SIZE == 64
Bit64u last_sync_icount;
#endif
} bx_debugger;
// cosim commands for handling of comparison of simulator
// environments when both simulators have reached a common
// point (synchronized).
// cosim compare_at_sync iaddr (default is on)
// cosim compare_at_sync cpu (default is off)
// cosim compare_at_sync memory (default is off)
// cosim compare iaddr
// cosim compare cpu
// cosim compare memory
typedef struct {
FILE *fp;
char fname[BX_MAX_PATH];
unsigned lineno;
} bx_infile_stack_entry_t;
bx_infile_stack_entry_t bx_infile_stack[BX_INFILE_DEPTH];
int bx_infile_stack_index = 0;
static int bx_nest_infile(char *path);
static void bx_debug_ctrlc_handler(int signum);
static void bx_unnest_infile(void);
static void bx_get_command(void);
static void bx_dbg_print_guard_results();
static void bx_dbg_breakpoint_changed(void);
bx_dbg_callback_t bx_dbg_callback[BX_NUM_SIMULATORS];
bx_guard_t bx_guard;
// DMA stuff
void bx_dbg_post_dma_reports(void);
#define BX_BATCH_DMA_BUFSIZE 512
static struct {
unsigned this_many; // batch this many max before posting events
unsigned Qsize; // this many have been batched
struct {
Bit32u addr; // address of DMA op
unsigned len; // number of bytes in op
unsigned what; // BX_READ or BX_WRITE
Bit32u val; // value of DMA op
bx_dbg_icount_t icount; // icount at this dma op
} Q[BX_BATCH_DMA_BUFSIZE];
} bx_dbg_batch_dma;
// some buffers for disassembly
#if BX_DISASM
static Bit8u bx_disasm_ibuf[32];
static char bx_disasm_tbuf[512];
#endif
int
bx_dbg_main(int argc, char *argv[])
{
int i, bochs_argc=0, sim1_argc=0, sim2_argc=0;
char **bochs_argv = NULL;
char **sim1_argv = NULL;
char **sim2_argv = NULL;
argc = 1;
bx_dbg_batch_dma.this_many = 1;
bx_dbg_batch_dma.Qsize = 0;
// initialize callback functions, and guard environment
memset(bx_dbg_callback, 0, sizeof(bx_dbg_callback));
memset(&bx_guard, 0, sizeof(bx_guard));
bx_guard.async.irq = 1;
bx_guard.async.dma = 1;
memset(&bx_debugger, 0, sizeof(bx_debugger));
#if BX_NUM_SIMULATORS >= 2
bx_debugger.icount_quantum = BX_DBG_DEFAULT_ICOUNT_QUANTUM;
bx_debugger.IO_journal.size = 0;
bx_debugger.IO_journal.head = 0;
bx_debugger.IO_journal.tail = 0;
bx_debugger.UCmem_journal.size = 0;
bx_debugger.UCmem_journal.head = 0;
bx_debugger.UCmem_journal.tail = 0;
bx_debugger.async_journal.size = 0;
bx_debugger.async_journal.head = 0;
bx_debugger.async_journal.tail = 0;
bx_debugger.master = 0;
bx_debugger.slave = 1;
bx_debugger.compare_at_sync.iaddr = 1;
bx_debugger.fast_forward_mode = 0;
#endif
bx_debugger.auto_disassemble = 1;
bx_debugger.disassemble_size = 32;
bx_debugger.default_display_format = 'x';
bx_debugger.default_unit_size = 'w';
bx_debugger.default_addr = 0;
bx_debugger.next_bpoint_id = 1;
bx_debugger.last_sync_icount = 0;
argv0 = strdup(argv[0]);
bx_debug_rc_fname[0] = '\0';
bochs_argv = (char **) &argv[0];
sim1_argv = bochs_argv; // start out with something reasonable
sim2_argv = bochs_argv; // start out with something reasonable
bochs_argc = 1;
sim1_argc = 1;
sim2_argc = 1;
// process "-rc pathname" option, if it exists
i = 1;
if ( (argc >= 2) && !strcmp(argv[1], "-rc") ) {
if ( argc == 2 ) {
BX_ERROR(( "%s: -rc option used, but no path specified.",
argv[0] ));
bx_dbg_usage();
BX_EXIT(1);
}
strncpy(bx_debug_rc_fname, argv[2], BX_MAX_PATH-1);
i += 2; // skip past "-rc" and filename
bochs_argv = (char **) &argv[2];
}
// process options to bochs framework
for (; i<argc; i++) {
if (strcmp(argv[i], "-sim1") == 0) {
break;
}
else if (strcmp(argv[i], "-sim2") == 0) {
break;
}
bochs_argc++;
}
if (i<argc) { // more args to process
// process options to each CPU simulator
if (strcmp(argv[i], "-sim1") == 0) {
process_sim1:
sim1_argv = (char **) &argv[i];
i++;
for (; i<argc; i++) {
if (strcmp(argv[i], "-sim2") == 0)
goto process_sim2;
sim1_argc++;
}
}
else if (strcmp(argv[i], "-sim2") == 0) {
process_sim2:
sim2_argv = (char **) &argv[i];
i++;
for (; i<argc; i++) {
if (strcmp(argv[i], "-sim1") == 0)
goto process_sim1;
sim2_argc++;
}
}
}
bx_infile_stack_index = 0;
bx_infile_stack[0].fp = stdin;
strncpy(bx_infile_stack[0].fname, argv[0], BX_MAX_PATH);
bx_infile_stack[0].fname[BX_MAX_PATH-1] = 0;
bx_infile_stack[0].lineno = 0;
if (bx_debug_rc_fname[0] == '\0') {
BX_INFO(("Warning: no rc file specified.", argv[0]));
}
else {
BX_INFO (("%s: using rc file '%s'.", argv[0], bx_debug_rc_fname));
// if there's an error, the user will know about it before proceeding
(void) bx_nest_infile(bx_debug_rc_fname);
}
#if BX_DISASM
memset(bx_disasm_ibuf, 0, sizeof(bx_disasm_ibuf));
#endif
BX_SIM1_INIT(&bx_dbg_callback[0], sim1_argc, sim1_argv);
#if BX_NUM_SIMULATORS > 1
BX_SIM2_INIT(&bx_dbg_callback[1], sim2_argc, sim2_argv);
#endif
// parse any remaining args in the usual way
bx_parse_cmdline (1, bochs_argc, bochs_argv);
// initialize hardware
bx_init_hardware();
#if BX_NUM_SIMULATORS >= 2
bx_debugger.compare_at_sync.cpu = 0;
bx_debugger.compare_at_sync.memory = 0;
#endif
// call init routines for each CPU+mem simulator
// initialize for SMP. one memory, multiple processors.
#if BX_NUM_SIMULATORS > 1
#error cosimulation not supported until SMP stuff settles
BX_MEM(1) = new BX_MEM_C ();
BX_CPU(1) = new BX_CPU_C (BX_MEM(1));
BX_CPU(1)->reset(BX_RESET_HARDWARE);
BX_MEM(1)->init_memory(bx_options.memory.Osize->get () * 1024*1024);
BX_MEM(1)->load_ROM(bx_options.rom.path->getptr (), bx_options.rom.address->get ());
BX_MEM(1)->load_ROM(bx_options.vgarom.path->getptr (), 0xc0000);
#endif
// (mch) Moved from main.cc
bx_devices.init(BX_MEM(0));
bx_devices.reset();
SIM->set_init_done (1);
bx_gui.init_signal_handlers ();
bx_pc_system.start_timers();
// setup Ctrl-C handler
signal(SIGINT, bx_debug_ctrlc_handler);
// Print disassembly of the first instruction... you wouldn't think it
// would have to be so hard. First initialize guard_found, since it is used
// in the disassembly code to decide what instruction to print.
for (i=0; i<BX_SMP_PROCESSORS; i++) {
BX_CPU(i)->guard_found.cs =
BX_CPU(i)->sregs[BX_SEG_REG_CS].selector.value;
BX_CPU(i)->guard_found.eip =
BX_CPU(i)->prev_eip;
BX_CPU(i)->guard_found.laddr =
BX_CPU(i)->sregs[BX_SEG_REG_CS].cache.u.segment.base
+ BX_CPU(i)->prev_eip;
BX_CPU(i)->guard_found.is_32bit_code =
BX_CPU(i)->sregs[BX_SEG_REG_CS].cache.u.segment.d_b;
}
// finally, call the usual function to print the disassembly
fprintf (stderr, "Next at t=%lld\n", bx_pc_system.time_ticks ());
bx_dbg_disassemble_current (-1, 0); // all cpus, don't print time
bx_dbg_user_input_loop();
bx_dbg_exit(0);
return(0); // keep compiler happy
}
void
bx_dbg_usage(void)
{
fprintf (stderr, "usage: %s [-rc path] [-sim1 ... ] [-sim2 ... ]\n", argv0);
}
void
bx_dbg_user_input_loop(void)
{
int reti;
unsigned include_cmd_len = strlen(BX_INCLUDE_CMD);
while ( 1 ) {
bx_get_command();
if ( (*tmp_buf_ptr == '\n') || (*tmp_buf_ptr == 0) ) {
if (bx_infile_stack_index == 0)
fprintf(stderr, "\n");
}
else if ( (strncmp(tmp_buf_ptr, BX_INCLUDE_CMD, include_cmd_len) == 0) &&
(tmp_buf_ptr[include_cmd_len] == ' ' ||
tmp_buf_ptr[include_cmd_len] == '\t') ) {
char *ptr;
int len;
ptr = tmp_buf_ptr + include_cmd_len+1;
while ( *ptr==' ' || *ptr=='\t' )
ptr++;
len = strlen(ptr);
if (len == 0) {
fprintf(stderr, "%s: no filename given to 'source' command.\n", argv0);
if (bx_infile_stack_index > 0) {
fprintf(stderr, "%s: ERROR in source file causes exit.\n", argv0);
bx_dbg_exit(1);
}
continue;
}
ptr[len-1] = 0; // get rid of newline
reti = bx_nest_infile(ptr);
if ((reti==0) && (bx_infile_stack_index > 0)) {
fprintf(stderr, "%s: ERROR in source file causes exit.\n", argv0);
bx_dbg_exit(1);
}
}
else {
// Give a chance to the command line extensions, to
// consume the command. If they return 0, then
// we need to process the command. A return of 1
// means, the extensions have handled the command
if ( bx_dbg_extensions(tmp_buf_ptr)==0 ) {
// process command here
bx_add_lex_input(tmp_buf_ptr);
bxparse();
}
}
}
}
void
bx_get_command(void)
{
char *charptr_ret;
bx_infile_stack[bx_infile_stack_index].lineno++;
char prompt[256];
if (bx_infile_stack_index == 0) {
sprintf(prompt, "<bochs:%d> ", bx_infile_stack[bx_infile_stack_index].lineno);
}
#if HAVE_LIBREADLINE
if (bx_infile_stack_index == 0) {
charptr_ret = readline (prompt);
2001-05-23 12:27:10 +04:00
// beware, returns NULL on end of file
if (charptr_ret && strlen(charptr_ret) > 0) {
add_history (charptr_ret);
strcpy (tmp_buf, charptr_ret);
strcat (tmp_buf, "\n");
free (charptr_ret);
charptr_ret = &tmp_buf[0];
}
} else {
charptr_ret = fgets(tmp_buf, 512,
bx_infile_stack[bx_infile_stack_index].fp);
}
#else
if (bx_infile_stack_index == 0)
fprintf (stderr, "%s", prompt);
charptr_ret = fgets(tmp_buf, 512,
bx_infile_stack[bx_infile_stack_index].fp);
#endif
if (charptr_ret == NULL) {
// see if error was due to EOF condition
if (feof(bx_infile_stack[bx_infile_stack_index].fp)) {
if (bx_infile_stack_index > 0) {
// nested level of include files, pop back to previous one
bx_unnest_infile();
}
else {
// not nested, sitting at stdin prompt, user wants out
bx_dbg_quit_command();
}
// call recursively
bx_get_command();
return;
}
// error was not EOF, see if it was from a Ctrl-C
if (bx_guard.interrupt_requested) {
tmp_buf[0] = '\n';
tmp_buf[1] = 0;
tmp_buf_ptr = &tmp_buf[0];
bx_guard.interrupt_requested = 0;
return;
}
fprintf(stderr, "fgets() returned ERROR.\n");
fprintf(stderr, "intr request was %u\n", bx_guard.interrupt_requested);
bx_dbg_exit(1);
}
tmp_buf_ptr = &tmp_buf[0];
// look for first non-whitespace character
while ( ((*tmp_buf_ptr == ' ') || (*tmp_buf_ptr == '\t')) &&
(*tmp_buf_ptr != '\n') && (*tmp_buf_ptr != 0) ) {
tmp_buf_ptr++;
}
return;
}
int
bx_nest_infile(char *path)
{
FILE *tmp_fp;
tmp_fp = fopen(path, "r");
if (!tmp_fp) {
fprintf(stderr, "%s: can not open file '%s' for reading.\n",
argv0, path);
return(0);
}
if ( (bx_infile_stack_index+1) >= BX_INFILE_DEPTH ) {
fprintf(stderr, "%s: source files nested too deeply\n", argv0);
return(0);
}
bx_infile_stack_index++;
bx_infile_stack[bx_infile_stack_index].fp = tmp_fp;
strncpy(bx_infile_stack[bx_infile_stack_index].fname, path, BX_MAX_PATH);
bx_infile_stack[bx_infile_stack_index].fname[BX_MAX_PATH-1] = 0;
bx_infile_stack[bx_infile_stack_index].lineno = 0;
return(1);
}
void
bx_unnest_infile(void)
{
if (bx_infile_stack_index <= 0) {
fprintf(stderr, "%s: ERROR: unnest_infile(): nesting level = 0.\n",
argv0);
bx_dbg_exit(1);
}
fclose(bx_infile_stack[bx_infile_stack_index].fp);
bx_infile_stack_index--;
}
int
bxwrap(void)
{
fprintf(stderr, "%s: ERROR: bxwrap() called.\n", argv0);
bx_dbg_exit(1);
return(0); // keep compiler quiet
}
void
bxerror(char *s)
{
fprintf(stderr, "%s:%d: %s at '%s'\n",
bx_infile_stack[bx_infile_stack_index].fname,
bx_infile_stack[bx_infile_stack_index].lineno,
s, bxtext);
if (bx_infile_stack_index > 0) {
fprintf(stderr, "%s: ERROR in source file causes exit.\n", argv0);
bx_dbg_exit(1);
}
}
void
bx_debug_ctrlc_handler(int signum)
{
UNUSED(signum);
BX_INFO(("Ctrl-C detected in signal handler."));
signal(SIGINT, bx_debug_ctrlc_handler);
bx_guard.interrupt_requested = 1;
}
void
bx_dbg_exit(int code)
{
BX_DEBUG(( "dbg: before sim1_exit" ));
for (int cpu=0; cpu < BX_SMP_PROCESSORS; cpu++) {
2001-05-29 18:28:38 +04:00
if (BX_CPU(cpu)) BX_CPU(cpu)->atexit();
}
#if BX_NUM_SIMULATORS >= 2
fprintf(stderr, "before sim2_exit\n");
2001-05-29 18:28:38 +04:00
if (BX_CPU(1)) BX_CPU(1)->atexit();
#endif
bx_atexit();
exit(code);
}
//
// comands invoked from parser
//
void
bx_dbg_quit_command(void)
{
BX_INFO(("dbg: Quit"));
bx_dbg_exit(0);
}
void
bx_dbg_trace_on_command(void)
{
BX_CPU(dbg_cpu)->trace = 1;
fprintf (stderr, "Tracing enabled for %s\n", BX_CPU(dbg_cpu)->name);
}
void
bx_dbg_trace_off_command(void)
{
BX_CPU(dbg_cpu)->trace = 0;
fprintf (stderr, "Tracing disabled for %s\n", BX_CPU(dbg_cpu)->name);
}
void
bx_dbg_trace_reg_on_command(void)
{
BX_CPU(dbg_cpu)->trace_reg = 1;
fprintf (stderr, "Register-Tracing enabled for %s\n", BX_CPU(dbg_cpu)->name);
}
void
bx_dbg_trace_reg_off_command(void)
{
BX_CPU(dbg_cpu)->trace_reg = 0;
fprintf (stderr, "Register-Tracing disabled for %s\n", BX_CPU(dbg_cpu)->name);
}
void
bx_dbg_ptime_command(void)
{
fprintf(stderr, "ptime: %lld\n", bx_pc_system.time_ticks());
#if BX_NUM_SIMULATORS >= 2
fprintf(stderr,
#if BX_DBG_ICOUNT_SIZE == 32
"Last synchronized icount was %lu\n",
(unsigned long) bx_debugger.last_sync_icount
#else // BX_DBG_ICOUNT_SIZE == 64
"Last synchronized icount was %Lu\n",
(unsigned long long) bx_debugger.last_sync_icount
#endif /* BX_DBG_ICOUNT_SIZE == 32 */
);
#endif /* BX_NUM_SIMULATORS >= 2 */
}
int timebp_timer = -1;
Bit64u timebp_queue[MAX_CONCURRENT_BPS];
int timebp_queue_size = 0;
void
bx_dbg_timebp_command(Boolean absolute, Bit64u time)
{
Bit64u diff = (absolute) ? time - bx_pc_system.time_ticks() : time;
Bit64u abs_time = (absolute) ? time : time + bx_pc_system.time_ticks();
if (diff < 0) {
fprintf(stderr, "Request for time break point in the past. I can't let you do that.\n");
return;
}
if (timebp_queue_size == MAX_CONCURRENT_BPS) {
fprintf(stderr, "Too many time break points\n");
return;
}
if (timebp_timer >= 0) {
if (timebp_queue_size == 0 || abs_time < timebp_queue[0]) {
/* first in queue */
for (int i = timebp_queue_size; i >= 0; i--)
timebp_queue[i+1] = timebp_queue[i];
timebp_queue[0] = abs_time;
timebp_queue_size++;
bx_pc_system.activate_timer_ticks(timebp_timer, diff, 1);
} else {
/* not first, insert at suitable place */
for (int i = 1; i < timebp_queue_size; i++) {
if (timebp_queue[i] == abs_time) {
fprintf(stderr, "Time breakpoint not inserted (duplicate)\n");
return;
} else if (abs_time < timebp_queue[i]) {
for (int j = timebp_queue_size; j >= i; j++)
timebp_queue[j+1] = timebp_queue[j];
timebp_queue[i] = abs_time;
goto inserted;
}
}
/* last */
timebp_queue[timebp_queue_size] = abs_time;
inserted:
timebp_queue_size++;
}
} else {
timebp_queue_size = 1;
timebp_queue[0] = abs_time;
timebp_timer = bx_pc_system.register_timer_ticks(&bx_pc_system, bx_pc_system_c::timebp_handler, diff, 0, 1);
}
fprintf(stderr, "Time breakpoint inserted. Delta = %d\n", diff);
}
void
bx_dbg_diff_memory(void)
{
#if BX_NUM_SIMULATORS < 2
printf("diff-memory supported only in cosimulation mode\n");
#else
int num_pages = bx_options.memory.Osize->get () * 1024 / 4;
for (int i = 0; i < num_pages; i++) {
BX_CPU(dbg_cpu)->dbg_dirty_pages[i] = 1;
}
if (bx_dbg_compare_sim_memory())
printf("[diff-memory] Diff detected\n");
else
printf("[diff-memory] No diff detected\n");
#endif /* NUM_SIMULATORS < 2 */
}
void
bx_dbg_sync_memory(Boolean set)
{
#if BX_NUM_SIMULATORS < 2
printf("sync-memory supported only in cosimulation mode\n");
#else
bx_debugger.compare_at_sync.memory = set;
printf("Memory sync %s\n", (set) ? "enabled" : "disabled");
#endif
}
void
bx_dbg_sync_cpu(Boolean set)
{
#if BX_NUM_SIMULATORS < 2
printf("sync-cpu supported only in cosimulation mode\n");
#else
bx_debugger.compare_at_sync.cpu = set;
printf("Register file sync %s\n", (set) ? "enabled" : "disabled");
#endif
}
void
bx_dbg_fast_forward(Bit32u num)
{
#if BX_NUM_SIMULATORS < 2
printf("fast-forward supported only in cosimulation mode\n");
#else
printf("Entering fast-forward mode\n");
// Bit32u save_icount_quantum = bx_debugger.icount_quantum;
// bx_debugger.icount_quantum = num;
bx_guard.interrupt_requested = 0;
bx_debugger.fast_forward_mode = 1;
for (Bit32u e = 0; e < num; e += bx_debugger.icount_quantum)
if (!bx_dbg_cosimulateN(bx_debugger.icount_quantum))
break;
bx_debugger.fast_forward_mode = 0;
// bx_debugger.icount_quantum = save_icount_quantum;
bx_vga.timer_handler(&bx_vga);
printf("Copying CPU...\n");
bx_dbg_cpu_t cpu;
if (!BX_CPU(0)->dbg_get_cpu(&cpu) || !BX_CPU(1)->dbg_set_cpu(&cpu))
printf("Error copying CPU data!\n");
printf("Copying memory...\n");
int num_pages = bx_options.memory.Osize->get () * 1024 / 4;
for (int i = 0; i < num_pages; i++) {
if (BX_CPU(0)->dbg_dirty_pages[i]) {
Bit32u page_start = i * 1024 * 4;
printf("Copying page %08x\n", page_start);
extern Bit8u* SIM1_GET_PHYS_PTR(Bit32u page_start);
Bit8u* sim0_page_vec = bx_mem0.vector + page_start;
Bit8u* sim1_page_vec = SIM1_GET_PHYS_PTR(page_start);
memcpy(sim1_page_vec, sim0_page_vec, 1024 * 4);
}
}
printf("Taking async events...\n");
printf("Exiting fast-forward mode\n");
#endif
}
static Bit32u
conv_4xBit8u_to_Bit32u (Bit8u* buf)
{
Bit32u ret = 0;
for (int i = 0; i < 4; i++) {
ret |= (buf[i] << (8 * i));
}
return ret;
}
/*
(mch) Print various info for logical address.
*/
void
bx_dbg_info_address(Bit32u seg_reg_num, Bit32u offset)
{
#if BX_NUM_SIMULATORS < 2
printf("addr-info only supported in cosim configuration.\n");
#else
for (int sim = 0; sim < 2; sim++)
{
/* Find page table base address */
bx_dbg_cpu_t regs;
BX_CPU(sim)->dbg_get_cpu(&regs);
Bit32u base = regs.cr3 & ~0xfff;
Bit8u buf[4];
Bit32u directory_addr = base + (offset >> 22) * 4;
Bit32u directory;
if (BX_CPU(sim)->mem->dbg_fetch_mem(directory_addr, 4, buf)) {
directory = conv_4xBit8u_to_Bit32u(buf);
Bit32u table_addr = (directory & ~0xfff) + ((offset >> 12) & 0x3ff) * 4;
Bit32u table;
printf("[%s] ", SIM_NAME(sim));
printf("PDE: %08x (", directory);
printf("%s, %s, %s, %s, %s)",
(directory & 1) ? "Present" : "Not present",
(directory & 2) ? "Read/Write" : "Read-only",
(directory & 4) ? "User" : "Supervisor",
(directory & (1 << 5)) ? "Accessed" : "-",
(directory & (1 << 6)) ? "Dirty" : "-");
if (directory & 1) {
if (BX_CPU(sim)->mem->dbg_fetch_mem(table_addr, 4, buf)) {
table = conv_4xBit8u_to_Bit32u(buf);
printf(", PTE: %08x (", table);
printf("%s, %s, %s, %s, %s)\n",
(table & 1) ? "Present" : "Not present",
(table & 2) ? "Read/Write" : "Read-only",
(table & 4) ? "User" : "Supervisor",
(table & (1 << 5)) ? "Accessed" : "-",
(table & (1 << 6)) ? "Dirty" : "-");
} else {
printf("[%s] Could not read from physical address %08x\n",
SIM_NAME(sim), directory_addr);
return;
}
} else {
printf("\n");
}
} else {
printf("[%s] Could not read from physical address %08x\n",
SIM_NAME(sim), directory_addr);
return;
}
}
#endif
}
void
bx_dbg_record_command(char* path_quoted)
{
// skip beginning double quote
if (path_quoted[0] == '"')
path_quoted++;
// null out ending quote
int len = strlen(path_quoted);
if (path_quoted[len - 1] == '"')
path_quoted[len - 1] = '\0';
bx_dbg.record_io = fopen(path_quoted, "w");
if (bx_dbg.record_io)
fprintf(stderr, "IO record file '%s' opened\n", path_quoted);
else
fprintf(stderr, "Error opening '%s' for writing\n", path_quoted);
}
static FILE* playback_file = 0;
struct playback_entry_t
{
char command[100];
Bit32u argument;
void trigger ();
};
static playback_entry_t playback_entry;
static Bit64u last_playback_time = 0;
static int playback_timer_index = -1;
void
bx_dbg_playback_command(char* path_quoted)
{
// skip beginning double quote
if (path_quoted[0] == '"')
path_quoted++;
// null out ending quote
int len = strlen(path_quoted);
if (path_quoted[len - 1] == '"')
path_quoted[len - 1] = '\0';
playback_file = fopen(path_quoted, "r");
if (playback_file) {
fprintf(stderr, "Playback from '%s'\n", path_quoted);
last_playback_time = 0;
fprintf(stderr, "playback times relative from %lld\n", bx_pc_system.time_ticks());
enter_playback_entry();
} else
fprintf(stderr, "Error opening '%s' for reading\n", path_quoted);
}
// BW added. toggles vm86 mode switch breakpoint
//dummy not used and may be null
void
bx_dbg_modebp_command(char* dummy)
{
BX_CPU(dbg_cpu)->debug_vm == BX_CPU(dbg_cpu)->eflags.vm;
BX_CPU(dbg_cpu)->mode_break = !BX_CPU(dbg_cpu)->mode_break;
fprintf(stderr," mode switch break %s\n",
BX_CPU(dbg_cpu)->mode_break ? "enabled" : "disabled");
}
// where
// stack trace: ebp -> old ebp
// return eip at ebp + 4
void
bx_dbg_where_command()
{
if (!BX_CPU(dbg_cpu)->protected_mode()) {
fprintf(stderr, "'where' only supported in protected mode\n");
return;
}
if (BX_CPU(dbg_cpu)->sregs[BX_SREG_SS].cache.u.segment.base != 0) {
fprintf(stderr, "non-zero stack base\n");
return;
}
Bit32u bp = EBP;
Bit32u ip = EIP;
fprintf(stderr, "(%d) 0x%08x\n", 0, ip);
for (int i = 1; i < 50; i++) {
// Up
Boolean paddr_valid;
Bit32u paddr;
Bit8u buf[4];
// bp = [bp];
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(bp, &paddr, &paddr_valid);
if (paddr_valid) {
if (BX_MEM(0)->dbg_fetch_mem(paddr, 4, buf)) {
bp = conv_4xBit8u_to_Bit32u(buf);
} else {
fprintf(stderr, "(%d) Physical memory read error (BP)\n", i);
break;
}
} else {
fprintf(stderr, "(%d) Could not translate linear address (BP)\n", i);
break;
}
// ip = [bp + 4];
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(bp + 4, &paddr, &paddr_valid);
if (paddr_valid) {
if (BX_MEM(0)->dbg_fetch_mem(paddr, 4, buf)) {
ip = conv_4xBit8u_to_Bit32u(buf);
} else {
fprintf(stderr, "(%d) Physical memory read error (IP)\n", i);
break;
}
} else {
fprintf(stderr, "(%d) Could not translate linear address (IP)\n", i);
break;
}
// Print
fprintf(stderr, "(%d) 0x%08x\n", i, ip);
}
}
void
bx_dbg_print_string_command(Bit32u start_addr)
{
fprintf(stderr, "0x%08x: ", start_addr);
for (int i = 0; ; i++) {
Bit32u paddr;
Bit32u paddr_valid;
Bit8u buf[1];
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(start_addr+i, &paddr, &paddr_valid);
if (paddr_valid) {
if (BX_MEM(0)->dbg_fetch_mem(paddr, 1, buf)) {
if (buf[0] == 0)
break;
if (isgraph(buf[0]) || buf[0] == 0x20)
fprintf(stderr, "%c", buf[0]);
else
fprintf(stderr, "\\%d", buf[0]);
} else {
fprintf(stderr, "<read error>");
break;
}
} else {
fprintf(stderr, "<no translation>");
break;
}
}
fprintf(stderr, "\n");
}
static Bit32u last_cr3;
static int last_pe = 0;
static int last_vm = 0;
unsigned int dbg_show_mask = 0;
// 0x80 print mode
// 0x40 print interrupts
// 0x20 print calls
//BW added. toggles show symbolic info (calls to begin with)
// 0x1 call
// 0x2 return
// 0x4 int
// 0x8 iret
// 0x10 interrupts (includes iret)
static void dbg_dump_table(Boolean);
void bx_dbg_show_command(char* arg)
{
if(arg) {
if (!strcmp(arg,"\"mode\"")){
dbg_show_mask = 0x80;
} else if (!strcmp(arg,"\"int\"")){
dbg_show_mask = 0xc0;
} else if(!strcmp(arg,"\"call\"")){
dbg_show_mask = 0xe0;
} else if(!strcmp(arg,"\"ret\"")){
dbg_show_mask = 0xe0;
} else if(!strcmp(arg,"\"off\"")){
dbg_show_mask = 0x0;
} else if(!strcmp(arg,"\"tab\"")){
dbg_dump_table(1);
return;
} else if(!strcmp(arg,"\"c\"")){
dbg_dump_table(0);
return;
} else if(!strcmp(arg,"\"dbg-all\"")){
bx_dbg.floppy = 1;
bx_dbg.keyboard = 1;
bx_dbg.video = 1;
bx_dbg.disk = 1;
bx_dbg.pit = 1;
bx_dbg.pic = 1;
bx_dbg.bios = 1;
bx_dbg.cmos = 1;
bx_dbg.a20 = 1;
bx_dbg.interrupts = 1;
bx_dbg.exceptions = 1;
bx_dbg.unsupported = 1;
bx_dbg.temp = 1;
bx_dbg.reset = 1;
bx_dbg.mouse = 1;
bx_dbg.io = 1;
bx_dbg.debugger = 1;
bx_dbg.xms = 1;
bx_dbg.v8086 = 1;
bx_dbg.paging = 1;
bx_dbg.creg = 1;
bx_dbg.dreg = 1;
bx_dbg.dma = 1;
bx_dbg.unsupported_io = 1;
/* bx_dbg.record_io = 1; this is a pointer .. somewhere */
printf("Turned on all bx_dbg flags\n");
return;
} else if(!strcmp(arg,"\"none\"")){
bx_dbg.floppy = 0;
bx_dbg.keyboard = 0;
bx_dbg.video = 0;
bx_dbg.disk = 0;
bx_dbg.pit = 0;
bx_dbg.pic = 0;
bx_dbg.bios = 0;
bx_dbg.cmos = 0;
bx_dbg.a20 = 0;
bx_dbg.interrupts = 0;
bx_dbg.exceptions = 0;
bx_dbg.unsupported = 0;
bx_dbg.temp = 0;
bx_dbg.reset = 0;
bx_dbg.mouse = 0;
bx_dbg.io = 0;
bx_dbg.debugger = 0;
bx_dbg.xms = 0;
bx_dbg.v8086 = 0;
bx_dbg.paging = 0;
bx_dbg.creg = 0;
bx_dbg.dreg = 0;
bx_dbg.dma = 0;
bx_dbg.unsupported_io = 0;
/* bx_dbg.record_io = 0; this is a pointer .. somewhere */
printf("Turned off all bx_dbg flags\n");
return;
} else if(!strcmp(arg,"\"vga\"")){
bx_vga.timer ();
return;
} else {
printf("Unrecognized arg: %s ('mode' 'int' 'call' 'ret' 'dbg-all' are valid)\n",arg);
return;
}
} else {
fprintf(stderr," show mask is 0x%x\n", dbg_show_mask);
return;
}
// enable trace if any print is active
if(dbg_show_mask & 0xe0)
dbg_show_mask |= 0x1f;
fprintf(stderr," show mask is 0x%x, cleared show_flag\n", dbg_show_mask);
BX_CPU(dbg_cpu)->show_flag = 0;
last_cr3 = BX_CPU(dbg_cpu)->cr3;
last_pe = BX_CPU(dbg_cpu)->cr0.pe;
last_vm = BX_CPU(dbg_cpu)->eflags.vm;
fprintf(stderr,"%10lld: address %04x:%08x %08x\n\n",
bx_pc_system.time_ticks(),
BX_CPU(dbg_cpu)->guard_found.cs,
BX_CPU(dbg_cpu)->guard_found.eip,
BX_CPU(dbg_cpu)->guard_found.laddr);
}
void
playback_function(void* this_ptr)
{
((playback_entry_t*)this_ptr)->trigger();
}
void
enter_playback_entry()
{
static const int playback_buf_size = 100;
char playback_buf[playback_buf_size];
if (!fgets(playback_buf, playback_buf_size, playback_file))
return;
Bit64u time;
Bit32u argument;
if (sscanf(playback_buf, "%s %lld %x", playback_entry.command, &time, &playback_entry.argument) != 3) {
fprintf(stderr, "Parse error in playback string '%s'\n", playback_buf);
return;
}
Bit64u diff = time - last_playback_time;
last_playback_time = time;
if (diff < 0) {
BX_PANIC(("Negative diff in playback"));
} else if (diff == 0) {
playback_entry.trigger();
} else {
if (playback_timer_index >= 0)
bx_pc_system.activate_timer_ticks(playback_timer_index, diff, 0);
else
playback_timer_index = bx_pc_system.register_timer_ticks(&playback_entry, playback_function, diff, 0, 1);
}
}
void
playback_entry_t::trigger ()
{
if (!strcmp("gen_scancode", command)) {
bx_devices.keyboard->gen_scancode(argument);
} else {
fprintf(stderr, "Unknown playback command '%s'\n", command);
return;
}
enter_playback_entry();
}
void
bx_dbg_print_stack_command(int nwords)
{
// Get linear address for stack top
Bit32u sp = (BX_CPU(dbg_cpu)->sregs[BX_SREG_SS].cache.u.segment.d_b) ? ESP : SP;
Bit32u linear_sp = sp + BX_CPU(dbg_cpu)->sregs[BX_SREG_SS].cache.u.segment.base;
Bit8u buf[8];
for (int i = 0; i < nwords; i++) {
Bit32u paddr;
Boolean paddr_valid;
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(sp, &paddr, &paddr_valid);
if (paddr_valid) {
if (BX_MEM(0)->dbg_fetch_mem(paddr, 2, buf))
fprintf(stderr, " %08x [%08x] %04x\n", linear_sp, paddr, (int)buf[0] | ((int)buf[1] << 8));
else
fprintf(stderr, " %08x [%08x] <read error>\n", paddr, linear_sp);
} else {
fprintf(stderr, " %08x <could not translate>\n", linear_sp);
}
sp += 2;
linear_sp += 2;
}
}
#if !BX_HAVE_HASH_MAP
static char *BX_HAVE_HASH_MAP_ERR = "context not implemented because BX_HAVE_HASH_MAP=0\n";
char*
bx_dbg_symbolic_address(Bit32u context, Bit32u eip, Bit32u base)
{
static Boolean first = true;
if (first) {
fprintf (stderr, BX_HAVE_HASH_MAP_ERR);
first = false;
}
return "unknown context";
}
void
bx_dbg_symbol_command(char* filename, Boolean global, Bit32u offset)
{
fprintf (stderr, BX_HAVE_HASH_MAP_ERR);
}
#else /* if BX_HAVE_HASH_MAP == 1 */
/* Haven't figured out how to port this code to OSF1 cxx compiler.
Until a more portable solution is found, at least make it easy
to disable the template code: just set BX_HAVE_HASH_MAP=0
in config.h */
#include <hash_map.h>
#include <set.h>
struct symbol_entry_t
{
symbol_entry_t (Bit32u _start = 0, char* _name = 0)
{
start = _start;
name = _name;
}
char* name;
Bit32u start;
};
struct lt_symbol_entry_t
{
bool operator()(const symbol_entry_t* s1, const symbol_entry_t* s2) const
{
return s1->start < s2->start;
}
};
struct context_t
{
context_t (Bit32u);
static context_t* get_context(Bit32u);
symbol_entry_t* get_symbol_entry(Bit32u);
void add_symbol(symbol_entry_t*);
private:
static hash_map<int,context_t*>* map;
set<symbol_entry_t*,lt_symbol_entry_t>* syms;
Bit32u id;
};
hash_map<int,context_t*>* context_t::map = new hash_map<int,context_t*>;
context_t::context_t (Bit32u _id)
{
id = _id;
syms = new set<symbol_entry_t*, lt_symbol_entry_t>;
(*map)[id] = this;
}
context_t*
context_t::get_context(Bit32u i)
{
return (*map)[i];
}
symbol_entry_t*
context_t::get_symbol_entry(Bit32u ip)
{
symbol_entry_t probe;
probe.start = ip;
// find the first symbol whose address is greater than ip.
if (syms->empty ()) return 0;
set<symbol_entry_t*>::iterator iter = syms->upper_bound(&probe);
if (iter == syms->end()) {
// return the last symbol
return *iter;
} else if (iter == syms->begin()) {
// ip is before the first symbol. Return no symbol.
return 0;
} else {
// return previous symbol, so that the reported address is
// prev_symbol+offset.
iter--;
return *iter;
}
}
void
context_t::add_symbol(symbol_entry_t* sym)
{
syms->insert(sym);
}
char*
bx_dbg_symbolic_address(Bit32u context, Bit32u eip, Bit32u base)
{
static char buf[80];
#if 0
// bbd: I don't see why we shouldn't allow symbol lookups on
// segments with a nonzero base. I need to trace user
// processes in Linux, which have a base of 0xc0000000.
if (base != 0) {
snprintf (buf, 80, "non-zero base");
return buf;
}
#endif
// Look up this context
context_t* cntx = context_t::get_context(context);
if (!cntx) {
// Try global context
cntx = context_t::get_context(0);
if (!cntx) {
snprintf (buf, 80, "unknown context");
return buf;
}
}
symbol_entry_t* entr = cntx->get_symbol_entry(eip);
if (!entr) {
snprintf (buf, 80, "no symbol");
return buf;
}
snprintf (buf, 80, "%s+%x", entr->name, eip - entr->start);
return buf;
}
char*
bx_dbg_symbolic_address_16bit(Bit32u eip, Bit32u cs)
{
// in 16-bit code, the segment selector and offset are combined into a
// 20-bit linear address = (segment selector<<4) + offset.
eip &= 0xffff;
cs &= 0xffff;
return bx_dbg_symbolic_address (0, eip+(cs<<4), 0);
}
void
bx_dbg_symbol_command(char* filename, Boolean global, Bit32u offset)
{
if (filename[0] == '"')
filename++;
int len = strlen(filename);
if (filename[len - 1] == '"')
filename[len - 1] = '\0';
// Install symbols in correct context (page table)
// The file format should be
// address symbol (example '00002afe _StartLoseNT')
context_t* cntx = (global)
? context_t::get_context(0)
: context_t::get_context((BX_CPU(dbg_cpu)->cr3) >> 12);
if (!cntx)
cntx = (global)
? new context_t(0)
: new context_t((BX_CPU(dbg_cpu)->cr3) >> 12);
FILE* fp = fopen(filename, "r");
if (!fp) {
fprintf(stderr, "Could not open symbol file '%s'\n", filename);
return;
}
char buf[200];
while (fgets(buf, 200, fp)) {
// Parse
char* sym_name = buf;
for (int i = 0; i < 200 && buf[i]; i++) {
if (buf[i] == ' ') {
buf[i] = '\0';
sym_name = buf + i + 1;
break;
}
}
if (sym_name == buf) {
fprintf(stderr, "Syntax error '%s'\n", buf);
break;
}
Bit32u addr = strtoul(buf, 0, 16);
if (sym_name[strlen(sym_name)-1] == '\n')
sym_name[strlen(sym_name)-1] = '\0';
symbol_entry_t* sym = new symbol_entry_t(addr + offset, strdup(sym_name));
cntx->add_symbol(sym);
}
}
#endif
int num_write_watchpoints = 0;
int num_read_watchpoints = 0;
Bit32u write_watchpoint[MAX_WRITE_WATCHPOINTS];
Bit32u read_watchpoint[MAX_READ_WATCHPOINTS];
Boolean watchpoint_continue = 0;
void
bx_dbg_watch(int read, Bit32u address)
{
if (read == -1) {
// print watch point info
int i;
for (i = 0; i < num_read_watchpoints; i++) {
Bit8u buf[2];
if (BX_MEM(0)->dbg_fetch_mem(read_watchpoint[i], 2, buf))
fprintf(stderr, "read %08x (%04x)\n", read_watchpoint[i], (int)buf[0] | ((int)buf[1] << 8));
else
fprintf(stderr, "read %08x (read error)\n", read_watchpoint[i]);
}
for (i = 0; i < num_write_watchpoints; i++) {
Bit8u buf[2];
if (BX_MEM(0)->dbg_fetch_mem(write_watchpoint[i], 2, buf))
fprintf(stderr, "write %08x (%04x)\n", write_watchpoint[i], (int)buf[0] | ((int)buf[1] << 8));
else
fprintf(stderr, "write %08x (read error)\n", write_watchpoint[i]);
}
} else {
if (read) {
if (num_read_watchpoints == MAX_READ_WATCHPOINTS) {
fprintf(stderr, "Too many read watchpoints\n");
return;
}
read_watchpoint[num_read_watchpoints++] = address;
fprintf(stderr, "Read watchpoint at %08x inserted\n", address);
} else {
if (num_write_watchpoints == MAX_WRITE_WATCHPOINTS) {
fprintf(stderr, "Too many write watchpoints\n");
return;
}
write_watchpoint[num_write_watchpoints++] = address;
fprintf(stderr, "Write watchpoint at %08x inserted\n", address);
}
}
}
void
bx_dbg_unwatch(int read, Bit32u address)
{
if (read == -1) {
// unwatch all
num_read_watchpoints = num_write_watchpoints = 0;
fprintf(stderr, "All watchpoints removed\n");
} else {
if (read) {
fprintf(stderr, "Watchpoint remove not implemented\n");
} else {
fprintf(stderr, "Watchpoint remove not implemented\n");
}
}
}
void
bx_dbg_continue_command(void)
{
// continue executing, until a guard found
one_more:
#if BX_NUM_SIMULATORS >= 2
bx_guard.interrupt_requested = 0;
2002-03-12 12:16:41 +03:00
bx_guard.special_unwind_stack = 0;
while (1) {
if ( !bx_dbg_cosimulateN(bx_debugger.icount_quantum) )
break;
}
#else
bx_guard.icount = 0;
// I must guard for ICOUNT or one CPU could run forever without giving
// the others a chance.
bx_guard.guard_for |= BX_DBG_GUARD_ICOUNT;
bx_guard.guard_for |= BX_DBG_GUARD_CTRL_C; // stop on Ctrl-C
bx_guard.interrupt_requested = 0;
2002-03-12 12:16:41 +03:00
bx_guard.special_unwind_stack = 0;
int stop = 0;
int which = -1;
while (!stop) {
- my speed boost changes to main.cc and cpu.cc on June 5 were an improvement in performance, but I did not check the debugger carefully enough while testing them. Part of the performance gain in main.cc revision 1.33 and cpu.cc revision 1.9 was to allow bochs to stay in the cpu loop forever in a single processor simulation. (In a multiprocessor simulation it must quit the loop periodically to give the other procs a chance to simulate too. Cooperative multiprocessing?) In the process, I restored calls to BX_TICK in the cpu loop for 1-proc simulation only, and removed them from the outer loop. (See main.cc, since it was done right.) However I never made the equivalent change in the debugger code, so in the debugger, there were ticks coming from the cpu loop and then an equivalent number of ticks coming from the debugger code just outside the cpu loop. The result was, of course, that simulation time went at 2x the correct rate. This simulation time speedup was made even worse because the continue loop in the debugger would increment ticks by one quantum (5 at the time) no matter how many instructions had actually been executed. So in trace mode in particular, the way it was implemented before today, cpu loop would run only one instruction at a time and the simulation time would get incremented 1+5=6 times! One tick from the cpu loop, then 5 erroneous ticks from the continue loop. Anyway, much of this nonsense should be fixed now. For uniprocessor simulations, only the cpu loop does ticks (for best performance). For multiprocessor simulations, the cpu loop exits after one quantum and the code that calls the cpu loop gets to increment ticks instead.
2001-09-28 03:08:30 +04:00
// the quantum is an arbitrary number of cycles to run in each
// processor. In SMP mode, when this limit is reached, the
// cpu_loop exits so that another processor can be simulated
// for a few cycles. With a single processor, the quantum
// setting should have no effect, although a low setting does
// lead to poor performance because cpu_loop is returning and
// getting called again, over and over.
int quantum = 25;
int cpu;
for (cpu=0; cpu < BX_SMP_PROCESSORS; cpu++) {
BX_CPU(cpu)->guard_found.guard_found = 0;
BX_CPU(cpu)->guard_found.icount = 0;
bx_guard.icount = quantum;
BX_CPU(cpu)->cpu_loop (-1);
/// check out BX_CPU(cpu)->guard_found.icount
//fprintf (stderr, "dbg_cont: after cpu_loop guard_found.icount=%d\n", BX_CPU(cpu)->guard_found.icount);
// set stop flag if a guard found other than icount or halted
unsigned long found = BX_CPU(cpu)->guard_found.guard_found;
stop_reason_t reason = (stop_reason_t) BX_CPU(cpu)->stop_reason;
if (found & BX_DBG_GUARD_ICOUNT) {
// I expected this guard, don't stop
} else if (found!=0) {
stop = 1;
which = cpu;
} else if (reason != STOP_NO_REASON && reason != STOP_CPU_HALTED) {
stop = 1;
which = cpu;
}
// even if stop==1, finish cycling through all processors.
// "which" remembers which cpu set the stop flag. If multiple
// cpus set stop, too bad.
}
// increment time tick only after all processors have had their chance.
- my speed boost changes to main.cc and cpu.cc on June 5 were an improvement in performance, but I did not check the debugger carefully enough while testing them. Part of the performance gain in main.cc revision 1.33 and cpu.cc revision 1.9 was to allow bochs to stay in the cpu loop forever in a single processor simulation. (In a multiprocessor simulation it must quit the loop periodically to give the other procs a chance to simulate too. Cooperative multiprocessing?) In the process, I restored calls to BX_TICK in the cpu loop for 1-proc simulation only, and removed them from the outer loop. (See main.cc, since it was done right.) However I never made the equivalent change in the debugger code, so in the debugger, there were ticks coming from the cpu loop and then an equivalent number of ticks coming from the debugger code just outside the cpu loop. The result was, of course, that simulation time went at 2x the correct rate. This simulation time speedup was made even worse because the continue loop in the debugger would increment ticks by one quantum (5 at the time) no matter how many instructions had actually been executed. So in trace mode in particular, the way it was implemented before today, cpu loop would run only one instruction at a time and the simulation time would get incremented 1+5=6 times! One tick from the cpu loop, then 5 erroneous ticks from the continue loop. Anyway, much of this nonsense should be fixed now. For uniprocessor simulations, only the cpu loop does ticks (for best performance). For multiprocessor simulations, the cpu loop exits after one quantum and the code that calls the cpu loop gets to increment ticks instead.
2001-09-28 03:08:30 +04:00
#if BX_SMP_PROCESSORS==1
// all ticks are handled inside the cpu loop
#else
// We must tick by the number of instructions that were
// ACTUALLY executed, not the number that we asked it to
// execute. Even this is tricky with SMP because one might
// have hit a breakpoint, while others executed the whole
// quantum.
int max_executed = 0;
for (cpu=0; cpu<BX_SMP_PROCESSORS; cpu++) {
if (BX_CPU(cpu)->guard_found.icount > max_executed)
max_executed = BX_CPU(cpu)->guard_found.icount;
}
// potential deadlock if all processors are halted. Then
// max_executed will be 0, tick will be incremented by zero, and
// there will never be a timed event to wake them up. To avoid this,
// always tick by a minimum of 1.
if (max_executed < 1) max_executed=1;
- my speed boost changes to main.cc and cpu.cc on June 5 were an improvement in performance, but I did not check the debugger carefully enough while testing them. Part of the performance gain in main.cc revision 1.33 and cpu.cc revision 1.9 was to allow bochs to stay in the cpu loop forever in a single processor simulation. (In a multiprocessor simulation it must quit the loop periodically to give the other procs a chance to simulate too. Cooperative multiprocessing?) In the process, I restored calls to BX_TICK in the cpu loop for 1-proc simulation only, and removed them from the outer loop. (See main.cc, since it was done right.) However I never made the equivalent change in the debugger code, so in the debugger, there were ticks coming from the cpu loop and then an equivalent number of ticks coming from the debugger code just outside the cpu loop. The result was, of course, that simulation time went at 2x the correct rate. This simulation time speedup was made even worse because the continue loop in the debugger would increment ticks by one quantum (5 at the time) no matter how many instructions had actually been executed. So in trace mode in particular, the way it was implemented before today, cpu loop would run only one instruction at a time and the simulation time would get incremented 1+5=6 times! One tick from the cpu loop, then 5 erroneous ticks from the continue loop. Anyway, much of this nonsense should be fixed now. For uniprocessor simulations, only the cpu loop does ticks (for best performance). For multiprocessor simulations, the cpu loop exits after one quantum and the code that calls the cpu loop gets to increment ticks instead.
2001-09-28 03:08:30 +04:00
BX_TICKN(max_executed);
#endif /* BX_SMP_PROCESSORS>1 */
}
- my speed boost changes to main.cc and cpu.cc on June 5 were an improvement in performance, but I did not check the debugger carefully enough while testing them. Part of the performance gain in main.cc revision 1.33 and cpu.cc revision 1.9 was to allow bochs to stay in the cpu loop forever in a single processor simulation. (In a multiprocessor simulation it must quit the loop periodically to give the other procs a chance to simulate too. Cooperative multiprocessing?) In the process, I restored calls to BX_TICK in the cpu loop for 1-proc simulation only, and removed them from the outer loop. (See main.cc, since it was done right.) However I never made the equivalent change in the debugger code, so in the debugger, there were ticks coming from the cpu loop and then an equivalent number of ticks coming from the debugger code just outside the cpu loop. The result was, of course, that simulation time went at 2x the correct rate. This simulation time speedup was made even worse because the continue loop in the debugger would increment ticks by one quantum (5 at the time) no matter how many instructions had actually been executed. So in trace mode in particular, the way it was implemented before today, cpu loop would run only one instruction at a time and the simulation time would get incremented 1+5=6 times! One tick from the cpu loop, then 5 erroneous ticks from the continue loop. Anyway, much of this nonsense should be fixed now. For uniprocessor simulations, only the cpu loop does ticks (for best performance). For multiprocessor simulations, the cpu loop exits after one quantum and the code that calls the cpu loop gets to increment ticks instead.
2001-09-28 03:08:30 +04:00
#endif /* BX_NUM_SIMULATORS */
// (mch) hack
bx_vga.timer_handler(&bx_vga);
BX_INSTR_DEBUG_PROMPT();
bx_dbg_print_guard_results();
if (watchpoint_continue && (BX_CPU(which)->stop_reason == STOP_READ_WATCH_POINT ||
BX_CPU(which)->stop_reason == STOP_WRITE_WATCH_POINT))
goto one_more;
}
void
bx_dbg_stepN_command(bx_dbg_icount_t count)
{
if (count == 0) {
fprintf(stderr, "Error: stepN: count=0\n");
return;
}
#if BX_NUM_SIMULATORS >= 2
bx_guard.interrupt_requested = 0;
2002-03-12 12:16:41 +03:00
bx_guard.special_unwind_stack = 0;
bx_dbg_cosimulateN(count);
#else
// single CPU
bx_guard.guard_for |= BX_DBG_GUARD_ICOUNT; // looking for icount
bx_guard.guard_for |= BX_DBG_GUARD_CTRL_C; // or Ctrl-C
// for now, step each CPU one BX_DBG_DEFAULT_ICOUNT_QUANTUM at a time
//BX_INFO(("Stepping each CPU a total of %d cycles", count));
for (unsigned cycle=0; cycle < count; cycle++) {
for (unsigned cpu=0; cpu < BX_SMP_PROCESSORS; cpu++) {
//BX_INFO(("Stepping %s", BX_CPU(cpu)->name));
bx_guard.icount = 1;
bx_guard.interrupt_requested = 0;
BX_CPU(cpu)->guard_found.guard_found = 0;
BX_CPU(cpu)->guard_found.icount = 0;
BX_CPU(cpu)->cpu_loop(-1);
}
- my speed boost changes to main.cc and cpu.cc on June 5 were an improvement in performance, but I did not check the debugger carefully enough while testing them. Part of the performance gain in main.cc revision 1.33 and cpu.cc revision 1.9 was to allow bochs to stay in the cpu loop forever in a single processor simulation. (In a multiprocessor simulation it must quit the loop periodically to give the other procs a chance to simulate too. Cooperative multiprocessing?) In the process, I restored calls to BX_TICK in the cpu loop for 1-proc simulation only, and removed them from the outer loop. (See main.cc, since it was done right.) However I never made the equivalent change in the debugger code, so in the debugger, there were ticks coming from the cpu loop and then an equivalent number of ticks coming from the debugger code just outside the cpu loop. The result was, of course, that simulation time went at 2x the correct rate. This simulation time speedup was made even worse because the continue loop in the debugger would increment ticks by one quantum (5 at the time) no matter how many instructions had actually been executed. So in trace mode in particular, the way it was implemented before today, cpu loop would run only one instruction at a time and the simulation time would get incremented 1+5=6 times! One tick from the cpu loop, then 5 erroneous ticks from the continue loop. Anyway, much of this nonsense should be fixed now. For uniprocessor simulations, only the cpu loop does ticks (for best performance). For multiprocessor simulations, the cpu loop exits after one quantum and the code that calls the cpu loop gets to increment ticks instead.
2001-09-28 03:08:30 +04:00
#if BX_SMP_PROCESSORS==1
// ticks are handled inside the cpu loop
#else
BX_TICK1 ();
- my speed boost changes to main.cc and cpu.cc on June 5 were an improvement in performance, but I did not check the debugger carefully enough while testing them. Part of the performance gain in main.cc revision 1.33 and cpu.cc revision 1.9 was to allow bochs to stay in the cpu loop forever in a single processor simulation. (In a multiprocessor simulation it must quit the loop periodically to give the other procs a chance to simulate too. Cooperative multiprocessing?) In the process, I restored calls to BX_TICK in the cpu loop for 1-proc simulation only, and removed them from the outer loop. (See main.cc, since it was done right.) However I never made the equivalent change in the debugger code, so in the debugger, there were ticks coming from the cpu loop and then an equivalent number of ticks coming from the debugger code just outside the cpu loop. The result was, of course, that simulation time went at 2x the correct rate. This simulation time speedup was made even worse because the continue loop in the debugger would increment ticks by one quantum (5 at the time) no matter how many instructions had actually been executed. So in trace mode in particular, the way it was implemented before today, cpu loop would run only one instruction at a time and the simulation time would get incremented 1+5=6 times! One tick from the cpu loop, then 5 erroneous ticks from the continue loop. Anyway, much of this nonsense should be fixed now. For uniprocessor simulations, only the cpu loop does ticks (for best performance). For multiprocessor simulations, the cpu loop exits after one quantum and the code that calls the cpu loop gets to increment ticks instead.
2001-09-28 03:08:30 +04:00
#endif
}
//BX_INFO(("Stepped each CPU a total of %d cycles", count));
#endif
BX_INSTR_DEBUG_PROMPT();
bx_dbg_print_guard_results();
}
#if BX_NUM_SIMULATORS >= 2
unsigned
bx_dbg_cosimulateN(bx_dbg_icount_t count)
{
// execute both master & slave for count instructions,
// handling asynchronous events, etc.
// returns 0 = didn't get through all count instructions
// either a guard was hit, or a divergence occurred
// 1 = got through all count instructions
unsigned master, slave;
bx_dbg_icount_t master_icount, slave_icount;
Boolean bail_out = 0;
unsigned ret = 0;
Boolean save_INTR;
Boolean pre_A20, post_A20;
unsigned async_head;
bx_dbg_icount_t async_icount, curr_icount;
if (count == 0) {
fprintf(stderr, "Error: cosimulateN: count=0\n");
bx_dbg_exit(1);
}
bx_guard.guard_for |= BX_DBG_GUARD_ICOUNT; // stop at icount
bx_guard.guard_for &= ~BX_DBG_GUARD_CTRL_C; // ignore Ctrl-C
one_time_slice:
// take minimum of requested count and maximum count quantum
if (count > bx_debugger.icount_quantum)
bx_guard.icount = bx_debugger.icount_quantum;
else
bx_guard.icount = count;
// for now, assume...
master = bx_debugger.master;
slave = bx_debugger.slave;
// run master simulator
bx_debugger.master_slave_mode = BX_DBG_MASTER_MODE;
if (bx_guard.interrupt_requested) {
bail_out = 1;
fprintf(stderr, "ctrlc typed\n");
}
bx_guard_found[master].guard_found = 0;
bx_guard_found[master].icount = 0;
if (doit) fprintf(stderr, "requesting run of master for %u\n",
(unsigned) bx_guard.icount);
// save A20 value before master run
pre_A20 = bx_pc_system.get_enable_a20();
BX_MEM(master)->cpu_loop(-1);
post_A20 = bx_pc_system.get_enable_a20(); // A20 after master run
master_icount = bx_guard_found[master].icount;
slave_icount = 0;
if (master_icount)
bx_pc_system.tickn(master_icount);
save_INTR = bx_pc_system.INTR; // value after master run
bx_pc_system.INTR = 0; // in case slave uses directly
// Change A20 for slave run to model what it was at beginning of
// master run, only if it needs to be changed.
if (pre_A20 != post_A20) {
bx_pc_system.set_enable_a20(pre_A20);
if (BX_MEM(slave)->set_A20)
BX_MEM(slave)->set_A20(pre_A20);
}
// if guard was anything except for icount, we should terminate
// after synchronizing slave to master
if (bx_guard_found[master].guard_found & ~BX_DBG_GUARD_ICOUNT)
bail_out = 1;
// Synchronize slave to master. Account for Ctrl-C's typed during execution of
// slave.
bx_debugger.master_slave_mode = BX_DBG_SLAVE_MODE;
do {
// run slave for remaining instructions to catch up to master
curr_icount = master_icount - slave_icount;
if (bx_debugger.async_journal.size) {
// If there were asynchronous events which occurred while the
// master was running, have to run the slave up to each of these
// points individually, and force it to take them on exactly the
// same boundaries.
async_head = bx_debugger.async_journal.head;
async_icount = bx_debugger.async_journal.element[async_head].icount;
curr_icount = async_icount; // only run to next async event
}
else {
async_head = 0; // keep compiler happy
async_icount = 0; // keep compiler happy
}
bx_guard_found[slave].guard_found = 0;
bx_guard_found[slave].icount = 0;
bx_guard.icount = curr_icount;
if (curr_icount) {
// Async event may be before completion of any instructions,
// for example taking of interrupt.
if (doit) fprintf(stderr, "requesting run of slave for %u\n",
(unsigned) bx_guard.icount);
if (bx_debugger.fast_forward_mode) {
bx_guard_found[slave].icount = curr_icount;
bx_guard_found[slave].guard_found = BX_DBG_GUARD_ICOUNT;
} else {
BX_MEM(slave)->cpu_loop(-1);
}
}
slave_icount += bx_guard_found[slave].icount;
if (bx_guard_found[slave].guard_found & ~BX_DBG_GUARD_ICOUNT) {
bail_out = 1;
// If user type Ctrl-C we're done after synchronizing. If not,
// then we have reached a true guard, and it's time to bail.
if (bx_guard_found[slave].guard_found &
~(BX_DBG_GUARD_ICOUNT | BX_DBG_GUARD_CTRL_C))
break;
}
if (bx_debugger.async_journal.size) {
// sanity check: slave should be at async point
if (bx_guard_found[slave].icount != async_icount) {
fprintf(stderr, "Error: comsimulateN: async: slave not at sync point.\n");
bx_dbg_exit(1);
}
switch (bx_debugger.async_journal.element[async_head].what) {
case BX_DBG_ASYNC_JOURNAL_IAC:
if (!bx_debugger.fast_forward_mode) {
if (doit)
fprintf(stderr, "slave: forcing interrupt %u\n",
bx_debugger.async_journal.element[async_head].u.iac.val);
BX_MEM(slave)->dbg_force_interrupt(
bx_debugger.async_journal.element[async_head].u.iac.val);
}
break;
case BX_DBG_ASYNC_JOURNAL_A20:
bx_pc_system.set_enable_a20(
bx_debugger.async_journal.element[async_head].u.a20.val);
if (BX_MEM(slave)->set_A20)
BX_MEM(slave)->set_A20(
bx_debugger.async_journal.element[async_head].u.a20.val);
break;
case BX_DBG_ASYNC_JOURNAL_NMI:
case BX_DBG_ASYNC_JOURNAL_RESET:
default:
fprintf(stderr, "Error: cosimulateN: unimplemented async event.\n");
}
// async event processed, dequeue it
bx_debugger.async_journal.size--;
bx_debugger.async_journal.head++;
}
} while (slave_icount < master_icount);
bx_pc_system.INTR = save_INTR; // restore INTR to value after master run
// At this point, both simulators should be at the same point. Either
// they have finished executing for the desired count, or at least for
// a time quantum. Check to see if the environments are in sync.
int iaddr_res;
if (!bx_debugger.fast_forward_mode) {
if (bx_debugger.compare_at_sync.iaddr && (iaddr_res = bx_dbg_compare_sim_iaddr())) {
if (iaddr_res == 1)
bail_out = 1;
} else if (bx_debugger.compare_at_sync.cpu && bx_dbg_compare_sim_cpu())
bail_out = 1;
else if (bx_debugger.compare_at_sync.memory && bx_dbg_compare_sim_memory())
bail_out = 1;
}
if (bail_out) {
#ifdef DEBUGGER_ERROR
extern void DEBUGGER_ERROR(void);
DEBUGGER_ERROR();
#endif
ret = 0; // didn't complete, stopped
}
else {
count -= master_icount;
// last icount known to be in sync
bx_debugger.last_sync_icount += master_icount;
if (count)
goto one_time_slice;
ret = 1; // completed OK
}
bx_guard.guard_for &= ~BX_DBG_GUARD_ICOUNT;
return(ret);
}
#endif // #if BX_NUM_SIMULATORS >= 2
#if BX_NUM_SIMULATORS >= 2
int
bx_dbg_compare_sim_iaddr(void)
{
// returns 0 = same, 1 = different, 2 = false diff
if (BX_CPU(dbg_cpu)->guard_found.laddr != bx_guard_found[1].laddr) {
#ifdef FALSE_DIFF_DETECT
extern int FALSE_DIFF_DETECT();
if (FALSE_DIFF_DETECT())
return 2;
#endif
fprintf(stderr,
#if BX_DBG_ICOUNT_SIZE == 32
"*** Iaddr divergence ***: last know synchronized icount was %lu\n",
(unsigned long) bx_debugger.last_sync_icount
#else // BX_DBG_ICOUNT_SIZE == 64
"*** Iaddr divergence ***: last know synchronized icount was %Lu\n",
(unsigned long long) bx_debugger.last_sync_icount
#endif
);
// fprintf(stderr, "Divergence: sim[0].laddr=%x, sim[1].laddr=%x\n",
// (unsigned) BX_CPU(dbg_cpu)->guard_found.laddr,
// (unsigned) bx_guard_found[1].laddr);
return(1); // different
}
return(0); // same
}
Boolean
bx_dbg_compare_sim_cpu(void)
{
// (mch) Get cpu structures from both simulators
// Compare the structures (except the descriptor parts of the
// segment registers
bx_dbg_cpu_t regs[2];
BX_MEM(0)->dbg_get_cpu(regs + 0);
BX_MEM(1)->dbg_get_cpu(regs + 1);
Boolean ret = 0;
Boolean warn = 0;
// (mch) Yes I know these are macros. The would have been
// inner functions if g++ had supported it.
#define TEST_REG(reg, reg_name) do { \
if (regs[0].reg != regs[1].reg) { \
printf("COSIM ERROR: [%s] %s: 0x%08x %s: 0x%08x\n", reg_name, SIM_NAME0, regs[0].reg, SIM_NAME1_STR, regs[1].reg); \
ret = 1; \
} \
} while(0)
#define TEST_REG_WARN(reg, reg_name, mask) do { \
if ((regs[0].reg & mask) != (regs[1].reg & mask)) { \
printf("COSIM WARNING: [%s] %s: 0x%08x %s: 0x%08x\n", reg_name, SIM_NAME0, (regs[0].reg & mask), SIM_NAME1_STR, (regs[1].reg & mask)); \
warn = 1; \
} \
} while(0)
TEST_REG(eax, "eax");
TEST_REG(ebx, "ebx");
TEST_REG(ecx, "ecx");
TEST_REG(edx, "edx");
TEST_REG(ebp, "ebp");
TEST_REG(esi, "esi");
TEST_REG(edi, "edi");
TEST_REG(esp, "esp");
TEST_REG_WARN(eflags, "eflags & CF", 0x1);
#define EFLAGS_MASK (~((1 << 11) | (1 << 7) | (1 << 6) | (1 << 4) | (1 << 2) | (1 << 0)))
regs[0].eflags &= EFLAGS_MASK;
regs[1].eflags &= EFLAGS_MASK;
TEST_REG(eflags, "eflags");
TEST_REG(eip, "eip");
#define TEST_SEG_REG(reg, reg_name) do { \
if (regs[0].reg.sel != regs[1].reg.sel || regs[0].reg.valid != regs[1].reg.valid) { \
printf("COSIM ERROR: [%s] %s: 0x%04x (%d) %s: 0x%04x (%d)\n", reg_name, SIM_NAME0, regs[0].reg.sel, regs[0].reg.valid, SIM_NAME1_STR, regs[1].reg.sel, regs[1].reg.valid); \
ret = 1; \
} \
} while(0)
TEST_SEG_REG(cs, "cs");
TEST_SEG_REG(ss, "ss");
TEST_SEG_REG(ds, "ds");
TEST_SEG_REG(es, "es");
TEST_SEG_REG(fs, "fs");
TEST_SEG_REG(gs, "gs");
TEST_SEG_REG(ldtr, "ldtr");
TEST_SEG_REG(tr, "tr");
if (regs[0].gdtr.base != regs[1].gdtr.base || regs[0].gdtr.limit != regs[1].gdtr.limit) {
printf("COSIM ERROR: [gdtr] %s: 0x%08x:0x%04x %s 0x%08x:0x%04x\n",
SIM_NAME0, regs[0].gdtr.base, regs[0].gdtr.limit, SIM_NAME1_STR, regs[1].gdtr.base, regs[1].gdtr.limit);
ret = 1;
}
if (regs[0].idtr.base != regs[1].idtr.base || regs[0].idtr.limit != regs[1].idtr.limit) {
printf("COSIM ERROR: [idtr] %s: 0x%08x:0x%04x %s 0x%08x:0x%04x\n",
SIM_NAME0, regs[0].idtr.base, regs[0].idtr.limit, SIM_NAME1_STR, regs[1].idtr.base, regs[1].idtr.limit);
ret = 1;
}
// drX ignored
// trX ignored
TEST_REG(cr0, "cr0");
TEST_REG(cr1, "cr1");
TEST_REG(cr2, "cr2");
TEST_REG(cr3, "cr3");
TEST_REG(cr4, "cr4");
if (regs[0].inhibit_mask != regs[1].inhibit_mask) {
printf("COSIM ERROR [inhibit_mask] %s: %d %s: %d\n",
SIM_NAME0, regs[0].inhibit_mask, SIM_NAME1_STR, regs[1].inhibit_mask);
ret = 1;
}
if (ret) {
fprintf(stderr,
#if BX_DBG_ICOUNT_SIZE == 32
"*** CPU divergence ***: last know synchronized icount was %lu\n",
(unsigned long) bx_debugger.last_sync_icount
#else // BX_DBG_ICOUNT_SIZE == 64
"*** CPU divergence ***: last know synchronized icount was %Lu\n",
(unsigned long long) bx_debugger.last_sync_icount
#endif
);
} else if (warn) {
fprintf(stderr,
#if BX_DBG_ICOUNT_SIZE == 32
"=== CPU divergence ===: last know synchronized icount was %lu\n",
(unsigned long) bx_debugger.last_sync_icount
#else // BX_DBG_ICOUNT_SIZE == 64
"=== CPU divergence ===: last know synchronized icount was %Lu\n",
(unsigned long long) bx_debugger.last_sync_icount
#endif
);
#ifdef DEBUGGER_ERROR
extern void DEBUGGER_ERROR(void);
DEBUGGER_ERROR();
#endif
}
return ret;
}
void
clear_dirty_bits (void)
{
int num_pages = bx_options.memory.Osize->get () * 1024 / 4;
for (int i = 0; i < num_pages; i++) {
BX_MEM(0)->dbg_dirty_pages[i] = 0;
BX_MEM(1)->dbg_dirty_pages[i] = 0;
}
}
Boolean always_check_page[128 * 1024 / 4];
void
bx_dbg_always_check(Bit32u page_start, Boolean on)
{
always_check_page[page_start / (4 * 1024)] = on;
printf("Forced check on page %08x %s\n",
page_start, on ? "enabled" : "disabled");
}
Boolean
bx_dbg_compare_sim_memory(void)
{
Boolean ret = 0;
int num_pages = bx_options.memory.Osize->get () * 1024 / 4;
for (int i = 0; i < num_pages; i++) {
Boolean sim0_dirty = BX_MEM(0)->dbg_dirty_pages[i];
Boolean sim1_dirty = BX_MEM(1)->dbg_dirty_pages[i];
Bit32u page_start = i * 1024 * 4;
if ((sim0_dirty != sim1_dirty) || sim0_dirty || always_check_page[i]) {
// Page has been written, compare
// (mch) I'm quite aware of how hackish this is. I don't care.
extern Bit8u* SIM1_GET_PHYS_PTR(Bit32u page_start);
Bit8u* sim0_page_vec = bx_mem0.vector + page_start;
Bit8u* sim1_page_vec = SIM1_GET_PHYS_PTR(page_start);
if (memcmp(sim0_page_vec, sim1_page_vec, 1024 * 4)) {
printf("COSIM ERROR Physical page %08x differs in content\n", page_start);
for (int j = 0; j < 1024 * 4; j++) {
if (sim0_page_vec[j] != sim1_page_vec[j]) {
printf("%08x %s: %02x %s: %02x\n",
page_start+j, SIM_NAME0, sim0_page_vec[j], SIM_NAME1_STR, sim1_page_vec[j]);
}
}
ret = 1;
}
}
}
if (ret) {
fprintf(stderr,
#if BX_DBG_ICOUNT_SIZE == 32
"*** Memory divergence ***: last know synchronized icount was %lu\n",
(unsigned long) bx_debugger.last_sync_icount
#else // BX_DBG_ICOUNT_SIZE == 64
"*** Memory divergence ***: last know synchronized icount was %Lu\n",
(unsigned long long) bx_debugger.last_sync_icount
#endif
);
}
clear_dirty_bits();
return ret;
}
#endif
void bx_dbg_disassemble_current (int which_cpu, int print_time)
{
Bit32u phy;
Boolean valid;
if (which_cpu < 0) {
// iterate over all of them.
for (int i=0; i<BX_SMP_PROCESSORS; i++)
bx_dbg_disassemble_current (i, print_time);
return;
}
BX_CPU(which_cpu)->dbg_xlate_linear2phy(BX_CPU(which_cpu)->guard_found.laddr, &phy, &valid);
if (valid) {
unsigned ilen;
BX_CPU(which_cpu)->mem->dbg_fetch_mem(phy, 16, bx_disasm_ibuf);
ilen = bx_disassemble.disasm(BX_CPU(which_cpu)->guard_found.is_32bit_code,
bx_disasm_ibuf, bx_disasm_tbuf);
// Note: it would be nice to display only the modified registers here, the easy
// way out I have thought of would be to keep a prev_eax, prev_ebx, etc copies
// in each cpu description (see cpu/cpu.h) and update/compare those "prev" values
// from here. (eks)
if( BX_CPU(dbg_cpu)->trace_reg )
fprintf( stderr,
"eax: %08X\tecx: %08X\tedx: %08X\tebx: %08X\tesp: %08X\tebp: %08X\tesi: %08X\tedi: %08X\ncf=%u af=%u zf=%u sf=%u of=%u pf=%u tf=%u if=%u df=%u iopl=%u nt=%u rf=%u vm=%u\n",
BX_CPU(which_cpu)->gen_reg[0],
BX_CPU(which_cpu)->gen_reg[1],
BX_CPU(which_cpu)->gen_reg[2],
BX_CPU(which_cpu)->gen_reg[3],
BX_CPU(which_cpu)->gen_reg[4],
BX_CPU(which_cpu)->gen_reg[5],
BX_CPU(which_cpu)->gen_reg[6],
BX_CPU(which_cpu)->gen_reg[7],
!!BX_CPU(which_cpu)->get_CF(),
!!BX_CPU(which_cpu)->get_AF(),
!!BX_CPU(which_cpu)->get_ZF(),
!!BX_CPU(which_cpu)->get_SF(),
!!BX_CPU(which_cpu)->get_OF(),
!!BX_CPU(which_cpu)->get_PF(),
BX_CPU(which_cpu)->eflags.tf,
BX_CPU(which_cpu)->eflags.if_,
BX_CPU(which_cpu)->eflags.df,
BX_CPU(which_cpu)->eflags.iopl,
BX_CPU(which_cpu)->eflags.nt,
BX_CPU(which_cpu)->eflags.rf,
BX_CPU(which_cpu)->eflags.vm
);
if (print_time)
fprintf (stderr, "(%u).[%lld] ", which_cpu, bx_pc_system.time_ticks());
else
fprintf (stderr, "(%u) ", which_cpu);
if (BX_CPU(which_cpu)->guard_found.is_32bit_code) {
fprintf(stderr, "%04x:%08x (%s): ",
(unsigned) BX_CPU(which_cpu)->guard_found.cs,
(unsigned) BX_CPU(which_cpu)->guard_found.eip,
bx_dbg_symbolic_address((BX_CPU(which_cpu)->cr3) >> 12, BX_CPU(which_cpu)->guard_found.eip, BX_CPU(which_cpu)->sregs[BX_SREG_CS].cache.u.segment.base));
}
else {
fprintf(stderr, "%04x:%04x (%s): ",
(unsigned) BX_CPU(which_cpu)->guard_found.cs,
(unsigned) BX_CPU(which_cpu)->guard_found.eip,
bx_dbg_symbolic_address_16bit(BX_CPU(which_cpu)->guard_found.eip, BX_CPU(which_cpu)->sregs[BX_SREG_CS].selector.value));
}
for (unsigned j=0; j<ilen; j++)
fprintf(stderr, "%02x", (unsigned) bx_disasm_ibuf[j]);
fprintf(stderr, ": %s\n", bx_disasm_tbuf);
}
else {
fprintf(stderr, "(%u).[%lld] ??? (physical address not available)\n", which_cpu, bx_pc_system.time_ticks());
}
}
void
bx_dbg_print_guard_results(void)
{
unsigned i;
unsigned sim;
for (sim=0; sim<BX_SMP_PROCESSORS; sim++) {
unsigned long found = BX_CPU(sim)->guard_found.guard_found;
if (found & BX_DBG_GUARD_ICOUNT) {
}
else if (found & BX_DBG_GUARD_CTRL_C) {
}
#if BX_DBG_SUPPORT_VIR_BPOINT
else if (found & BX_DBG_GUARD_IADDR_VIR) {
i = BX_CPU(sim)->guard_found.iaddr_index;
fprintf(stderr, "(%u) Breakpoint %u, 0x%x (0x%x:0x%x)\n",
sim,
bx_guard.iaddr.vir[i].bpoint_id,
BX_CPU(sim)->guard_found.laddr,
BX_CPU(sim)->guard_found.cs,
BX_CPU(sim)->guard_found.eip);
}
#endif
#if BX_DBG_SUPPORT_LIN_BPOINT
else if (found & BX_DBG_GUARD_IADDR_LIN) {
i = BX_CPU(sim)->guard_found.iaddr_index;
fprintf(stderr, "(%u) Breakpoint %u, 0x%x in ?? ()\n",
sim,
bx_guard.iaddr.lin[i].bpoint_id,
BX_CPU(sim)->guard_found.laddr);
}
#endif
#if BX_DBG_SUPPORT_PHY_BPOINT
else if (found & BX_DBG_GUARD_IADDR_PHY) {
i = BX_CPU(sim)->guard_found.iaddr_index;
fprintf(stderr, "(%u) Breakpoint %u, 0x%x in ?? ()\n",
sim,
bx_guard.iaddr.phy[i].bpoint_id,
BX_CPU(sim)->guard_found.laddr);
}
#endif
else if (BX_CPU(sim)->stop_reason == STOP_CPU_HALTED) {
/* returned early because processor is in halt state */
}
else if (BX_CPU(sim)->stop_reason == STOP_MAGIC_BREAK_POINT) {
fprintf(stderr, "(%u) Magic breakpoint\n", sim);
} else if (BX_CPU(sim)->stop_reason == STOP_TIME_BREAK_POINT) {
fprintf(stderr, "(%u) Caught time breakpoint\n", sim);
} else if (BX_CPU(sim)->stop_reason == STOP_MODE_BREAK_POINT) {
fprintf(stderr, "(%u) Caught vm mode switch breakpoint to %s mode\n",
sim, BX_CPU(sim)->eflags.vm ? "virtual 86" : "protected");
} else if (BX_CPU(sim)->stop_reason == STOP_READ_WATCH_POINT) {
fprintf(stderr, "(%u) Caught read watch point at %08X\n", sim, BX_CPU(sim)->watchpoint);
} else if (BX_CPU(sim)->stop_reason == STOP_WRITE_WATCH_POINT) {
fprintf(stderr, "(%u) Caught write watch point at %08X\n", sim, BX_CPU(sim)->watchpoint);
}
else {
fprintf(stderr, "Error: (%u) print_guard_results: guard_found ? (stop reason %u)\n",
sim, BX_CPU(sim)->stop_reason);
}
#if BX_DISASM
if (bx_debugger.auto_disassemble) {
if (sim==0) {
// print this only once
fprintf (stderr, "Next at t=%lld\n", bx_pc_system.time_ticks ());
}
bx_dbg_disassemble_current (sim, 0); // one cpu, don't print time
}
#endif // #if BX_DISASM
}
}
void
bx_dbg_breakpoint_changed(void)
{
#if BX_DBG_SUPPORT_VIR_BPOINT
if (bx_guard.iaddr.num_virtual)
bx_guard.guard_for |= BX_DBG_GUARD_IADDR_VIR;
else
bx_guard.guard_for &= ~BX_DBG_GUARD_IADDR_VIR;
#endif
#if BX_DBG_SUPPORT_LIN_BPOINT
if (bx_guard.iaddr.num_linear)
bx_guard.guard_for |= BX_DBG_GUARD_IADDR_LIN;
else
bx_guard.guard_for &= ~BX_DBG_GUARD_IADDR_LIN;
#endif
#if BX_DBG_SUPPORT_PHY_BPOINT
if (bx_guard.iaddr.num_physical)
bx_guard.guard_for |= BX_DBG_GUARD_IADDR_PHY;
else
bx_guard.guard_for &= ~BX_DBG_GUARD_IADDR_PHY;
#endif
}
void
bx_dbg_del_breakpoint_command(unsigned handle)
{
unsigned i;
#if BX_DBG_SUPPORT_VIR_BPOINT
// see if breakpoint is a virtual breakpoint
for (i=0; i<bx_guard.iaddr.num_virtual; i++) {
if (bx_guard.iaddr.vir[i].bpoint_id == handle) {
// found breakpoint, delete it by shifting remaining entries left
for (unsigned j=i; j<(bx_guard.iaddr.num_virtual-1); j++) {
bx_guard.iaddr.vir[j] = bx_guard.iaddr.vir[j+1];
}
bx_guard.iaddr.num_virtual--;
goto done;
}
}
#endif
#if BX_DBG_SUPPORT_LIN_BPOINT
// see if breakpoint is a linear breakpoint
for (i=0; i<bx_guard.iaddr.num_linear; i++) {
if (bx_guard.iaddr.lin[i].bpoint_id == handle) {
// found breakpoint, delete it by shifting remaining entries left
for (unsigned j=i; j<(bx_guard.iaddr.num_linear-1); j++) {
bx_guard.iaddr.lin[j] = bx_guard.iaddr.lin[j+1];
}
bx_guard.iaddr.num_linear--;
goto done;
}
}
#endif
#if BX_DBG_SUPPORT_PHY_BPOINT
// see if breakpoint is a physical breakpoint
for (i=0; i<bx_guard.iaddr.num_physical; i++) {
if (bx_guard.iaddr.phy[i].bpoint_id == handle) {
// found breakpoint, delete it by shifting remaining entries left
for (unsigned j=i; j<(bx_guard.iaddr.num_physical-1); j++) {
bx_guard.iaddr.phy[j] = bx_guard.iaddr.phy[j+1];
}
bx_guard.iaddr.num_physical--;
goto done;
}
}
#endif
fprintf(stderr, "Error: breakpoint %u not found.\n", handle);
return;
done:
bx_dbg_breakpoint_changed();
}
void
bx_dbg_vbreakpoint_command(Boolean specific, Bit32u cs, Bit32u eip)
{
#if BX_DBG_SUPPORT_VIR_BPOINT
if (specific == 0) {
fprintf(stderr, "Error: vbreak without address not implemented yet.\n");
return;
}
if (bx_guard.iaddr.num_virtual >= BX_DBG_MAX_VIR_BPOINTS) {
fprintf(stderr, "Error: no more virtual breakpoint slots left.\n");
fprintf(stderr, "Error: see BX_DBG_MAX_VIR_BPOINTS.\n");
return;
}
bx_guard.iaddr.vir[bx_guard.iaddr.num_virtual].cs = cs;
bx_guard.iaddr.vir[bx_guard.iaddr.num_virtual].eip = eip;
bx_guard.iaddr.vir[bx_guard.iaddr.num_virtual].bpoint_id = bx_debugger.next_bpoint_id++;
bx_guard.iaddr.num_virtual++;
bx_guard.guard_for |= BX_DBG_GUARD_IADDR_VIR;
#else
fprintf(stderr, "Error: virtual breakpoint support not compiled in.\n");
fprintf(stderr, "Error: see BX_DBG_SUPPORT_VIR_BPOINT.\n");
#endif
}
void
bx_dbg_lbreakpoint_command(Boolean specific, Bit32u laddress)
{
#if BX_DBG_SUPPORT_LIN_BPOINT
if (specific == 0) {
fprintf(stderr, "Error: lbreak without address not implemented yet.\n");
return;
}
if (bx_guard.iaddr.num_linear >= BX_DBG_MAX_LIN_BPOINTS) {
fprintf(stderr, "Error: no more linear breakpoint slots left.\n");
fprintf(stderr, "Error: see BX_DBG_MAX_LIN_BPOINTS.\n");
return;
}
bx_guard.iaddr.lin[bx_guard.iaddr.num_linear].addr = laddress;
bx_guard.iaddr.lin[bx_guard.iaddr.num_linear].bpoint_id = bx_debugger.next_bpoint_id++;
bx_guard.iaddr.num_linear++;
bx_guard.guard_for |= BX_DBG_GUARD_IADDR_LIN;
#else
fprintf(stderr, "Error: linear breakpoint support not compiled in.\n");
fprintf(stderr, "Error: see BX_DBG_SUPPORT_LIN_BPOINT.\n");
#endif
}
void
bx_dbg_pbreakpoint_command(Boolean specific, Bit32u paddress)
{
#if BX_DBG_SUPPORT_PHY_BPOINT
if (specific == 0) {
fprintf(stderr, "Error: pbreak without address not implemented yet.\n");
return;
}
if (bx_guard.iaddr.num_physical >= BX_DBG_MAX_PHY_BPOINTS) {
fprintf(stderr, "Error: no more physical breakpoint slots left.\n");
fprintf(stderr, "Error: see BX_DBG_MAX_PHY_BPOINTS.\n");
return;
}
bx_guard.iaddr.phy[bx_guard.iaddr.num_physical].addr = paddress;
bx_guard.iaddr.phy[bx_guard.iaddr.num_physical].bpoint_id = bx_debugger.next_bpoint_id++;
bx_guard.iaddr.num_physical++;
bx_guard.guard_for |= BX_DBG_GUARD_IADDR_PHY;
#else
fprintf(stderr, "Error: physical breakpoint support not compiled in.\n");
fprintf(stderr, "Error: see BX_DBG_SUPPORT_PHY_BPOINT.\n");
#endif
}
void
bx_dbg_info_bpoints_command(void)
{
unsigned i;
// Num Type Disp Enb Address What
// 1 breakpoint keep y 0x00010664 in main at temp.c:7
fprintf(stderr, "Num Type Disp Enb Address\n");
#if BX_DBG_SUPPORT_VIR_BPOINT
for (i=0; i<bx_guard.iaddr.num_virtual; i++) {
fprintf(stderr, "%3u ", bx_guard.iaddr.vir[i].bpoint_id);
fprintf(stderr, "vbreakpoint ");
fprintf(stderr, "keep ");
fprintf(stderr, "y ");
fprintf(stderr, "0x%04x:0x%08x\n",
bx_guard.iaddr.vir[i].cs,
bx_guard.iaddr.vir[i].eip);
}
#endif
#if BX_DBG_SUPPORT_LIN_BPOINT
for (i=0; i<bx_guard.iaddr.num_linear; i++) {
fprintf(stderr, "%3u ", bx_guard.iaddr.lin[i].bpoint_id);
fprintf(stderr, "lbreakpoint ");
fprintf(stderr, "keep ");
fprintf(stderr, "y ");
fprintf(stderr, "0x%08x\n",
bx_guard.iaddr.lin[i].addr);
}
#endif
#if BX_DBG_SUPPORT_PHY_BPOINT
for (i=0; i<bx_guard.iaddr.num_physical; i++) {
fprintf(stderr, "%3u ", bx_guard.iaddr.phy[i].bpoint_id);
fprintf(stderr, "pbreakpoint ");
fprintf(stderr, "keep ");
fprintf(stderr, "y ");
fprintf(stderr, "0x%08x\n",
bx_guard.iaddr.phy[i].addr);
}
#endif
}
void
bx_dbg_set_command(char *p1, char *p2, char *p3)
{
fprintf(stderr, "Error: %s %s %s: command 'set' not implemented yet.\n",
p1, p2, p3);
}
void
bx_dbg_take_command(char *what, unsigned n)
{
if ( !strcmp(what, "dma") ) {
unsigned i;
if (n == 0) {
fprintf(stderr, "Error: take what n=0.\n");
return;
}
bx_dbg_post_dma_reports(); // in case there's some pending reports
bx_dbg_batch_dma.this_many = n;
for (i=0; i<n; i++) {
BX_CPU(0)->dbg_take_dma();
}
bx_dbg_batch_dma.this_many = 1; // reset to normal
bx_dbg_post_dma_reports(); // print reports and flush
if (bx_guard.report.dma)
fprintf(stderr, "done\n");
}
else if ( !strcmp(what, "irq") ) {
BX_CPU(0)->dbg_take_irq();
if (bx_guard.report.irq)
fprintf(stderr, "done\n");
}
else {
fprintf(stderr, "Error: Take '%s' not understood.\n", what);
}
}
void
bx_dbg_info_registers_command(int which_regs_mask)
{
Bit32u reg;
bx_dbg_cpu_t cpu;
for (unsigned i=0; i<BX_SMP_PROCESSORS; i++) {
if (which_regs_mask & BX_INFO_CPU_REGS) {
memset(&cpu, 0, sizeof(cpu));
BX_CPU(i)->dbg_get_cpu(&cpu);
#if (BX_SMP_PROCESSORS > 1)
fprintf(stderr, "%s:\n", BX_CPU(i)->name, i);
#endif
reg = cpu.eax;
fprintf(stderr, "eax 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.ecx;
fprintf(stderr, "ecx 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.edx;
fprintf(stderr, "edx 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.ebx;
fprintf(stderr, "ebx 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.esp;
fprintf(stderr, "esp 0x%-8x\t0x%-8x\n", (unsigned) reg, (int) reg);
reg = cpu.ebp;
fprintf(stderr, "ebp 0x%-8x\t0x%-8x\n", (unsigned) reg, (int) reg);
reg = cpu.esi;
fprintf(stderr, "esi 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.edi;
fprintf(stderr, "edi 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.eip;
fprintf(stderr, "eip 0x%-8x\t0x%-8x\n", (unsigned) reg, (int) reg);
reg = cpu.eflags;
fprintf(stderr, "eflags 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.cs.sel;
fprintf(stderr, "cs 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.ss.sel;
fprintf(stderr, "ss 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.ds.sel;
fprintf(stderr, "ds 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.es.sel;
fprintf(stderr, "es 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.fs.sel;
fprintf(stderr, "fs 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
reg = cpu.gs.sel;
fprintf(stderr, "gs 0x%-8x\t%d\n", (unsigned) reg, (int) reg);
}
if (which_regs_mask & BX_INFO_FPU_REGS) {
BX_CPU(i)->fpu_print_regs ();
}
}
}
void
bx_dbg_info_program_command(void)
{
fprintf(stderr, " Using the running image of child process -1.\n");
fprintf(stderr, "Program stopped at 0x0.\n");
fprintf(stderr, "It stopped at breakpoint 0.\n");
}
void
bx_dbg_dump_cpu_command(void)
{
bx_dbg_cpu_t cpu;
for (unsigned i=0; i<BX_SMP_PROCESSORS; i++ ) {
BX_CPU(i)->dbg_get_cpu(&cpu);
#if (BX_SMP_PROCESSORS >= 2)
fprintf(stderr, "CPU#%u\n", i);
#endif
fprintf(stderr, "eax:0x%x\n", (unsigned) cpu.eax);
fprintf(stderr, "ebx:0x%x\n", (unsigned) cpu.ebx);
fprintf(stderr, "ecx:0x%x\n", (unsigned) cpu.ecx);
fprintf(stderr, "edx:0x%x\n", (unsigned) cpu.edx);
fprintf(stderr, "ebp:0x%x\n", (unsigned) cpu.ebp);
fprintf(stderr, "esi:0x%x\n", (unsigned) cpu.esi);
fprintf(stderr, "edi:0x%x\n", (unsigned) cpu.edi);
fprintf(stderr, "esp:0x%x\n", (unsigned) cpu.esp);
fprintf(stderr, "eflags:0x%x\n", (unsigned) cpu.eflags);
fprintf(stderr, "eip:0x%x\n", (unsigned) cpu.eip);
fprintf(stderr, "cs:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.cs.sel, (unsigned) cpu.cs.des_l,
(unsigned) cpu.cs.des_h, (unsigned) cpu.cs.valid);
fprintf(stderr, "ss:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.ss.sel, (unsigned) cpu.ss.des_l,
(unsigned) cpu.ss.des_h, (unsigned) cpu.ss.valid);
fprintf(stderr, "ds:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.ds.sel, (unsigned) cpu.ds.des_l,
(unsigned) cpu.ds.des_h, (unsigned) cpu.ds.valid);
fprintf(stderr, "es:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.es.sel, (unsigned) cpu.es.des_l,
(unsigned) cpu.es.des_h, (unsigned) cpu.es.valid);
fprintf(stderr, "fs:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.fs.sel, (unsigned) cpu.fs.des_l,
(unsigned) cpu.fs.des_h, (unsigned) cpu.fs.valid);
fprintf(stderr, "gs:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.gs.sel, (unsigned) cpu.gs.des_l,
(unsigned) cpu.gs.des_h, (unsigned) cpu.gs.valid);
fprintf(stderr, "ldtr:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.ldtr.sel, (unsigned) cpu.ldtr.des_l,
(unsigned) cpu.ldtr.des_h, (unsigned) cpu.ldtr.valid);
fprintf(stderr, "tr:s=0x%x, dl=0x%x, dh=0x%x, valid=%u\n",
(unsigned) cpu.tr.sel, (unsigned) cpu.tr.des_l,
(unsigned) cpu.tr.des_h, (unsigned) cpu.tr.valid);
fprintf(stderr, "gdtr:base=0x%x, limit=0x%x\n",
(unsigned) cpu.gdtr.base, (unsigned) cpu.gdtr.limit);
fprintf(stderr, "idtr:base=0x%x, limit=0x%x\n",
(unsigned) cpu.idtr.base, (unsigned) cpu.idtr.limit);
fprintf(stderr, "dr0:0x%x\n", (unsigned) cpu.dr0);
fprintf(stderr, "dr1:0x%x\n", (unsigned) cpu.dr1);
fprintf(stderr, "dr2:0x%x\n", (unsigned) cpu.dr2);
fprintf(stderr, "dr3:0x%x\n", (unsigned) cpu.dr3);
fprintf(stderr, "dr6:0x%x\n", (unsigned) cpu.dr6);
fprintf(stderr, "dr7:0x%x\n", (unsigned) cpu.dr7);
fprintf(stderr, "tr3:0x%x\n", (unsigned) cpu.tr3);
fprintf(stderr, "tr4:0x%x\n", (unsigned) cpu.tr4);
fprintf(stderr, "tr5:0x%x\n", (unsigned) cpu.tr5);
fprintf(stderr, "tr6:0x%x\n", (unsigned) cpu.tr6);
fprintf(stderr, "tr7:0x%x\n", (unsigned) cpu.tr7);
fprintf(stderr, "cr0:0x%x\n", (unsigned) cpu.cr0);
fprintf(stderr, "cr1:0x%x\n", (unsigned) cpu.cr1);
fprintf(stderr, "cr2:0x%x\n", (unsigned) cpu.cr2);
fprintf(stderr, "cr3:0x%x\n", (unsigned) cpu.cr3);
fprintf(stderr, "cr4:0x%x\n", (unsigned) cpu.cr4);
fprintf(stderr, "inhibit_mask:%u\n", cpu.inhibit_mask);
}
#if BX_PCI_SUPPORT
if (bx_options.Oi440FXSupport->get ()) {
bx_devices.pci->print_i440fx_state();
}
#endif
fprintf(stderr, "done\n");
}
void
bx_dbg_examine_command(char *command, char *format, Boolean format_passed,
Bit32u addr, Boolean addr_passed, int simulator)
{
unsigned repeat_count, i;
char ch, display_format, unit_size;
Boolean iteration;
unsigned data_size;
Boolean paddr_valid;
Bit32u paddr;
Bit8u data8;
Bit16u data16;
Bit32u data32;
unsigned columns, per_line, offset;
unsigned char digit;
unsigned biti;
Boolean is_linear;
unsigned char databuf[8];
if (simulator == 0)
printf("[%s]:\n", SIM_NAME0);
else
printf("[%s]:\n", SIM_NAME1_STR);
// If command was the extended "xp" command, meaning eXamine Physical memory,
// then flag memory address as physical, rather than linear.
if (strcmp(command, "xp") == 0) {
is_linear = 0;
}
else {
is_linear = 1;
}
if (addr_passed==0)
addr = bx_debugger.default_addr;
if (format_passed==0) {
display_format = bx_debugger.default_display_format;
unit_size = bx_debugger.default_unit_size;
repeat_count = 1;
}
else {
if (format==NULL) {
fprintf(stderr, "dbg_examine: format NULL\n");
bx_dbg_exit(1);
}
if (strlen(format) < 2) {
fprintf(stderr, "dbg_examine: invalid format passed.\n");
bx_dbg_exit(1);
}
if (format[0] != '/') {
fprintf(stderr, "dbg_examine: '/' is not first char of format.\n");
bx_dbg_exit(1);
}
format++;
repeat_count = 0;
ch = *format;
iteration = 0;
while ( (ch>='0') && (ch<='9') ) {
iteration = 1;
repeat_count = 10*repeat_count + (ch-'0');
format++;
ch = *format;
}
if (iteration==0) {
// if no count given, use default
repeat_count = 1;
}
else if (repeat_count==0) {
// count give, but zero is an error
fprintf(stderr, "dbg_examine: repeat count given but is zero.\n");
return;
}
// set up the default display format and unit size parameters
display_format = bx_debugger.default_display_format;
unit_size = bx_debugger.default_unit_size;
for (i=0; i<=1; i++) {
if (ch==0) break; // bail on null character
switch (ch) {
case 'x': // hex
case 'd': // signed decimal
case 'u': // unsigned decimal
case 'o': // octal
case 't': // binary
case 'c': // chars
case 's': // null terminated string
case 'i': // machine instruction
display_format = ch;
break;
case 'b': // bytes
case 'h': // halfwords (two bytes)
case 'w': // words (4 bytes)
case 'g': // giant words (8 bytes)
unit_size = ch;
break;
default:
fprintf(stderr, "dbg_examine: invalid format passed.\n");
bx_dbg_exit(1);
break;
}
format++;
ch = *format;
}
// store current options as default
bx_debugger.default_display_format = display_format;
bx_debugger.default_unit_size = unit_size;
}
//fprintf(stderr, " repeat count was %u\n", repeat_count);
//fprintf(stderr, " display_format = '%c'\n", display_format);
//fprintf(stderr, " unit_size = '%c'\n", unit_size);
if ( (display_format == 'i') || (display_format == 's') ) {
fprintf(stderr, "error: dbg_examine: 'i' and 's' formats not supported.\n");
return;
}
if (unit_size == 'g') {
fprintf(stderr, "error: dbg_examine: 'g' (8-byte) unit size not supported.\n");
return;
}
data_size = 0;
per_line = 0;
offset = 0;
switch (unit_size) {
case 'b': data_size = 1; per_line = 8; break;
case 'h': data_size = 2; per_line = 8; break;
case 'w': data_size = 4; per_line = 4; break;
//case 'g': data_size = 8; per_line = 2; break;
}
columns = per_line + 1; // set current number columns past limit
for (i=1; i<=repeat_count; i++) {
if (columns > per_line) {
// if not 1st run, need a newline from last line
if (i!=1)
fprintf(stderr, "\n");
fprintf(stderr, "0x%x <bogus+%u>:", addr, offset);
columns = 1;
}
if (is_linear) {
BX_CPU(simulator)->dbg_xlate_linear2phy(addr, &paddr, &paddr_valid);
if (!paddr_valid) {
fprintf(stderr, "error: examine memory: no tranlation for linear-to-phy mem available.\n");
return;
}
}
else {
paddr = addr; // address is already physical address
}
BX_MEM(simulator)->dbg_fetch_mem(paddr, data_size, databuf);
//FIXME HanishKVC The char display for data to be properly integrated
// so that repeat_count, columns, etc. can be set or used properly.
// Also for data_size of 2 and 4 how to display the individual
// characters i.e in which order to be decided.
switch (data_size) {
case 1:
data8 = databuf[0];
switch (display_format) {
case 'x': fprintf(stderr, "\t0x%02x", (unsigned) data8); break;
case 'd': fprintf(stderr, "\t%d", (int) (Bit8s) data8); break;
case 'u': fprintf(stderr, "\t%u", (unsigned) data8); break;
case 'o': fprintf(stderr, "\t%o", (unsigned) data8); break;
case 't':
fputc('\t', stderr);
for (biti=7; ; biti--) {
digit = (data8 >> biti) & 0x01;
fputc(digit + '0', stderr);
if (biti==0) break;
}
break;
case 'c': fprintf(stderr, " %c",data8); break;
}
break;
case 2:
#ifdef BX_LITTLE_ENDIAN
data16 = * (Bit16u *) databuf;
#else
data16 = (databuf[1]<<8) | databuf[0];
#endif
switch (display_format) {
case 'x': fprintf(stderr, "\t0x%04x", (unsigned) data16); break;
case 'd': fprintf(stderr, "\t%d", (int) (Bit16s) data16); break;
case 'u': fprintf(stderr, "\t%u", (unsigned) data16); break;
case 'o': fprintf(stderr, "\t%o", (unsigned) data16); break;
case 't':
fputc('\t', stderr);
for (biti=15; ; biti--) {
digit = (data16 >> biti) & 0x01;
fputc(digit + '0', stderr);
if (biti==0) break;
}
break;
case 'c': fprintf(stderr, " %c %c",data16>>8,data16&0xff); break;
}
break;
case 4:
#ifdef BX_LITTLE_ENDIAN
data32 = * (Bit32u *) databuf;
#else
data32 = (databuf[3]<<24) | (databuf[2]<<16) |
(databuf[1]<<8) | databuf[0];
#endif
switch (display_format) {
case 'x': fprintf(stderr, "\t0x%08x", (unsigned) data32); break;
case 'd': fprintf(stderr, "\t%d", (int) (Bit32s) data32); break;
case 'u': fprintf(stderr, "\t%u", (unsigned) data32); break;
case 'o': fprintf(stderr, "\t%o", (unsigned) data32); break;
case 't':
fputc('\t', stderr);
for (biti=31; ; biti--) {
digit = (data32 >> biti) & 0x01;
fputc(digit + '0', stderr);
if (biti==0) break;
}
break;
case 'c':
fprintf(stderr, " %c %c",data32>>24,(data32>>16)&0xff);
fprintf(stderr, " %c %c",(data32>>8)&0xff,data32&0xff);
break;
}
break;
}
addr += data_size;
bx_debugger.default_addr = addr;
columns++;
offset += data_size;
}
fprintf(stderr, "\n");
}
void
bx_dbg_setpmem_command(Bit32u addr, unsigned len, Bit32u val)
{
Boolean is_OK;
Bit8u buf[4];
switch ( len ) {
case 1:
buf[0] = (Bit8u) val;
break;
case 2:
buf[0] = val & 0xff;
buf[1] = (val>>8) & 0xff;
break;
case 4:
buf[0] = val & 0xff; val >>= 8;
buf[1] = val & 0xff; val >>= 8;
buf[2] = val & 0xff; val >>= 8;
buf[3] = val & 0xff;
break;
default:
fprintf(stderr, "Error: setpmem: bad length value = %u\n", len);
return;
}
is_OK = BX_MEM(0)->dbg_set_mem(addr, len, buf);
if (!is_OK) {
fprintf(stderr, "Error: setpmem: could not set memory, out of physical bounds?\n");
}
}
void
bx_dbg_set_symbol_command(char *symbol, Bit32u val)
{
Boolean is_OK;
symbol++; // get past '$'
if ( !strcmp(symbol, "eax") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_EAX, val);
}
else if ( !strcmp(symbol, "ecx") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_ECX, val);
}
else if ( !strcmp(symbol, "edx") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_EDX, val);
}
else if ( !strcmp(symbol, "ebx") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_EBX, val);
}
else if ( !strcmp(symbol, "esp") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_ESP, val);
}
else if ( !strcmp(symbol, "ebp") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_EBP, val);
}
else if ( !strcmp(symbol, "esi") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_ESI, val);
}
else if ( !strcmp(symbol, "edi") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_EDI, val);
}
else if ( !strcmp(symbol, "eip") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_EIP, val);
}
else if ( !strcmp(symbol, "eflags") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_EFLAGS, val);
}
else if ( !strcmp(symbol, "cs") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_CS, val);
}
else if ( !strcmp(symbol, "ss") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_SS, val);
}
else if ( !strcmp(symbol, "ds") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_DS, val);
}
else if ( !strcmp(symbol, "es") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_ES, val);
}
else if ( !strcmp(symbol, "fs") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_FS, val);
}
else if ( !strcmp(symbol, "gs") ) {
is_OK = BX_CPU(dbg_cpu)->dbg_set_reg(BX_DBG_REG_GS, val);
}
else if ( !strcmp(symbol, "cpu") ) {
#if ((BX_SMP_PROCESSORS>1) && (BX_SUPPORT_APIC))
if ((val > BX_SMP_PROCESSORS)
|| (val >= APIC_MAX_ID)
|| (apic_index[val] == NULL)) {
fprintf (stderr, "invalid cpu id number %d\n", val);
return;
}
dbg_cpu = val;
#endif
}
else if ( !strcmp(symbol, "synchronous_dma") ) {
bx_guard.async.dma = !val;
return;
}
else if ( !strcmp(symbol, "synchronous_irq") ) {
bx_guard.async.irq = !val;
return;
}
else if ( !strcmp(symbol, "event_reports") ) {
bx_guard.report.irq = val;
bx_guard.report.a20 = val;
bx_guard.report.io = val;
bx_guard.report.ucmem = val;
bx_guard.report.dma = val;
return;
}
else if ( !strcmp(symbol, "auto_disassemble") ) {
bx_debugger.auto_disassemble = (val > 0);
return;
}
else if ( !strcmp(symbol, "disassemble_size") ) {
if ( (val!=16) && (val!=32) ) {
fprintf(stderr, "Error: disassemble_size must be 16 or 32.\n");
return;
}
bx_debugger.disassemble_size = val;
return;
}
else {
fprintf(stderr, "Error: set: unrecognized symbol.\n");
return;
}
if (!is_OK) {
fprintf(stderr, "Error: could not set register '%s'.\n", symbol);
}
}
void
bx_dbg_query_command(char *what)
{
unsigned pending;
if ( !strcmp(what, "pending") ) {
pending = BX_CPU(0)->dbg_query_pending();
if ( pending & BX_DBG_PENDING_DMA )
fprintf(stderr, "pending DMA\n");
if ( pending & BX_DBG_PENDING_IRQ )
fprintf(stderr, "pending IRQ\n");
if (!pending)
fprintf(stderr, "pending none\n");
fprintf(stderr, "done\n");
}
else {
fprintf(stderr, "Error: Query '%s' not understood.\n", what);
}
}
void
bx_dbg_set_cpu_command(void)
{
FILE *fp;
int reti;
char *rets;
Boolean retb;
unsigned long ul1, ul2, ul3, ul4;
bx_dbg_cpu_t cpu;
fp = bx_infile_stack[bx_infile_stack_index].fp;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "eax:0x%lx", &ul1); cpu.eax = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "ebx:0x%lx", &ul1); cpu.ebx = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "ecx:0x%lx", &ul1); cpu.ecx = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "edx:0x%lx", &ul1); cpu.edx = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "ebp:0x%lx", &ul1); cpu.ebp = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "esi:0x%lx", &ul1); cpu.esi = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "edi:0x%lx", &ul1); cpu.edi = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "esp:0x%lx", &ul1); cpu.esp = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "eflags:0x%lx", &ul1); cpu.eflags = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "eip:0x%lx", &ul1); cpu.eip = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "cs:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.cs.sel = (Bit16u) ul1;
cpu.cs.des_l = ul2;
cpu.cs.des_h = ul3;
cpu.cs.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "ss:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.ss.sel = (Bit16u) ul1;
cpu.ss.des_l = ul2;
cpu.ss.des_h = ul3;
cpu.ss.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "ds:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.ds.sel = (Bit16u) ul1;
cpu.ds.des_l = ul2;
cpu.ds.des_h = ul3;
cpu.ds.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "es:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.es.sel = (Bit16u) ul1;
cpu.es.des_l = ul2;
cpu.es.des_h = ul3;
cpu.es.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "fs:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.fs.sel = (Bit16u) ul1;
cpu.fs.des_l = ul2;
cpu.fs.des_h = ul3;
cpu.fs.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "gs:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.gs.sel = (Bit16u) ul1;
cpu.gs.des_l = ul2;
cpu.gs.des_h = ul3;
cpu.gs.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "ldtr:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.ldtr.sel = (Bit16u) ul1;
cpu.ldtr.des_l = ul2;
cpu.ldtr.des_h = ul3;
cpu.ldtr.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "tr:s=0x%lx, dl=0x%lx, dh=0x%lx, valid=%lu",
&ul1, &ul2, &ul3, &ul4);
cpu.tr.sel = (Bit16u) ul1;
cpu.tr.des_l = ul2;
cpu.tr.des_h = ul3;
cpu.tr.valid = ul4;
if (reti != 4) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "gdtr:base=0x%lx, limit=0x%lx",
&ul1, &ul2);
cpu.gdtr.base = ul1;
cpu.gdtr.limit = ul2;
if (reti != 2) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "idtr:base=0x%lx, limit=0x%lx",
&ul1, &ul2);
cpu.idtr.base = ul1;
cpu.idtr.limit = ul2;
if (reti != 2) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "dr0:0x%lx", &ul1); cpu.dr0 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "dr1:0x%lx", &ul1); cpu.dr1 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "dr2:0x%lx", &ul1); cpu.dr2 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "dr3:0x%lx", &ul1); cpu.dr3 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "dr6:0x%lx", &ul1); cpu.dr6 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "dr7:0x%lx", &ul1); cpu.dr7 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "tr3:0x%lx", &ul1); cpu.tr3 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "tr4:0x%lx", &ul1); cpu.tr4 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "tr5:0x%lx", &ul1); cpu.tr5 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "tr6:0x%lx", &ul1); cpu.tr6 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "tr7:0x%lx", &ul1); cpu.tr7 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "cr0:0x%lx", &ul1); cpu.cr0 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "cr1:0x%lx", &ul1); cpu.cr1 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "cr2:0x%lx", &ul1); cpu.cr2 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "cr3:0x%lx", &ul1); cpu.cr3 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "cr4:0x%lx", &ul1); cpu.cr4 = ul1;
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "inhibit_mask:%u", &cpu.inhibit_mask);
if (reti != 1) goto scanf_error;
rets = fgets(tmp_buf, 512, fp); if (!rets) goto eof_error;
reti = sscanf(tmp_buf, "done");
if (reti != 0) goto scanf_error;
retb = BX_CPU(0)->dbg_set_cpu(&cpu);
if (retb == 0)
fprintf(stderr, "Error: dbg_set_cpu encountered error\n");
else
fprintf(stderr, "OK\n");
return;
eof_error:
fprintf(stderr, "Error: EOF encountered in dbg_set_cpu input stream\n");
return;
scanf_error:
fprintf(stderr, "Error: scanf returned error in dbg_set_cpu input stream\n");
return;
}
void
bx_dbg_disassemble_command(bx_num_range range)
{
#if BX_DISASM
Boolean paddr_valid;
Bit32u paddr;
unsigned ilen;
if (range.to == EMPTY_ARG) {
// should set to cs:eip. FIXME
BX_INFO(("Error: type 'disassemble ADDR' or 'disassemble ADDR:ADDR'"));
return;
}
do {
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(range.from, &paddr, &paddr_valid);
if (paddr_valid) {
BX_MEM(0)->dbg_fetch_mem(paddr, 16, bx_disasm_ibuf);
ilen = bx_disassemble.disasm(bx_debugger.disassemble_size==32,
bx_disasm_ibuf, bx_disasm_tbuf);
fprintf(stderr, "%08x: ", (unsigned) range.from);
for (unsigned j=0; j<ilen; j++)
fprintf(stderr, "%02x", (unsigned) bx_disasm_ibuf[j]);
fprintf(stderr, ": %s\n", bx_disasm_tbuf);
}
else {
fprintf(stderr, "??? (physical address not available)\n");
ilen = 0; // keep compiler happy
range.from = range.to; // bail out
}
range.from += ilen;
} while (range.from < range.to);
#else
UNUSED(range);
#endif // #if BX_DISASM
}
//NOTE simple minded maths logic
void
bx_dbg_maths_command(char *command, int data1, int data2)
{
if(strcmp(command,"add") == 0)
{
fprintf(stderr," %x + %x = %x ", data1, data2, data1+data2);
}
else if(strcmp(command,"sub") == 0)
{
fprintf(stderr," %x - %x = %x ", data1, data2, data1-data2);
}
else if(strcmp(command,"mul") == 0)
{
fprintf(stderr," %x * %x = %x ", data1, data2, data1*data2);
}
else if(strcmp(command,"div") == 0)
{
fprintf(stderr," %x / %x = %x ", data1, data2, data1/data2);
}
fprintf(stderr,"\n");
}
//FIXME HanishKVC requires better error checking in POST FIX expression
//NOTE Uses POST FIX EXPRESSION handling for better maths
void
bx_dbg_maths_expression_command(char *expr)
{
int data1, data2, res;
int biti,digit;
char *next_token;
fprintf(stderr,"%s\n",expr);
expr++; // skip " in the string token passed
while(expr[0] == ' ')expr++; // skip any spaces following the "
next_token = strtok(expr," ");
if(next_token == NULL) return;
data1 = res = strtol(next_token,NULL,0);
do
{
switch(next_token[0])
{
case '+':
res = data1+data2;
fprintf(stderr," %x + %x = %x ",data1,data2,res);
data1 = res;
break;
case '-':
res = data1-data2;
fprintf(stderr," %x - %x = %x ",data1,data2,res);
data1 = res;
break;
case '*':
res = data1*data2;
fprintf(stderr," %x * %x = %x ",data1,data2,res);
data1 = res;
break;
case '/':
res = data1/data2;
fprintf(stderr," %x / %x = %x ",data1,data2,res);
data1 = res;
break;
case '&':
res = data1 & data2;
fprintf(stderr," %x & %x = %x ",data1,data2,res);
data1 = res;
break;
case '|':
res = data1 | data2;
fprintf(stderr," %x | %x = %x ",data1,data2,res);
data1 = res;
break;
case '~':
res = ~data1;
fprintf(stderr," ~ %x = %x ",data1,res);
data1 = res;
break;
default:
data2 = strtol(next_token,NULL,0);
break;
}
next_token = strtok(NULL," ");
if(next_token == NULL) break;
}while(1);
fprintf(stderr,"\n");
//FIXME HanishKVC If sizeof changes from a Byte addressed to
// Word addressed machine & so on then the logic
// below requires to be updated
fprintf(stderr," Binary of %x : ",res);
for(biti=(sizeof(int)*8)-1; ; biti--)
{
digit = (res >> biti) & 0x01;
fputc(digit + '0', stderr);
if(biti==0) break;
if((biti%4) == 0) fputc(' ',stderr);
}
fprintf(stderr,"\n");
}
void
bx_dbg_v2l_command(unsigned seg_no, Bit32u offset)
{
#if BX_NUM_SIMULATORS > 1
fprintf(stderr, "Error: v2l not supported for nsim > 1\n"
#else
bx_dbg_sreg_t sreg;
Bit32u laddr;
if (seg_no > 5) {
fprintf(stderr, "Error: seg_no out of bounds\n");
return;
}
BX_CPU(dbg_cpu)->dbg_get_sreg(&sreg, seg_no);
if (!sreg.valid) {
fprintf(stderr, "Error: segment valid bit cleared\n");
return;
}
laddr = (sreg.des_l>>16) |
((sreg.des_h<<16)&0x00ff0000) |
(sreg.des_h & 0xff000000);
laddr += offset;
fprintf(stderr, "laddr: 0x%x (%u)\n",
(unsigned) laddr, (unsigned) laddr);
#endif
}
void
bx_dbg_instrument_command(char *comm)
{
#if BX_INSTRUMENTATION
if ( !strcmp(comm, "start") ) {
BX_INSTR_START ();
}
else if ( !strcmp(comm, "stop") ) {
BX_INSTR_STOP ();
}
else if ( !strcmp(comm, "reset") ) {
BX_INSTR_RESET ();
}
else if ( !strcmp(comm, "print") ) {
BX_INSTR_PRINT ();
}
else {
fprintf(stderr, "Error: command instrument %s not implemented.\n", comm);
bx_dbg_exit(1);
}
#else
UNUSED(comm);
fprintf(stderr, "Error: instrumentation not enabled.\n");
#endif
}
void
bx_dbg_loader_command(char *path_quoted)
{
size_t len;
// skip beginning double quote
if (path_quoted[0] == '"')
path_quoted++;
// null out ending quote
len = strlen(path_quoted);
if (path_quoted[len - 1] == '"')
path_quoted[len - 1] = '\0';
#if BX_USE_LOADER
{
bx_loader_misc_t loader_misc;
BX_CPU(0)->loader(path_quoted, &loader_misc);
#if 0
fprintf(stderr, "dr0: 0x%08x\n", loader_misc.dr0);
fprintf(stderr, "dr1: 0x%08x\n", loader_misc.dr1);
fprintf(stderr, "dr2: 0x%08x\n", loader_misc.dr2);
fprintf(stderr, "dr3: 0x%08x\n", loader_misc.dr3);
fprintf(stderr, "dr6: 0x%08x\n", loader_misc.dr6);
fprintf(stderr, "dr7: 0x%08x\n", loader_misc.dr7);
#endif
bx_cpu.dr0 = loader_misc.dr0;
bx_cpu.dr1 = loader_misc.dr1;
bx_cpu.dr2 = loader_misc.dr2;
bx_cpu.dr3 = loader_misc.dr3;
bx_cpu.dr7 = loader_misc.dr7;
}
#else
fprintf(stderr, "Error: loader not implemented.\n");
#endif
}
void
bx_dbg_doit_command(unsigned n)
{
// generic command to add temporary hacks to
// for debugging purposes
UNUSED(n);
bx_dbg.interrupts = n;
bx_dbg.exceptions = n;
}
void
bx_dbg_crc_command(Bit32u addr1, Bit32u addr2)
{
Bit32u crc1, crc2;
if (addr1 >= addr2) {
fprintf(stderr, "Error: crc: invalid range.\n");
return;
}
if (!BX_MEM(0)->dbg_crc32(crc32, addr1, addr2, &crc1)) {
fprintf(stderr, "sim0: could not CRC memory\n");
return;
}
#if BX_NUM_SIMULATORS == 1
fprintf(stderr, "0x%lx\n", crc1);
#else
if (!BX_MEM(1)->dbg_crc32(crc32, addr1, addr2, &crc2)) {
fprintf(stderr, "sim1: could not CRC memory\n");
return;
}
if (crc1 == crc2) {
fprintf(stderr, "CRC same: 0x%x\n", (unsigned) crc1);
}
else {
fprintf(stderr, "CRC different: sim0=0x%x, sim1=0x%x\n",
(unsigned) crc1, (unsigned) crc2);
}
#endif
}
void
bx_dbg_info_dirty_command(void)
{
unsigned char *page_tbl = BX_MEM(0)->dbg_dirty_pages;
unsigned page_tbl_size = BX_MEM(0)->dbg_count_dirty_pages ();
for (unsigned i=0; i<page_tbl_size; i++) {
if (page_tbl[i]) {
fprintf(stderr, "0x%x\n", i);
page_tbl[i] = 0; // reset to clean
}
}
}
void bx_dbg_print_descriptor (FILE *fp, unsigned char desc[8], int verbose)
{
int lo = (desc[3] << 24) | (desc[2] << 16) | (desc[1] << 8) | (desc[0]);
int hi = (desc[7] << 24) | (desc[6] << 16) | (desc[5] << 8) | (desc[4]);
//fprintf (fp, "descriptor hi,lo = %08x,%08x\n", hi, lo);
int base = ((lo >> 16) & 0xffff)
| ((hi << 16) & 0xff0000)
| (hi & 0xff000000);
int limit = (lo & 0xffff);
int segment = (lo >> 16) & 0xffff;
int offset = (lo & 0xffff) | (hi & 0xffff0000);
int type = (hi >> 8) & 0x0f;
int dpl = (hi >> 13) & 0x03;
int s = (hi >> 12) & 0x01;
int present = (hi >> 15) & 0x01;
int avl = (hi >> 20) & 0x01;
int d_b = (hi >> 22) & 0x01;
int g = (hi >> 23) & 0x01;
int base_is_jump_addr;
#if 0
if (s) {
// either a code or a data segment. bit 11 (type file MSB) then says
// 0=data segment, 1=code seg
if (type&8) {
fprintf (fp, "Segment type: Code, %s%s%s\n",
(type&2)? "Execute/Read" : "Execute-Only",
(type&4)? ", Conforming" : "",
(type&1)? ", Accessed" : "");
fprintf (fp, "D flag=%d (use %d-bit addresses, %d-bit or 8-bit operands)\n", d_b, d_b? 32 : 16);
} else {
fprintf (fp, "Segment type: Data, %s%s%s\n",
(type&2)? "Read/Write" : "Read-Only",
(type&4)? ", Expand-down" : "",
(type&1)? ", Accessed" : "");
}
} else {
// types from IA32-devel-guide-3, page 3-15.
static char *type_names[16] = { "Reserved", "16-Bit TSS (available)", "LDT", "16-Bit TSS (Busy)", "16-Bit Call Gate", "Task Gate", "16-Bit Interrupt Gate", "16-Bit Trap Gate", "Reserved", "32-Bit TSS (Available)", "Reserved", "32-Bit TSS (Busy)", "32-Bit Call Gate", "Reserved", "32-Bit Interrupt Gate", "32-Bit Trap Gate" };
// some kind of gate?
fprintf (fp, "System segment, type=0x%x=%s\n", type, type_names[type]);
base_is_jump_addr = 1;
// for call gates, print segment:offset and parameter count p.40-15
// for task gate, only present,dpl,TSS segment selector exist. p.5-13
// for interrupt gate, segment:offset,p,dpl
// for trap gate, segment:offset,p,dpl
}
fprintf (fp, "DPL=descriptor privilege level=%d\n", dpl);
if (base_is_jump_addr) {
fprintf (fp, "target address=%04x:%08x\n", segment, offset);
} else {
fprintf (fp, "base address=%p\n", base);
fprintf (fp, "G=granularity=%d\n", g);
fprintf (fp, "limit=0x%x %s (see G)\n", limit, g?"4K-byte units" : "bytes");
fprintf (fp, "AVL=available to OS=%d\n", avl);
}
fprintf (fp, "P=present=%d\n", present);
#endif
/* brief output */
// 32-bit trap gate, target=0010:c0108ec4, DPL=0, present=1
// code segment, base=0000:00cfffff, length=0xffff
if (s) {
// either a code or a data segment. bit 11 (type file MSB) then says
// 0=data segment, 1=code seg
if (type&8) {
fprintf (fp, "Code segment, linearaddr=%08x, len=%04x %s, %s%s%s, %d-bit addrs\n",
base, limit, g ? "* 4Kbytes" : "bytes",
(type&2)? "Execute/Read" : "Execute-Only",
(type&4)? ", Conforming" : "",
(type&1)? ", Accessed" : "",
d_b? 32 : 16);
} else {
fprintf (fp, "Data segment, linearaddr=%08x, len=%04x %s, %s%s%s\n",
base, limit, g ? "* 4Kbytes" : "bytes",
(type&2)? "Read/Write" : "Read-Only",
(type&4)? ", Expand-down" : "",
(type&1)? ", Accessed" : "");
}
} else {
// types from IA32-devel-guide-3, page 3-15.
static char *undef = "???";
static char *type_names[16] = { undef, "16-Bit TSS (available)", "LDT", "16-Bit TSS (Busy)", "16-Bit Call Gate", "Task Gate", "16-Bit Interrupt Gate", "16-Bit Trap Gate", undef, "32-Bit TSS (Available)", undef, "32-Bit TSS (Busy)", "32-Bit Call Gate", undef, "32-Bit Interrupt Gate", "32-Bit Trap Gate" };
fprintf (fp, "%s ", type_names[type]);
// only print more if type is valid
if (type_names[type] == undef) {
fprintf (fp, "descriptor hi=%08x, lo=%08x", hi, lo);
} else {
// for call gates, print segment:offset and parameter count p.4-15
// for task gate, only present,dpl,TSS segment selector exist. p.5-13
// for interrupt gate, segment:offset,p,dpl
// for trap gate, segment:offset,p,dpl
2001-11-11 07:55:14 +03:00
// for TSS, base address and segment limit
switch (type) {
case 1: case 3: // 16-bit TSS
case 9: case 11: // 32-bit TSS
limit = (hi&0x000f0000) | (lo&0xffff);
fprintf (fp, "at %08x, length 0x%x", base, limit);
break;
case 2:
// it's an LDT. not much to print.
break;
default:
// task, int, trap, or call gate.
fprintf (fp, "target=%04x:%08x, DPL=%d", segment, offset, dpl);
}
}
fprintf (fp, "\n");
}
}
void
bx_dbg_info_idt_command(bx_num_range range) {
bx_dbg_cpu_t cpu;
BX_CPU(0)->dbg_get_cpu(&cpu);
int n, print_table = 0;
if (range.to == EMPTY_ARG) {
// show all entries
range.from = 0;
range.to = (cpu.idtr.limit) / 8;
print_table = 1;
}
if (print_table)
fprintf (stderr, "Interrupt Descriptor Table (0x%08x):\n", cpu.idtr.base);
for (n = range.from; n<=range.to; n++) {
Bit32u paddr, paddr_valid;
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(cpu.idtr.base + 8*n, &paddr, &paddr_valid);
if (!paddr_valid) {
fprintf (stderr, "error: IDTR+8*%d points to invalid linear address %p\n",
n, cpu.idtr.base);
return;
}
// read 8-byte entry from IDT
unsigned char entry[8];
BX_MEM(0)->dbg_fetch_mem (paddr, 8, entry);
fprintf (stderr, "IDT[0x%02x]=", n);
bx_dbg_print_descriptor (stderr, entry, 0);
}
if (print_table) fprintf (stderr, "You can list individual entries with 'info idt NUM' or groups with 'info idt NUM:NUM'\n");
}
void
bx_dbg_info_gdt_command(bx_num_range range) {
bx_dbg_cpu_t cpu;
BX_CPU(0)->dbg_get_cpu(&cpu);
int n, print_table = 0;
if (range.to == EMPTY_ARG) {
// show all entries
range.from = 0;
range.to = (cpu.gdtr.limit) / 8;
print_table = 1;
}
if (print_table)
fprintf (stderr, "Global Descriptor Table (0x%08x):\n", cpu.gdtr.base);
for (n = range.from; n<=range.to; n++) {
Bit32u paddr, paddr_valid;
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(cpu.gdtr.base + 8*n, &paddr, &paddr_valid);
if (!paddr_valid) {
fprintf (stderr, "error: GDTR+8*%d points to invalid linear address %p\n",
n, cpu.gdtr.base);
return;
}
unsigned char entry[8];
// read 8-byte entry from GDT
BX_MEM(0)->dbg_fetch_mem (paddr, 8, entry);
fprintf (stderr, "GDT[0x%02x]=", n);
bx_dbg_print_descriptor (stderr, entry, 0);
}
if (print_table) fprintf (stderr, "You can list individual interrupts with 'info gdt NUM'.\n");
}
void
bx_dbg_info_ldt_command(bx_num_range n) {
bx_dbg_cpu_t cpu;
BX_CPU(0)->dbg_get_cpu(&cpu);
fprintf (stderr, "Local Descriptor Table output not implemented\n");
}
void
bx_dbg_info_tss_command(bx_num_range n) {
bx_dbg_cpu_t cpu;
BX_CPU(0)->dbg_get_cpu(&cpu);
fprintf (stderr, "TSS output not implemented\n");
}
bx_num_range
make_num_range (Bit64s from, Bit64s to)
{
bx_num_range x;
x.from = from;
x.to = to;
return x;
}
void
bx_dbg_info_control_regs_command(void)
{
bx_dbg_cpu_t cpu;
BX_CPU(0)->dbg_get_cpu(&cpu);
int cr0 = cpu.cr0;
int cr2 = cpu.cr2;
int cr3 = cpu.cr3;
int cr4 = cpu.cr4;
fprintf (stderr, "CR0=0x%08x\n", cr0);
fprintf (stderr, " PG=paging=%d\n", (cr0>>31) & 1);
fprintf (stderr, " CD=cache disable=%d\n", (cr0>>30) & 1);
fprintf (stderr, " NW=not write through=%d\n", (cr0>>29) & 1);
fprintf (stderr, " AM=alignment mask=%d\n", (cr0>>18) & 1);
fprintf (stderr, " WP=write protect=%d\n", (cr0>>16) & 1);
fprintf (stderr, " NE=numeric error=%d\n", (cr0>>5) & 1);
fprintf (stderr, " ET=extension type=%d\n", (cr0>>4) & 1);
fprintf (stderr, " TS=task switched=%d\n", (cr0>>3) & 1);
fprintf (stderr, " EM=FPU emulation=%d\n", (cr0>>2) & 1);
fprintf (stderr, " MP=monitor coprocessor=%d\n", (cr0>>1) & 1);
fprintf (stderr, " PE=protection enable=%d\n", (cr0>>0) & 1);
fprintf (stderr, "CR2=page fault linear address=0x%08x\n", cr2);
fprintf (stderr, "CR3=0x%08x\n", cr3);
fprintf (stderr, " PCD=page-level cache disable=%d\n", (cr3>>4) & 1);
fprintf (stderr, " PWT=page-level writes transparent=%d\n", (cr3>>3) & 1);
fprintf (stderr, "CR4=0x%08x\n", cr4);
fprintf (stderr, " VME=virtual-8086 mode extensions=%d\n", (cr4>>0) & 1);
fprintf (stderr, " PVI=protected-mode virtual interrupts=%d\n", (cr4>>1) & 1);
fprintf (stderr, " TSD=time stamp disable=%d\n", (cr4>>2) & 1);
fprintf (stderr, " DE=debugging extensions=%d\n", (cr4>>3) & 1);
fprintf (stderr, " PSE=page size extensions=%d\n", (cr4>>4) & 1);
fprintf (stderr, " PAE=physical address extension=%d\n", (cr4>>5) & 1);
fprintf (stderr, " MCE=machine check enable=%d\n", (cr4>>6) & 1);
fprintf (stderr, " PGE=page global enable=%d\n", (cr4>>7) & 1);
fprintf (stderr, " PCE=performance-monitor counter enable=%d\n", (cr4>>8) & 1);
fprintf (stderr, " OXFXSR=OS support for FXSAVE/FXRSTOR=%d\n", (cr4>>9) & 1);
fprintf (stderr, " OSXMMEXCPT=OS support for unmasked SIMD FP exceptions=%d\n", (cr4>>10) & 1);
}
/*
* this implements the info ne2k commands in the debugger.
* info ne2k - shows all registers
* info ne2k page N - shows all registers in a page
* info ne2k page N reg M - shows just one register
*/
void
bx_dbg_info_ne2k(int page, int reg)
{
#if BX_NE2K_SUPPORT
bx_ne2k.print_info (stderr, page, reg, 0);
#else
fprintf (stderr, "NE2000 support is not compiled in.\n");
#endif
}
//
// Reports from various events
//
void
bx_dbg_iac_report(unsigned vector, unsigned irq)
{
#if BX_NUM_SIMULATORS > 1
unsigned tail, master;
#endif
if (doit) fprintf(stderr, "iac report: vector=%u\n", vector);
if (bx_guard.report.irq) {
fprintf(stderr, "event icount=%u IRQ irq=%u vec=%x\n",
(unsigned) BX_CPU(dbg_cpu)->guard_found.icount, irq, vector);
}
#if BX_NUM_SIMULATORS > 1
if (bx_debugger.master_slave_mode == BX_DBG_SLAVE_MODE ) {
fprintf(stderr, "Error: iac_report: in slave mode.\n");
bx_dbg_exit(1);
}
// Master simulator mode
if (bx_debugger.async_journal.size >= BX_DBG_ASYNC_JOURNAL_SIZE) {
fprintf(stderr, "Error: iac: async journal full.\n");
bx_dbg_exit(1);
}
if (bx_debugger.async_journal.size == 0) {
// start off point head & tail at same element
bx_debugger.async_journal.head = 0;
tail = bx_debugger.async_journal.tail = 0;
}
else {
tail = bx_debugger.async_journal.tail + 1;
}
if (tail >= BX_DBG_ASYNC_JOURNAL_SIZE) {
fprintf(stderr, "Error: iac_report: journal wrapped.\n");
bx_dbg_exit(0);
}
master = bx_debugger.master;
bx_debugger.async_journal.element[tail].what = BX_DBG_ASYNC_JOURNAL_IAC;
bx_debugger.async_journal.element[tail].icount = bx_guard_found[master].icount;
bx_debugger.async_journal.element[tail].u.iac.val = vector;
if (bx_debugger.async_journal.size)
bx_debugger.async_journal.tail++;
bx_debugger.async_journal.size++;
#endif
}
void
bx_dbg_a20_report(unsigned val)
{
if (bx_guard.report.a20) {
fprintf(stderr, "event icount=%u A20 val=%u\n",
(unsigned) BX_CPU(dbg_cpu)->guard_found.icount, val);
}
}
#if BX_NUM_SIMULATORS > 1
void
bx_dbg_journal_a20_event(unsigned val)
{
unsigned tail, master;
if (bx_debugger.master_slave_mode == BX_DBG_SLAVE_MODE ) {
fprintf(stderr, "Error: a20_report: in slave mode.\n");
bx_dbg_exit(1);
}
// Master simulator mode
if (bx_debugger.async_journal.size >= BX_DBG_ASYNC_JOURNAL_SIZE) {
fprintf(stderr, "Error: async journal full.\n");
bx_dbg_exit(1);
}
if (bx_debugger.async_journal.size == 0) {
// start off point head & tail at same element
bx_debugger.async_journal.head = 0;
tail = bx_debugger.async_journal.tail = 0;
}
else {
tail = bx_debugger.async_journal.tail + 1;
}
if (tail >= BX_DBG_ASYNC_JOURNAL_SIZE) {
fprintf(stderr, "Error: a20_report: journal wrapped.\n");
bx_dbg_exit(0);
}
master = bx_debugger.master;
bx_debugger.async_journal.element[tail].what = BX_DBG_ASYNC_JOURNAL_A20;
bx_debugger.async_journal.element[tail].icount = bx_guard_found[master].icount;
bx_debugger.async_journal.element[tail].u.a20.val = val;
if (bx_debugger.async_journal.size)
bx_debugger.async_journal.tail++;
bx_debugger.async_journal.size++;
}
#endif
void
bx_dbg_io_report(Bit32u addr, unsigned size, unsigned op, Bit32u val)
{
if (bx_guard.report.io) {
fprintf(stderr, "event icount=%u IO addr=0x%x size=%u op=%s val=0x%x\n",
(unsigned) BX_CPU(dbg_cpu)->guard_found.icount,
(unsigned) addr,
size,
(op==BX_READ) ? "read" : "write",
(unsigned) val);
}
// nothing else to do. bx_dbg_inp() and bx_dbg_outp() do the journaling.
}
void
bx_dbg_ucmem_report(Bit32u addr, unsigned size, unsigned op, Bit32u val)
{
if (bx_guard.report.ucmem) {
fprintf(stderr, "event icount=%u UCmem addr=0x%x size=%u op=%s val=0x%x\n",
(unsigned) BX_CPU(dbg_cpu)->guard_found.icount,
(unsigned) addr,
size,
(op==BX_READ) ? "read" : "write",
(unsigned) val);
}
// nothing else to do. bx_dbg_ucmem_read() and bx_dbg_ucmem_write()
// do the journaling.
}
void
bx_dbg_dma_report(Bit32u addr, unsigned len, unsigned what, Bit32u val)
{
if (bx_dbg_batch_dma.this_many == 0) {
fprintf(stderr, "%s: DMA batch this_many=0.\n", argv0);
bx_dbg_exit(1);
}
// if Q is full, post events (and flush)
if (bx_dbg_batch_dma.Qsize >= bx_dbg_batch_dma.this_many) {
fprintf(stderr, "%s: DMA batch Q was not flushed.\n", argv0);
bx_dbg_exit(1);
}
// if Q already has MAX elements in it
if (bx_dbg_batch_dma.Qsize >= BX_BATCH_DMA_BUFSIZE) {
fprintf(stderr, "%s: DMA batch buffer overrun.\n", argv0);
bx_dbg_exit(1);
}
bx_dbg_batch_dma.Qsize++;
bx_dbg_batch_dma.Q[bx_dbg_batch_dma.Qsize-1].addr = addr;
bx_dbg_batch_dma.Q[bx_dbg_batch_dma.Qsize-1].len = len;
bx_dbg_batch_dma.Q[bx_dbg_batch_dma.Qsize-1].what = what;
bx_dbg_batch_dma.Q[bx_dbg_batch_dma.Qsize-1].val = val;
bx_dbg_batch_dma.Q[bx_dbg_batch_dma.Qsize-1].icount = BX_CPU(dbg_cpu)->guard_found.icount;
// if Q is full, post events (and flush)
if (bx_dbg_batch_dma.Qsize >= bx_dbg_batch_dma.this_many)
bx_dbg_post_dma_reports();
}
void
bx_dbg_post_dma_reports(void)
{
unsigned i;
unsigned addr, len, what, val;
unsigned last_addr, last_len, last_what;
unsigned print_header;
unsigned first_iteration;
if (bx_guard.report.dma) {
if (bx_dbg_batch_dma.Qsize == 0) return; // nothing batched to print
// compress output so all contiguous DMA ops of the same type and size
// are printed on the same line
last_addr = bx_dbg_batch_dma.Q[0].addr;
last_len = bx_dbg_batch_dma.Q[0].len;
last_what = bx_dbg_batch_dma.Q[0].what;
first_iteration = 1;
for (i=0; i<bx_dbg_batch_dma.Qsize; i++) {
addr = bx_dbg_batch_dma.Q[i].addr;
len = bx_dbg_batch_dma.Q[i].len;
what = bx_dbg_batch_dma.Q[i].what;
val = bx_dbg_batch_dma.Q[i].val;
if (len != last_len)
print_header = 1;
else if (what != last_what)
print_header = 1;
else if (addr != (last_addr + last_len))
print_header = 1;
else
print_header = 0;
// now store current values for next iteration
last_addr = addr;
last_len = len;
last_what = what;
if (print_header) {
if (!first_iteration) // need return from previous line
fprintf(stderr, "\n");
else
first_iteration = 0;
// need to output the event header
fprintf(stderr, "event icount=%u DMA addr=0x%x size=%u op=%s val=0x%x",
(unsigned) bx_dbg_batch_dma.Q[i].icount,
addr, len, (what==BX_READ) ? "read" : "write",
val );
print_header = 0;
}
else {
// *no* need to output the event header
fprintf(stderr, " 0x%x", val);
}
}
if (bx_dbg_batch_dma.Qsize)
fprintf(stderr, "\n");
}
// empty Q, regardless of whether reports are printed
bx_dbg_batch_dma.Qsize = 0;
}
//
// Cosimulation routines
//
#if (BX_NUM_SIMULATORS >= 2)
Bit8u
bx_dbg_ucmem_read(Bit32u addr)
{
Bit8u value;
unsigned head, tail;
if ( bx_debugger.master_slave_mode == BX_DBG_MASTER_MODE ) {
if (!bx_debugger.fast_forward_mode) {
if (bx_debugger.UCmem_journal.size >= BX_DBG_UCMEM_JOURNAL_SIZE) {
fprintf(stderr, "dbg_ucmem_read: journal full.\n");
bx_dbg_exit(0);
}
if (bx_debugger.UCmem_journal.size == 0) {
// start off point head & tail at same element
bx_debugger.UCmem_journal.head = 0;
tail = bx_debugger.UCmem_journal.tail = 0;
}
else {
tail = bx_debugger.UCmem_journal.tail + 1;
}
if (tail >= BX_DBG_UCMEM_JOURNAL_SIZE) {
fprintf(stderr, "dbg_ucmem_read: journal wrapped.\n");
bx_dbg_exit(0);
}
value = bx_devices.vga->mem_read(addr);
bx_dbg_ucmem_report(addr, 1, BX_READ, value);
bx_debugger.UCmem_journal.element[tail].op = BX_READ;
bx_debugger.UCmem_journal.element[tail].len = 1;
bx_debugger.UCmem_journal.element[tail].addr = addr;
bx_debugger.UCmem_journal.element[tail].value = value;
if (bx_debugger.UCmem_journal.size)
bx_debugger.UCmem_journal.tail++;
bx_debugger.UCmem_journal.size++;
if (doit)
fprintf(stderr, "MASTER UCR: head:%u tail%u size:%u\n",
bx_debugger.UCmem_journal.head,
bx_debugger.UCmem_journal.tail,
bx_debugger.UCmem_journal.size);
return(value);
} else {
value = bx_devices.vga->mem_read(addr);
return(value);
}
}
else {
if (bx_debugger.UCmem_journal.size == 0) {
fprintf(stderr, "Error: ucmem_read: journal empty.\n");
return(0xff);
}
head = bx_debugger.UCmem_journal.head;
value = bx_debugger.UCmem_journal.element[head].value;
if ((bx_debugger.UCmem_journal.element[head].op != BX_READ) ||
(bx_debugger.UCmem_journal.element[head].len != 1) ||
(bx_debugger.UCmem_journal.element[head].addr != addr)) {
fprintf(stderr, "Error: ucmem_read: out of sync with journal.\n");
fprintf(stderr, "Error: master: op=%1s len=%u addr=0x%x val=0x%x\n",
(bx_debugger.UCmem_journal.element[head].op==BX_READ) ? "W" : "R",
(unsigned) bx_debugger.UCmem_journal.element[head].len,
(unsigned) bx_debugger.UCmem_journal.element[head].addr,
(unsigned) bx_debugger.UCmem_journal.element[head].value);
fprintf(stderr, "Error: slave: op=W len=%u addr=0x%x val=0x%x\n",
(unsigned) 1, (unsigned) addr, (unsigned) value);
return(0xff);
}
// slave UCmem op in sync with journaled master op, delete this entry
bx_debugger.UCmem_journal.head++;
bx_debugger.UCmem_journal.size--;
return(value);
}
}
void
bx_dbg_ucmem_write(Bit32u addr, Bit8u value)
{
unsigned tail, head;
if ( bx_debugger.master_slave_mode == BX_DBG_MASTER_MODE ) {
if (!bx_debugger.fast_forward_mode) {
if (bx_debugger.UCmem_journal.size >= BX_DBG_UCMEM_JOURNAL_SIZE) {
fprintf(stderr, "dbg_ucmem_write: journal full.\n");
bx_dbg_exit(0);
}
if (bx_debugger.UCmem_journal.size == 0) {
// start off point head & tail at same element
bx_debugger.UCmem_journal.head = 0;
tail = bx_debugger.UCmem_journal.tail = 0;
}
else {
tail = bx_debugger.UCmem_journal.tail + 1;
}
if (tail >= BX_DBG_UCMEM_JOURNAL_SIZE) {
fprintf(stderr, "dbg_ucmem_write: journal wrapped.\n");
bx_dbg_exit(0);
}
bx_debugger.UCmem_journal.element[tail].op = BX_WRITE;
bx_debugger.UCmem_journal.element[tail].len = 1;
bx_debugger.UCmem_journal.element[tail].addr = addr;
bx_debugger.UCmem_journal.element[tail].value = value;
if (bx_debugger.UCmem_journal.size)
bx_debugger.UCmem_journal.tail++;
bx_debugger.UCmem_journal.size++;
bx_devices.vga->mem_write(addr, value);
bx_dbg_ucmem_report(addr, 1, BX_WRITE, value);
} else {
bx_devices.vga->mem_write(addr, value);
}
}
else {
if (bx_debugger.UCmem_journal.size == 0) {
fprintf(stderr, "Error: ucmem_write: journal empty.\n");
return;
}
head = bx_debugger.UCmem_journal.head;
if ((bx_debugger.UCmem_journal.element[head].op != BX_WRITE) ||
(bx_debugger.UCmem_journal.element[head].len != 1) ||
(bx_debugger.UCmem_journal.element[head].addr != addr) ||
(bx_debugger.UCmem_journal.element[head].value != value) ) {
fprintf(stderr, "Error: ucmem_write: out of sync with journal.\n");
fprintf(stderr, "Error: master: op=%1s len=%u addr=0x%x val=0x%x\n",
(bx_debugger.UCmem_journal.element[head].op==BX_WRITE) ? "W" : "R",
(unsigned) bx_debugger.UCmem_journal.element[head].len,
(unsigned) bx_debugger.UCmem_journal.element[head].addr,
(unsigned) bx_debugger.UCmem_journal.element[head].value);
fprintf(stderr, "Error: slave: op=W len=%u addr=0x%x val=0x%x\n",
(unsigned) 1, (unsigned) addr, (unsigned) value);
return;
}
// slave UCmem op in sync with journaled master op, delete this entry
bx_debugger.UCmem_journal.head++;
bx_debugger.UCmem_journal.size--;
}
}
void
bx_dbg_async_pin_request(unsigned what, Boolean val)
{
// Request from IO devices for change in pin external to CPU.
// This is pended until CPU ack's with bx_dbg_async_pin_ack().
if (bx_debugger.master_slave_mode != BX_DBG_MASTER_MODE) {
fprintf(stderr, "Error: dbg_async_pin_request not in master mode.\n");
bx_dbg_exit(1);
}
switch (what) {
case BX_DBG_ASYNC_PENDING_A20:
// Q pending status
bx_guard.async_changes_pending.which |= BX_DBG_ASYNC_PENDING_A20;
bx_guard.async_changes_pending.a20 = val;
return;
break;
case BX_DBG_ASYNC_PENDING_RESET:
case BX_DBG_ASYNC_PENDING_NMI:
default:
fprintf(stderr, "Error: set_async_pin: unhandled case.\n");
bx_dbg_exit(1);
}
}
void
bx_dbg_async_pin_ack(unsigned what, Boolean val)
{
// Acknowledgement from master simulator for pending change in pin
// external to CPU.
if (bx_debugger.master_slave_mode != BX_DBG_MASTER_MODE) {
fprintf(stderr, "Error: dbg_async_pin_ack: not master mode.\n");
bx_dbg_exit(1);
}
switch (what) {
case BX_DBG_ASYNC_PENDING_A20:
// get rid of pending status
bx_guard.async_changes_pending.which &= ~BX_DBG_ASYNC_PENDING_A20;
// notify pc_system of change
bx_pc_system.set_enable_a20(val);
if (BX_CPU(bx_debugger.master)->set_A20)
BX_CPU(bx_debugger.master)->set_A20(val);
bx_dbg_journal_a20_event(val);
return;
break;
case BX_DBG_ASYNC_PENDING_RESET:
case BX_DBG_ASYNC_PENDING_NMI:
default:
fprintf(stderr, "Error: set_async_pin: unhandled case.\n");
bx_dbg_exit(1);
}
}
Bit32u
bx_dbg_inp(Bit16u addr, unsigned len)
{
Bit32u value;
unsigned tail, head;
if ( bx_debugger.master_slave_mode == BX_DBG_MASTER_MODE ) {
if (!bx_debugger.fast_forward_mode) {
if (bx_debugger.IO_journal.size >= BX_DBG_IO_JOURNAL_SIZE) {
fprintf(stderr, "dbg_inp: journal full.\n");
bx_dbg_exit(0);
}
if (bx_debugger.IO_journal.size == 0) {
// start off point head & tail at same element
bx_debugger.IO_journal.head = 0;
tail = bx_debugger.IO_journal.tail = 0;
}
else {
tail = bx_debugger.IO_journal.tail + 1;
}
if (tail >= BX_DBG_IO_JOURNAL_SIZE) {
fprintf(stderr, "dbg_inp: journal wrapped.\n");
bx_dbg_exit(0);
}
value = bx_pc_system.inp(addr, len);
bx_debugger.IO_journal.element[tail].op = BX_READ;
bx_debugger.IO_journal.element[tail].len = (Bit8u) len;
bx_debugger.IO_journal.element[tail].addr = addr;
bx_debugger.IO_journal.element[tail].value = value;
if (bx_debugger.IO_journal.size)
bx_debugger.IO_journal.tail++;
bx_debugger.IO_journal.size++;
//fprintf(stderr, "MASTER IN: head:%u tail%u size:%u\n",
// bx_debugger.IO_journal.head,
// bx_debugger.IO_journal.tail,
// bx_debugger.IO_journal.size);
return(value);
} else {
value = bx_pc_system.inp(addr, len);
return(value);
}
}
else {
if (bx_debugger.IO_journal.size == 0) {
fprintf(stderr, "Error: dbg_inp: journal empty.\n");
return(0xffffffff);
}
head = bx_debugger.IO_journal.head;
value = bx_debugger.IO_journal.element[head].value;
if ((bx_debugger.IO_journal.element[head].op != BX_READ) ||
(bx_debugger.IO_journal.element[head].len != len) ||
(bx_debugger.IO_journal.element[head].addr != addr) ) {
fprintf(stderr, "Error: dbg_inp: out of sync with journal.\n");
fprintf(stderr, "Error: master: op=%3s len=%u addr=0x%x\n",
(bx_debugger.IO_journal.element[head].op==BX_WRITE) ? "OUT" : "IN",
(unsigned) bx_debugger.IO_journal.element[head].len,
(unsigned) bx_debugger.IO_journal.element[head].addr);
fprintf(stderr, "Error: slave: op=OUT len=%u addr=0x%x\n",
(unsigned) len, (unsigned) addr);
return(0xffffffff);
}
// slave IO op in sync with journaled master op, delete this entry
bx_debugger.IO_journal.head++;
bx_debugger.IO_journal.size--;
// fprintf(stderr, "SLAVE IN: head:%u tail%u size:%u\n",
// bx_debugger.IO_journal.head,
// bx_debugger.IO_journal.tail,
// bx_debugger.IO_journal.size);
return(value);
}
}
void
bx_dbg_outp(Bit16u addr, Bit32u value, unsigned len)
{
unsigned tail, head;
if ( bx_debugger.master_slave_mode == BX_DBG_MASTER_MODE ) {
if (!bx_debugger.fast_forward_mode) {
if (bx_debugger.IO_journal.size >= BX_DBG_IO_JOURNAL_SIZE) {
fprintf(stderr, "dbg_outp: IO journal full.\n");
bx_dbg_exit(0);
}
if (bx_debugger.IO_journal.size == 0) {
// start off point head & tail at same element
bx_debugger.IO_journal.head = 0;
tail = bx_debugger.IO_journal.tail = 0;
}
else {
tail = bx_debugger.IO_journal.tail + 1;
}
if (tail >= BX_DBG_IO_JOURNAL_SIZE) {
fprintf(stderr, "dbg_outp: IO journal wrapped.\n");
bx_dbg_exit(0);
}
bx_debugger.IO_journal.element[tail].op = BX_WRITE;
bx_debugger.IO_journal.element[tail].len = (Bit8u) len;
bx_debugger.IO_journal.element[tail].addr = addr;
bx_debugger.IO_journal.element[tail].value = value;
if (bx_debugger.IO_journal.size)
bx_debugger.IO_journal.tail++;
bx_debugger.IO_journal.size++;
bx_pc_system.outp(addr, value, len);
if (doit)
fprintf(stderr, "master: IO journal size now %u\n", bx_debugger.IO_journal.size);
} else {
bx_pc_system.outp(addr, value, len);
}
}
else {
if (bx_debugger.IO_journal.size == 0) {
fprintf(stderr, "Error: dbg_outp: journal empty.\n");
return;
}
head = bx_debugger.IO_journal.head;
if ((bx_debugger.IO_journal.element[head].op != BX_WRITE) ||
(bx_debugger.IO_journal.element[head].len != len) ||
(bx_debugger.IO_journal.element[head].addr != addr) ||
(bx_debugger.IO_journal.element[head].value != value) ) {
fprintf(stderr, "Error: dbg_outp: out of sync with journal.\n");
fprintf(stderr, "Error: master: op=%3s len=%u addr=0x%x val=0x%x\n",
(bx_debugger.IO_journal.element[head].op==BX_WRITE) ? "OUT" : "IN",
(unsigned) bx_debugger.IO_journal.element[head].len,
(unsigned) bx_debugger.IO_journal.element[head].addr,
(unsigned) bx_debugger.IO_journal.element[head].value);
fprintf(stderr, "Error: slave: op=OUT len=%u addr=0x%x val=0x%x\n",
(unsigned) len, (unsigned) addr, (unsigned) value);
return;
}
// slave IO op in sync with journaled master op, delete this entry
bx_debugger.IO_journal.head++;
bx_debugger.IO_journal.size--;
if (doit)
fprintf(stderr, "slave: IO journal size now %u\n", bx_debugger.IO_journal.size);
}
}
void
bx_dbg_raise_HLDA(void)
{
fprintf(stderr, "dbg_HLDA called\n");
bx_dbg_exit(0);
}
Bit8u
bx_dbg_IAC(void)
{
// Convience routine. bochs skips this, and calls the PIC code
// directly. This is for other simulators to interface to the
// the PIC code.
unsigned iac;
iac = bx_devices.pic->IAC();
return(iac);
}
void
bx_dbg_set_INTR(Boolean b)
{
if ( bx_debugger.master_slave_mode == BX_DBG_SLAVE_MODE ) {
fprintf(stderr, "Error: set_INTR in slave mode.\n");
bx_dbg_exit(1);
}
bx_pc_system.INTR = b;
BX_CPU(bx_debugger.master)->set_INTR(b);
}
#endif // #if (BX_NUM_SIMULATORS >= 2)
// BW added. return non zero to cause a stop
#if BX_DEBUGGER
static int symbol_level;
int
bx_dbg_symbolic_output(void)
{
/* modes & address spaces */
if(BX_CPU(dbg_cpu)->cr0.pe != last_pe) {
fprintf(stderr,"%10lld: Switched %s protected mode\n",
bx_pc_system.time_ticks(),
last_pe ? "from" : "to");
last_pe = !last_pe;
}
if(last_vm != BX_CPU(dbg_cpu)->eflags.vm) {
fprintf(stderr,"%10lld: %s V86 mode\n",
bx_pc_system.time_ticks(),
last_vm ? "Exited" : "Entered");
last_vm = !last_vm;
}
if(last_cr3 != BX_CPU(dbg_cpu)->cr3)
fprintf(stderr,"\n%10lld: Address space switched since last trigger. CR3: 0x%08x\n",
bx_pc_system.time_ticks(), BX_CPU(dbg_cpu)->cr3);
/* interrupts */
if (dbg_show_mask & 0x40) {
if(BX_CPU(dbg_cpu)->show_flag & 0x4) {
fprintf(stderr,"%10lld: softint %04x:%08x %08x\n",
bx_pc_system.time_ticks(),
BX_CPU(dbg_cpu)->guard_found.cs,
BX_CPU(dbg_cpu)->guard_found.eip,
BX_CPU(dbg_cpu)->guard_found.laddr);
}
if((BX_CPU(dbg_cpu)->show_flag & 0x10) && !(BX_CPU(dbg_cpu)->show_flag & 0x4)) {
fprintf(stderr,"\n%10lld: exception (not softint) %04x:%08x %08x\n",
bx_pc_system.time_ticks(),
BX_CPU(dbg_cpu)->guard_found.cs,
BX_CPU(dbg_cpu)->guard_found.eip,
BX_CPU(dbg_cpu)->guard_found.laddr);
}
if(BX_CPU(dbg_cpu)->show_flag & 0x8) {
fprintf(stderr,"%10lld: iret %04x:%08x %08x (from %08x)\n\n",
bx_pc_system.time_ticks(),
BX_CPU(dbg_cpu)->guard_found.cs,
BX_CPU(dbg_cpu)->guard_found.eip,
BX_CPU(dbg_cpu)->guard_found.laddr,
BX_CPU(dbg_cpu)->show_eip);
}
}
/* calls */
if(BX_CPU(dbg_cpu)->show_flag & 0x1) {
Bit32u phy = 0;
Boolean valid;
if (dbg_show_mask & 0x20) {
BX_CPU(dbg_cpu)->dbg_xlate_linear2phy(BX_CPU(dbg_cpu)->guard_found.laddr,
&phy, &valid);
fprintf(stderr,"%10lld:%*s call %04x:%08x 0x%08x (%08x) %s",
bx_pc_system.time_ticks(),
symbol_level+1," ",
BX_CPU(dbg_cpu)->guard_found.cs,
BX_CPU(dbg_cpu)->guard_found.eip,
BX_CPU(dbg_cpu)->guard_found.laddr,
phy,
bx_dbg_symbolic_address(BX_CPU(dbg_cpu)->cr3,
BX_CPU(dbg_cpu)->guard_found.eip,
BX_CPU(dbg_cpu)->guard_found.laddr - BX_CPU(dbg_cpu)->guard_found.eip) );
if(!valid)
fprintf(stderr," phys not valid");
fprintf(stderr,"\n");
}
symbol_level++;
if(symbol_level > 40)
symbol_level = 10;
}
if (BX_CPU(dbg_cpu)->show_flag & 0x2) {
symbol_level--;
if(symbol_level < 0)
symbol_level = 0;
}
BX_CPU(dbg_cpu)->show_flag = 0;
last_cr3 = BX_CPU(dbg_cpu)->cr3;
return 0;
}
#endif
// BW added to dump page table
static void
dbg_lin2phys(BX_CPU_C *cpu, Bit32u laddress, Bit32u *phy, Boolean *valid, Bit32u *tlb_phy, Boolean *tlb_valid) {
Bit32u lpf, ppf, poffset, TLB_index, paddress;
Bit32u pde, pde_addr;
Bit32u pte, pte_addr;
*tlb_valid = 0;
if (cpu->cr0.pg == 0) {
*phy = laddress;
*valid = 1;
return;
}
lpf = laddress & 0xfffff000; // linear page frame
poffset = laddress & 0x00000fff; // physical offset
TLB_index = BX_TLB_INDEX_OF(lpf);
// see if page is in the TLB first
if (cpu->TLB.entry[TLB_index].lpf == lpf) {
*tlb_phy = cpu->TLB.entry[TLB_index].ppf | poffset;
*tlb_valid = 1;
}
// Get page dir entry
pde_addr = (cpu->cr3 & 0xfffff000) |
((laddress & 0xffc00000) >> 20);
BX_MEM(0)->read_physical(cpu, pde_addr, 4, &pde);
if ( !(pde & 0x01) ) {
// Page Directory Entry NOT present
goto page_fault;
}
// Get page table entry
pte_addr = (pde & 0xfffff000) |
((laddress & 0x003ff000) >> 10);
BX_MEM(0)->read_physical(cpu, pte_addr, 4, &pte);
if ( !(pte & 0x01) ) {
// Page Table Entry NOT present
goto page_fault;
}
ppf = pte & 0xfffff000;
paddress = ppf | poffset;
*phy = paddress;
*valid = 1;
return;
page_fault:
*phy = 0;
*valid = 0;
return;
}
static void dbg_dump_table(Boolean all)
{
Bit32u lina;
Bit32u phy, tlb_phy;
Boolean valid, tlb_valid;
Bit32u start_lina, start_phy; // start of a valid translation interval
if (BX_CPU(dbg_cpu)->cr0.pg == 0) {
printf("paging off\n");
return;
}
printf("cr3: %08x \n", BX_CPU(dbg_cpu)->cr3);
lina = 0;
start_lina = 1;
start_phy = 2;
while(1) {
dbg_lin2phys(BX_CPU(dbg_cpu), lina, &phy, &valid, &tlb_phy, &tlb_valid);
if(valid) {
if( (lina - start_lina != phy - start_phy) || tlb_valid) {
if(all && (start_lina != 1))
printf("%08x - %08x: %8x - %8x\n",
start_lina, lina - 0x1000, start_phy, start_phy + (lina-0x1000-start_lina));
start_lina = lina;
start_phy = phy;
}
if(tlb_valid) {
if(all && tlb_phy == phy)
printf("%08x : %8x (%8x) in TLB\n",
lina, phy, tlb_phy);
if(tlb_phy != phy)
printf("%08x : %8x (%8x) in TLB Phys differs!!!\n",
lina, phy, tlb_phy);
start_lina = 1;
start_phy = 2;
}
} else {
if(all && start_lina != 1)
printf("%08x - %08x: %8x - %8x\n",
start_lina, lina - 0x1000, start_phy, start_phy + (lina-0x1000-start_lina));
if(tlb_valid) {
printf("%08x : (%8x) in TLB Table not valid!!!\n",
lina, tlb_phy);
}
start_lina = 1;
start_phy = 2;
}
if(lina == 0xfffff000)
break;
lina += 0x1000;
}
if(all & start_lina != 1)
printf("%08x - %08x: %8x - %8x\n",
start_lina, 0xfffff000, start_phy, start_phy + (0xfffff000-start_lina));
}