minix/kernel/debug.c
2010-11-18 15:12:01 +00:00

404 lines
7.8 KiB
C

/* This file implements kernel debugging functionality that is not included
* in the standard kernel. Available functionality includes timing of lock
* functions and sanity checking of the scheduling queues.
*/
#include "kernel.h"
#include "proc.h"
#include "debug.h"
#include <minix/callnr.h>
#include <minix/sysutil.h>
#include <minix/u64.h>
#include <limits.h>
#include <string.h>
#define MAX_LOOP (NR_PROCS + NR_TASKS)
PUBLIC int runqueues_ok_cpu(unsigned cpu)
{
int q, l = 0;
register struct proc *xp;
struct proc **rdy_head, **rdy_tail;
rdy_head = get_cpu_var(cpu, run_q_head);
rdy_tail = get_cpu_var(cpu, run_q_tail);
for (xp = BEG_PROC_ADDR; xp < END_PROC_ADDR; ++xp) {
xp->p_found = 0;
if (l++ > MAX_LOOP) panic("check error");
}
for (q=l=0; q < NR_SCHED_QUEUES; q++) {
if (rdy_head[q] && !rdy_tail[q]) {
printf("head but no tail in %d\n", q);
return 0;
}
if (!rdy_head[q] && rdy_tail[q]) {
printf("tail but no head in %d\n", q);
return 0;
}
if (rdy_tail[q] && rdy_tail[q]->p_nextready) {
printf("tail and tail->next not null in %d\n", q);
return 0;
}
for(xp = rdy_head[q]; xp; xp = xp->p_nextready) {
const vir_bytes vxp = (vir_bytes) xp;
vir_bytes dxp;
if(vxp < (vir_bytes) BEG_PROC_ADDR || vxp >= (vir_bytes) END_PROC_ADDR) {
printf("xp out of range\n");
return 0;
}
dxp = vxp - (vir_bytes) BEG_PROC_ADDR;
if(dxp % sizeof(struct proc)) {
printf("xp not a real pointer");
return 0;
}
if(!proc_ptr_ok(xp)) {
printf("xp bogus pointer");
return 0;
}
if (RTS_ISSET(xp, RTS_SLOT_FREE)) {
printf("scheduling error: dead proc q %d %d\n",
q, xp->p_endpoint);
return 0;
}
if (!proc_is_runnable(xp)) {
printf("scheduling error: unready on runq %d proc %d\n",
q, xp->p_nr);
return 0;
}
if (xp->p_priority != q) {
printf("scheduling error: wrong priority q %d proc %d ep %d name %s\n",
q, xp->p_nr, xp->p_endpoint, xp->p_name);
return 0;
}
if (xp->p_found) {
printf("scheduling error: double sched q %d proc %d\n",
q, xp->p_nr);
return 0;
}
xp->p_found = 1;
if (!xp->p_nextready && rdy_tail[q] != xp) {
printf("sched err: last element not tail q %d proc %d\n",
q, xp->p_nr);
return 0;
}
if (l++ > MAX_LOOP) {
printf("loop in schedule queue?");
return 0;
}
}
}
l = 0;
for (xp = BEG_PROC_ADDR; xp < END_PROC_ADDR; ++xp) {
if(!proc_ptr_ok(xp)) {
printf("xp bogus pointer in proc table\n");
return 0;
}
if (isemptyp(xp))
continue;
if(proc_is_runnable(xp) && !xp->p_found) {
printf("sched error: ready proc %d not on queue\n", xp->p_nr);
return 0;
if (l++ > MAX_LOOP) {
printf("loop in debug.c?\n");
return 0;
}
}
}
/* All is ok. */
return 1;
}
#ifdef CONFIG_SMP
PRIVATE int runqueues_ok_all(void)
{
unsigned c;
for (c = 0 ; c < ncpus; c++) {
if (!runqueues_ok_cpu(c))
return 0;
}
return 1;
}
PUBLIC int runqueues_ok(void)
{
return runqueues_ok_all();
}
#else
PUBLIC int runqueues_ok(void)
{
return runqueues_ok_cpu(0);
}
#endif
PUBLIC char *
rtsflagstr(const u32_t flags)
{
static char str[100];
str[0] = '\0';
#define FLAG(n) if(flags & n) { strcat(str, #n " "); }
FLAG(RTS_SLOT_FREE);
FLAG(RTS_PROC_STOP);
FLAG(RTS_SENDING);
FLAG(RTS_RECEIVING);
FLAG(RTS_SIGNALED);
FLAG(RTS_SIG_PENDING);
FLAG(RTS_P_STOP);
FLAG(RTS_NO_PRIV);
FLAG(RTS_NO_ENDPOINT);
FLAG(RTS_VMINHIBIT);
FLAG(RTS_PAGEFAULT);
FLAG(RTS_VMREQUEST);
FLAG(RTS_VMREQTARGET);
FLAG(RTS_PREEMPTED);
FLAG(RTS_NO_QUANTUM);
return str;
}
PUBLIC char *
miscflagstr(const u32_t flags)
{
static char str[100];
str[0] = '\0';
FLAG(MF_REPLY_PEND);
FLAG(MF_ASYNMSG);
FLAG(MF_FULLVM);
FLAG(MF_DELIVERMSG);
FLAG(MF_KCALL_RESUME);
return str;
}
PUBLIC char *
schedulerstr(struct proc *scheduler)
{
if (scheduler != NULL)
{
return scheduler->p_name;
}
return "KERNEL";
}
PRIVATE void
print_proc_name(struct proc *pp)
{
char *name = pp->p_name;
endpoint_t ep = pp->p_endpoint;
if(name) {
printf("%s(%d)", name, ep);
}
else {
printf("%d", ep);
}
}
PRIVATE void
print_endpoint(endpoint_t ep)
{
int proc_nr;
struct proc *pp = NULL;
switch(ep) {
case ANY:
printf("ANY");
break;
case SELF:
printf("SELF");
break;
case NONE:
printf("NONE");
break;
default:
if(!isokendpt(ep, &proc_nr)) {
printf("??? %d\n", ep);
}
else {
pp = proc_addr(proc_nr);
if(isemptyp(pp)) {
printf("??? empty slot %d\n", proc_nr);
}
else {
print_proc_name(pp);
}
}
break;
}
}
PRIVATE void
print_sigmgr(struct proc *pp)
{
endpoint_t sig_mgr, bak_sig_mgr;
sig_mgr = priv(pp)->s_sig_mgr;
bak_sig_mgr = priv(pp)->s_bak_sig_mgr;
printf("sigmgr ");
print_endpoint(sig_mgr);
if(bak_sig_mgr != NONE) {
printf(" / ");
print_endpoint(bak_sig_mgr);
}
}
PUBLIC void print_proc(struct proc *pp)
{
struct proc *depproc = NULL;
endpoint_t dep;
printf("%d: %s %d prio %d time %d/%d cycles 0x%x%08x cpu %2d "
"cr3 0x%lx rts %s misc %s sched %s ",
proc_nr(pp), pp->p_name, pp->p_endpoint,
pp->p_priority, pp->p_user_time,
pp->p_sys_time, ex64hi(pp->p_cycles),
ex64lo(pp->p_cycles), pp->p_cpu,
pp->p_seg.p_cr3,
rtsflagstr(pp->p_rts_flags), miscflagstr(pp->p_misc_flags),
schedulerstr(pp->p_scheduler));
print_sigmgr(pp);
dep = P_BLOCKEDON(pp);
if(dep != NONE) {
printf(" blocked on: ");
print_endpoint(dep);
}
printf("\n");
}
PRIVATE void print_proc_depends(struct proc *pp, const int level)
{
struct proc *depproc = NULL;
endpoint_t dep;
#define COL { int i; for(i = 0; i < level; i++) printf("> "); }
if(level >= NR_PROCS) {
printf("loop??\n");
return;
}
COL
print_proc(pp);
COL
proc_stacktrace(pp);
dep = P_BLOCKEDON(pp);
if(dep != NONE && dep != ANY) {
int procno;
if(isokendpt(dep, &procno)) {
depproc = proc_addr(procno);
if(isemptyp(depproc))
depproc = NULL;
}
if (depproc)
print_proc_depends(depproc, level+1);
}
}
PUBLIC void print_proc_recursive(struct proc *pp)
{
print_proc_depends(pp, 0);
}
#if DEBUG_DUMPIPC
PRIVATE const char *mtypename(int mtype, int iscall)
{
/* use generated file to recognize message types */
if (iscall) {
switch(mtype) {
#define IDENT(x) case x: return #x;
#include "extracted-mtype.h"
#undef IDENT(
}
} else {
switch(mtype) {
#define IDENT(x) case x: return #x;
#include "extracted-errno.h"
#undef IDENT(
}
}
/* no match */
return NULL;
}
PRIVATE void printparam(const char *name, const void *data, size_t size)
{
printf(" %s=", name);
switch (size) {
case sizeof(char): printf("%d", *(char *) data); break;
case sizeof(short): printf("%d", *(short *) data); break;
case sizeof(int): printf("%d", *(int *) data); break;
default: printf("(%u bytes)", size); break;
}
}
PRIVATE void printproc(struct proc *rp)
{
if (rp)
printf(" %s(%d)", rp->p_name, rp - proc);
else
printf(" kernel");
}
PRIVATE void printmsg(message *msg, struct proc *src, struct proc *dst,
char operation, int iscall, int printparams)
{
const char *name;
int mtype = msg->m_type;
/* source, destination and message type */
printf("%c", operation);
printproc(src);
printproc(dst);
name = mtypename(mtype, iscall);
if (name) {
printf(" %s(%d)", name, mtype);
} else {
printf(" %d", mtype);
}
if (iscall && printparams) {
#define IDENT(x, y) if (mtype == x) printparam(#y, &msg->y, sizeof(msg->y));
#include "extracted-mfield.h"
#undef IDENT
}
printf("\n");
}
PUBLIC void printmsgkcall(message *msg, struct proc *proc)
{
printmsg(msg, proc, NULL, 'k', 1, 1);
}
PUBLIC void printmsgkresult(message *msg, struct proc *proc)
{
printmsg(msg, NULL, proc, 'k', 0, 0);
}
PUBLIC void printmsgrecv(message *msg, struct proc *src, struct proc *dst)
{
printmsg(msg, src, dst, 'r', src->p_misc_flags & MF_REPLY_PEND, 0);
}
PUBLIC void printmsgsend(message *msg, struct proc *src, struct proc *dst)
{
printmsg(msg, src, dst, 's', src->p_misc_flags & MF_REPLY_PEND, 1);
}
#endif