#include <mach_kdb.h>
#include <mach_ldebug.h>
#include <kern/lock.h>
#include <kern/locks.h>
#include <kern/kalloc.h>
#include <kern/misc_protos.h>
#include <kern/thread.h>
#include <kern/processor.h>
#include <kern/cpu_data.h>
#include <kern/cpu_number.h>
#include <kern/sched_prim.h>
#include <kern/xpr.h>
#include <kern/debug.h>
#include <string.h>
#if MACH_KDB
#include <ddb/db_command.h>
#include <ddb/db_output.h>
#include <ddb/db_sym.h>
#include <ddb/db_print.h>
#endif
#ifdef __ppc__
#include <ppc/Firmware.h>
#endif
#include <sys/kdebug.h>
#define LCK_RW_LCK_EXCLUSIVE_CODE 0x100
#define LCK_RW_LCK_EXCLUSIVE1_CODE 0x101
#define LCK_RW_LCK_SHARED_CODE 0x102
#define LCK_RW_LCK_SH_TO_EX_CODE 0x103
#define LCK_RW_LCK_SH_TO_EX1_CODE 0x104
#define LCK_RW_LCK_EX_TO_SH_CODE 0x105
#define ANY_LOCK_DEBUG (USLOCK_DEBUG || LOCK_DEBUG || MUTEX_DEBUG)
unsigned int LcksOpts=0;
unsigned int lock_wait_time[2] = { (unsigned int)-1, 100 } ;
#if MACH_KDB
void db_print_simple_lock(
simple_lock_t addr);
void db_print_mutex(
mutex_t * addr);
#endif
#if USLOCK_DEBUG
int uslock_check = 1;
int max_lock_loops = 100000000;
decl_simple_lock_data(extern , printf_lock)
decl_simple_lock_data(extern , panic_lock)
#if MACH_KDB
decl_simple_lock_data(extern , kdb_lock)
#endif
#endif
typedef void *pc_t;
#define INVALID_PC ((void *) VM_MAX_KERNEL_ADDRESS)
#define INVALID_THREAD ((void *) VM_MAX_KERNEL_ADDRESS)
#if ANY_LOCK_DEBUG
#define OBTAIN_PC(pc,l) ((pc) = (void *) GET_RETURN_PC(&(l)))
#define DECL_PC(pc) pc_t pc;
#else
#define DECL_PC(pc)
#ifdef lint
#define OBTAIN_PC(pc,l) ++pc
#else
#define OBTAIN_PC(pc,l)
#endif
#endif
#if USLOCK_DEBUG
#define USLDBG(stmt) stmt
void usld_lock_init(usimple_lock_t, unsigned short);
void usld_lock_pre(usimple_lock_t, pc_t);
void usld_lock_post(usimple_lock_t, pc_t);
void usld_unlock(usimple_lock_t, pc_t);
void usld_lock_try_pre(usimple_lock_t, pc_t);
void usld_lock_try_post(usimple_lock_t, pc_t);
int usld_lock_common_checks(usimple_lock_t, char *);
#else
#define USLDBG(stmt)
#endif
lck_spin_t *
lck_spin_alloc_init(
lck_grp_t *grp,
lck_attr_t *attr)
{
lck_spin_t *lck;
if ((lck = (lck_spin_t *)kalloc(sizeof(lck_spin_t))) != 0)
lck_spin_init(lck, grp, attr);
return(lck);
}
void
lck_spin_free(
lck_spin_t *lck,
lck_grp_t *grp)
{
lck_spin_destroy(lck, grp);
kfree(lck, sizeof(lck_spin_t));
}
void
lck_spin_init(
lck_spin_t *lck,
lck_grp_t *grp,
__unused lck_attr_t *attr)
{
usimple_lock_init((usimple_lock_t) lck, 0);
lck_grp_reference(grp);
lck_grp_lckcnt_incr(grp, LCK_TYPE_SPIN);
}
void
lck_spin_destroy(
lck_spin_t *lck,
lck_grp_t *grp)
{
if (lck->lck_spin_data[0] == LCK_SPIN_TAG_DESTROYED)
return;
lck->lck_spin_data[0] = LCK_SPIN_TAG_DESTROYED;
lck_grp_lckcnt_decr(grp, LCK_TYPE_SPIN);
lck_grp_deallocate(grp);
return;
}
void
lck_spin_lock(
lck_spin_t *lck)
{
usimple_lock((usimple_lock_t) lck);
}
void
lck_spin_unlock(
lck_spin_t *lck)
{
usimple_unlock((usimple_lock_t) lck);
}
boolean_t
lck_spin_try_lock(
lck_spin_t *lck)
{
usimple_lock_try((usimple_lock_t) lck);
}
void
usimple_lock_init(
usimple_lock_t l,
__unused unsigned short tag)
{
#ifndef MACHINE_SIMPLE_LOCK
USLDBG(usld_lock_init(l, tag));
hw_lock_init(&l->interlock);
#else
simple_lock_init((simple_lock_t)l,tag);
#endif
}
void
usimple_lock(
usimple_lock_t l)
{
#ifndef MACHINE_SIMPLE_LOCK
pc_t pc = NULL;
OBTAIN_PC(pc, l);
USLDBG(usld_lock_pre(l, pc));
if(!hw_lock_to(&l->interlock, LockTimeOut))
panic("simple lock deadlock detection - l=%08X, cpu=%d, ret=%08X", l, cpu_number(), pc);
USLDBG(usld_lock_post(l, pc));
#else
simple_lock((simple_lock_t)l);
#endif
}
void
usimple_unlock(
usimple_lock_t l)
{
#ifndef MACHINE_SIMPLE_LOCK
DECL_PC(pc);
OBTAIN_PC(pc, l);
USLDBG(usld_unlock(l, pc));
hw_lock_unlock(&l->interlock);
#else
simple_unlock_rwmb((simple_lock_t)l);
#endif
}
unsigned int
usimple_lock_try(
usimple_lock_t l)
{
#ifndef MACHINE_SIMPLE_LOCK
DECL_PC(pc);
unsigned int success;
OBTAIN_PC(pc, l);
USLDBG(usld_lock_try_pre(l, pc));
if ((success = hw_lock_try(&l->interlock))) {
USLDBG(usld_lock_try_post(l, pc));
}
return success;
#else
return(simple_lock_try((simple_lock_t)l));
#endif
}
#if USLOCK_DEBUG
#define USLOCK_CHECKED 0x0001
#define USLOCK_TAKEN 0x0002
#define USLOCK_INIT 0xBAA0
#define USLOCK_INITIALIZED (USLOCK_INIT|USLOCK_CHECKED)
#define USLOCK_CHECKING(l) (uslock_check && \
((l)->debug.state & USLOCK_CHECKED))
void usl_trace(usimple_lock_t, int, pc_t, const char *);
void
usld_lock_init(
usimple_lock_t l,
__unused unsigned short tag)
{
if (l == USIMPLE_LOCK_NULL)
panic("lock initialization: null lock pointer");
l->lock_type = USLOCK_TAG;
l->debug.state = uslock_check ? USLOCK_INITIALIZED : 0;
l->debug.lock_cpu = l->debug.unlock_cpu = 0;
l->debug.lock_pc = l->debug.unlock_pc = INVALID_PC;
l->debug.lock_thread = l->debug.unlock_thread = INVALID_THREAD;
l->debug.duration[0] = l->debug.duration[1] = 0;
l->debug.unlock_cpu = l->debug.unlock_cpu = 0;
l->debug.unlock_pc = l->debug.unlock_pc = INVALID_PC;
l->debug.unlock_thread = l->debug.unlock_thread = INVALID_THREAD;
}
int
usld_lock_common_checks(
usimple_lock_t l,
char *caller)
{
if (l == USIMPLE_LOCK_NULL)
panic("%s: null lock pointer", caller);
if (l->lock_type != USLOCK_TAG)
panic("%s: 0x%x is not a usimple lock", caller, (integer_t) l);
if (!(l->debug.state & USLOCK_INIT))
panic("%s: 0x%x is not an initialized lock",
caller, (integer_t) l);
return USLOCK_CHECKING(l);
}
void
usld_lock_pre(
usimple_lock_t l,
pc_t pc)
{
char caller[] = "usimple_lock";
if (!usld_lock_common_checks(l, caller))
return;
if ((l->debug.state & USLOCK_TAKEN) && l->debug.lock_thread &&
l->debug.lock_thread == (void *) current_thread()) {
printf("%s: lock 0x%x already locked (at 0x%x) by",
caller, (integer_t) l, l->debug.lock_pc);
printf(" current thread 0x%x (new attempt at pc 0x%x)\n",
l->debug.lock_thread, pc);
panic(caller);
}
mp_disable_preemption();
usl_trace(l, cpu_number(), pc, caller);
mp_enable_preemption();
}
void
usld_lock_post(
usimple_lock_t l,
pc_t pc)
{
register int mycpu;
char caller[] = "successful usimple_lock";
if (!usld_lock_common_checks(l, caller))
return;
if (!((l->debug.state & ~USLOCK_TAKEN) == USLOCK_INITIALIZED))
panic("%s: lock 0x%x became uninitialized",
caller, (integer_t) l);
if ((l->debug.state & USLOCK_TAKEN))
panic("%s: lock 0x%x became TAKEN by someone else",
caller, (integer_t) l);
mycpu = cpu_number();
l->debug.lock_thread = (void *)current_thread();
l->debug.state |= USLOCK_TAKEN;
l->debug.lock_pc = pc;
l->debug.lock_cpu = mycpu;
usl_trace(l, mycpu, pc, caller);
}
void
usld_unlock(
usimple_lock_t l,
pc_t pc)
{
register int mycpu;
char caller[] = "usimple_unlock";
if (!usld_lock_common_checks(l, caller))
return;
mycpu = cpu_number();
if (!(l->debug.state & USLOCK_TAKEN))
panic("%s: lock 0x%x hasn't been taken",
caller, (integer_t) l);
if (l->debug.lock_thread != (void *) current_thread())
panic("%s: unlocking lock 0x%x, owned by thread 0x%x",
caller, (integer_t) l, l->debug.lock_thread);
if (l->debug.lock_cpu != mycpu) {
printf("%s: unlocking lock 0x%x on cpu 0x%x",
caller, (integer_t) l, mycpu);
printf(" (acquired on cpu 0x%x)\n", l->debug.lock_cpu);
panic(caller);
}
usl_trace(l, mycpu, pc, caller);
l->debug.unlock_thread = l->debug.lock_thread;
l->debug.lock_thread = INVALID_PC;
l->debug.state &= ~USLOCK_TAKEN;
l->debug.unlock_pc = pc;
l->debug.unlock_cpu = mycpu;
}
void
usld_lock_try_pre(
usimple_lock_t l,
pc_t pc)
{
char caller[] = "usimple_lock_try";
if (!usld_lock_common_checks(l, caller))
return;
mp_disable_preemption();
usl_trace(l, cpu_number(), pc, caller);
mp_enable_preemption();
}
void
usld_lock_try_post(
usimple_lock_t l,
pc_t pc)
{
register int mycpu;
char caller[] = "successful usimple_lock_try";
if (!usld_lock_common_checks(l, caller))
return;
if (!((l->debug.state & ~USLOCK_TAKEN) == USLOCK_INITIALIZED))
panic("%s: lock 0x%x became uninitialized",
caller, (integer_t) l);
if ((l->debug.state & USLOCK_TAKEN))
panic("%s: lock 0x%x became TAKEN by someone else",
caller, (integer_t) l);
mycpu = cpu_number();
l->debug.lock_thread = (void *) current_thread();
l->debug.state |= USLOCK_TAKEN;
l->debug.lock_pc = pc;
l->debug.lock_cpu = mycpu;
usl_trace(l, mycpu, pc, caller);
}
usimple_lock_t traced_lock;
unsigned int lock_seq;
void
usl_trace(
usimple_lock_t l,
int mycpu,
pc_t pc,
const char * op_name)
{
if (traced_lock == l) {
XPR(XPR_SLOCK,
"seq %d, cpu %d, %s @ %x\n",
(integer_t) lock_seq, (integer_t) mycpu,
(integer_t) op_name, (integer_t) pc, 0);
lock_seq++;
}
}
#endif
lock_t *
lock_alloc(
boolean_t can_sleep,
unsigned short tag,
unsigned short tag1)
{
lock_t *l;
if ((l = (lock_t *)kalloc(sizeof(lock_t))) != 0)
lock_init(l, can_sleep, tag, tag1);
return(l);
}
void
lock_free(
lock_t *l)
{
kfree(l, sizeof(lock_t));
}
void
lock_init(
lock_t *l,
boolean_t can_sleep,
__unused unsigned short tag,
unsigned short tag1)
{
(void) memset((void *) l, 0, sizeof(lock_t));
simple_lock_init(&l->interlock, tag1);
l->want_write = FALSE;
l->want_upgrade = FALSE;
l->read_count = 0;
l->can_sleep = can_sleep;
}
#define DECREMENTER_TIMEOUT 1000000
void
lock_write(
register lock_t * l)
{
register int i;
boolean_t lock_miss = FALSE;
#if MACH_LDEBUG
int decrementer;
#endif
simple_lock(&l->interlock);
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while (l->want_write) {
if (!lock_miss) {
lock_miss = TRUE;
}
i = lock_wait_time[l->can_sleep ? 1 : 0];
if (i != 0) {
simple_unlock(&l->interlock);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - want_write");
#endif
while (--i != 0 && l->want_write)
continue;
simple_lock(&l->interlock);
}
if (l->can_sleep && l->want_write) {
l->waiting = TRUE;
thread_sleep_simple_lock((event_t) l,
simple_lock_addr(l->interlock),
THREAD_UNINT);
}
}
l->want_write = TRUE;
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while ((l->read_count != 0) || l->want_upgrade) {
if (!lock_miss) {
lock_miss = TRUE;
}
i = lock_wait_time[l->can_sleep ? 1 : 0];
if (i != 0) {
simple_unlock(&l->interlock);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - wait for readers");
#endif
while (--i != 0 && (l->read_count != 0 ||
l->want_upgrade))
continue;
simple_lock(&l->interlock);
}
if (l->can_sleep && (l->read_count != 0 || l->want_upgrade)) {
l->waiting = TRUE;
thread_sleep_simple_lock((event_t) l,
simple_lock_addr(l->interlock),
THREAD_UNINT);
}
}
simple_unlock(&l->interlock);
}
void
lock_done(
register lock_t * l)
{
boolean_t do_wakeup = FALSE;
simple_lock(&l->interlock);
if (l->read_count != 0) {
l->read_count--;
}
else
if (l->want_upgrade) {
l->want_upgrade = FALSE;
}
else {
l->want_write = FALSE;
}
if (l->waiting && (l->read_count == 0)) {
l->waiting = FALSE;
do_wakeup = TRUE;
}
simple_unlock(&l->interlock);
if (do_wakeup)
thread_wakeup((event_t) l);
}
void
lock_read(
register lock_t * l)
{
register int i;
#if MACH_LDEBUG
int decrementer;
#endif
simple_lock(&l->interlock);
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while (l->want_write || l->want_upgrade) {
i = lock_wait_time[l->can_sleep ? 1 : 0];
if (i != 0) {
simple_unlock(&l->interlock);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - wait no writers");
#endif
while (--i != 0 && (l->want_write || l->want_upgrade))
continue;
simple_lock(&l->interlock);
}
if (l->can_sleep && (l->want_write || l->want_upgrade)) {
l->waiting = TRUE;
thread_sleep_simple_lock((event_t) l,
simple_lock_addr(l->interlock),
THREAD_UNINT);
}
}
l->read_count++;
simple_unlock(&l->interlock);
}
boolean_t
lock_read_to_write(
register lock_t * l)
{
register int i;
boolean_t do_wakeup = FALSE;
#if MACH_LDEBUG
int decrementer;
#endif
simple_lock(&l->interlock);
l->read_count--;
if (l->want_upgrade) {
if (l->waiting && (l->read_count == 0)) {
l->waiting = FALSE;
do_wakeup = TRUE;
}
simple_unlock(&l->interlock);
if (do_wakeup)
thread_wakeup((event_t) l);
return (TRUE);
}
l->want_upgrade = TRUE;
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while (l->read_count != 0) {
i = lock_wait_time[l->can_sleep ? 1 : 0];
if (i != 0) {
simple_unlock(&l->interlock);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - read_count");
#endif
while (--i != 0 && l->read_count != 0)
continue;
simple_lock(&l->interlock);
}
if (l->can_sleep && l->read_count != 0) {
l->waiting = TRUE;
thread_sleep_simple_lock((event_t) l,
simple_lock_addr(l->interlock),
THREAD_UNINT);
}
}
simple_unlock(&l->interlock);
return (FALSE);
}
void
lock_write_to_read(
register lock_t * l)
{
boolean_t do_wakeup = FALSE;
simple_lock(&l->interlock);
l->read_count++;
if (l->want_upgrade)
l->want_upgrade = FALSE;
else
l->want_write = FALSE;
if (l->waiting) {
l->waiting = FALSE;
do_wakeup = TRUE;
}
simple_unlock(&l->interlock);
if (do_wakeup)
thread_wakeup((event_t) l);
}
#if 0
boolean_t
lock_try_write(
register lock_t * l)
{
pc_t pc;
simple_lock(&l->interlock);
if (l->want_write || l->want_upgrade || l->read_count) {
simple_unlock(&l->interlock);
return(FALSE);
}
l->want_write = TRUE;
simple_unlock(&l->interlock);
return(TRUE);
}
boolean_t
lock_try_read(
register lock_t * l)
{
pc_t pc;
simple_lock(&l->interlock);
if (l->want_write || l->want_upgrade) {
simple_unlock(&l->interlock);
return(FALSE);
}
l->read_count++;
simple_unlock(&l->interlock);
return(TRUE);
}
#endif
lck_rw_t *
lck_rw_alloc_init(
lck_grp_t *grp,
lck_attr_t *attr) {
lck_rw_t *lck;
if ((lck = (lck_rw_t *)kalloc(sizeof(lck_rw_t))) != 0)
lck_rw_init(lck, grp, attr);
return(lck);
}
void
lck_rw_free(
lck_rw_t *lck,
lck_grp_t *grp) {
lck_rw_destroy(lck, grp);
kfree(lck, sizeof(lck_rw_t));
}
void
lck_rw_init(
lck_rw_t *lck,
lck_grp_t *grp,
__unused lck_attr_t *attr) {
hw_lock_init(&lck->interlock);
lck->want_write = FALSE;
lck->want_upgrade = FALSE;
lck->read_count = 0;
lck->can_sleep = TRUE;
lck->lck_rw_tag = 0;
lck_grp_reference(grp);
lck_grp_lckcnt_incr(grp, LCK_TYPE_RW);
}
void
lck_rw_destroy(
lck_rw_t *lck,
lck_grp_t *grp) {
if (lck->lck_rw_tag == LCK_RW_TAG_DESTROYED)
return;
lck->lck_rw_tag = LCK_RW_TAG_DESTROYED;
lck_grp_lckcnt_decr(grp, LCK_TYPE_RW);
lck_grp_deallocate(grp);
return;
}
#define DECREMENTER_TIMEOUT 1000000
static boolean_t
lck_interlock_lock(lck_rw_t *lck)
{
boolean_t istate;
istate = ml_set_interrupts_enabled(FALSE);
hw_lock_lock(&lck->interlock);
return istate;
}
static void
lck_interlock_unlock(lck_rw_t *lck, boolean_t istate)
{
hw_lock_unlock(&lck->interlock);
ml_set_interrupts_enabled(istate);
}
void
lck_rw_lock_exclusive(
lck_rw_t *lck)
{
int i;
boolean_t lock_miss = FALSE;
wait_result_t res;
#if MACH_LDEBUG
int decrementer;
#endif
boolean_t istate;
istate = lck_interlock_lock(lck);
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while (lck->want_write) {
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_EXCLUSIVE_CODE) | DBG_FUNC_START, (int)lck, 0, 0, 0, 0);
if (!lock_miss) {
lock_miss = TRUE;
}
i = lock_wait_time[lck->can_sleep ? 1 : 0];
if (i != 0) {
lck_interlock_unlock(lck, istate);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - want_write");
#endif
while (--i != 0 && lck->want_write)
continue;
istate = lck_interlock_lock(lck);
}
if (lck->can_sleep && lck->want_write) {
lck->waiting = TRUE;
res = assert_wait((event_t) lck, THREAD_UNINT);
if (res == THREAD_WAITING) {
lck_interlock_unlock(lck, istate);
res = thread_block(THREAD_CONTINUE_NULL);
istate = lck_interlock_lock(lck);
}
}
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_EXCLUSIVE_CODE) | DBG_FUNC_END, (int)lck, res, 0, 0, 0);
}
lck->want_write = TRUE;
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while ((lck->read_count != 0) || lck->want_upgrade) {
if (!lock_miss) {
lock_miss = TRUE;
}
i = lock_wait_time[lck->can_sleep ? 1 : 0];
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_EXCLUSIVE1_CODE) | DBG_FUNC_START,
(int)lck, lck->read_count, lck->want_upgrade, i, 0);
if (i != 0) {
lck_interlock_unlock(lck, istate);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - wait for readers");
#endif
while (--i != 0 && (lck->read_count != 0 ||
lck->want_upgrade))
continue;
istate = lck_interlock_lock(lck);
}
if (lck->can_sleep && (lck->read_count != 0 || lck->want_upgrade)) {
lck->waiting = TRUE;
res = assert_wait((event_t) lck, THREAD_UNINT);
if (res == THREAD_WAITING) {
lck_interlock_unlock(lck, istate);
res = thread_block(THREAD_CONTINUE_NULL);
istate = lck_interlock_lock(lck);
}
}
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_EXCLUSIVE1_CODE) | DBG_FUNC_END,
(int)lck, lck->read_count, lck->want_upgrade, res, 0);
}
lck_interlock_unlock(lck, istate);
}
lck_rw_type_t
lck_rw_done(
lck_rw_t *lck)
{
boolean_t do_wakeup = FALSE;
lck_rw_type_t lck_rw_type;
boolean_t istate;
istate = lck_interlock_lock(lck);
if (lck->read_count != 0) {
lck_rw_type = LCK_RW_TYPE_SHARED;
lck->read_count--;
}
else {
lck_rw_type = LCK_RW_TYPE_EXCLUSIVE;
if (lck->want_upgrade)
lck->want_upgrade = FALSE;
else
lck->want_write = FALSE;
}
if (lck->waiting && (lck->read_count == 0)) {
lck->waiting = FALSE;
do_wakeup = TRUE;
}
lck_interlock_unlock(lck, istate);
if (do_wakeup)
thread_wakeup((event_t) lck);
return(lck_rw_type);
}
void
lck_rw_unlock(
lck_rw_t *lck,
lck_rw_type_t lck_rw_type)
{
if (lck_rw_type == LCK_RW_TYPE_SHARED)
lck_rw_unlock_shared(lck);
else if (lck_rw_type == LCK_RW_TYPE_EXCLUSIVE)
lck_rw_unlock_exclusive(lck);
else
panic("lck_rw_unlock(): Invalid RW lock type: %d\n", lck_rw_type);
}
void
lck_rw_unlock_shared(
lck_rw_t *lck)
{
lck_rw_type_t ret;
ret = lck_rw_done(lck);
if (ret != LCK_RW_TYPE_SHARED)
panic("lck_rw_unlock(): lock held in mode: %d\n", ret);
}
void
lck_rw_unlock_exclusive(
lck_rw_t *lck)
{
lck_rw_type_t ret;
ret = lck_rw_done(lck);
if (ret != LCK_RW_TYPE_EXCLUSIVE)
panic("lck_rw_unlock_exclusive(): lock held in mode: %d\n", ret);
}
void
lck_rw_lock(
lck_rw_t *lck,
lck_rw_type_t lck_rw_type)
{
if (lck_rw_type == LCK_RW_TYPE_SHARED)
lck_rw_lock_shared(lck);
else if (lck_rw_type == LCK_RW_TYPE_EXCLUSIVE)
lck_rw_lock_exclusive(lck);
else
panic("lck_rw_lock(): Invalid RW lock type: %x\n", lck_rw_type);
}
void
lck_rw_lock_shared(
lck_rw_t *lck)
{
int i;
wait_result_t res;
#if MACH_LDEBUG
int decrementer;
#endif
boolean_t istate;
istate = lck_interlock_lock(lck);
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while (lck->want_write || lck->want_upgrade) {
i = lock_wait_time[lck->can_sleep ? 1 : 0];
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_SHARED_CODE) | DBG_FUNC_START,
(int)lck, lck->want_write, lck->want_upgrade, i, 0);
if (i != 0) {
lck_interlock_unlock(lck, istate);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - wait no writers");
#endif
while (--i != 0 && (lck->want_write || lck->want_upgrade))
continue;
istate = lck_interlock_lock(lck);
}
if (lck->can_sleep && (lck->want_write || lck->want_upgrade)) {
lck->waiting = TRUE;
res = assert_wait((event_t) lck, THREAD_UNINT);
if (res == THREAD_WAITING) {
lck_interlock_unlock(lck, istate);
res = thread_block(THREAD_CONTINUE_NULL);
istate = lck_interlock_lock(lck);
}
}
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_SHARED_CODE) | DBG_FUNC_END,
(int)lck, lck->want_write, lck->want_upgrade, res, 0);
}
lck->read_count++;
lck_interlock_unlock(lck, istate);
}
boolean_t
lck_rw_lock_shared_to_exclusive(
lck_rw_t *lck)
{
int i;
boolean_t do_wakeup = FALSE;
wait_result_t res;
#if MACH_LDEBUG
int decrementer;
#endif
boolean_t istate;
istate = lck_interlock_lock(lck);
lck->read_count--;
if (lck->want_upgrade) {
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_SH_TO_EX_CODE) | DBG_FUNC_START,
(int)lck, lck->read_count, lck->want_upgrade, 0, 0);
if (lck->waiting && (lck->read_count == 0)) {
lck->waiting = FALSE;
do_wakeup = TRUE;
}
lck_interlock_unlock(lck, istate);
if (do_wakeup)
thread_wakeup((event_t) lck);
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_SH_TO_EX_CODE) | DBG_FUNC_END,
(int)lck, lck->read_count, lck->want_upgrade, 0, 0);
return (TRUE);
}
lck->want_upgrade = TRUE;
#if MACH_LDEBUG
decrementer = DECREMENTER_TIMEOUT;
#endif
while (lck->read_count != 0) {
i = lock_wait_time[lck->can_sleep ? 1 : 0];
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_SH_TO_EX1_CODE) | DBG_FUNC_START,
(int)lck, lck->read_count, i, 0, 0);
if (i != 0) {
lck_interlock_unlock(lck, istate);
#if MACH_LDEBUG
if (!--decrementer)
Debugger("timeout - read_count");
#endif
while (--i != 0 && lck->read_count != 0)
continue;
istate = lck_interlock_lock(lck);
}
if (lck->can_sleep && lck->read_count != 0) {
lck->waiting = TRUE;
res = assert_wait((event_t) lck, THREAD_UNINT);
if (res == THREAD_WAITING) {
lck_interlock_unlock(lck, istate);
res = thread_block(THREAD_CONTINUE_NULL);
istate = lck_interlock_lock(lck);
}
}
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_SH_TO_EX1_CODE) | DBG_FUNC_END,
(int)lck, lck->read_count, 0, 0, 0);
}
lck_interlock_unlock(lck, istate);
return (FALSE);
}
void
lck_rw_lock_exclusive_to_shared(
lck_rw_t *lck)
{
boolean_t do_wakeup = FALSE;
boolean_t istate;
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_EX_TO_SH_CODE) | DBG_FUNC_START,
(int)lck, lck->want_write, lck->want_upgrade, 0, 0);
istate = lck_interlock_lock(lck);
lck->read_count++;
if (lck->want_upgrade)
lck->want_upgrade = FALSE;
else
lck->want_write = FALSE;
if (lck->waiting) {
lck->waiting = FALSE;
do_wakeup = TRUE;
}
lck_interlock_unlock(lck, istate);
if (do_wakeup)
thread_wakeup((event_t) lck);
KERNEL_DEBUG(MACHDBG_CODE(DBG_MACH_LOCKS, LCK_RW_LCK_EX_TO_SH_CODE) | DBG_FUNC_END,
(int)lck, lck->want_write, lck->want_upgrade, lck->read_count, 0);
}
boolean_t
lck_rw_try_lock(
lck_rw_t *lck,
lck_rw_type_t lck_rw_type)
{
if (lck_rw_type == LCK_RW_TYPE_SHARED)
return(lck_rw_try_lock_shared(lck));
else if (lck_rw_type == LCK_RW_TYPE_EXCLUSIVE)
return(lck_rw_try_lock_exclusive(lck));
else
panic("lck_rw_try_lock(): Invalid rw lock type: %x\n", lck_rw_type);
return(FALSE);
}
boolean_t
lck_rw_try_lock_exclusive(
lck_rw_t *lck)
{
boolean_t istate;
istate = lck_interlock_lock(lck);
if (lck->want_write || lck->want_upgrade || lck->read_count) {
lck_interlock_unlock(lck, istate);
return(FALSE);
}
lck->want_write = TRUE;
lck_interlock_unlock(lck, istate);
return(TRUE);
}
boolean_t
lck_rw_try_lock_shared(
lck_rw_t *lck)
{
boolean_t istate;
istate = lck_interlock_lock(lck);
if (lck->want_write || lck->want_upgrade) {
lck_interlock_unlock(lck, istate);
return(FALSE);
}
lck->read_count++;
lck_interlock_unlock(lck, istate);
return(TRUE);
}
lck_mtx_t *
lck_mtx_alloc_init(
lck_grp_t *grp,
lck_attr_t *attr)
{
lck_mtx_t *lck;
if ((lck = (lck_mtx_t *)kalloc(sizeof(lck_mtx_t))) != 0)
lck_mtx_init(lck, grp, attr);
return(lck);
}
void
lck_mtx_free(
lck_mtx_t *lck,
lck_grp_t *grp)
{
lck_mtx_destroy(lck, grp);
kfree(lck, sizeof(lck_mtx_t));
}
static void
lck_mtx_ext_init(
lck_mtx_ext_t *lck,
lck_grp_t *grp,
lck_attr_t *attr)
{
lck->lck_mtx.lck_mtx_ilk = 0;
lck->lck_mtx.lck_mtx_locked = 0;
lck->lck_mtx.lck_mtx_waiters = 0;
lck->lck_mtx.lck_mtx_pri = 0;
lck->lck_mtx_attr = 0;
if ((attr->lck_attr_val) & LCK_ATTR_DEBUG) {
lck->lck_mtx_deb.pc = 0;
lck->lck_mtx_deb.thread = 0;
lck->lck_mtx_deb.type = MUTEX_TAG;
lck->lck_mtx_attr |= LCK_MTX_ATTR_DEBUG;
}
lck->lck_mtx_grp = grp;
}
void
lck_mtx_init(
lck_mtx_t *lck,
lck_grp_t *grp,
lck_attr_t *attr)
{
lck_mtx_ext_t *lck_ext;
if ((attr != LCK_ATTR_NULL) && ((attr->lck_attr_val) & LCK_ATTR_DEBUG)) {
if ((lck_ext = (lck_mtx_ext_t *)kalloc(sizeof(lck_mtx_ext_t))) != 0) {
lck_mtx_ext_init(lck_ext, grp, attr);
lck->lck_mtx_tag = LCK_MTX_TAG_INDIRECT;
lck->lck_mtx_ptr = lck_ext;
}
} else {
lck->lck_mtx_ilk = 0;
lck->lck_mtx_locked = 0;
lck->lck_mtx_waiters = 0;
lck->lck_mtx_pri = 0;
}
lck_grp_reference(grp);
lck_grp_lckcnt_incr(grp, LCK_TYPE_MTX);
}
void
lck_mtx_destroy(
lck_mtx_t *lck,
lck_grp_t *grp)
{
boolean_t lck_is_indirect;
if (lck->lck_mtx_tag == LCK_MTX_TAG_DESTROYED)
return;
lck_is_indirect = (lck->lck_mtx_tag == LCK_MTX_TAG_INDIRECT);
lck->lck_mtx_tag = LCK_MTX_TAG_DESTROYED;
if (lck_is_indirect)
kfree(lck->lck_mtx_ptr, sizeof(lck_mtx_ext_t));
lck_grp_lckcnt_decr(grp, LCK_TYPE_MTX);
lck_grp_deallocate(grp);
return;
}
void
lck_mtx_assert(
__unused lck_mtx_t *lck,
__unused unsigned int type)
{
}
#if MACH_KDB
void db_show_one_lock(lock_t *);
void
db_show_one_lock(
lock_t *lock)
{
db_printf("Read_count = 0x%x, %swant_upgrade, %swant_write, ",
lock->read_count,
lock->want_upgrade ? "" : "!",
lock->want_write ? "" : "!");
db_printf("%swaiting, %scan_sleep\n",
lock->waiting ? "" : "!", lock->can_sleep ? "" : "!");
db_printf("Interlock:\n");
db_show_one_simple_lock((db_expr_t)simple_lock_addr(lock->interlock),
TRUE, (db_expr_t)0, (char *)0);
}
#endif
mutex_t *
mutex_alloc(
unsigned short tag)
{
mutex_t *m;
if ((m = (mutex_t *)kalloc(sizeof(mutex_t))) != 0)
mutex_init(m, tag);
return(m);
}
void
mutex_free(
mutex_t *m)
{
kfree(m, sizeof(mutex_t));
}
void
_mutex_assert (
mutex_t *mutex,
unsigned int what)
{
thread_t thread = current_thread();
thread_t holder;
if (panicstr != NULL)
return;
holder = (thread_t) mutex->lck_mtx.lck_mtx_locked;
switch (what) {
case MA_OWNED:
if (thread != holder)
panic("mutex %x not owned\n", mutex);
break;
case MA_NOTOWNED:
if (thread == holder)
panic("mutex %x owned\n", mutex);
break;
}
}
#if MACH_KDB
char *simple_lock_labels = "ENTRY ILK THREAD DURATION CALLER";
char *mutex_labels = "ENTRY LOCKED WAITERS THREAD CALLER";
void
db_show_one_simple_lock (
db_expr_t addr,
boolean_t have_addr,
db_expr_t count,
char * modif)
{
simple_lock_t saddr = (simple_lock_t)addr;
if (saddr == (simple_lock_t)0 || !have_addr) {
db_error ("No simple_lock\n");
}
#if USLOCK_DEBUG
else if (saddr->lock_type != USLOCK_TAG)
db_error ("Not a simple_lock\n");
#endif
db_printf ("%s\n", simple_lock_labels);
db_print_simple_lock (saddr);
}
void
db_print_simple_lock (
simple_lock_t addr)
{
db_printf ("%08x %3d", addr, *hw_lock_addr(addr->interlock));
#if USLOCK_DEBUG
db_printf (" %08x", addr->debug.lock_thread);
db_printf (" %08x ", addr->debug.duration[1]);
db_printsym ((int)addr->debug.lock_pc, DB_STGY_ANY);
#endif
db_printf ("\n");
}
void
db_show_one_mutex (
db_expr_t addr,
boolean_t have_addr,
db_expr_t count,
char * modif)
{
mutex_t * maddr = (mutex_t *)addr;
if (maddr == (mutex_t *)0 || !have_addr)
db_error ("No mutex\n");
#if MACH_LDEBUG
else if (maddr->type != MUTEX_TAG)
db_error ("Not a mutex\n");
#endif
db_printf ("%s\n", mutex_labels);
db_print_mutex (maddr);
}
void
db_print_mutex (
mutex_t * addr)
{
db_printf ("%08x %6d %7d",
addr, *addr, addr->lck_mtx.lck_mtx_waiters);
#if MACH_LDEBUG
db_printf (" %08x ", addr->thread);
db_printsym (addr->pc, DB_STGY_ANY);
#endif
db_printf ("\n");
}
#endif