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/*
* Mach Operating System
* Copyright (c) 1993-1990 Carnegie Mellon University
* All Rights Reserved.
*
* Permission to use, copy, modify and distribute this software and its
* documentation is hereby granted, provided that both the copyright
* notice and this permission notice appear in all copies of the
* software, derivative works or modified versions, and any portions
* thereof, and that both notices appear in supporting documentation.
*
* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
* ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
*
* Carnegie Mellon requests users of this software to return to
*
* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
* School of Computer Science
* Carnegie Mellon University
* Pittsburgh PA 15213-3890
*
* any improvements or extensions that they make and grant Carnegie Mellon
* the rights to redistribute these changes.
*/
/*
* Author: David B. Golub, Carnegie Mellon University
* Date: 7/90
*/
#if MACH_KDB
/*
* Commands to run process.
*/
#include <mach/boolean.h>
#include <machine/db_machdep.h>
#include <ddb/db_lex.h>
#include <ddb/db_break.h>
#include <ddb/db_access.h>
#include <ddb/db_run.h>
#include <ddb/db_task_thread.h>
#include <ddb/db_command.h>
#include <ddb/db_examine.h>
#include <ddb/db_output.h>
#include <ddb/db_watch.h>
#include <ddb/db_cond.h>
int db_run_mode;
boolean_t db_sstep_print;
int db_loop_count;
int db_call_depth;
int db_inst_count;
int db_last_inst_count;
int db_load_count;
int db_store_count;
boolean_t
db_stop_at_pc(is_breakpoint, task)
boolean_t *is_breakpoint;
task_t task;
{
db_addr_t pc;
db_thread_breakpoint_t bkpt;
db_clear_task_single_step(DDB_REGS, task);
db_clear_breakpoints();
db_clear_watchpoints();
pc = PC_REGS(DDB_REGS);
#ifdef FIXUP_PC_AFTER_BREAK
if (*is_breakpoint) {
/*
* Breakpoint trap. Fix up the PC if the
* machine requires it.
*/
FIXUP_PC_AFTER_BREAK
pc = PC_REGS(DDB_REGS);
}
#endif
/*
* Now check for a breakpoint at this address.
*/
bkpt = db_find_thread_breakpoint_here(task, pc);
if (bkpt) {
if (db_cond_check(bkpt)) {
*is_breakpoint = TRUE;
return (TRUE); /* stop here */
}
}
*is_breakpoint = FALSE;
if (db_run_mode == STEP_INVISIBLE) {
db_run_mode = STEP_CONTINUE;
return (FALSE); /* continue */
}
if (db_run_mode == STEP_COUNT) {
return (FALSE); /* continue */
}
if (db_run_mode == STEP_ONCE) {
if (--db_loop_count > 0) {
if (db_sstep_print) {
db_print_loc_and_inst(pc, task);
}
return (FALSE); /* continue */
}
}
if (db_run_mode == STEP_RETURN) {
/* WARNING: the following assumes an instruction fits an int */
db_expr_t ins = db_get_task_value(pc, sizeof(int), FALSE, task);
/* continue until matching return */
if (!inst_trap_return(ins) &&
(!inst_return(ins) || --db_call_depth != 0)) {
if (db_sstep_print) {
if (inst_call(ins) || inst_return(ins)) {
int i;
db_printf("[after %6d /%4d] ",
db_inst_count,
db_inst_count - db_last_inst_count);
db_last_inst_count = db_inst_count;
for (i = db_call_depth; --i > 0; )
db_printf(" ");
db_print_loc_and_inst(pc, task);
db_printf("\n");
}
}
if (inst_call(ins))
db_call_depth++;
return (FALSE); /* continue */
}
}
if (db_run_mode == STEP_CALLT) {
/* WARNING: the following assumes an instruction fits an int */
db_expr_t ins = db_get_task_value(pc, sizeof(int), FALSE, task);
/* continue until call or return */
if (!inst_call(ins) &&
!inst_return(ins) &&
!inst_trap_return(ins)) {
return (FALSE); /* continue */
}
}
if (db_find_breakpoint_here(task, pc))
return(FALSE);
db_run_mode = STEP_NONE;
return (TRUE);
}
void
db_restart_at_pc(watchpt, task)
boolean_t watchpt;
task_t task;
{
db_addr_t pc = PC_REGS(DDB_REGS);
if ((db_run_mode == STEP_COUNT) ||
(db_run_mode == STEP_RETURN) ||
(db_run_mode == STEP_CALLT)) {
/*
* We are about to execute this instruction,
* so count it now.
*/
db_get_task_value(pc, sizeof(int), FALSE, task);
db_inst_count++;
db_load_count += inst_load(ins);
db_store_count += inst_store(ins);
#ifdef SOFTWARE_SSTEP
db_addr_t brpc;
/* Account for instructions in delay slots */
brpc = next_instr_address(pc, 1, task);
if ((brpc != pc) && (inst_branch(ins) || inst_call(ins))) {
/* Note: this ~assumes an instruction <= sizeof(int) */
db_get_task_value(brpc, sizeof(int), FALSE, task);
db_inst_count++;
db_load_count += inst_load(ins);
db_store_count += inst_store(ins);
}
#endif /* SOFTWARE_SSTEP */
}
if (db_run_mode == STEP_CONTINUE) {
if (watchpt || db_find_breakpoint_here(task, pc)) {
/*
* Step over breakpoint/watchpoint.
*/
db_run_mode = STEP_INVISIBLE;
db_set_task_single_step(DDB_REGS, task);
} else {
db_set_breakpoints();
db_set_watchpoints();
}
} else {
db_set_task_single_step(DDB_REGS, task);
}
}
void
db_single_step(regs, task)
db_regs_t *regs;
task_t task;
{
if (db_run_mode == STEP_CONTINUE) {
db_run_mode = STEP_INVISIBLE;
db_set_task_single_step(regs, task);
}
}
#ifdef SOFTWARE_SSTEP
/*
* Software implementation of single-stepping.
* If your machine does not have a trace mode
* similar to the vax or sun ones you can use
* this implementation, done for the mips.
* Just define the above conditional and provide
* the functions/macros defined below.
*
* extern boolean_t
* inst_branch(), returns true if the instruction might branch
* extern unsigned
* branch_taken(), return the address the instruction might
* branch to
* db_getreg_val(); return the value of a user register,
* as indicated in the hardware instruction
* encoding, e.g. 8 for r8
*
* next_instr_address(pc,bd,task) returns the address of the first
* instruction following the one at "pc",
* which is either in the taken path of
* the branch (bd==1) or not. This is
* for machines (mips) with branch delays.
*
* A single-step may involve at most 2 breakpoints -
* one for branch-not-taken and one for branch taken.
* If one of these addresses does not already have a breakpoint,
* we allocate a breakpoint and save it here.
* These breakpoints are deleted on return.
*/
db_breakpoint_t db_not_taken_bkpt = 0;
db_breakpoint_t db_taken_bkpt = 0;
db_breakpoint_t
db_find_temp_breakpoint(task, addr)
task_t task;
db_addr_t addr;
{
if (db_taken_bkpt && (db_taken_bkpt->address == addr) &&
db_taken_bkpt->task == task)
return db_taken_bkpt;
if (db_not_taken_bkpt && (db_not_taken_bkpt->address == addr) &&
db_not_taken_bkpt->task == task)
return db_not_taken_bkpt;
return 0;
}
void
db_set_task_single_step(regs, task)
db_regs_t *regs;
task_t task;
{
db_addr_t pc = PC_REGS(regs), brpc;
unsigned int inst;
boolean_t unconditional;
/*
* User was stopped at pc, e.g. the instruction
* at pc was not executed.
*/
inst = db_get_task_value(pc, sizeof(int), FALSE, task);
if (inst_branch(inst) || inst_call(inst)) {
extern db_expr_t getreg_val();
brpc = branch_taken(inst, pc, getreg_val, regs);
if (brpc != pc) { /* self-branches are hopeless */
db_taken_bkpt = db_set_temp_breakpoint(task, brpc);
} else
db_taken_bkpt = 0;
pc = next_instr_address(pc,1,task);
}
/* check if this control flow instruction is an unconditional transfer */
unconditional = inst_unconditional_flow_transfer(inst);
pc = next_instr_address(pc,0,task);
/*
We only set the sequential breakpoint if previous instruction was not
an unconditional change of flow of control. If the previous instruction
is an unconditional change of flow of control, setting a breakpoint in the
next sequential location may set a breakpoint in data or in another routine,
which could screw up either the program or the debugger.
(Consider, for instance, that the next sequential instruction is the
start of a routine needed by the debugger.)
*/
if (!unconditional && db_find_breakpoint_here(task, pc) == 0) {
db_not_taken_bkpt = db_set_temp_breakpoint(task, pc);
}
else
db_not_taken_bkpt = 0;
}
void
db_clear_task_single_step(regs, task)
db_regs_t *regs;
task_t task;
{
if (db_taken_bkpt != 0) {
db_delete_temp_breakpoint(task, db_taken_bkpt);
db_taken_bkpt = 0;
}
if (db_not_taken_bkpt != 0) {
db_delete_temp_breakpoint(task, db_not_taken_bkpt);
db_not_taken_bkpt = 0;
}
}
#endif /* SOFTWARE_SSTEP */
extern int db_cmd_loop_done;
/* single-step */
/*ARGSUSED*/
void
db_single_step_cmd(addr, have_addr, count, modif)
db_expr_t addr;
int have_addr;
db_expr_t count;
char * modif;
{
boolean_t print = FALSE;
if (count == -1)
count = 1;
if (modif[0] == 'p')
print = TRUE;
db_run_mode = STEP_ONCE;
db_loop_count = count;
db_sstep_print = print;
db_inst_count = 0;
db_last_inst_count = 0;
db_load_count = 0;
db_store_count = 0;
db_cmd_loop_done = 1;
}
/* trace and print until call/return */
/*ARGSUSED*/
void
db_trace_until_call_cmd(addr, have_addr, count, modif)
db_expr_t addr;
int have_addr;
db_expr_t count;
char * modif;
{
boolean_t print = FALSE;
if (modif[0] == 'p')
print = TRUE;
db_run_mode = STEP_CALLT;
db_sstep_print = print;
db_inst_count = 0;
db_last_inst_count = 0;
db_load_count = 0;
db_store_count = 0;
db_cmd_loop_done = 1;
}
/*ARGSUSED*/
void
db_trace_until_matching_cmd(addr, have_addr, count, modif)
db_expr_t addr;
int have_addr;
db_expr_t count;
char * modif;
{
boolean_t print = FALSE;
if (modif[0] == 'p')
print = TRUE;
db_run_mode = STEP_RETURN;
db_call_depth = 1;
db_sstep_print = print;
db_inst_count = 0;
db_last_inst_count = 0;
db_load_count = 0;
db_store_count = 0;
db_cmd_loop_done = 1;
}
/* continue */
/*ARGSUSED*/
void
db_continue_cmd(addr, have_addr, count, modif)
db_expr_t addr;
int have_addr;
db_expr_t count;
char * modif;
{
if (modif[0] == 'c')
db_run_mode = STEP_COUNT;
else
db_run_mode = STEP_CONTINUE;
db_inst_count = 0;
db_last_inst_count = 0;
db_load_count = 0;
db_store_count = 0;
db_cmd_loop_done = 1;
}
boolean_t
db_in_single_step()
{
return(db_run_mode != STEP_NONE && db_run_mode != STEP_CONTINUE);
}
#endif /* MACH_KDB */
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