RTEMS 4.11Annotated Report
Tue Aug 2 17:48:24 2011
0200fbf4 <_CORE_message_queue_Initialize>:
CORE_message_queue_Control *the_message_queue,
CORE_message_queue_Attributes *the_message_queue_attributes,
uint32_t maximum_pending_messages,
size_t maximum_message_size
)
{
200fbf4: 9d e3 bf a0 save %sp, -96, %sp
size_t message_buffering_required = 0;
size_t allocated_message_size;
the_message_queue->maximum_pending_messages = maximum_pending_messages;
200fbf8: f4 26 20 44 st %i2, [ %i0 + 0x44 ]
the_message_queue->number_of_pending_messages = 0;
200fbfc: c0 26 20 48 clr [ %i0 + 0x48 ]
the_message_queue->maximum_message_size = maximum_message_size;
200fc00: f6 26 20 4c st %i3, [ %i0 + 0x4c ]
/*
* Round size up to multiple of a pointer for chain init and
* check for overflow on adding overhead to each message.
*/
allocated_message_size = maximum_message_size;
if (allocated_message_size & (sizeof(uint32_t) - 1)) {
200fc04: 80 8e e0 03 btst 3, %i3
200fc08: 02 80 00 07 be 200fc24 <_CORE_message_queue_Initialize+0x30>
200fc0c: ba 10 00 1b mov %i3, %i5
allocated_message_size += sizeof(uint32_t);
200fc10: ba 06 e0 04 add %i3, 4, %i5
allocated_message_size &= ~(sizeof(uint32_t) - 1);
200fc14: ba 0f 7f fc and %i5, -4, %i5
}
if (allocated_message_size < maximum_message_size)
200fc18: 80 a7 40 1b cmp %i5, %i3
200fc1c: 0a 80 00 24 bcs 200fcac <_CORE_message_queue_Initialize+0xb8><== NEVER TAKEN
200fc20: b8 10 20 00 clr %i4
/*
* Calculate how much total memory is required for message buffering and
* check for overflow on the multiplication.
*/
if ( !size_t_mult32_with_overflow(
200fc24: ba 07 60 10 add %i5, 0x10, %i5
size_t a,
size_t b,
size_t *c
)
{
long long x = (long long)a*b;
200fc28: 90 10 20 00 clr %o0
200fc2c: 92 10 00 1a mov %i2, %o1
200fc30: 94 10 20 00 clr %o2
200fc34: 96 10 00 1d mov %i5, %o3
200fc38: 40 00 3e e2 call 201f7c0 <__muldi3>
200fc3c: b8 10 20 00 clr %i4
if ( x > SIZE_MAX )
200fc40: 80 a2 20 00 cmp %o0, 0
200fc44: 34 80 00 1b bg,a 200fcb0 <_CORE_message_queue_Initialize+0xbc>
200fc48: b0 0f 20 01 and %i4, 1, %i0
/*
* Attempt to allocate the message memory
*/
the_message_queue->message_buffers = (CORE_message_queue_Buffer *)
_Workspace_Allocate( message_buffering_required );
200fc4c: 40 00 0b fb call 2012c38 <_Workspace_Allocate>
200fc50: 90 10 00 09 mov %o1, %o0
return false;
/*
* Attempt to allocate the message memory
*/
the_message_queue->message_buffers = (CORE_message_queue_Buffer *)
200fc54: d0 26 20 5c st %o0, [ %i0 + 0x5c ]
_Workspace_Allocate( message_buffering_required );
if (the_message_queue->message_buffers == 0)
200fc58: 80 a2 20 00 cmp %o0, 0
200fc5c: 02 80 00 14 be 200fcac <_CORE_message_queue_Initialize+0xb8><== NEVER TAKEN
200fc60: 92 10 00 08 mov %o0, %o1
/*
* Initialize the pool of inactive messages, pending messages,
* and set of waiting threads.
*/
_Chain_Initialize (
200fc64: 90 06 20 60 add %i0, 0x60, %o0
200fc68: 94 10 00 1a mov %i2, %o2
200fc6c: 40 00 13 df call 2014be8 <_Chain_Initialize>
200fc70: 96 10 00 1d mov %i5, %o3
RTEMS_INLINE_ROUTINE void _Chain_Initialize_empty(
Chain_Control *the_chain
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *tail = _Chain_Tail( the_chain );
200fc74: 82 06 20 50 add %i0, 0x50, %g1
head->next = tail;
head->previous = NULL;
tail->previous = head;
200fc78: c2 26 20 58 st %g1, [ %i0 + 0x58 ]
allocated_message_size + sizeof( CORE_message_queue_Buffer_control )
);
_Chain_Initialize_empty( &the_message_queue->Pending_messages );
_Thread_queue_Initialize(
200fc7c: c2 06 40 00 ld [ %i1 ], %g1
RTEMS_INLINE_ROUTINE void _Chain_Initialize_empty(
Chain_Control *the_chain
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *tail = _Chain_Tail( the_chain );
200fc80: 84 06 20 54 add %i0, 0x54, %g2
200fc84: 82 18 60 01 xor %g1, 1, %g1
200fc88: 80 a0 00 01 cmp %g0, %g1
head->next = tail;
200fc8c: c4 26 20 50 st %g2, [ %i0 + 0x50 ]
head->previous = NULL;
200fc90: c0 26 20 54 clr [ %i0 + 0x54 ]
200fc94: 90 10 00 18 mov %i0, %o0
200fc98: 92 60 3f ff subx %g0, -1, %o1
200fc9c: 94 10 20 80 mov 0x80, %o2
200fca0: 96 10 20 06 mov 6, %o3
200fca4: 40 00 09 91 call 20122e8 <_Thread_queue_Initialize>
200fca8: b8 10 20 01 mov 1, %i4
STATES_WAITING_FOR_MESSAGE,
CORE_MESSAGE_QUEUE_STATUS_TIMEOUT
);
return true;
}
200fcac: b0 0f 20 01 and %i4, 1, %i0
200fcb0: 81 c7 e0 08 ret
200fcb4: 81 e8 00 00 restore
02007290 <_CORE_semaphore_Surrender>:
CORE_semaphore_Status _CORE_semaphore_Surrender(
CORE_semaphore_Control *the_semaphore,
Objects_Id id,
CORE_semaphore_API_mp_support_callout api_semaphore_mp_support
)
{
2007290: 9d e3 bf a0 save %sp, -96, %sp
ISR_Level level;
CORE_semaphore_Status status;
status = CORE_SEMAPHORE_STATUS_SUCCESSFUL;
if ( (the_thread = _Thread_queue_Dequeue(&the_semaphore->Wait_queue)) ) {
2007294: 90 10 00 18 mov %i0, %o0
2007298: 40 00 07 33 call 2008f64 <_Thread_queue_Dequeue>
200729c: ba 10 00 18 mov %i0, %i5
20072a0: 80 a2 20 00 cmp %o0, 0
20072a4: 12 80 00 0e bne 20072dc <_CORE_semaphore_Surrender+0x4c>
20072a8: b0 10 20 00 clr %i0
if ( !_Objects_Is_local_id( the_thread->Object.id ) )
(*api_semaphore_mp_support) ( the_thread, id );
#endif
} else {
_ISR_Disable( level );
20072ac: 7f ff eb b4 call 200217c <sparc_disable_interrupts>
20072b0: 01 00 00 00 nop
if ( the_semaphore->count < the_semaphore->Attributes.maximum_count )
20072b4: c2 07 60 48 ld [ %i5 + 0x48 ], %g1
20072b8: c4 07 60 40 ld [ %i5 + 0x40 ], %g2
20072bc: 80 a0 40 02 cmp %g1, %g2
20072c0: 1a 80 00 05 bcc 20072d4 <_CORE_semaphore_Surrender+0x44> <== NEVER TAKEN
20072c4: b0 10 20 04 mov 4, %i0
the_semaphore->count += 1;
20072c8: 82 00 60 01 inc %g1
{
Thread_Control *the_thread;
ISR_Level level;
CORE_semaphore_Status status;
status = CORE_SEMAPHORE_STATUS_SUCCESSFUL;
20072cc: b0 10 20 00 clr %i0
#endif
} else {
_ISR_Disable( level );
if ( the_semaphore->count < the_semaphore->Attributes.maximum_count )
the_semaphore->count += 1;
20072d0: c2 27 60 48 st %g1, [ %i5 + 0x48 ]
else
status = CORE_SEMAPHORE_MAXIMUM_COUNT_EXCEEDED;
_ISR_Enable( level );
20072d4: 7f ff eb ae call 200218c <sparc_enable_interrupts>
20072d8: 01 00 00 00 nop
}
return status;
}
20072dc: 81 c7 e0 08 ret
20072e0: 81 e8 00 00 restore
02006028 <_Event_Surrender>:
*/
void _Event_Surrender(
Thread_Control *the_thread
)
{
2006028: 9d e3 bf a0 save %sp, -96, %sp
rtems_event_set event_condition;
rtems_event_set seized_events;
rtems_option option_set;
RTEMS_API_Control *api;
api = the_thread->API_Extensions[ THREAD_API_RTEMS ];
200602c: f8 06 21 58 ld [ %i0 + 0x158 ], %i4
option_set = (rtems_option) the_thread->Wait.option;
2006030: f6 06 20 30 ld [ %i0 + 0x30 ], %i3
_ISR_Disable( level );
2006034: 7f ff f0 52 call 200217c <sparc_disable_interrupts>
2006038: ba 10 00 18 mov %i0, %i5
200603c: b0 10 00 08 mov %o0, %i0
pending_events = api->pending_events;
2006040: c4 07 00 00 ld [ %i4 ], %g2
event_condition = (rtems_event_set) the_thread->Wait.count;
2006044: c6 07 60 24 ld [ %i5 + 0x24 ], %g3
seized_events = _Event_sets_Get( pending_events, event_condition );
/*
* No events were seized in this operation
*/
if ( _Event_sets_Is_empty( seized_events ) ) {
2006048: 82 88 c0 02 andcc %g3, %g2, %g1
200604c: 02 80 00 43 be 2006158 <_Event_Surrender+0x130>
2006050: 01 00 00 00 nop
/*
* If we are in an ISR and sending to the current thread, then
* we have a critical section issue to deal with.
*/
if ( _ISR_Is_in_progress() &&
2006054: 09 00 80 6d sethi %hi(0x201b400), %g4
2006058: 88 11 22 dc or %g4, 0x2dc, %g4 ! 201b6dc <_Per_CPU_Information>
200605c: f2 01 20 08 ld [ %g4 + 8 ], %i1
2006060: 80 a6 60 00 cmp %i1, 0
2006064: 22 80 00 1d be,a 20060d8 <_Event_Surrender+0xb0>
2006068: c8 07 60 10 ld [ %i5 + 0x10 ], %g4
200606c: c8 01 20 0c ld [ %g4 + 0xc ], %g4
2006070: 80 a7 40 04 cmp %i5, %g4
2006074: 32 80 00 19 bne,a 20060d8 <_Event_Surrender+0xb0>
2006078: c8 07 60 10 ld [ %i5 + 0x10 ], %g4
_Thread_Is_executing( the_thread ) &&
((_Event_Sync_state == THREAD_BLOCKING_OPERATION_TIMEOUT) ||
200607c: 09 00 80 6d sethi %hi(0x201b400), %g4
2006080: f2 01 23 30 ld [ %g4 + 0x330 ], %i1 ! 201b730 <_Event_Sync_state>
/*
* If we are in an ISR and sending to the current thread, then
* we have a critical section issue to deal with.
*/
if ( _ISR_Is_in_progress() &&
_Thread_Is_executing( the_thread ) &&
2006084: 80 a6 60 02 cmp %i1, 2
2006088: 02 80 00 07 be 20060a4 <_Event_Surrender+0x7c> <== NEVER TAKEN
200608c: 80 a0 40 03 cmp %g1, %g3
((_Event_Sync_state == THREAD_BLOCKING_OPERATION_TIMEOUT) ||
(_Event_Sync_state == THREAD_BLOCKING_OPERATION_NOTHING_HAPPENED)) ) {
2006090: c8 01 23 30 ld [ %g4 + 0x330 ], %g4
* If we are in an ISR and sending to the current thread, then
* we have a critical section issue to deal with.
*/
if ( _ISR_Is_in_progress() &&
_Thread_Is_executing( the_thread ) &&
((_Event_Sync_state == THREAD_BLOCKING_OPERATION_TIMEOUT) ||
2006094: 80 a1 20 01 cmp %g4, 1
2006098: 32 80 00 10 bne,a 20060d8 <_Event_Surrender+0xb0>
200609c: c8 07 60 10 ld [ %i5 + 0x10 ], %g4
(_Event_Sync_state == THREAD_BLOCKING_OPERATION_NOTHING_HAPPENED)) ) {
if ( seized_events == event_condition || _Options_Is_any(option_set) ) {
20060a0: 80 a0 40 03 cmp %g1, %g3
20060a4: 02 80 00 04 be 20060b4 <_Event_Surrender+0x8c>
20060a8: 80 8e e0 02 btst 2, %i3
20060ac: 02 80 00 2b be 2006158 <_Event_Surrender+0x130> <== NEVER TAKEN
20060b0: 01 00 00 00 nop
RTEMS_INLINE_ROUTINE rtems_event_set _Event_sets_Clear(
rtems_event_set the_event_set,
rtems_event_set the_mask
)
{
return ( the_event_set & ~(the_mask) );
20060b4: 84 28 80 01 andn %g2, %g1, %g2
api->pending_events = _Event_sets_Clear( pending_events,seized_events );
20060b8: c4 27 00 00 st %g2, [ %i4 ]
the_thread->Wait.count = 0;
*(rtems_event_set *)the_thread->Wait.return_argument = seized_events;
20060bc: c4 07 60 28 ld [ %i5 + 0x28 ], %g2
_Thread_Is_executing( the_thread ) &&
((_Event_Sync_state == THREAD_BLOCKING_OPERATION_TIMEOUT) ||
(_Event_Sync_state == THREAD_BLOCKING_OPERATION_NOTHING_HAPPENED)) ) {
if ( seized_events == event_condition || _Options_Is_any(option_set) ) {
api->pending_events = _Event_sets_Clear( pending_events,seized_events );
the_thread->Wait.count = 0;
20060c0: c0 27 60 24 clr [ %i5 + 0x24 ]
*(rtems_event_set *)the_thread->Wait.return_argument = seized_events;
20060c4: c2 20 80 00 st %g1, [ %g2 ]
_Event_Sync_state = THREAD_BLOCKING_OPERATION_SATISFIED;
20060c8: 84 10 20 03 mov 3, %g2
20060cc: 03 00 80 6d sethi %hi(0x201b400), %g1
20060d0: c4 20 63 30 st %g2, [ %g1 + 0x330 ] ! 201b730 <_Event_Sync_state>
20060d4: 30 80 00 21 b,a 2006158 <_Event_Surrender+0x130>
}
/*
* Otherwise, this is a normal send to another thread
*/
if ( _States_Is_waiting_for_event( the_thread->current_state ) ) {
20060d8: 80 89 21 00 btst 0x100, %g4
20060dc: 02 80 00 1f be 2006158 <_Event_Surrender+0x130>
20060e0: 80 a0 40 03 cmp %g1, %g3
if ( seized_events == event_condition || _Options_Is_any( option_set ) ) {
20060e4: 02 80 00 04 be 20060f4 <_Event_Surrender+0xcc>
20060e8: 80 8e e0 02 btst 2, %i3
20060ec: 02 80 00 1b be 2006158 <_Event_Surrender+0x130> <== NEVER TAKEN
20060f0: 01 00 00 00 nop
20060f4: 84 28 80 01 andn %g2, %g1, %g2
api->pending_events = _Event_sets_Clear( pending_events, seized_events );
20060f8: c4 27 00 00 st %g2, [ %i4 ]
the_thread->Wait.count = 0;
*(rtems_event_set *)the_thread->Wait.return_argument = seized_events;
20060fc: c4 07 60 28 ld [ %i5 + 0x28 ], %g2
* Otherwise, this is a normal send to another thread
*/
if ( _States_Is_waiting_for_event( the_thread->current_state ) ) {
if ( seized_events == event_condition || _Options_Is_any( option_set ) ) {
api->pending_events = _Event_sets_Clear( pending_events, seized_events );
the_thread->Wait.count = 0;
2006100: c0 27 60 24 clr [ %i5 + 0x24 ]
*(rtems_event_set *)the_thread->Wait.return_argument = seized_events;
2006104: c2 20 80 00 st %g1, [ %g2 ]
_ISR_Flash( level );
2006108: 7f ff f0 21 call 200218c <sparc_enable_interrupts>
200610c: 90 10 00 18 mov %i0, %o0
2006110: 7f ff f0 1b call 200217c <sparc_disable_interrupts>
2006114: 01 00 00 00 nop
if ( !_Watchdog_Is_active( &the_thread->Timer ) ) {
2006118: c2 07 60 50 ld [ %i5 + 0x50 ], %g1
200611c: 80 a0 60 02 cmp %g1, 2
2006120: 02 80 00 06 be 2006138 <_Event_Surrender+0x110>
2006124: 82 10 20 03 mov 3, %g1
_ISR_Enable( level );
2006128: 7f ff f0 19 call 200218c <sparc_enable_interrupts>
200612c: 33 04 00 ff sethi %hi(0x1003fc00), %i1
RTEMS_INLINE_ROUTINE void _Thread_Unblock (
Thread_Control *the_thread
)
{
_Thread_Clear_state( the_thread, STATES_BLOCKED );
2006130: 10 80 00 08 b 2006150 <_Event_Surrender+0x128>
2006134: b2 16 63 f8 or %i1, 0x3f8, %i1 ! 1003fff8 <RAM_END+0xdc3fff8>
RTEMS_INLINE_ROUTINE void _Watchdog_Deactivate(
Watchdog_Control *the_watchdog
)
{
the_watchdog->state = WATCHDOG_REMOVE_IT;
2006138: c2 27 60 50 st %g1, [ %i5 + 0x50 ]
_Thread_Unblock( the_thread );
} else {
_Watchdog_Deactivate( &the_thread->Timer );
_ISR_Enable( level );
200613c: 7f ff f0 14 call 200218c <sparc_enable_interrupts>
2006140: 33 04 00 ff sethi %hi(0x1003fc00), %i1
(void) _Watchdog_Remove( &the_thread->Timer );
2006144: 40 00 0e 75 call 2009b18 <_Watchdog_Remove>
2006148: 90 07 60 48 add %i5, 0x48, %o0
200614c: b2 16 63 f8 or %i1, 0x3f8, %i1
2006150: 40 00 09 d6 call 20088a8 <_Thread_Clear_state>
2006154: 91 e8 00 1d restore %g0, %i5, %o0
_Thread_Unblock( the_thread );
}
return;
}
}
_ISR_Enable( level );
2006158: 7f ff f0 0d call 200218c <sparc_enable_interrupts>
200615c: 81 e8 00 00 restore
02006160 <_Event_Timeout>:
void _Event_Timeout(
Objects_Id id,
void *ignored
)
{
2006160: 9d e3 bf 98 save %sp, -104, %sp
Thread_Control *the_thread;
Objects_Locations location;
ISR_Level level;
the_thread = _Thread_Get( id, &location );
2006164: 90 10 00 18 mov %i0, %o0
2006168: 40 00 0a bb call 2008c54 <_Thread_Get>
200616c: 92 07 bf fc add %fp, -4, %o1
switch ( location ) {
2006170: c2 07 bf fc ld [ %fp + -4 ], %g1
2006174: 80 a0 60 00 cmp %g1, 0
2006178: 12 80 00 1d bne 20061ec <_Event_Timeout+0x8c> <== NEVER TAKEN
200617c: ba 10 00 08 mov %o0, %i5
*
* If it is not satisfied, then it is "nothing happened" and
* this is the "timeout" transition. After a request is satisfied,
* a timeout is not allowed to occur.
*/
_ISR_Disable( level );
2006180: 7f ff ef ff call 200217c <sparc_disable_interrupts>
2006184: 01 00 00 00 nop
RTEMS_INLINE_ROUTINE bool _Thread_Is_executing (
const Thread_Control *the_thread
)
{
return ( the_thread == _Thread_Executing );
2006188: 03 00 80 6d sethi %hi(0x201b400), %g1
return;
}
#endif
the_thread->Wait.count = 0;
if ( _Thread_Is_executing( the_thread ) ) {
200618c: c2 00 62 e8 ld [ %g1 + 0x2e8 ], %g1 ! 201b6e8 <_Per_CPU_Information+0xc>
2006190: 80 a7 40 01 cmp %i5, %g1
2006194: 12 80 00 09 bne 20061b8 <_Event_Timeout+0x58>
2006198: c0 27 60 24 clr [ %i5 + 0x24 ]
if ( _Event_Sync_state == THREAD_BLOCKING_OPERATION_NOTHING_HAPPENED )
200619c: 03 00 80 6d sethi %hi(0x201b400), %g1
20061a0: c4 00 63 30 ld [ %g1 + 0x330 ], %g2 ! 201b730 <_Event_Sync_state>
20061a4: 80 a0 a0 01 cmp %g2, 1
20061a8: 32 80 00 05 bne,a 20061bc <_Event_Timeout+0x5c>
20061ac: 82 10 20 06 mov 6, %g1
_Event_Sync_state = THREAD_BLOCKING_OPERATION_TIMEOUT;
20061b0: 84 10 20 02 mov 2, %g2
20061b4: c4 20 63 30 st %g2, [ %g1 + 0x330 ]
}
the_thread->Wait.return_code = RTEMS_TIMEOUT;
20061b8: 82 10 20 06 mov 6, %g1
20061bc: c2 27 60 34 st %g1, [ %i5 + 0x34 ]
_ISR_Enable( level );
20061c0: 7f ff ef f3 call 200218c <sparc_enable_interrupts>
20061c4: 01 00 00 00 nop
RTEMS_INLINE_ROUTINE void _Thread_Unblock (
Thread_Control *the_thread
)
{
_Thread_Clear_state( the_thread, STATES_BLOCKED );
20061c8: 90 10 00 1d mov %i5, %o0
20061cc: 13 04 00 ff sethi %hi(0x1003fc00), %o1
20061d0: 40 00 09 b6 call 20088a8 <_Thread_Clear_state>
20061d4: 92 12 63 f8 or %o1, 0x3f8, %o1 ! 1003fff8 <RAM_END+0xdc3fff8>
*
* This routine decrements the thread dispatch level.
*/
RTEMS_INLINE_ROUTINE uint32_t _Thread_Dispatch_decrement_disable_level(void)
{
_Thread_Dispatch_disable_level--;
20061d8: 03 00 80 6d sethi %hi(0x201b400), %g1
20061dc: c4 00 60 b0 ld [ %g1 + 0xb0 ], %g2 ! 201b4b0 <_Thread_Dispatch_disable_level>
20061e0: 84 00 bf ff add %g2, -1, %g2
20061e4: c4 20 60 b0 st %g2, [ %g1 + 0xb0 ]
return _Thread_Dispatch_disable_level;
20061e8: c2 00 60 b0 ld [ %g1 + 0xb0 ], %g1
20061ec: 81 c7 e0 08 ret
20061f0: 81 e8 00 00 restore
0200bc64 <_Heap_Extend>:
Heap_Control *heap,
void *extend_area_begin_ptr,
uintptr_t extend_area_size,
uintptr_t *extended_size_ptr
)
{
200bc64: 9d e3 bf 98 save %sp, -104, %sp
Heap_Block *start_block = first_block;
Heap_Block *merge_below_block = NULL;
Heap_Block *merge_above_block = NULL;
Heap_Block *link_below_block = NULL;
Heap_Block *link_above_block = NULL;
Heap_Block *extend_first_block = NULL;
200bc68: c0 27 bf f8 clr [ %fp + -8 ]
Heap_Block *extend_last_block = NULL;
200bc6c: c0 27 bf fc clr [ %fp + -4 ]
uintptr_t const page_size = heap->page_size;
uintptr_t const min_block_size = heap->min_block_size;
uintptr_t const extend_area_begin = (uintptr_t) extend_area_begin_ptr;
uintptr_t const extend_area_end = extend_area_begin + extend_area_size;
200bc70: ba 06 40 1a add %i1, %i2, %i5
uintptr_t extend_area_size,
uintptr_t *extended_size_ptr
)
{
Heap_Statistics *const stats = &heap->stats;
Heap_Block *const first_block = heap->first_block;
200bc74: e0 06 20 20 ld [ %i0 + 0x20 ], %l0
Heap_Block *merge_above_block = NULL;
Heap_Block *link_below_block = NULL;
Heap_Block *link_above_block = NULL;
Heap_Block *extend_first_block = NULL;
Heap_Block *extend_last_block = NULL;
uintptr_t const page_size = heap->page_size;
200bc78: e2 06 20 10 ld [ %i0 + 0x10 ], %l1
uintptr_t const min_block_size = heap->min_block_size;
200bc7c: d6 06 20 14 ld [ %i0 + 0x14 ], %o3
uintptr_t const extend_area_begin = (uintptr_t) extend_area_begin_ptr;
uintptr_t const extend_area_end = extend_area_begin + extend_area_size;
uintptr_t const free_size = stats->free_size;
200bc80: e4 06 20 30 ld [ %i0 + 0x30 ], %l2
uintptr_t extend_first_block_size = 0;
uintptr_t extended_size = 0;
bool extend_area_ok = false;
if ( extend_area_end < extend_area_begin ) {
200bc84: 80 a7 40 19 cmp %i5, %i1
200bc88: 0a 80 00 9f bcs 200bf04 <_Heap_Extend+0x2a0>
200bc8c: b8 10 20 00 clr %i4
return false;
}
extend_area_ok = _Heap_Get_first_and_last_block(
200bc90: 90 10 00 19 mov %i1, %o0
200bc94: 92 10 00 1a mov %i2, %o1
200bc98: 94 10 00 11 mov %l1, %o2
200bc9c: 98 07 bf f8 add %fp, -8, %o4
200bca0: 7f ff ed 4f call 20071dc <_Heap_Get_first_and_last_block>
200bca4: 9a 07 bf fc add %fp, -4, %o5
page_size,
min_block_size,
&extend_first_block,
&extend_last_block
);
if (!extend_area_ok ) {
200bca8: 80 8a 20 ff btst 0xff, %o0
200bcac: 02 80 00 96 be 200bf04 <_Heap_Extend+0x2a0>
200bcb0: b4 10 00 10 mov %l0, %i2
200bcb4: aa 10 20 00 clr %l5
200bcb8: ac 10 20 00 clr %l6
200bcbc: b8 10 20 00 clr %i4
200bcc0: a8 10 20 00 clr %l4
200bcc4: c2 06 20 18 ld [ %i0 + 0x18 ], %g1
(uintptr_t) start_block : heap->area_begin;
uintptr_t const sub_area_end = start_block->prev_size;
Heap_Block *const end_block =
_Heap_Block_of_alloc_area( sub_area_end, page_size );
if (
200bcc8: 80 a0 40 1d cmp %g1, %i5
200bccc: 1a 80 00 05 bcc 200bce0 <_Heap_Extend+0x7c>
200bcd0: e6 06 80 00 ld [ %i2 ], %l3
200bcd4: 80 a6 40 13 cmp %i1, %l3
200bcd8: 2a 80 00 8b bcs,a 200bf04 <_Heap_Extend+0x2a0>
200bcdc: b8 10 20 00 clr %i4
sub_area_end > extend_area_begin && extend_area_end > sub_area_begin
) {
return false;
}
if ( extend_area_end == sub_area_begin ) {
200bce0: 80 a7 40 01 cmp %i5, %g1
200bce4: 02 80 00 06 be 200bcfc <_Heap_Extend+0x98>
200bce8: 80 a7 40 13 cmp %i5, %l3
merge_below_block = start_block;
} else if ( extend_area_end < sub_area_end ) {
200bcec: 2a 80 00 05 bcs,a 200bd00 <_Heap_Extend+0x9c>
200bcf0: ac 10 00 1a mov %i2, %l6
200bcf4: 10 80 00 04 b 200bd04 <_Heap_Extend+0xa0>
200bcf8: 90 10 00 13 mov %l3, %o0
200bcfc: a8 10 00 1a mov %i2, %l4
200bd00: 90 10 00 13 mov %l3, %o0
200bd04: 40 00 15 fd call 20114f8 <.urem>
200bd08: 92 10 00 11 mov %l1, %o1
200bd0c: ae 04 ff f8 add %l3, -8, %l7
link_below_block = start_block;
}
if ( sub_area_end == extend_area_begin ) {
200bd10: 80 a4 c0 19 cmp %l3, %i1
200bd14: 12 80 00 05 bne 200bd28 <_Heap_Extend+0xc4>
200bd18: 90 25 c0 08 sub %l7, %o0, %o0
start_block->prev_size = extend_area_end;
200bd1c: fa 26 80 00 st %i5, [ %i2 ]
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Block_of_alloc_area(
uintptr_t alloc_begin,
uintptr_t page_size
)
{
return (Heap_Block *) (_Heap_Align_down( alloc_begin, page_size )
200bd20: 10 80 00 04 b 200bd30 <_Heap_Extend+0xcc>
200bd24: b8 10 00 08 mov %o0, %i4
merge_above_block = end_block;
} else if ( sub_area_end < extend_area_begin ) {
200bd28: 2a 80 00 02 bcs,a 200bd30 <_Heap_Extend+0xcc>
200bd2c: aa 10 00 08 mov %o0, %l5
- HEAP_BLOCK_HEADER_SIZE);
}
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Block_size( const Heap_Block *block )
{
return block->size_and_flag & ~HEAP_PREV_BLOCK_USED;
200bd30: f4 02 20 04 ld [ %o0 + 4 ], %i2
200bd34: b4 0e bf fe and %i2, -2, %i2
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Block_at(
const Heap_Block *block,
uintptr_t offset
)
{
return (Heap_Block *) ((uintptr_t) block + offset);
200bd38: b4 06 80 08 add %i2, %o0, %i2
link_above_block = end_block;
}
start_block = _Heap_Block_at( end_block, _Heap_Block_size( end_block ) );
} while ( start_block != first_block );
200bd3c: 80 a6 80 10 cmp %i2, %l0
200bd40: 12 bf ff e2 bne 200bcc8 <_Heap_Extend+0x64>
200bd44: 82 10 00 1a mov %i2, %g1
if ( extend_area_begin < heap->area_begin ) {
200bd48: c2 06 20 18 ld [ %i0 + 0x18 ], %g1
200bd4c: 80 a6 40 01 cmp %i1, %g1
200bd50: 3a 80 00 04 bcc,a 200bd60 <_Heap_Extend+0xfc>
200bd54: c2 06 20 1c ld [ %i0 + 0x1c ], %g1
heap->area_begin = extend_area_begin;
200bd58: 10 80 00 05 b 200bd6c <_Heap_Extend+0x108>
200bd5c: f2 26 20 18 st %i1, [ %i0 + 0x18 ]
} else if ( heap->area_end < extend_area_end ) {
200bd60: 80 a0 40 1d cmp %g1, %i5
200bd64: 2a 80 00 02 bcs,a 200bd6c <_Heap_Extend+0x108>
200bd68: fa 26 20 1c st %i5, [ %i0 + 0x1c ]
heap->area_end = extend_area_end;
}
extend_first_block_size =
(uintptr_t) extend_last_block - (uintptr_t) extend_first_block;
200bd6c: c4 07 bf f8 ld [ %fp + -8 ], %g2
200bd70: c2 07 bf fc ld [ %fp + -4 ], %g1
extend_first_block->prev_size = extend_area_end;
200bd74: fa 20 80 00 st %i5, [ %g2 ]
heap->area_begin = extend_area_begin;
} else if ( heap->area_end < extend_area_end ) {
heap->area_end = extend_area_end;
}
extend_first_block_size =
200bd78: 86 20 40 02 sub %g1, %g2, %g3
(uintptr_t) extend_last_block - (uintptr_t) extend_first_block;
extend_first_block->prev_size = extend_area_end;
extend_first_block->size_and_flag =
extend_first_block_size | HEAP_PREV_BLOCK_USED;
200bd7c: 88 10 e0 01 or %g3, 1, %g4
_Heap_Protection_block_initialize( heap, extend_first_block );
extend_last_block->prev_size = extend_first_block_size;
200bd80: c6 20 40 00 st %g3, [ %g1 ]
extend_first_block_size =
(uintptr_t) extend_last_block - (uintptr_t) extend_first_block;
extend_first_block->prev_size = extend_area_end;
extend_first_block->size_and_flag =
200bd84: c8 20 a0 04 st %g4, [ %g2 + 4 ]
extend_last_block->prev_size = extend_first_block_size;
extend_last_block->size_and_flag = 0;
_Heap_Protection_block_initialize( heap, extend_last_block );
if ( (uintptr_t) extend_first_block < (uintptr_t) heap->first_block ) {
200bd88: c6 06 20 20 ld [ %i0 + 0x20 ], %g3
200bd8c: 80 a0 c0 02 cmp %g3, %g2
200bd90: 08 80 00 04 bleu 200bda0 <_Heap_Extend+0x13c>
200bd94: c0 20 60 04 clr [ %g1 + 4 ]
heap->first_block = extend_first_block;
200bd98: 10 80 00 06 b 200bdb0 <_Heap_Extend+0x14c>
200bd9c: c4 26 20 20 st %g2, [ %i0 + 0x20 ]
} else if ( (uintptr_t) extend_last_block > (uintptr_t) heap->last_block ) {
200bda0: c4 06 20 24 ld [ %i0 + 0x24 ], %g2
200bda4: 80 a0 80 01 cmp %g2, %g1
200bda8: 2a 80 00 02 bcs,a 200bdb0 <_Heap_Extend+0x14c>
200bdac: c2 26 20 24 st %g1, [ %i0 + 0x24 ]
heap->last_block = extend_last_block;
}
if ( merge_below_block != NULL ) {
200bdb0: 80 a5 20 00 cmp %l4, 0
200bdb4: 02 80 00 14 be 200be04 <_Heap_Extend+0x1a0>
200bdb8: b2 06 60 08 add %i1, 8, %i1
Heap_Control *heap,
uintptr_t extend_area_begin,
Heap_Block *first_block
)
{
uintptr_t const page_size = heap->page_size;
200bdbc: f4 06 20 10 ld [ %i0 + 0x10 ], %i2
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Align_up(
uintptr_t value,
uintptr_t alignment
)
{
uintptr_t remainder = value % alignment;
200bdc0: 92 10 00 1a mov %i2, %o1
200bdc4: 40 00 15 cd call 20114f8 <.urem>
200bdc8: 90 10 00 19 mov %i1, %o0
if ( remainder != 0 ) {
200bdcc: 80 a2 20 00 cmp %o0, 0
200bdd0: 02 80 00 04 be 200bde0 <_Heap_Extend+0x17c>
200bdd4: c2 05 00 00 ld [ %l4 ], %g1
return value - remainder + alignment;
200bdd8: b2 06 40 1a add %i1, %i2, %i1
200bddc: b2 26 40 08 sub %i1, %o0, %i1
uintptr_t const new_first_block_alloc_begin =
_Heap_Align_up( extend_area_begin + HEAP_BLOCK_HEADER_SIZE, page_size );
uintptr_t const new_first_block_begin =
200bde0: 92 06 7f f8 add %i1, -8, %o1
uintptr_t const first_block_begin = (uintptr_t) first_block;
uintptr_t const new_first_block_size =
first_block_begin - new_first_block_begin;
Heap_Block *const new_first_block = (Heap_Block *) new_first_block_begin;
new_first_block->prev_size = first_block->prev_size;
200bde4: c2 26 7f f8 st %g1, [ %i1 + -8 ]
uintptr_t const new_first_block_alloc_begin =
_Heap_Align_up( extend_area_begin + HEAP_BLOCK_HEADER_SIZE, page_size );
uintptr_t const new_first_block_begin =
new_first_block_alloc_begin - HEAP_BLOCK_HEADER_SIZE;
uintptr_t const first_block_begin = (uintptr_t) first_block;
uintptr_t const new_first_block_size =
200bde8: 82 25 00 09 sub %l4, %o1, %g1
first_block_begin - new_first_block_begin;
Heap_Block *const new_first_block = (Heap_Block *) new_first_block_begin;
new_first_block->prev_size = first_block->prev_size;
new_first_block->size_and_flag = new_first_block_size | HEAP_PREV_BLOCK_USED;
200bdec: 82 10 60 01 or %g1, 1, %g1
_Heap_Free_block( heap, new_first_block );
200bdf0: 90 10 00 18 mov %i0, %o0
200bdf4: 7f ff ff 92 call 200bc3c <_Heap_Free_block>
200bdf8: c2 22 60 04 st %g1, [ %o1 + 4 ]
link_below_block,
extend_last_block
);
}
if ( merge_above_block != NULL ) {
200bdfc: 10 80 00 08 b 200be1c <_Heap_Extend+0x1b8>
200be00: 80 a7 20 00 cmp %i4, 0
heap->last_block = extend_last_block;
}
if ( merge_below_block != NULL ) {
_Heap_Merge_below( heap, extend_area_begin, merge_below_block );
} else if ( link_below_block != NULL ) {
200be04: 80 a5 a0 00 cmp %l6, 0
200be08: 02 80 00 04 be 200be18 <_Heap_Extend+0x1b4>
200be0c: ac 25 80 01 sub %l6, %g1, %l6
{
uintptr_t const last_block_begin = (uintptr_t) last_block;
uintptr_t const link_begin = (uintptr_t) link;
last_block->size_and_flag =
(link_begin - last_block_begin) | HEAP_PREV_BLOCK_USED;
200be10: ac 15 a0 01 or %l6, 1, %l6
)
{
uintptr_t const last_block_begin = (uintptr_t) last_block;
uintptr_t const link_begin = (uintptr_t) link;
last_block->size_and_flag =
200be14: ec 20 60 04 st %l6, [ %g1 + 4 ]
link_below_block,
extend_last_block
);
}
if ( merge_above_block != NULL ) {
200be18: 80 a7 20 00 cmp %i4, 0
200be1c: 02 80 00 15 be 200be70 <_Heap_Extend+0x20c>
200be20: ba 07 7f f8 add %i5, -8, %i5
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Align_down(
uintptr_t value,
uintptr_t alignment
)
{
return value - (value % alignment);
200be24: d2 06 20 10 ld [ %i0 + 0x10 ], %o1
uintptr_t extend_area_end
)
{
uintptr_t const page_size = heap->page_size;
uintptr_t const last_block_begin = (uintptr_t) last_block;
uintptr_t const last_block_new_size = _Heap_Align_down(
200be28: ba 27 40 1c sub %i5, %i4, %i5
200be2c: 40 00 15 b3 call 20114f8 <.urem>
200be30: 90 10 00 1d mov %i5, %o0
);
Heap_Block *const new_last_block =
_Heap_Block_at( last_block, last_block_new_size );
new_last_block->size_and_flag =
(last_block->size_and_flag - last_block_new_size)
200be34: c4 07 20 04 ld [ %i4 + 4 ], %g2
200be38: ba 27 40 08 sub %i5, %o0, %i5
page_size
);
Heap_Block *const new_last_block =
_Heap_Block_at( last_block, last_block_new_size );
new_last_block->size_and_flag =
200be3c: 82 07 40 1c add %i5, %i4, %g1
(last_block->size_and_flag - last_block_new_size)
200be40: 84 20 80 1d sub %g2, %i5, %g2
| HEAP_PREV_BLOCK_USED;
200be44: 84 10 a0 01 or %g2, 1, %g2
page_size
);
Heap_Block *const new_last_block =
_Heap_Block_at( last_block, last_block_new_size );
new_last_block->size_and_flag =
200be48: c4 20 60 04 st %g2, [ %g1 + 4 ]
RTEMS_INLINE_ROUTINE void _Heap_Block_set_size(
Heap_Block *block,
uintptr_t size
)
{
uintptr_t flag = block->size_and_flag & HEAP_PREV_BLOCK_USED;
200be4c: c2 07 20 04 ld [ %i4 + 4 ], %g1
(last_block->size_and_flag - last_block_new_size)
| HEAP_PREV_BLOCK_USED;
_Heap_Block_set_size( last_block, last_block_new_size );
_Heap_Free_block( heap, last_block );
200be50: 90 10 00 18 mov %i0, %o0
200be54: 82 08 60 01 and %g1, 1, %g1
200be58: 92 10 00 1c mov %i4, %o1
block->size_and_flag = size | flag;
200be5c: ba 17 40 01 or %i5, %g1, %i5
200be60: 7f ff ff 77 call 200bc3c <_Heap_Free_block>
200be64: fa 27 20 04 st %i5, [ %i4 + 4 ]
extend_first_block,
extend_last_block
);
}
if ( merge_below_block == NULL && merge_above_block == NULL ) {
200be68: 10 80 00 0f b 200bea4 <_Heap_Extend+0x240>
200be6c: 80 a7 20 00 cmp %i4, 0
);
}
if ( merge_above_block != NULL ) {
_Heap_Merge_above( heap, merge_above_block, extend_area_end );
} else if ( link_above_block != NULL ) {
200be70: 80 a5 60 00 cmp %l5, 0
200be74: 02 80 00 0b be 200bea0 <_Heap_Extend+0x23c>
200be78: c4 07 bf f8 ld [ %fp + -8 ], %g2
RTEMS_INLINE_ROUTINE void _Heap_Block_set_size(
Heap_Block *block,
uintptr_t size
)
{
uintptr_t flag = block->size_and_flag & HEAP_PREV_BLOCK_USED;
200be7c: c6 05 60 04 ld [ %l5 + 4 ], %g3
_Heap_Link_above(
200be80: c2 07 bf fc ld [ %fp + -4 ], %g1
200be84: 86 08 e0 01 and %g3, 1, %g3
)
{
uintptr_t const link_begin = (uintptr_t) link;
uintptr_t const first_block_begin = (uintptr_t) first_block;
_Heap_Block_set_size( link, first_block_begin - link_begin );
200be88: 84 20 80 15 sub %g2, %l5, %g2
block->size_and_flag = size | flag;
200be8c: 84 10 c0 02 or %g3, %g2, %g2
200be90: c4 25 60 04 st %g2, [ %l5 + 4 ]
last_block->size_and_flag |= HEAP_PREV_BLOCK_USED;
200be94: c4 00 60 04 ld [ %g1 + 4 ], %g2
200be98: 84 10 a0 01 or %g2, 1, %g2
200be9c: c4 20 60 04 st %g2, [ %g1 + 4 ]
extend_first_block,
extend_last_block
);
}
if ( merge_below_block == NULL && merge_above_block == NULL ) {
200bea0: 80 a7 20 00 cmp %i4, 0
200bea4: 32 80 00 09 bne,a 200bec8 <_Heap_Extend+0x264>
200bea8: c2 06 20 24 ld [ %i0 + 0x24 ], %g1
200beac: 80 a5 20 00 cmp %l4, 0
200beb0: 32 80 00 06 bne,a 200bec8 <_Heap_Extend+0x264>
200beb4: c2 06 20 24 ld [ %i0 + 0x24 ], %g1
_Heap_Free_block( heap, extend_first_block );
200beb8: d2 07 bf f8 ld [ %fp + -8 ], %o1
200bebc: 7f ff ff 60 call 200bc3c <_Heap_Free_block>
200bec0: 90 10 00 18 mov %i0, %o0
*/
RTEMS_INLINE_ROUTINE void _Heap_Set_last_block_size( Heap_Control *heap )
{
_Heap_Block_set_size(
heap->last_block,
(uintptr_t) heap->first_block - (uintptr_t) heap->last_block
200bec4: c2 06 20 24 ld [ %i0 + 0x24 ], %g1
* This feature will be used to terminate the scattered heap area list. See
* also _Heap_Extend().
*/
RTEMS_INLINE_ROUTINE void _Heap_Set_last_block_size( Heap_Control *heap )
{
_Heap_Block_set_size(
200bec8: c4 06 20 20 ld [ %i0 + 0x20 ], %g2
RTEMS_INLINE_ROUTINE void _Heap_Block_set_size(
Heap_Block *block,
uintptr_t size
)
{
uintptr_t flag = block->size_and_flag & HEAP_PREV_BLOCK_USED;
200becc: c6 00 60 04 ld [ %g1 + 4 ], %g3
* This feature will be used to terminate the scattered heap area list. See
* also _Heap_Extend().
*/
RTEMS_INLINE_ROUTINE void _Heap_Set_last_block_size( Heap_Control *heap )
{
_Heap_Block_set_size(
200bed0: 84 20 80 01 sub %g2, %g1, %g2
RTEMS_INLINE_ROUTINE void _Heap_Block_set_size(
Heap_Block *block,
uintptr_t size
)
{
uintptr_t flag = block->size_and_flag & HEAP_PREV_BLOCK_USED;
200bed4: 86 08 e0 01 and %g3, 1, %g3
block->size_and_flag = size | flag;
200bed8: 84 10 c0 02 or %g3, %g2, %g2
200bedc: c4 20 60 04 st %g2, [ %g1 + 4 ]
}
_Heap_Set_last_block_size( heap );
extended_size = stats->free_size - free_size;
200bee0: c2 06 20 30 ld [ %i0 + 0x30 ], %g1
stats->size += extended_size;
if ( extended_size_ptr != NULL )
*extended_size_ptr = extended_size;
return true;
200bee4: b8 10 20 01 mov 1, %i4
_Heap_Free_block( heap, extend_first_block );
}
_Heap_Set_last_block_size( heap );
extended_size = stats->free_size - free_size;
200bee8: a4 20 40 12 sub %g1, %l2, %l2
/* Statistics */
stats->size += extended_size;
200beec: c2 06 20 2c ld [ %i0 + 0x2c ], %g1
if ( extended_size_ptr != NULL )
200bef0: 80 a6 e0 00 cmp %i3, 0
_Heap_Set_last_block_size( heap );
extended_size = stats->free_size - free_size;
/* Statistics */
stats->size += extended_size;
200bef4: 82 00 40 12 add %g1, %l2, %g1
if ( extended_size_ptr != NULL )
200bef8: 02 80 00 03 be 200bf04 <_Heap_Extend+0x2a0> <== NEVER TAKEN
200befc: c2 26 20 2c st %g1, [ %i0 + 0x2c ]
200bf00: e4 26 c0 00 st %l2, [ %i3 ]
*extended_size_ptr = extended_size;
return true;
}
200bf04: b0 0f 20 01 and %i4, 1, %i0
200bf08: 81 c7 e0 08 ret
200bf0c: 81 e8 00 00 restore
0200c074 <_Heap_Free>:
return do_free;
}
#endif
bool _Heap_Free( Heap_Control *heap, void *alloc_begin_ptr )
{
200c074: 9d e3 bf a0 save %sp, -96, %sp
* If NULL return true so a free on NULL is considered a valid release. This
* is a special case that could be handled by the in heap check how-ever that
* would result in false being returned which is wrong.
*/
if ( alloc_begin_ptr == NULL ) {
return true;
200c078: 88 10 20 01 mov 1, %g4
/*
* If NULL return true so a free on NULL is considered a valid release. This
* is a special case that could be handled by the in heap check how-ever that
* would result in false being returned which is wrong.
*/
if ( alloc_begin_ptr == NULL ) {
200c07c: 80 a6 60 00 cmp %i1, 0
200c080: 02 80 00 77 be 200c25c <_Heap_Free+0x1e8>
200c084: 90 10 00 19 mov %i1, %o0
200c088: d2 06 20 10 ld [ %i0 + 0x10 ], %o1
200c08c: 40 00 2b 26 call 2016d24 <.urem>
200c090: ba 06 7f f8 add %i1, -8, %i5
RTEMS_INLINE_ROUTINE bool _Heap_Is_block_in_heap(
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
200c094: da 06 20 20 ld [ %i0 + 0x20 ], %o5
uintptr_t alloc_begin,
uintptr_t page_size
)
{
return (Heap_Block *) (_Heap_Align_down( alloc_begin, page_size )
- HEAP_BLOCK_HEADER_SIZE);
200c098: ba 27 40 08 sub %i5, %o0, %i5
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
200c09c: 80 a7 40 0d cmp %i5, %o5
200c0a0: 0a 80 00 05 bcs 200c0b4 <_Heap_Free+0x40>
200c0a4: 82 10 20 00 clr %g1
200c0a8: c2 06 20 24 ld [ %i0 + 0x24 ], %g1
200c0ac: 80 a0 40 1d cmp %g1, %i5
200c0b0: 82 60 3f ff subx %g0, -1, %g1
}
alloc_begin = (uintptr_t) alloc_begin_ptr;
block = _Heap_Block_of_alloc_area( alloc_begin, heap->page_size );
if ( !_Heap_Is_block_in_heap( heap, block ) ) {
200c0b4: 80 a0 60 00 cmp %g1, 0
200c0b8: 02 80 00 69 be 200c25c <_Heap_Free+0x1e8>
200c0bc: 88 10 20 00 clr %g4
--stats->used_blocks;
++stats->frees;
stats->free_size += block_size;
return( true );
}
200c0c0: d6 07 60 04 ld [ %i5 + 4 ], %o3
- HEAP_BLOCK_HEADER_SIZE);
}
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Block_size( const Heap_Block *block )
{
return block->size_and_flag & ~HEAP_PREV_BLOCK_USED;
200c0c4: 84 0a ff fe and %o3, -2, %g2
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Block_at(
const Heap_Block *block,
uintptr_t offset
)
{
return (Heap_Block *) ((uintptr_t) block + offset);
200c0c8: 82 00 80 1d add %g2, %i5, %g1
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
200c0cc: 80 a0 40 0d cmp %g1, %o5
200c0d0: 0a 80 00 05 bcs 200c0e4 <_Heap_Free+0x70> <== NEVER TAKEN
200c0d4: 86 10 20 00 clr %g3
200c0d8: c6 06 20 24 ld [ %i0 + 0x24 ], %g3
200c0dc: 80 a0 c0 01 cmp %g3, %g1
200c0e0: 86 60 3f ff subx %g0, -1, %g3
_Heap_Protection_block_check( heap, block );
block_size = _Heap_Block_size( block );
next_block = _Heap_Block_at( block, block_size );
if ( !_Heap_Is_block_in_heap( heap, next_block ) ) {
200c0e4: 80 a0 e0 00 cmp %g3, 0
200c0e8: 02 80 00 5d be 200c25c <_Heap_Free+0x1e8> <== NEVER TAKEN
200c0ec: 88 10 20 00 clr %g4
--stats->used_blocks;
++stats->frees;
stats->free_size += block_size;
return( true );
}
200c0f0: de 00 60 04 ld [ %g1 + 4 ], %o7
return false;
}
_Heap_Protection_block_check( heap, next_block );
if ( !_Heap_Is_prev_used( next_block ) ) {
200c0f4: 80 8b e0 01 btst 1, %o7
200c0f8: 02 80 00 59 be 200c25c <_Heap_Free+0x1e8>
200c0fc: 9e 0b ff fe and %o7, -2, %o7
if ( !_Heap_Protection_determine_block_free( heap, block ) ) {
return true;
}
next_block_size = _Heap_Block_size( next_block );
next_is_free = next_block != heap->last_block
200c100: c8 06 20 24 ld [ %i0 + 0x24 ], %g4
&& !_Heap_Is_prev_used( _Heap_Block_at( next_block, next_block_size ));
200c104: 80 a0 40 04 cmp %g1, %g4
200c108: 02 80 00 07 be 200c124 <_Heap_Free+0xb0>
200c10c: 98 10 20 00 clr %o4
--stats->used_blocks;
++stats->frees;
stats->free_size += block_size;
return( true );
}
200c110: 86 00 40 0f add %g1, %o7, %g3
block->size_and_flag = size | flag;
}
RTEMS_INLINE_ROUTINE bool _Heap_Is_prev_used( const Heap_Block *block )
{
return block->size_and_flag & HEAP_PREV_BLOCK_USED;
200c114: c6 00 e0 04 ld [ %g3 + 4 ], %g3
200c118: 86 08 e0 01 and %g3, 1, %g3
return true;
}
next_block_size = _Heap_Block_size( next_block );
next_is_free = next_block != heap->last_block
&& !_Heap_Is_prev_used( _Heap_Block_at( next_block, next_block_size ));
200c11c: 80 a0 00 03 cmp %g0, %g3
200c120: 98 60 3f ff subx %g0, -1, %o4
if ( !_Heap_Is_prev_used( block ) ) {
200c124: 80 8a e0 01 btst 1, %o3
200c128: 12 80 00 25 bne 200c1bc <_Heap_Free+0x148>
200c12c: 80 8b 20 ff btst 0xff, %o4
uintptr_t const prev_size = block->prev_size;
200c130: d6 07 40 00 ld [ %i5 ], %o3
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Block_at(
const Heap_Block *block,
uintptr_t offset
)
{
return (Heap_Block *) ((uintptr_t) block + offset);
200c134: 86 27 40 0b sub %i5, %o3, %g3
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
200c138: 80 a0 c0 0d cmp %g3, %o5
200c13c: 0a 80 00 04 bcs 200c14c <_Heap_Free+0xd8> <== NEVER TAKEN
200c140: 94 10 20 00 clr %o2
200c144: 80 a1 00 03 cmp %g4, %g3
200c148: 94 60 3f ff subx %g0, -1, %o2
Heap_Block * const prev_block = _Heap_Block_at( block, -prev_size );
if ( !_Heap_Is_block_in_heap( heap, prev_block ) ) {
200c14c: 80 a2 a0 00 cmp %o2, 0
200c150: 02 80 00 43 be 200c25c <_Heap_Free+0x1e8> <== NEVER TAKEN
200c154: 88 10 20 00 clr %g4
block->size_and_flag = size | flag;
}
RTEMS_INLINE_ROUTINE bool _Heap_Is_prev_used( const Heap_Block *block )
{
return block->size_and_flag & HEAP_PREV_BLOCK_USED;
200c158: da 00 e0 04 ld [ %g3 + 4 ], %o5
return( false );
}
/* As we always coalesce free blocks, the block that preceedes prev_block
must have been used. */
if ( !_Heap_Is_prev_used ( prev_block) ) {
200c15c: 80 8b 60 01 btst 1, %o5
200c160: 02 80 00 3f be 200c25c <_Heap_Free+0x1e8> <== NEVER TAKEN
200c164: 80 8b 20 ff btst 0xff, %o4
_HAssert( false );
return( false );
}
if ( next_is_free ) { /* coalesce both */
200c168: 02 80 00 0e be 200c1a0 <_Heap_Free+0x12c>
200c16c: 88 00 80 0b add %g2, %o3, %g4
uintptr_t const size = block_size + prev_size + next_block_size;
200c170: 9e 01 00 0f add %g4, %o7, %o7
return _Heap_Free_list_tail(heap)->prev;
}
RTEMS_INLINE_ROUTINE void _Heap_Free_list_remove( Heap_Block *block )
{
Heap_Block *next = block->next;
200c174: c8 00 60 08 ld [ %g1 + 8 ], %g4
Heap_Block *prev = block->prev;
200c178: c2 00 60 0c ld [ %g1 + 0xc ], %g1
prev->next = next;
200c17c: c8 20 60 08 st %g4, [ %g1 + 8 ]
next->prev = prev;
200c180: c2 21 20 0c st %g1, [ %g4 + 0xc ]
_Heap_Free_list_remove( next_block );
stats->free_blocks -= 1;
200c184: c2 06 20 38 ld [ %i0 + 0x38 ], %g1
200c188: 82 00 7f ff add %g1, -1, %g1
200c18c: c2 26 20 38 st %g1, [ %i0 + 0x38 ]
prev_block->size_and_flag = size | HEAP_PREV_BLOCK_USED;
next_block = _Heap_Block_at( prev_block, size );
_HAssert(!_Heap_Is_prev_used( next_block));
next_block->prev_size = size;
200c190: de 23 c0 03 st %o7, [ %o7 + %g3 ]
if ( next_is_free ) { /* coalesce both */
uintptr_t const size = block_size + prev_size + next_block_size;
_Heap_Free_list_remove( next_block );
stats->free_blocks -= 1;
prev_block->size_and_flag = size | HEAP_PREV_BLOCK_USED;
200c194: 82 13 e0 01 or %o7, 1, %g1
200c198: 10 80 00 27 b 200c234 <_Heap_Free+0x1c0>
200c19c: c2 20 e0 04 st %g1, [ %g3 + 4 ]
next_block = _Heap_Block_at( prev_block, size );
_HAssert(!_Heap_Is_prev_used( next_block));
next_block->prev_size = size;
} else { /* coalesce prev */
uintptr_t const size = block_size + prev_size;
prev_block->size_and_flag = size | HEAP_PREV_BLOCK_USED;
200c1a0: 9e 11 20 01 or %g4, 1, %o7
200c1a4: de 20 e0 04 st %o7, [ %g3 + 4 ]
next_block->size_and_flag &= ~HEAP_PREV_BLOCK_USED;
200c1a8: c6 00 60 04 ld [ %g1 + 4 ], %g3
next_block->prev_size = size;
200c1ac: c8 20 80 1d st %g4, [ %g2 + %i5 ]
_HAssert(!_Heap_Is_prev_used( next_block));
next_block->prev_size = size;
} else { /* coalesce prev */
uintptr_t const size = block_size + prev_size;
prev_block->size_and_flag = size | HEAP_PREV_BLOCK_USED;
next_block->size_and_flag &= ~HEAP_PREV_BLOCK_USED;
200c1b0: 86 08 ff fe and %g3, -2, %g3
200c1b4: 10 80 00 20 b 200c234 <_Heap_Free+0x1c0>
200c1b8: c6 20 60 04 st %g3, [ %g1 + 4 ]
next_block->prev_size = size;
}
} else if ( next_is_free ) { /* coalesce next */
200c1bc: 22 80 00 0d be,a 200c1f0 <_Heap_Free+0x17c>
200c1c0: c6 06 20 08 ld [ %i0 + 8 ], %g3
RTEMS_INLINE_ROUTINE void _Heap_Free_list_replace(
Heap_Block *old_block,
Heap_Block *new_block
)
{
Heap_Block *next = old_block->next;
200c1c4: c8 00 60 08 ld [ %g1 + 8 ], %g4
Heap_Block *prev = old_block->prev;
200c1c8: c2 00 60 0c ld [ %g1 + 0xc ], %g1
new_block->next = next;
200c1cc: c8 27 60 08 st %g4, [ %i5 + 8 ]
new_block->prev = prev;
200c1d0: c2 27 60 0c st %g1, [ %i5 + 0xc ]
uintptr_t const size = block_size + next_block_size;
200c1d4: 86 03 c0 02 add %o7, %g2, %g3
next->prev = new_block;
prev->next = new_block;
200c1d8: fa 20 60 08 st %i5, [ %g1 + 8 ]
Heap_Block *prev = old_block->prev;
new_block->next = next;
new_block->prev = prev;
next->prev = new_block;
200c1dc: fa 21 20 0c st %i5, [ %g4 + 0xc ]
_Heap_Free_list_replace( next_block, block );
block->size_and_flag = size | HEAP_PREV_BLOCK_USED;
200c1e0: 82 10 e0 01 or %g3, 1, %g1
next_block = _Heap_Block_at( block, size );
next_block->prev_size = size;
200c1e4: c6 20 c0 1d st %g3, [ %g3 + %i5 ]
next_block->prev_size = size;
}
} else if ( next_is_free ) { /* coalesce next */
uintptr_t const size = block_size + next_block_size;
_Heap_Free_list_replace( next_block, block );
block->size_and_flag = size | HEAP_PREV_BLOCK_USED;
200c1e8: 10 80 00 13 b 200c234 <_Heap_Free+0x1c0>
200c1ec: c2 27 60 04 st %g1, [ %i5 + 4 ]
)
{
Heap_Block *next = block_before->next;
new_block->next = next;
new_block->prev = block_before;
200c1f0: f0 27 60 0c st %i0, [ %i5 + 0xc ]
Heap_Block *new_block
)
{
Heap_Block *next = block_before->next;
new_block->next = next;
200c1f4: c6 27 60 08 st %g3, [ %i5 + 8 ]
new_block->prev = block_before;
block_before->next = new_block;
next->prev = new_block;
200c1f8: fa 20 e0 0c st %i5, [ %g3 + 0xc ]
next_block->prev_size = size;
} else { /* no coalesce */
/* Add 'block' to the head of the free blocks list as it tends to
produce less fragmentation than adding to the tail. */
_Heap_Free_list_insert_after( _Heap_Free_list_head( heap), block );
block->size_and_flag = block_size | HEAP_PREV_BLOCK_USED;
200c1fc: 86 10 a0 01 or %g2, 1, %g3
200c200: c6 27 60 04 st %g3, [ %i5 + 4 ]
next_block->size_and_flag &= ~HEAP_PREV_BLOCK_USED;
200c204: c6 00 60 04 ld [ %g1 + 4 ], %g3
next_block->prev_size = block_size;
200c208: c4 20 80 1d st %g2, [ %g2 + %i5 ]
} else { /* no coalesce */
/* Add 'block' to the head of the free blocks list as it tends to
produce less fragmentation than adding to the tail. */
_Heap_Free_list_insert_after( _Heap_Free_list_head( heap), block );
block->size_and_flag = block_size | HEAP_PREV_BLOCK_USED;
next_block->size_and_flag &= ~HEAP_PREV_BLOCK_USED;
200c20c: 86 08 ff fe and %g3, -2, %g3
200c210: c6 20 60 04 st %g3, [ %g1 + 4 ]
next_block->prev_size = block_size;
/* Statistics */
++stats->free_blocks;
200c214: c2 06 20 38 ld [ %i0 + 0x38 ], %g1
if ( stats->max_free_blocks < stats->free_blocks ) {
200c218: c6 06 20 3c ld [ %i0 + 0x3c ], %g3
block->size_and_flag = block_size | HEAP_PREV_BLOCK_USED;
next_block->size_and_flag &= ~HEAP_PREV_BLOCK_USED;
next_block->prev_size = block_size;
/* Statistics */
++stats->free_blocks;
200c21c: 82 00 60 01 inc %g1
{
Heap_Block *next = block_before->next;
new_block->next = next;
new_block->prev = block_before;
block_before->next = new_block;
200c220: fa 26 20 08 st %i5, [ %i0 + 8 ]
if ( stats->max_free_blocks < stats->free_blocks ) {
200c224: 80 a0 c0 01 cmp %g3, %g1
200c228: 1a 80 00 03 bcc 200c234 <_Heap_Free+0x1c0>
200c22c: c2 26 20 38 st %g1, [ %i0 + 0x38 ]
stats->max_free_blocks = stats->free_blocks;
200c230: c2 26 20 3c st %g1, [ %i0 + 0x3c ]
}
}
/* Statistics */
--stats->used_blocks;
200c234: c2 06 20 40 ld [ %i0 + 0x40 ], %g1
++stats->frees;
stats->free_size += block_size;
return( true );
200c238: 88 10 20 01 mov 1, %g4
stats->max_free_blocks = stats->free_blocks;
}
}
/* Statistics */
--stats->used_blocks;
200c23c: 82 00 7f ff add %g1, -1, %g1
200c240: c2 26 20 40 st %g1, [ %i0 + 0x40 ]
++stats->frees;
200c244: c2 06 20 50 ld [ %i0 + 0x50 ], %g1
200c248: 82 00 60 01 inc %g1
200c24c: c2 26 20 50 st %g1, [ %i0 + 0x50 ]
stats->free_size += block_size;
200c250: c2 06 20 30 ld [ %i0 + 0x30 ], %g1
200c254: 84 00 40 02 add %g1, %g2, %g2
200c258: c4 26 20 30 st %g2, [ %i0 + 0x30 ]
return( true );
}
200c25c: b0 09 20 01 and %g4, 1, %i0
200c260: 81 c7 e0 08 ret
200c264: 81 e8 00 00 restore
020187f4 <_Heap_Size_of_alloc_area>:
bool _Heap_Size_of_alloc_area(
Heap_Control *heap,
void *alloc_begin_ptr,
uintptr_t *alloc_size
)
{
20187f4: 9d e3 bf a0 save %sp, -96, %sp
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Align_down(
uintptr_t value,
uintptr_t alignment
)
{
return value - (value % alignment);
20187f8: d2 06 20 10 ld [ %i0 + 0x10 ], %o1
20187fc: 7f ff f9 4a call 2016d24 <.urem>
2018800: 90 10 00 19 mov %i1, %o0
RTEMS_INLINE_ROUTINE bool _Heap_Is_block_in_heap(
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
2018804: c6 06 20 20 ld [ %i0 + 0x20 ], %g3
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Align_down(
uintptr_t value,
uintptr_t alignment
)
{
return value - (value % alignment);
2018808: ba 06 7f f8 add %i1, -8, %i5
uintptr_t alloc_begin,
uintptr_t page_size
)
{
return (Heap_Block *) (_Heap_Align_down( alloc_begin, page_size )
- HEAP_BLOCK_HEADER_SIZE);
201880c: 90 27 40 08 sub %i5, %o0, %o0
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
2018810: 80 a2 00 03 cmp %o0, %g3
2018814: 0a 80 00 05 bcs 2018828 <_Heap_Size_of_alloc_area+0x34>
2018818: 84 10 20 00 clr %g2
201881c: c2 06 20 24 ld [ %i0 + 0x24 ], %g1
2018820: 80 a0 40 08 cmp %g1, %o0
2018824: 84 60 3f ff subx %g0, -1, %g2
uintptr_t const alloc_begin = (uintptr_t) alloc_begin_ptr;
Heap_Block *block = _Heap_Block_of_alloc_area( alloc_begin, page_size );
Heap_Block *next_block = NULL;
uintptr_t block_size = 0;
if ( !_Heap_Is_block_in_heap( heap, block ) ) {
2018828: 80 a0 a0 00 cmp %g2, 0
201882c: 02 80 00 15 be 2018880 <_Heap_Size_of_alloc_area+0x8c>
2018830: 82 10 20 00 clr %g1
- HEAP_BLOCK_HEADER_SIZE);
}
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Block_size( const Heap_Block *block )
{
return block->size_and_flag & ~HEAP_PREV_BLOCK_USED;
2018834: fa 02 20 04 ld [ %o0 + 4 ], %i5
2018838: ba 0f 7f fe and %i5, -2, %i5
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Block_at(
const Heap_Block *block,
uintptr_t offset
)
{
return (Heap_Block *) ((uintptr_t) block + offset);
201883c: ba 07 40 08 add %i5, %o0, %i5
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
2018840: 80 a7 40 03 cmp %i5, %g3
2018844: 0a 80 00 05 bcs 2018858 <_Heap_Size_of_alloc_area+0x64> <== NEVER TAKEN
2018848: 84 10 20 00 clr %g2
201884c: c2 06 20 24 ld [ %i0 + 0x24 ], %g1
2018850: 80 a0 40 1d cmp %g1, %i5
2018854: 84 60 3f ff subx %g0, -1, %g2
}
block_size = _Heap_Block_size( block );
next_block = _Heap_Block_at( block, block_size );
if (
2018858: 80 a0 a0 00 cmp %g2, 0
201885c: 02 80 00 09 be 2018880 <_Heap_Size_of_alloc_area+0x8c> <== NEVER TAKEN
2018860: 82 10 20 00 clr %g1
block->size_and_flag = size | flag;
}
RTEMS_INLINE_ROUTINE bool _Heap_Is_prev_used( const Heap_Block *block )
{
return block->size_and_flag & HEAP_PREV_BLOCK_USED;
2018864: c4 07 60 04 ld [ %i5 + 4 ], %g2
!_Heap_Is_block_in_heap( heap, next_block )
|| !_Heap_Is_prev_used( next_block )
2018868: 80 88 a0 01 btst 1, %g2
201886c: 02 80 00 05 be 2018880 <_Heap_Size_of_alloc_area+0x8c> <== NEVER TAKEN
2018870: ba 27 40 19 sub %i5, %i1, %i5
return false;
}
*alloc_size = (uintptr_t) next_block + HEAP_ALLOC_BONUS - alloc_begin;
return true;
2018874: 82 10 20 01 mov 1, %g1
|| !_Heap_Is_prev_used( next_block )
) {
return false;
}
*alloc_size = (uintptr_t) next_block + HEAP_ALLOC_BONUS - alloc_begin;
2018878: ba 07 60 04 add %i5, 4, %i5
201887c: fa 26 80 00 st %i5, [ %i2 ]
return true;
}
2018880: b0 08 60 01 and %g1, 1, %i0
2018884: 81 c7 e0 08 ret
2018888: 81 e8 00 00 restore
020080d8 <_Heap_Walk>:
bool _Heap_Walk(
Heap_Control *heap,
int source,
bool dump
)
{
20080d8: 9d e3 bf 80 save %sp, -128, %sp
uintptr_t const min_block_size = heap->min_block_size;
Heap_Block *const first_block = heap->first_block;
Heap_Block *const last_block = heap->last_block;
Heap_Block *block = first_block;
Heap_Walk_printer printer = dump ?
_Heap_Walk_print : _Heap_Walk_print_nothing;
20080dc: 3b 00 80 20 sethi %hi(0x2008000), %i5
Heap_Control *heap,
int source,
bool dump
)
{
uintptr_t const page_size = heap->page_size;
20080e0: f8 06 20 10 ld [ %i0 + 0x10 ], %i4
uintptr_t const min_block_size = heap->min_block_size;
20080e4: e0 06 20 14 ld [ %i0 + 0x14 ], %l0
Heap_Block *const first_block = heap->first_block;
20080e8: f6 06 20 20 ld [ %i0 + 0x20 ], %i3
Heap_Block *const last_block = heap->last_block;
20080ec: e2 06 20 24 ld [ %i0 + 0x24 ], %l1
Heap_Block *block = first_block;
Heap_Walk_printer printer = dump ?
_Heap_Walk_print : _Heap_Walk_print_nothing;
20080f0: 80 a6 a0 00 cmp %i2, 0
20080f4: 02 80 00 04 be 2008104 <_Heap_Walk+0x2c>
20080f8: ba 17 60 84 or %i5, 0x84, %i5
20080fc: 3b 00 80 20 sethi %hi(0x2008000), %i5
2008100: ba 17 60 8c or %i5, 0x8c, %i5 ! 200808c <_Heap_Walk_print>
if ( !_System_state_Is_up( _System_state_Get() ) ) {
2008104: 03 00 80 5c sethi %hi(0x2017000), %g1
2008108: c4 00 63 e4 ld [ %g1 + 0x3e4 ], %g2 ! 20173e4 <_System_state_Current>
200810c: 80 a0 a0 03 cmp %g2, 3
2008110: 12 80 01 24 bne 20085a0 <_Heap_Walk+0x4c8>
2008114: 82 10 20 01 mov 1, %g1
Heap_Block *const first_free_block = _Heap_Free_list_first( heap );
Heap_Block *const last_free_block = _Heap_Free_list_last( heap );
Heap_Block *const first_block = heap->first_block;
Heap_Block *const last_block = heap->last_block;
(*printer)(
2008118: c2 06 20 1c ld [ %i0 + 0x1c ], %g1
200811c: da 06 20 18 ld [ %i0 + 0x18 ], %o5
2008120: c2 23 a0 5c st %g1, [ %sp + 0x5c ]
2008124: f6 23 a0 60 st %i3, [ %sp + 0x60 ]
2008128: e2 23 a0 64 st %l1, [ %sp + 0x64 ]
200812c: c2 06 20 08 ld [ %i0 + 8 ], %g1
2008130: 90 10 00 19 mov %i1, %o0
2008134: c2 23 a0 68 st %g1, [ %sp + 0x68 ]
2008138: c2 06 20 0c ld [ %i0 + 0xc ], %g1
200813c: 92 10 20 00 clr %o1
2008140: c2 23 a0 6c st %g1, [ %sp + 0x6c ]
2008144: 15 00 80 52 sethi %hi(0x2014800), %o2
2008148: 96 10 00 1c mov %i4, %o3
200814c: 94 12 a1 98 or %o2, 0x198, %o2
2008150: 9f c7 40 00 call %i5
2008154: 98 10 00 10 mov %l0, %o4
heap->area_begin, heap->area_end,
first_block, last_block,
first_free_block, last_free_block
);
if ( page_size == 0 ) {
2008158: 80 a7 20 00 cmp %i4, 0
200815c: 12 80 00 07 bne 2008178 <_Heap_Walk+0xa0>
2008160: 80 8f 20 07 btst 7, %i4
(*printer)( source, true, "page size is zero\n" );
2008164: 15 00 80 52 sethi %hi(0x2014800), %o2
2008168: 90 10 00 19 mov %i1, %o0
200816c: 92 10 20 01 mov 1, %o1
2008170: 10 80 00 32 b 2008238 <_Heap_Walk+0x160>
2008174: 94 12 a2 30 or %o2, 0x230, %o2
return false;
}
if ( !_Addresses_Is_aligned( (void *) page_size ) ) {
2008178: 22 80 00 08 be,a 2008198 <_Heap_Walk+0xc0>
200817c: 90 10 00 10 mov %l0, %o0
(*printer)(
2008180: 15 00 80 52 sethi %hi(0x2014800), %o2
2008184: 90 10 00 19 mov %i1, %o0
2008188: 92 10 20 01 mov 1, %o1
200818c: 94 12 a2 48 or %o2, 0x248, %o2
2008190: 10 80 01 0b b 20085bc <_Heap_Walk+0x4e4>
2008194: 96 10 00 1c mov %i4, %o3
RTEMS_INLINE_ROUTINE bool _Heap_Is_aligned(
uintptr_t value,
uintptr_t alignment
)
{
return (value % alignment) == 0;
2008198: 7f ff e6 52 call 2001ae0 <.urem>
200819c: 92 10 00 1c mov %i4, %o1
);
return false;
}
if ( !_Heap_Is_aligned( min_block_size, page_size ) ) {
20081a0: 80 a2 20 00 cmp %o0, 0
20081a4: 22 80 00 08 be,a 20081c4 <_Heap_Walk+0xec>
20081a8: 90 06 e0 08 add %i3, 8, %o0
(*printer)(
20081ac: 15 00 80 52 sethi %hi(0x2014800), %o2
20081b0: 90 10 00 19 mov %i1, %o0
20081b4: 92 10 20 01 mov 1, %o1
20081b8: 94 12 a2 68 or %o2, 0x268, %o2
20081bc: 10 80 01 00 b 20085bc <_Heap_Walk+0x4e4>
20081c0: 96 10 00 10 mov %l0, %o3
20081c4: 7f ff e6 47 call 2001ae0 <.urem>
20081c8: 92 10 00 1c mov %i4, %o1
);
return false;
}
if (
20081cc: 80 a2 20 00 cmp %o0, 0
20081d0: 22 80 00 08 be,a 20081f0 <_Heap_Walk+0x118>
20081d4: c2 06 e0 04 ld [ %i3 + 4 ], %g1
!_Heap_Is_aligned( _Heap_Alloc_area_of_block( first_block ), page_size )
) {
(*printer)(
20081d8: 15 00 80 52 sethi %hi(0x2014800), %o2
20081dc: 90 10 00 19 mov %i1, %o0
20081e0: 92 10 20 01 mov 1, %o1
20081e4: 94 12 a2 90 or %o2, 0x290, %o2
20081e8: 10 80 00 f5 b 20085bc <_Heap_Walk+0x4e4>
20081ec: 96 10 00 1b mov %i3, %o3
);
return false;
}
if ( !_Heap_Is_prev_used( first_block ) ) {
20081f0: 80 88 60 01 btst 1, %g1
20081f4: 32 80 00 07 bne,a 2008210 <_Heap_Walk+0x138>
20081f8: f4 04 60 04 ld [ %l1 + 4 ], %i2
(*printer)(
20081fc: 15 00 80 52 sethi %hi(0x2014800), %o2
2008200: 90 10 00 19 mov %i1, %o0
2008204: 92 10 20 01 mov 1, %o1
2008208: 10 80 00 0c b 2008238 <_Heap_Walk+0x160>
200820c: 94 12 a2 c8 or %o2, 0x2c8, %o2
- HEAP_BLOCK_HEADER_SIZE);
}
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Block_size( const Heap_Block *block )
{
return block->size_and_flag & ~HEAP_PREV_BLOCK_USED;
2008210: b4 0e bf fe and %i2, -2, %i2
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Block_at(
const Heap_Block *block,
uintptr_t offset
)
{
return (Heap_Block *) ((uintptr_t) block + offset);
2008214: b4 04 40 1a add %l1, %i2, %i2
block->size_and_flag = size | flag;
}
RTEMS_INLINE_ROUTINE bool _Heap_Is_prev_used( const Heap_Block *block )
{
return block->size_and_flag & HEAP_PREV_BLOCK_USED;
2008218: c2 06 a0 04 ld [ %i2 + 4 ], %g1
);
return false;
}
if ( _Heap_Is_free( last_block ) ) {
200821c: 80 88 60 01 btst 1, %g1
2008220: 12 80 00 0a bne 2008248 <_Heap_Walk+0x170>
2008224: 80 a6 80 1b cmp %i2, %i3
(*printer)(
2008228: 15 00 80 52 sethi %hi(0x2014800), %o2
200822c: 90 10 00 19 mov %i1, %o0
2008230: 92 10 20 01 mov 1, %o1
2008234: 94 12 a2 f8 or %o2, 0x2f8, %o2
2008238: 9f c7 40 00 call %i5
200823c: 01 00 00 00 nop
if ( !_System_state_Is_up( _System_state_Get() ) ) {
return true;
}
if ( !_Heap_Walk_check_control( source, printer, heap ) ) {
return false;
2008240: 10 80 00 d8 b 20085a0 <_Heap_Walk+0x4c8>
2008244: 82 10 20 00 clr %g1 ! 0 <PROM_START>
);
return false;
}
if (
2008248: 02 80 00 06 be 2008260 <_Heap_Walk+0x188>
200824c: 15 00 80 52 sethi %hi(0x2014800), %o2
_Heap_Block_at( last_block, _Heap_Block_size( last_block ) ) != first_block
) {
(*printer)(
2008250: 90 10 00 19 mov %i1, %o0
2008254: 92 10 20 01 mov 1, %o1
2008258: 10 bf ff f8 b 2008238 <_Heap_Walk+0x160>
200825c: 94 12 a3 10 or %o2, 0x310, %o2
int source,
Heap_Walk_printer printer,
Heap_Control *heap
)
{
uintptr_t const page_size = heap->page_size;
2008260: e6 06 20 10 ld [ %i0 + 0x10 ], %l3
return &heap->free_list;
}
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Free_list_first( Heap_Control *heap )
{
return _Heap_Free_list_head(heap)->next;
2008264: d6 06 20 08 ld [ %i0 + 8 ], %o3
const Heap_Block *const free_list_tail = _Heap_Free_list_tail( heap );
2008268: 10 80 00 33 b 2008334 <_Heap_Walk+0x25c>
200826c: a4 10 00 18 mov %i0, %l2
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
2008270: 80 a0 80 0b cmp %g2, %o3
2008274: 18 80 00 05 bgu 2008288 <_Heap_Walk+0x1b0>
2008278: 82 10 20 00 clr %g1
200827c: c2 06 20 24 ld [ %i0 + 0x24 ], %g1
2008280: 80 a0 40 0b cmp %g1, %o3
2008284: 82 60 3f ff subx %g0, -1, %g1
const Heap_Block *const first_free_block = _Heap_Free_list_first( heap );
const Heap_Block *prev_block = free_list_tail;
const Heap_Block *free_block = first_free_block;
while ( free_block != free_list_tail ) {
if ( !_Heap_Is_block_in_heap( heap, free_block ) ) {
2008288: 80 a0 60 00 cmp %g1, 0
200828c: 32 80 00 07 bne,a 20082a8 <_Heap_Walk+0x1d0>
2008290: 90 02 e0 08 add %o3, 8, %o0
(*printer)(
2008294: 15 00 80 52 sethi %hi(0x2014800), %o2
2008298: 90 10 00 19 mov %i1, %o0
200829c: 92 10 20 01 mov 1, %o1
20082a0: 10 80 00 c7 b 20085bc <_Heap_Walk+0x4e4>
20082a4: 94 12 a3 40 or %o2, 0x340, %o2
RTEMS_INLINE_ROUTINE bool _Heap_Is_aligned(
uintptr_t value,
uintptr_t alignment
)
{
return (value % alignment) == 0;
20082a8: d6 27 bf f8 st %o3, [ %fp + -8 ]
20082ac: 7f ff e6 0d call 2001ae0 <.urem>
20082b0: 92 10 00 13 mov %l3, %o1
);
return false;
}
if (
20082b4: 80 a2 20 00 cmp %o0, 0
20082b8: 02 80 00 07 be 20082d4 <_Heap_Walk+0x1fc>
20082bc: d6 07 bf f8 ld [ %fp + -8 ], %o3
!_Heap_Is_aligned( _Heap_Alloc_area_of_block( free_block ), page_size )
) {
(*printer)(
20082c0: 15 00 80 52 sethi %hi(0x2014800), %o2
20082c4: 90 10 00 19 mov %i1, %o0
20082c8: 92 10 20 01 mov 1, %o1
20082cc: 10 80 00 bc b 20085bc <_Heap_Walk+0x4e4>
20082d0: 94 12 a3 60 or %o2, 0x360, %o2
- HEAP_BLOCK_HEADER_SIZE);
}
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Block_size( const Heap_Block *block )
{
return block->size_and_flag & ~HEAP_PREV_BLOCK_USED;
20082d4: c2 02 e0 04 ld [ %o3 + 4 ], %g1
20082d8: 82 08 7f fe and %g1, -2, %g1
block = next_block;
} while ( block != first_block );
return true;
}
20082dc: 82 02 c0 01 add %o3, %g1, %g1
block->size_and_flag = size | flag;
}
RTEMS_INLINE_ROUTINE bool _Heap_Is_prev_used( const Heap_Block *block )
{
return block->size_and_flag & HEAP_PREV_BLOCK_USED;
20082e0: c2 00 60 04 ld [ %g1 + 4 ], %g1
);
return false;
}
if ( _Heap_Is_used( free_block ) ) {
20082e4: 80 88 60 01 btst 1, %g1
20082e8: 22 80 00 07 be,a 2008304 <_Heap_Walk+0x22c>
20082ec: d8 02 e0 0c ld [ %o3 + 0xc ], %o4
(*printer)(
20082f0: 15 00 80 52 sethi %hi(0x2014800), %o2
20082f4: 90 10 00 19 mov %i1, %o0
20082f8: 92 10 20 01 mov 1, %o1
20082fc: 10 80 00 b0 b 20085bc <_Heap_Walk+0x4e4>
2008300: 94 12 a3 90 or %o2, 0x390, %o2
);
return false;
}
if ( free_block->prev != prev_block ) {
2008304: 80 a3 00 12 cmp %o4, %l2
2008308: 22 80 00 0a be,a 2008330 <_Heap_Walk+0x258>
200830c: a4 10 00 0b mov %o3, %l2
(*printer)(
2008310: 15 00 80 52 sethi %hi(0x2014800), %o2
2008314: 90 10 00 19 mov %i1, %o0
2008318: 92 10 20 01 mov 1, %o1
200831c: 94 12 a3 b0 or %o2, 0x3b0, %o2
2008320: 9f c7 40 00 call %i5
2008324: 01 00 00 00 nop
if ( !_System_state_Is_up( _System_state_Get() ) ) {
return true;
}
if ( !_Heap_Walk_check_control( source, printer, heap ) ) {
return false;
2008328: 10 80 00 9e b 20085a0 <_Heap_Walk+0x4c8>
200832c: 82 10 20 00 clr %g1 ! 0 <PROM_START>
return false;
}
prev_block = free_block;
free_block = free_block->next;
2008330: d6 02 e0 08 ld [ %o3 + 8 ], %o3
const Heap_Block *const free_list_tail = _Heap_Free_list_tail( heap );
const Heap_Block *const first_free_block = _Heap_Free_list_first( heap );
const Heap_Block *prev_block = free_list_tail;
const Heap_Block *free_block = first_free_block;
while ( free_block != free_list_tail ) {
2008334: 80 a2 c0 18 cmp %o3, %i0
2008338: 32 bf ff ce bne,a 2008270 <_Heap_Walk+0x198>
200833c: c4 06 20 20 ld [ %i0 + 0x20 ], %g2
2008340: 2d 00 80 53 sethi %hi(0x2014c00), %l6
if ( !_Heap_Is_prev_used( next_block ) ) {
if ( !_Heap_Walk_check_free_block( source, printer, heap, block ) ) {
return false;
}
} else if (prev_used) {
(*printer)(
2008344: 2f 00 80 53 sethi %hi(0x2014c00), %l7
"block 0x%08x: size %u\n",
block,
block_size
);
} else {
(*printer)(
2008348: ac 15 a1 70 or %l6, 0x170, %l6
if ( !_Heap_Is_prev_used( next_block ) ) {
if ( !_Heap_Walk_check_free_block( source, printer, heap, block ) ) {
return false;
}
} else if (prev_used) {
(*printer)(
200834c: ae 15 e1 58 or %l7, 0x158, %l7
" (= first free)"
: (block->prev == free_list_head ? " (= head)" : ""),
block->next,
block->next == last_free_block ?
" (= last free)"
: (block->next == free_list_tail ? " (= tail)" : "")
2008350: 2b 00 80 53 sethi %hi(0x2014c00), %l5
block = next_block;
} while ( block != first_block );
return true;
}
2008354: c2 06 a0 04 ld [ %i2 + 4 ], %g1
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
2008358: c6 06 20 20 ld [ %i0 + 0x20 ], %g3
- HEAP_BLOCK_HEADER_SIZE);
}
RTEMS_INLINE_ROUTINE uintptr_t _Heap_Block_size( const Heap_Block *block )
{
return block->size_and_flag & ~HEAP_PREV_BLOCK_USED;
200835c: a4 08 7f fe and %g1, -2, %l2
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Block_at(
const Heap_Block *block,
uintptr_t offset
)
{
return (Heap_Block *) ((uintptr_t) block + offset);
2008360: a6 04 80 1a add %l2, %i2, %l3
const Heap_Control *heap,
const Heap_Block *block
)
{
return (uintptr_t) block >= (uintptr_t) heap->first_block
&& (uintptr_t) block <= (uintptr_t) heap->last_block;
2008364: 80 a0 c0 13 cmp %g3, %l3
2008368: 18 80 00 05 bgu 200837c <_Heap_Walk+0x2a4> <== NEVER TAKEN
200836c: 84 10 20 00 clr %g2
2008370: c4 06 20 24 ld [ %i0 + 0x24 ], %g2
2008374: 80 a0 80 13 cmp %g2, %l3
2008378: 84 60 3f ff subx %g0, -1, %g2
bool const prev_used = _Heap_Is_prev_used( block );
Heap_Block *const next_block = _Heap_Block_at( block, block_size );
uintptr_t const next_block_begin = (uintptr_t) next_block;
bool const is_not_last_block = block != last_block;
if ( !_Heap_Is_block_in_heap( heap, next_block ) ) {
200837c: 80 a0 a0 00 cmp %g2, 0
2008380: 12 80 00 07 bne 200839c <_Heap_Walk+0x2c4>
2008384: 84 1e 80 11 xor %i2, %l1, %g2
(*printer)(
2008388: 15 00 80 52 sethi %hi(0x2014800), %o2
200838c: 90 10 00 19 mov %i1, %o0
2008390: 92 10 20 01 mov 1, %o1
2008394: 10 80 00 2c b 2008444 <_Heap_Walk+0x36c>
2008398: 94 12 a3 e8 or %o2, 0x3e8, %o2
uintptr_t const block_begin = (uintptr_t) block;
uintptr_t const block_size = _Heap_Block_size( block );
bool const prev_used = _Heap_Is_prev_used( block );
Heap_Block *const next_block = _Heap_Block_at( block, block_size );
uintptr_t const next_block_begin = (uintptr_t) next_block;
bool const is_not_last_block = block != last_block;
200839c: 80 a0 00 02 cmp %g0, %g2
RTEMS_INLINE_ROUTINE bool _Heap_Is_aligned(
uintptr_t value,
uintptr_t alignment
)
{
return (value % alignment) == 0;
20083a0: c2 27 bf fc st %g1, [ %fp + -4 ]
20083a4: a8 40 20 00 addx %g0, 0, %l4
20083a8: 90 10 00 12 mov %l2, %o0
20083ac: 7f ff e5 cd call 2001ae0 <.urem>
20083b0: 92 10 00 1c mov %i4, %o1
);
return false;
}
if ( !_Heap_Is_aligned( block_size, page_size ) && is_not_last_block ) {
20083b4: 80 a2 20 00 cmp %o0, 0
20083b8: 02 80 00 0c be 20083e8 <_Heap_Walk+0x310>
20083bc: c2 07 bf fc ld [ %fp + -4 ], %g1
20083c0: 80 8d 20 ff btst 0xff, %l4
20083c4: 02 80 00 0a be 20083ec <_Heap_Walk+0x314>
20083c8: 80 a4 80 10 cmp %l2, %l0
(*printer)(
20083cc: 15 00 80 53 sethi %hi(0x2014c00), %o2
20083d0: 90 10 00 19 mov %i1, %o0
20083d4: 92 10 20 01 mov 1, %o1
20083d8: 94 12 a0 18 or %o2, 0x18, %o2
20083dc: 96 10 00 1a mov %i2, %o3
20083e0: 10 bf ff d0 b 2008320 <_Heap_Walk+0x248>
20083e4: 98 10 00 12 mov %l2, %o4
);
return false;
}
if ( block_size < min_block_size && is_not_last_block ) {
20083e8: 80 a4 80 10 cmp %l2, %l0
20083ec: 1a 80 00 0d bcc 2008420 <_Heap_Walk+0x348>
20083f0: 80 a4 c0 1a cmp %l3, %i2
20083f4: 80 8d 20 ff btst 0xff, %l4
20083f8: 02 80 00 0a be 2008420 <_Heap_Walk+0x348> <== NEVER TAKEN
20083fc: 80 a4 c0 1a cmp %l3, %i2
(*printer)(
2008400: 15 00 80 53 sethi %hi(0x2014c00), %o2
2008404: 90 10 00 19 mov %i1, %o0
2008408: 92 10 20 01 mov 1, %o1
200840c: 94 12 a0 48 or %o2, 0x48, %o2
2008410: 96 10 00 1a mov %i2, %o3
2008414: 98 10 00 12 mov %l2, %o4
2008418: 10 80 00 3d b 200850c <_Heap_Walk+0x434>
200841c: 9a 10 00 10 mov %l0, %o5
);
return false;
}
if ( next_block_begin <= block_begin && is_not_last_block ) {
2008420: 38 80 00 0c bgu,a 2008450 <_Heap_Walk+0x378>
2008424: a8 08 60 01 and %g1, 1, %l4
2008428: 80 8d 20 ff btst 0xff, %l4
200842c: 02 80 00 09 be 2008450 <_Heap_Walk+0x378>
2008430: a8 08 60 01 and %g1, 1, %l4
(*printer)(
2008434: 15 00 80 53 sethi %hi(0x2014c00), %o2
2008438: 90 10 00 19 mov %i1, %o0
200843c: 92 10 20 01 mov 1, %o1
2008440: 94 12 a0 78 or %o2, 0x78, %o2
2008444: 96 10 00 1a mov %i2, %o3
2008448: 10 bf ff b6 b 2008320 <_Heap_Walk+0x248>
200844c: 98 10 00 13 mov %l3, %o4
block->size_and_flag = size | flag;
}
RTEMS_INLINE_ROUTINE bool _Heap_Is_prev_used( const Heap_Block *block )
{
return block->size_and_flag & HEAP_PREV_BLOCK_USED;
2008450: c2 04 e0 04 ld [ %l3 + 4 ], %g1
);
return false;
}
if ( !_Heap_Is_prev_used( next_block ) ) {
2008454: 80 88 60 01 btst 1, %g1
2008458: 12 80 00 40 bne 2008558 <_Heap_Walk+0x480>
200845c: 90 10 00 19 mov %i1, %o0
false,
"block 0x%08x: size %u, prev 0x%08x%s, next 0x%08x%s\n",
block,
block_size,
block->prev,
block->prev == first_free_block ?
2008460: da 06 a0 0c ld [ %i2 + 0xc ], %o5
Heap_Block *const last_free_block = _Heap_Free_list_last( heap );
bool const prev_used = _Heap_Is_prev_used( block );
uintptr_t const block_size = _Heap_Block_size( block );
Heap_Block *const next_block = _Heap_Block_at( block, block_size );
(*printer)(
2008464: c2 06 20 08 ld [ %i0 + 8 ], %g1
2008468: 05 00 80 52 sethi %hi(0x2014800), %g2
return _Heap_Free_list_head(heap)->next;
}
RTEMS_INLINE_ROUTINE Heap_Block *_Heap_Free_list_last( Heap_Control *heap )
{
return _Heap_Free_list_tail(heap)->prev;
200846c: c8 06 20 0c ld [ %i0 + 0xc ], %g4
2008470: 80 a3 40 01 cmp %o5, %g1
2008474: 02 80 00 07 be 2008490 <_Heap_Walk+0x3b8>
2008478: 86 10 a1 58 or %g2, 0x158, %g3
block,
block_size,
block->prev,
block->prev == first_free_block ?
" (= first free)"
: (block->prev == free_list_head ? " (= head)" : ""),
200847c: 80 a3 40 18 cmp %o5, %i0
2008480: 12 80 00 04 bne 2008490 <_Heap_Walk+0x3b8>
2008484: 86 15 61 20 or %l5, 0x120, %g3
2008488: 07 00 80 52 sethi %hi(0x2014800), %g3
200848c: 86 10 e1 68 or %g3, 0x168, %g3 ! 2014968 <_Status_Object_name_errors_to_status+0x48>
block->next,
block->next == last_free_block ?
2008490: c4 06 a0 08 ld [ %i2 + 8 ], %g2
Heap_Block *const last_free_block = _Heap_Free_list_last( heap );
bool const prev_used = _Heap_Is_prev_used( block );
uintptr_t const block_size = _Heap_Block_size( block );
Heap_Block *const next_block = _Heap_Block_at( block, block_size );
(*printer)(
2008494: 1f 00 80 52 sethi %hi(0x2014800), %o7
2008498: 80 a0 80 04 cmp %g2, %g4
200849c: 02 80 00 07 be 20084b8 <_Heap_Walk+0x3e0>
20084a0: 82 13 e1 78 or %o7, 0x178, %g1
" (= first free)"
: (block->prev == free_list_head ? " (= head)" : ""),
block->next,
block->next == last_free_block ?
" (= last free)"
: (block->next == free_list_tail ? " (= tail)" : "")
20084a4: 80 a0 80 18 cmp %g2, %i0
20084a8: 12 80 00 04 bne 20084b8 <_Heap_Walk+0x3e0>
20084ac: 82 15 61 20 or %l5, 0x120, %g1
20084b0: 03 00 80 52 sethi %hi(0x2014800), %g1
20084b4: 82 10 61 88 or %g1, 0x188, %g1 ! 2014988 <_Status_Object_name_errors_to_status+0x68>
Heap_Block *const last_free_block = _Heap_Free_list_last( heap );
bool const prev_used = _Heap_Is_prev_used( block );
uintptr_t const block_size = _Heap_Block_size( block );
Heap_Block *const next_block = _Heap_Block_at( block, block_size );
(*printer)(
20084b8: c6 23 a0 5c st %g3, [ %sp + 0x5c ]
20084bc: c4 23 a0 60 st %g2, [ %sp + 0x60 ]
20084c0: c2 23 a0 64 st %g1, [ %sp + 0x64 ]
20084c4: 90 10 00 19 mov %i1, %o0
20084c8: 92 10 20 00 clr %o1
20084cc: 15 00 80 53 sethi %hi(0x2014c00), %o2
20084d0: 96 10 00 1a mov %i2, %o3
20084d4: 94 12 a0 b0 or %o2, 0xb0, %o2
20084d8: 9f c7 40 00 call %i5
20084dc: 98 10 00 12 mov %l2, %o4
block->next == last_free_block ?
" (= last free)"
: (block->next == free_list_tail ? " (= tail)" : "")
);
if ( block_size != next_block->prev_size ) {
20084e0: da 04 c0 00 ld [ %l3 ], %o5
20084e4: 80 a4 80 0d cmp %l2, %o5
20084e8: 02 80 00 0d be 200851c <_Heap_Walk+0x444>
20084ec: 80 a5 20 00 cmp %l4, 0
(*printer)(
20084f0: 15 00 80 53 sethi %hi(0x2014c00), %o2
20084f4: e6 23 a0 5c st %l3, [ %sp + 0x5c ]
20084f8: 90 10 00 19 mov %i1, %o0
20084fc: 92 10 20 01 mov 1, %o1
2008500: 94 12 a0 e8 or %o2, 0xe8, %o2
2008504: 96 10 00 1a mov %i2, %o3
2008508: 98 10 00 12 mov %l2, %o4
200850c: 9f c7 40 00 call %i5
2008510: 01 00 00 00 nop
2008514: 10 80 00 23 b 20085a0 <_Heap_Walk+0x4c8>
2008518: 82 10 20 00 clr %g1 ! 0 <PROM_START>
);
return false;
}
if ( !prev_used ) {
200851c: 32 80 00 0a bne,a 2008544 <_Heap_Walk+0x46c>
2008520: c2 06 20 08 ld [ %i0 + 8 ], %g1
(*printer)(
2008524: 15 00 80 53 sethi %hi(0x2014c00), %o2
2008528: 90 10 00 19 mov %i1, %o0
200852c: 92 10 20 01 mov 1, %o1
2008530: 10 80 00 22 b 20085b8 <_Heap_Walk+0x4e0>
2008534: 94 12 a1 28 or %o2, 0x128, %o2
{
const Heap_Block *const free_list_tail = _Heap_Free_list_tail( heap );
const Heap_Block *free_block = _Heap_Free_list_first( heap );
while ( free_block != free_list_tail ) {
if ( free_block == block ) {
2008538: 02 80 00 17 be 2008594 <_Heap_Walk+0x4bc>
200853c: 80 a4 c0 1b cmp %l3, %i3
return true;
}
free_block = free_block->next;
2008540: c2 00 60 08 ld [ %g1 + 8 ], %g1
)
{
const Heap_Block *const free_list_tail = _Heap_Free_list_tail( heap );
const Heap_Block *free_block = _Heap_Free_list_first( heap );
while ( free_block != free_list_tail ) {
2008544: 80 a0 40 18 cmp %g1, %i0
2008548: 12 bf ff fc bne 2008538 <_Heap_Walk+0x460>
200854c: 80 a0 40 1a cmp %g1, %i2
return false;
}
if ( !_Heap_Walk_is_in_free_list( heap, block ) ) {
(*printer)(
2008550: 10 80 00 17 b 20085ac <_Heap_Walk+0x4d4>
2008554: 15 00 80 53 sethi %hi(0x2014c00), %o2
if ( !_Heap_Is_prev_used( next_block ) ) {
if ( !_Heap_Walk_check_free_block( source, printer, heap, block ) ) {
return false;
}
} else if (prev_used) {
2008558: 80 a5 20 00 cmp %l4, 0
200855c: 02 80 00 08 be 200857c <_Heap_Walk+0x4a4>
2008560: 92 10 20 00 clr %o1
(*printer)(
2008564: 94 10 00 17 mov %l7, %o2
2008568: 96 10 00 1a mov %i2, %o3
200856c: 9f c7 40 00 call %i5
2008570: 98 10 00 12 mov %l2, %o4
block->prev_size
);
}
block = next_block;
} while ( block != first_block );
2008574: 10 80 00 08 b 2008594 <_Heap_Walk+0x4bc>
2008578: 80 a4 c0 1b cmp %l3, %i3
"block 0x%08x: size %u\n",
block,
block_size
);
} else {
(*printer)(
200857c: da 06 80 00 ld [ %i2 ], %o5
2008580: 94 10 00 16 mov %l6, %o2
2008584: 96 10 00 1a mov %i2, %o3
2008588: 9f c7 40 00 call %i5
200858c: 98 10 00 12 mov %l2, %o4
block->prev_size
);
}
block = next_block;
} while ( block != first_block );
2008590: 80 a4 c0 1b cmp %l3, %i3
2008594: 12 bf ff 70 bne 2008354 <_Heap_Walk+0x27c>
2008598: b4 10 00 13 mov %l3, %i2
return true;
200859c: 82 10 20 01 mov 1, %g1
}
20085a0: b0 08 60 01 and %g1, 1, %i0
20085a4: 81 c7 e0 08 ret
20085a8: 81 e8 00 00 restore
return false;
}
if ( !_Heap_Walk_is_in_free_list( heap, block ) ) {
(*printer)(
20085ac: 90 10 00 19 mov %i1, %o0
20085b0: 92 10 20 01 mov 1, %o1
20085b4: 94 12 a1 98 or %o2, 0x198, %o2
20085b8: 96 10 00 1a mov %i2, %o3
20085bc: 9f c7 40 00 call %i5
20085c0: 01 00 00 00 nop
20085c4: 10 bf ff f7 b 20085a0 <_Heap_Walk+0x4c8>
20085c8: 82 10 20 00 clr %g1 ! 0 <PROM_START>
020078b4 <_Objects_Allocate>:
*/
Objects_Control *_Objects_Allocate(
Objects_Information *information
)
{
20078b4: 9d e3 bf a0 save %sp, -96, %sp
* If the application is using the optional manager stubs and
* still attempts to create the object, the information block
* should be all zeroed out because it is in the BSS. So let's
* check that code for this manager is even present.
*/
if ( information->size == 0 )
20078b8: c2 06 20 18 ld [ %i0 + 0x18 ], %g1
*/
Objects_Control *_Objects_Allocate(
Objects_Information *information
)
{
20078bc: ba 10 00 18 mov %i0, %i5
* If the application is using the optional manager stubs and
* still attempts to create the object, the information block
* should be all zeroed out because it is in the BSS. So let's
* check that code for this manager is even present.
*/
if ( information->size == 0 )
20078c0: 80 a0 60 00 cmp %g1, 0
20078c4: 02 80 00 20 be 2007944 <_Objects_Allocate+0x90> <== NEVER TAKEN
20078c8: b0 10 20 00 clr %i0
/*
* OK. The manager should be initialized and configured to have objects.
* With any luck, it is safe to attempt to allocate an object.
*/
the_object = (Objects_Control *) _Chain_Get( &information->Inactive );
20078cc: b8 07 60 20 add %i5, 0x20, %i4
20078d0: 7f ff fd 87 call 2006eec <_Chain_Get>
20078d4: 90 10 00 1c mov %i4, %o0
if ( information->auto_extend ) {
20078d8: c2 0f 60 12 ldub [ %i5 + 0x12 ], %g1
20078dc: 80 a0 60 00 cmp %g1, 0
20078e0: 02 80 00 19 be 2007944 <_Objects_Allocate+0x90>
20078e4: b0 10 00 08 mov %o0, %i0
/*
* If the list is empty then we are out of objects and need to
* extend information base.
*/
if ( !the_object ) {
20078e8: 80 a2 20 00 cmp %o0, 0
20078ec: 32 80 00 0a bne,a 2007914 <_Objects_Allocate+0x60>
20078f0: c2 17 60 0a lduh [ %i5 + 0xa ], %g1
_Objects_Extend_information( information );
20078f4: 40 00 00 1d call 2007968 <_Objects_Extend_information>
20078f8: 90 10 00 1d mov %i5, %o0
the_object = (Objects_Control *) _Chain_Get( &information->Inactive );
20078fc: 7f ff fd 7c call 2006eec <_Chain_Get>
2007900: 90 10 00 1c mov %i4, %o0
}
if ( the_object ) {
2007904: b0 92 20 00 orcc %o0, 0, %i0
2007908: 02 80 00 0f be 2007944 <_Objects_Allocate+0x90>
200790c: 01 00 00 00 nop
uint32_t block;
block = (uint32_t) _Objects_Get_index( the_object->id ) -
2007910: c2 17 60 0a lduh [ %i5 + 0xa ], %g1
2007914: d0 16 20 0a lduh [ %i0 + 0xa ], %o0
_Objects_Get_index( information->minimum_id );
block /= information->allocation_size;
2007918: d2 17 60 14 lduh [ %i5 + 0x14 ], %o1
200791c: 40 00 3c 56 call 2016a74 <.udiv>
2007920: 90 22 00 01 sub %o0, %g1, %o0
information->inactive_per_block[ block ]--;
2007924: c2 07 60 30 ld [ %i5 + 0x30 ], %g1
2007928: 91 2a 20 02 sll %o0, 2, %o0
200792c: c4 00 40 08 ld [ %g1 + %o0 ], %g2
2007930: 84 00 bf ff add %g2, -1, %g2
2007934: c4 20 40 08 st %g2, [ %g1 + %o0 ]
information->inactive--;
2007938: c2 17 60 2c lduh [ %i5 + 0x2c ], %g1
200793c: 82 00 7f ff add %g1, -1, %g1
2007940: c2 37 60 2c sth %g1, [ %i5 + 0x2c ]
);
}
#endif
return the_object;
}
2007944: 81 c7 e0 08 ret
2007948: 81 e8 00 00 restore
02007cc0 <_Objects_Get_information>:
Objects_Information *_Objects_Get_information(
Objects_APIs the_api,
uint16_t the_class
)
{
2007cc0: 9d e3 bf a0 save %sp, -96, %sp
Objects_Information *info;
int the_class_api_maximum;
if ( !the_class )
2007cc4: 80 a6 60 00 cmp %i1, 0
2007cc8: 02 80 00 17 be 2007d24 <_Objects_Get_information+0x64>
2007ccc: ba 10 20 00 clr %i5
/*
* This call implicitly validates the_api so we do not call
* _Objects_Is_api_valid above here.
*/
the_class_api_maximum = _Objects_API_maximum_class( the_api );
2007cd0: 40 00 11 66 call 200c268 <_Objects_API_maximum_class>
2007cd4: 90 10 00 18 mov %i0, %o0
if ( the_class_api_maximum == 0 )
2007cd8: 80 a2 20 00 cmp %o0, 0
2007cdc: 02 80 00 12 be 2007d24 <_Objects_Get_information+0x64>
2007ce0: 80 a6 40 08 cmp %i1, %o0
return NULL;
if ( the_class > (uint32_t) the_class_api_maximum )
2007ce4: 18 80 00 10 bgu 2007d24 <_Objects_Get_information+0x64>
2007ce8: 03 00 80 6d sethi %hi(0x201b400), %g1
return NULL;
if ( !_Objects_Information_table[ the_api ] )
2007cec: b1 2e 20 02 sll %i0, 2, %i0
2007cf0: 82 10 60 18 or %g1, 0x18, %g1
2007cf4: c2 00 40 18 ld [ %g1 + %i0 ], %g1
2007cf8: 80 a0 60 00 cmp %g1, 0
2007cfc: 02 80 00 0a be 2007d24 <_Objects_Get_information+0x64> <== NEVER TAKEN
2007d00: b3 2e 60 02 sll %i1, 2, %i1
return NULL;
info = _Objects_Information_table[ the_api ][ the_class ];
2007d04: fa 00 40 19 ld [ %g1 + %i1 ], %i5
if ( !info )
2007d08: 80 a7 60 00 cmp %i5, 0
2007d0c: 02 80 00 06 be 2007d24 <_Objects_Get_information+0x64> <== NEVER TAKEN
2007d10: 01 00 00 00 nop
* In a multprocessing configuration, we may access remote objects.
* Thus we may have 0 local instances and still have a valid object
* pointer.
*/
#if !defined(RTEMS_MULTIPROCESSING)
if ( info->maximum == 0 )
2007d14: c2 17 60 10 lduh [ %i5 + 0x10 ], %g1
return NULL;
2007d18: 80 a0 00 01 cmp %g0, %g1
2007d1c: 82 60 20 00 subx %g0, 0, %g1
2007d20: ba 0f 40 01 and %i5, %g1, %i5
#endif
return info;
}
2007d24: 81 c7 e0 08 ret
2007d28: 91 e8 00 1d restore %g0, %i5, %o0
020087f4 <_Objects_Id_to_name>:
*/
Objects_Name_or_id_lookup_errors _Objects_Id_to_name (
Objects_Id id,
Objects_Name *name
)
{
20087f4: 9d e3 bf 98 save %sp, -104, %sp
/*
* Caller is trusted for name != NULL.
*/
tmpId = (id == OBJECTS_ID_OF_SELF) ? _Thread_Executing->Object.id : id;
20087f8: 92 96 20 00 orcc %i0, 0, %o1
20087fc: 12 80 00 06 bne 2008814 <_Objects_Id_to_name+0x20>
2008800: 83 32 60 18 srl %o1, 0x18, %g1
2008804: 03 00 80 72 sethi %hi(0x201c800), %g1
2008808: c2 00 62 b8 ld [ %g1 + 0x2b8 ], %g1 ! 201cab8 <_Per_CPU_Information+0xc>
200880c: d2 00 60 08 ld [ %g1 + 8 ], %o1
2008810: 83 32 60 18 srl %o1, 0x18, %g1
2008814: 82 08 60 07 and %g1, 7, %g1
*/
RTEMS_INLINE_ROUTINE bool _Objects_Is_api_valid(
uint32_t the_api
)
{
if ( !the_api || the_api > OBJECTS_APIS_LAST )
2008818: 84 00 7f ff add %g1, -1, %g2
200881c: 80 a0 a0 02 cmp %g2, 2
2008820: 18 80 00 12 bgu 2008868 <_Objects_Id_to_name+0x74>
2008824: ba 10 20 03 mov 3, %i5
the_api = _Objects_Get_API( tmpId );
if ( !_Objects_Is_api_valid( the_api ) )
return OBJECTS_INVALID_ID;
if ( !_Objects_Information_table[ the_api ] )
2008828: 10 80 00 12 b 2008870 <_Objects_Id_to_name+0x7c>
200882c: 83 28 60 02 sll %g1, 2, %g1
return OBJECTS_INVALID_ID;
the_class = _Objects_Get_class( tmpId );
information = _Objects_Information_table[ the_api ][ the_class ];
2008830: 85 28 a0 02 sll %g2, 2, %g2
2008834: d0 00 40 02 ld [ %g1 + %g2 ], %o0
if ( !information )
2008838: 80 a2 20 00 cmp %o0, 0
200883c: 02 80 00 0b be 2008868 <_Objects_Id_to_name+0x74> <== NEVER TAKEN
2008840: 01 00 00 00 nop
#if defined(RTEMS_SCORE_OBJECT_ENABLE_STRING_NAMES)
if ( information->is_string )
return OBJECTS_INVALID_ID;
#endif
the_object = _Objects_Get( information, tmpId, &ignored_location );
2008844: 7f ff ff ce call 200877c <_Objects_Get>
2008848: 94 07 bf fc add %fp, -4, %o2
if ( !the_object )
200884c: 80 a2 20 00 cmp %o0, 0
2008850: 02 80 00 06 be 2008868 <_Objects_Id_to_name+0x74>
2008854: 01 00 00 00 nop
return OBJECTS_INVALID_ID;
*name = the_object->name;
2008858: c2 02 20 0c ld [ %o0 + 0xc ], %g1
_Thread_Enable_dispatch();
return OBJECTS_NAME_OR_ID_LOOKUP_SUCCESSFUL;
200885c: ba 10 20 00 clr %i5
the_object = _Objects_Get( information, tmpId, &ignored_location );
if ( !the_object )
return OBJECTS_INVALID_ID;
*name = the_object->name;
_Thread_Enable_dispatch();
2008860: 40 00 03 62 call 20095e8 <_Thread_Enable_dispatch>
2008864: c2 26 40 00 st %g1, [ %i1 ]
return OBJECTS_NAME_OR_ID_LOOKUP_SUCCESSFUL;
}
2008868: 81 c7 e0 08 ret
200886c: 91 e8 00 1d restore %g0, %i5, %o0
the_api = _Objects_Get_API( tmpId );
if ( !_Objects_Is_api_valid( the_api ) )
return OBJECTS_INVALID_ID;
if ( !_Objects_Information_table[ the_api ] )
2008870: 05 00 80 71 sethi %hi(0x201c400), %g2
2008874: 84 10 a3 e8 or %g2, 0x3e8, %g2 ! 201c7e8 <_Objects_Information_table>
2008878: c2 00 80 01 ld [ %g2 + %g1 ], %g1
200887c: 80 a0 60 00 cmp %g1, 0
2008880: 12 bf ff ec bne 2008830 <_Objects_Id_to_name+0x3c>
2008884: 85 32 60 1b srl %o1, 0x1b, %g2
2008888: 30 bf ff f8 b,a 2008868 <_Objects_Id_to_name+0x74>
02008da4 <_RBTree_Extract_unprotected>:
*/
void _RBTree_Extract_unprotected(
RBTree_Control *the_rbtree,
RBTree_Node *the_node
)
{
2008da4: 9d e3 bf a0 save %sp, -96, %sp
RBTree_Node *leaf, *target;
RBTree_Color victim_color;
RBTree_Direction dir;
if (!the_node) return;
2008da8: 80 a6 60 00 cmp %i1, 0
2008dac: 02 80 00 73 be 2008f78 <_RBTree_Extract_unprotected+0x1d4>
2008db0: 01 00 00 00 nop
/* check if min needs to be updated */
if (the_node == the_rbtree->first[RBT_LEFT]) {
2008db4: c2 06 20 08 ld [ %i0 + 8 ], %g1
2008db8: 80 a6 40 01 cmp %i1, %g1
2008dbc: 32 80 00 0d bne,a 2008df0 <_RBTree_Extract_unprotected+0x4c>
2008dc0: c2 06 20 0c ld [ %i0 + 0xc ], %g1
if (the_node->child[RBT_RIGHT])
2008dc4: c2 06 60 08 ld [ %i1 + 8 ], %g1
2008dc8: 80 a0 60 00 cmp %g1, 0
2008dcc: 22 80 00 04 be,a 2008ddc <_RBTree_Extract_unprotected+0x38>
2008dd0: c2 06 40 00 ld [ %i1 ], %g1
the_rbtree->first[RBT_LEFT] = the_node->child[RBT_RIGHT];
2008dd4: 10 80 00 06 b 2008dec <_RBTree_Extract_unprotected+0x48>
2008dd8: c2 26 20 08 st %g1, [ %i0 + 8 ]
else {
the_rbtree->first[RBT_LEFT] = the_node->parent;
if(_RBTree_Are_nodes_equal((RBTree_Node *)the_rbtree,
2008ddc: 80 a6 00 01 cmp %i0, %g1
2008de0: 12 80 00 03 bne 2008dec <_RBTree_Extract_unprotected+0x48>
2008de4: c2 26 20 08 st %g1, [ %i0 + 8 ]
the_rbtree->first[RBT_LEFT]))
the_rbtree->first[RBT_LEFT] = NULL;
2008de8: c0 26 20 08 clr [ %i0 + 8 ]
}
}
/* check if max needs to be updated: note, min can equal max (1 element) */
if (the_node == the_rbtree->first[RBT_RIGHT]) {
2008dec: c2 06 20 0c ld [ %i0 + 0xc ], %g1
2008df0: 80 a6 40 01 cmp %i1, %g1
2008df4: 12 80 00 0b bne 2008e20 <_RBTree_Extract_unprotected+0x7c>
2008df8: c2 06 60 04 ld [ %i1 + 4 ], %g1
if (the_node->child[RBT_LEFT])
2008dfc: 80 a0 60 00 cmp %g1, 0
2008e00: 22 80 00 04 be,a 2008e10 <_RBTree_Extract_unprotected+0x6c>
2008e04: c4 06 40 00 ld [ %i1 ], %g2
the_rbtree->first[RBT_RIGHT] = the_node->child[RBT_LEFT];
2008e08: 10 80 00 06 b 2008e20 <_RBTree_Extract_unprotected+0x7c>
2008e0c: c2 26 20 0c st %g1, [ %i0 + 0xc ]
else {
the_rbtree->first[RBT_RIGHT] = the_node->parent;
if(_RBTree_Are_nodes_equal((RBTree_Node *)the_rbtree,
2008e10: 80 a6 00 02 cmp %i0, %g2
2008e14: 12 80 00 03 bne 2008e20 <_RBTree_Extract_unprotected+0x7c>
2008e18: c4 26 20 0c st %g2, [ %i0 + 0xc ]
the_rbtree->first[RBT_RIGHT]))
the_rbtree->first[RBT_RIGHT] = NULL;
2008e1c: c0 26 20 0c clr [ %i0 + 0xc ]
* either max in node->child[RBT_LEFT] or min in node->child[RBT_RIGHT],
* and replace the_node with the target node. This maintains the binary
* search tree property, but may violate the red-black properties.
*/
if (the_node->child[RBT_LEFT] && the_node->child[RBT_RIGHT]) {
2008e20: ba 90 60 00 orcc %g1, 0, %i5
2008e24: 02 80 00 36 be 2008efc <_RBTree_Extract_unprotected+0x158>
2008e28: f8 06 60 08 ld [ %i1 + 8 ], %i4
2008e2c: 80 a7 20 00 cmp %i4, 0
2008e30: 32 80 00 05 bne,a 2008e44 <_RBTree_Extract_unprotected+0xa0>
2008e34: c2 07 60 08 ld [ %i5 + 8 ], %g1
2008e38: 10 80 00 35 b 2008f0c <_RBTree_Extract_unprotected+0x168>
2008e3c: b8 10 00 01 mov %g1, %i4
target = the_node->child[RBT_LEFT]; /* find max in node->child[RBT_LEFT] */
while (target->child[RBT_RIGHT]) target = target->child[RBT_RIGHT];
2008e40: c2 07 60 08 ld [ %i5 + 8 ], %g1
2008e44: 80 a0 60 00 cmp %g1, 0
2008e48: 32 bf ff fe bne,a 2008e40 <_RBTree_Extract_unprotected+0x9c>
2008e4c: ba 10 00 01 mov %g1, %i5
* target's position (target is the right child of target->parent)
* when target vacates it. if there is no child, then target->parent
* should become NULL. This may cause the coloring to be violated.
* For now we store the color of the node being deleted in victim_color.
*/
leaf = target->child[RBT_LEFT];
2008e50: f8 07 60 04 ld [ %i5 + 4 ], %i4
if(leaf) {
2008e54: 80 a7 20 00 cmp %i4, 0
2008e58: 02 80 00 05 be 2008e6c <_RBTree_Extract_unprotected+0xc8>
2008e5c: 01 00 00 00 nop
leaf->parent = target->parent;
2008e60: c2 07 40 00 ld [ %i5 ], %g1
2008e64: 10 80 00 04 b 2008e74 <_RBTree_Extract_unprotected+0xd0>
2008e68: c2 27 00 00 st %g1, [ %i4 ]
} else {
/* fix the tree here if the child is a null leaf. */
_RBTree_Extract_validate_unprotected(target);
2008e6c: 7f ff ff 53 call 2008bb8 <_RBTree_Extract_validate_unprotected>
2008e70: 90 10 00 1d mov %i5, %o0
}
victim_color = target->color;
dir = target != target->parent->child[0];
2008e74: c4 07 40 00 ld [ %i5 ], %g2
leaf->parent = target->parent;
} else {
/* fix the tree here if the child is a null leaf. */
_RBTree_Extract_validate_unprotected(target);
}
victim_color = target->color;
2008e78: c2 07 60 0c ld [ %i5 + 0xc ], %g1
dir = target != target->parent->child[0];
2008e7c: c6 00 a0 04 ld [ %g2 + 4 ], %g3
2008e80: 86 1f 40 03 xor %i5, %g3, %g3
2008e84: 80 a0 00 03 cmp %g0, %g3
2008e88: 86 40 20 00 addx %g0, 0, %g3
target->parent->child[dir] = leaf;
2008e8c: 87 28 e0 02 sll %g3, 2, %g3
2008e90: 84 00 80 03 add %g2, %g3, %g2
2008e94: f8 20 a0 04 st %i4, [ %g2 + 4 ]
/* now replace the_node with target */
dir = the_node != the_node->parent->child[0];
2008e98: c4 06 40 00 ld [ %i1 ], %g2
2008e9c: c6 00 a0 04 ld [ %g2 + 4 ], %g3
2008ea0: 86 1e 40 03 xor %i1, %g3, %g3
2008ea4: 80 a0 00 03 cmp %g0, %g3
2008ea8: 86 40 20 00 addx %g0, 0, %g3
the_node->parent->child[dir] = target;
2008eac: 87 28 e0 02 sll %g3, 2, %g3
2008eb0: 84 00 80 03 add %g2, %g3, %g2
2008eb4: fa 20 a0 04 st %i5, [ %g2 + 4 ]
/* set target's new children to the original node's children */
target->child[RBT_RIGHT] = the_node->child[RBT_RIGHT];
2008eb8: c4 06 60 08 ld [ %i1 + 8 ], %g2
2008ebc: c4 27 60 08 st %g2, [ %i5 + 8 ]
if (the_node->child[RBT_RIGHT])
2008ec0: c4 06 60 08 ld [ %i1 + 8 ], %g2
2008ec4: 80 a0 a0 00 cmp %g2, 0
2008ec8: 32 80 00 02 bne,a 2008ed0 <_RBTree_Extract_unprotected+0x12c><== ALWAYS TAKEN
2008ecc: fa 20 80 00 st %i5, [ %g2 ]
the_node->child[RBT_RIGHT]->parent = target;
target->child[RBT_LEFT] = the_node->child[RBT_LEFT];
2008ed0: c4 06 60 04 ld [ %i1 + 4 ], %g2
2008ed4: c4 27 60 04 st %g2, [ %i5 + 4 ]
if (the_node->child[RBT_LEFT])
2008ed8: c4 06 60 04 ld [ %i1 + 4 ], %g2
2008edc: 80 a0 a0 00 cmp %g2, 0
2008ee0: 32 80 00 02 bne,a 2008ee8 <_RBTree_Extract_unprotected+0x144>
2008ee4: fa 20 80 00 st %i5, [ %g2 ]
/* finally, update the parent node and recolor. target has completely
* replaced the_node, and target's child has moved up the tree if needed.
* the_node is no longer part of the tree, although it has valid pointers
* still.
*/
target->parent = the_node->parent;
2008ee8: c4 06 40 00 ld [ %i1 ], %g2
2008eec: c4 27 40 00 st %g2, [ %i5 ]
target->color = the_node->color;
2008ef0: c4 06 60 0c ld [ %i1 + 0xc ], %g2
2008ef4: 10 80 00 14 b 2008f44 <_RBTree_Extract_unprotected+0x1a0>
2008ef8: c4 27 60 0c st %g2, [ %i5 + 0xc ]
* violated. We will fix it later.
* For now we store the color of the node being deleted in victim_color.
*/
leaf = the_node->child[RBT_LEFT] ?
the_node->child[RBT_LEFT] : the_node->child[RBT_RIGHT];
if( leaf ) {
2008efc: 80 a7 20 00 cmp %i4, 0
2008f00: 32 80 00 04 bne,a 2008f10 <_RBTree_Extract_unprotected+0x16c>
2008f04: c2 06 40 00 ld [ %i1 ], %g1
2008f08: 30 80 00 04 b,a 2008f18 <_RBTree_Extract_unprotected+0x174>
leaf->parent = the_node->parent;
2008f0c: c2 06 40 00 ld [ %i1 ], %g1
2008f10: 10 80 00 04 b 2008f20 <_RBTree_Extract_unprotected+0x17c>
2008f14: c2 27 00 00 st %g1, [ %i4 ]
} else {
/* fix the tree here if the child is a null leaf. */
_RBTree_Extract_validate_unprotected(the_node);
2008f18: 7f ff ff 28 call 2008bb8 <_RBTree_Extract_validate_unprotected>
2008f1c: 90 10 00 19 mov %i1, %o0
}
victim_color = the_node->color;
/* remove the_node from the tree */
dir = the_node != the_node->parent->child[0];
2008f20: c4 06 40 00 ld [ %i1 ], %g2
leaf->parent = the_node->parent;
} else {
/* fix the tree here if the child is a null leaf. */
_RBTree_Extract_validate_unprotected(the_node);
}
victim_color = the_node->color;
2008f24: c2 06 60 0c ld [ %i1 + 0xc ], %g1
/* remove the_node from the tree */
dir = the_node != the_node->parent->child[0];
2008f28: c6 00 a0 04 ld [ %g2 + 4 ], %g3
2008f2c: 86 1e 40 03 xor %i1, %g3, %g3
2008f30: 80 a0 00 03 cmp %g0, %g3
2008f34: 86 40 20 00 addx %g0, 0, %g3
the_node->parent->child[dir] = leaf;
2008f38: 87 28 e0 02 sll %g3, 2, %g3
2008f3c: 84 00 80 03 add %g2, %g3, %g2
2008f40: f8 20 a0 04 st %i4, [ %g2 + 4 ]
/* fix coloring. leaf has moved up the tree. The color of the deleted
* node is in victim_color. There are two cases:
* 1. Deleted a red node, its child must be black. Nothing must be done.
* 2. Deleted a black node, its child must be red. Paint child black.
*/
if (victim_color == RBT_BLACK) { /* eliminate case 1 */
2008f44: 80 a0 60 00 cmp %g1, 0
2008f48: 32 80 00 06 bne,a 2008f60 <_RBTree_Extract_unprotected+0x1bc>
2008f4c: c2 06 20 04 ld [ %i0 + 4 ], %g1
if (leaf) {
2008f50: 80 a7 20 00 cmp %i4, 0
2008f54: 32 80 00 02 bne,a 2008f5c <_RBTree_Extract_unprotected+0x1b8>
2008f58: c0 27 20 0c clr [ %i4 + 0xc ]
/* Wipe the_node */
_RBTree_Set_off_rbtree(the_node);
/* set root to black, if it exists */
if (the_rbtree->root) the_rbtree->root->color = RBT_BLACK;
2008f5c: c2 06 20 04 ld [ %i0 + 4 ], %g1
*/
RTEMS_INLINE_ROUTINE void _RBTree_Set_off_rbtree(
RBTree_Node *node
)
{
node->parent = node->child[RBT_LEFT] = node->child[RBT_RIGHT] = NULL;
2008f60: c0 26 60 08 clr [ %i1 + 8 ]
2008f64: c0 26 60 04 clr [ %i1 + 4 ]
2008f68: 80 a0 60 00 cmp %g1, 0
2008f6c: 02 80 00 03 be 2008f78 <_RBTree_Extract_unprotected+0x1d4>
2008f70: c0 26 40 00 clr [ %i1 ]
2008f74: c0 20 60 0c clr [ %g1 + 0xc ]
2008f78: 81 c7 e0 08 ret
2008f7c: 81 e8 00 00 restore
02008bb8 <_RBTree_Extract_validate_unprotected>:
* of the extract operation.
*/
void _RBTree_Extract_validate_unprotected(
RBTree_Node *the_node
)
{
2008bb8: 9d e3 bf a0 save %sp, -96, %sp
RBTree_Node *parent, *sibling;
RBTree_Direction dir;
parent = the_node->parent;
2008bbc: fa 06 00 00 ld [ %i0 ], %i5
if(!parent->parent) return;
2008bc0: c2 07 40 00 ld [ %i5 ], %g1
2008bc4: 80 a0 60 00 cmp %g1, 0
2008bc8: 02 80 00 6e be 2008d80 <_RBTree_Extract_validate_unprotected+0x1c8>
2008bcc: 90 10 00 18 mov %i0, %o0
sibling = _RBTree_Sibling(the_node);
2008bd0: 7f ff ff ca call 2008af8 <_RBTree_Sibling>
2008bd4: b4 10 20 01 mov 1, %i2
/* continue to correct tree as long as the_node is black and not the root */
while (!_RBTree_Is_red(the_node) && parent->parent) {
2008bd8: 10 80 00 5d b 2008d4c <_RBTree_Extract_validate_unprotected+0x194>
2008bdc: c2 06 20 0c ld [ %i0 + 0xc ], %g1
*/
RTEMS_INLINE_ROUTINE bool _RBTree_Is_red(
const RBTree_Node *the_node
)
{
return (the_node && the_node->color == RBT_RED);
2008be0: 22 80 00 15 be,a 2008c34 <_RBTree_Extract_validate_unprotected+0x7c><== NEVER TAKEN
2008be4: c4 02 20 08 ld [ %o0 + 8 ], %g2 <== NOT EXECUTED
2008be8: c2 02 20 0c ld [ %o0 + 0xc ], %g1
2008bec: 80 a0 60 01 cmp %g1, 1
2008bf0: 32 80 00 11 bne,a 2008c34 <_RBTree_Extract_validate_unprotected+0x7c>
2008bf4: c4 02 20 08 ld [ %o0 + 8 ], %g2
* then rotate parent left, making the sibling be the_node's grandparent.
* Now the_node has a black sibling and red parent. After rotation,
* update sibling pointer.
*/
if (_RBTree_Is_red(sibling)) {
parent->color = RBT_RED;
2008bf8: c2 27 60 0c st %g1, [ %i5 + 0xc ]
sibling->color = RBT_BLACK;
dir = the_node != parent->child[0];
2008bfc: c2 07 60 04 ld [ %i5 + 4 ], %g1
* Now the_node has a black sibling and red parent. After rotation,
* update sibling pointer.
*/
if (_RBTree_Is_red(sibling)) {
parent->color = RBT_RED;
sibling->color = RBT_BLACK;
2008c00: c0 22 20 0c clr [ %o0 + 0xc ]
dir = the_node != parent->child[0];
2008c04: 82 1e 00 01 xor %i0, %g1, %g1
2008c08: 80 a0 00 01 cmp %g0, %g1
_RBTree_Rotate(parent, dir);
2008c0c: 90 10 00 1d mov %i5, %o0
* update sibling pointer.
*/
if (_RBTree_Is_red(sibling)) {
parent->color = RBT_RED;
sibling->color = RBT_BLACK;
dir = the_node != parent->child[0];
2008c10: b8 40 20 00 addx %g0, 0, %i4
_RBTree_Rotate(parent, dir);
2008c14: 7f ff ff ca call 2008b3c <_RBTree_Rotate>
2008c18: 92 10 00 1c mov %i4, %o1
sibling = parent->child[!dir];
2008c1c: 80 a0 00 1c cmp %g0, %i4
2008c20: 82 60 3f ff subx %g0, -1, %g1
2008c24: 83 28 60 02 sll %g1, 2, %g1
2008c28: 82 07 40 01 add %i5, %g1, %g1
2008c2c: d0 00 60 04 ld [ %g1 + 4 ], %o0
}
/* sibling is black, see if both of its children are also black. */
if (!_RBTree_Is_red(sibling->child[RBT_RIGHT]) &&
2008c30: c4 02 20 08 ld [ %o0 + 8 ], %g2
2008c34: 80 a0 a0 00 cmp %g2, 0
2008c38: 02 80 00 06 be 2008c50 <_RBTree_Extract_validate_unprotected+0x98>
2008c3c: 82 10 20 00 clr %g1
* This function maintains the properties of the red-black tree.
*
* @note It does NOT disable interrupts to ensure the atomicity
* of the extract operation.
*/
void _RBTree_Extract_validate_unprotected(
2008c40: c2 00 a0 0c ld [ %g2 + 0xc ], %g1
2008c44: 82 18 60 01 xor %g1, 1, %g1
2008c48: 80 a0 00 01 cmp %g0, %g1
2008c4c: 82 60 3f ff subx %g0, -1, %g1
_RBTree_Rotate(parent, dir);
sibling = parent->child[!dir];
}
/* sibling is black, see if both of its children are also black. */
if (!_RBTree_Is_red(sibling->child[RBT_RIGHT]) &&
2008c50: 80 a0 60 00 cmp %g1, 0
2008c54: 32 80 00 14 bne,a 2008ca4 <_RBTree_Extract_validate_unprotected+0xec>
2008c58: c2 07 60 04 ld [ %i5 + 4 ], %g1
!_RBTree_Is_red(sibling->child[RBT_LEFT])) {
2008c5c: c4 02 20 04 ld [ %o0 + 4 ], %g2
2008c60: 80 a0 a0 00 cmp %g2, 0
2008c64: 02 80 00 07 be 2008c80 <_RBTree_Extract_validate_unprotected+0xc8>
2008c68: 80 a0 60 00 cmp %g1, 0
* This function maintains the properties of the red-black tree.
*
* @note It does NOT disable interrupts to ensure the atomicity
* of the extract operation.
*/
void _RBTree_Extract_validate_unprotected(
2008c6c: c2 00 a0 0c ld [ %g2 + 0xc ], %g1
2008c70: 82 18 60 01 xor %g1, 1, %g1
2008c74: 80 a0 00 01 cmp %g0, %g1
2008c78: 82 60 3f ff subx %g0, -1, %g1
_RBTree_Rotate(parent, dir);
sibling = parent->child[!dir];
}
/* sibling is black, see if both of its children are also black. */
if (!_RBTree_Is_red(sibling->child[RBT_RIGHT]) &&
2008c7c: 80 a0 60 00 cmp %g1, 0
2008c80: 32 80 00 09 bne,a 2008ca4 <_RBTree_Extract_validate_unprotected+0xec>
2008c84: c2 07 60 04 ld [ %i5 + 4 ], %g1
!_RBTree_Is_red(sibling->child[RBT_LEFT])) {
sibling->color = RBT_RED;
2008c88: f4 22 20 0c st %i2, [ %o0 + 0xc ]
2008c8c: c2 07 60 0c ld [ %i5 + 0xc ], %g1
2008c90: 80 a0 60 01 cmp %g1, 1
2008c94: 32 80 00 3d bne,a 2008d88 <_RBTree_Extract_validate_unprotected+0x1d0>
2008c98: f8 07 40 00 ld [ %i5 ], %i4
if (_RBTree_Is_red(parent)) {
parent->color = RBT_BLACK;
break;
2008c9c: 10 80 00 33 b 2008d68 <_RBTree_Extract_validate_unprotected+0x1b0>
2008ca0: c0 27 60 0c clr [ %i5 + 0xc ]
* cases, either the_node is to the left or the right of the parent.
* In both cases, first check if one of sibling's children is black,
* and if so rotate in the proper direction and update sibling pointer.
* Then switch the sibling and parent colors, and rotate through parent.
*/
dir = the_node != parent->child[0];
2008ca4: 82 1e 00 01 xor %i0, %g1, %g1
2008ca8: 80 a0 00 01 cmp %g0, %g1
2008cac: b8 40 20 00 addx %g0, 0, %i4
if (!_RBTree_Is_red(sibling->child[!dir])) {
2008cb0: 80 a0 00 1c cmp %g0, %i4
2008cb4: b6 60 3f ff subx %g0, -1, %i3
2008cb8: 83 2e e0 02 sll %i3, 2, %g1
2008cbc: 82 02 00 01 add %o0, %g1, %g1
2008cc0: c4 00 60 04 ld [ %g1 + 4 ], %g2
2008cc4: 80 a0 a0 00 cmp %g2, 0
2008cc8: 02 80 00 06 be 2008ce0 <_RBTree_Extract_validate_unprotected+0x128>
2008ccc: 82 10 20 00 clr %g1
* This function maintains the properties of the red-black tree.
*
* @note It does NOT disable interrupts to ensure the atomicity
* of the extract operation.
*/
void _RBTree_Extract_validate_unprotected(
2008cd0: c2 00 a0 0c ld [ %g2 + 0xc ], %g1
2008cd4: 82 18 60 01 xor %g1, 1, %g1
2008cd8: 80 a0 00 01 cmp %g0, %g1
2008cdc: 82 60 3f ff subx %g0, -1, %g1
* In both cases, first check if one of sibling's children is black,
* and if so rotate in the proper direction and update sibling pointer.
* Then switch the sibling and parent colors, and rotate through parent.
*/
dir = the_node != parent->child[0];
if (!_RBTree_Is_red(sibling->child[!dir])) {
2008ce0: 80 a0 60 00 cmp %g1, 0
2008ce4: 32 80 00 0e bne,a 2008d1c <_RBTree_Extract_validate_unprotected+0x164>
2008ce8: c2 07 60 0c ld [ %i5 + 0xc ], %g1
sibling->color = RBT_RED;
2008cec: 82 10 20 01 mov 1, %g1
2008cf0: c2 22 20 0c st %g1, [ %o0 + 0xc ]
sibling->child[dir]->color = RBT_BLACK;
2008cf4: 83 2f 20 02 sll %i4, 2, %g1
2008cf8: 82 02 00 01 add %o0, %g1, %g1
2008cfc: c2 00 60 04 ld [ %g1 + 4 ], %g1
_RBTree_Rotate(sibling, !dir);
2008d00: 92 1f 20 01 xor %i4, 1, %o1
2008d04: 7f ff ff 8e call 2008b3c <_RBTree_Rotate>
2008d08: c0 20 60 0c clr [ %g1 + 0xc ]
sibling = parent->child[!dir];
2008d0c: 83 2e e0 02 sll %i3, 2, %g1
2008d10: 82 07 40 01 add %i5, %g1, %g1
2008d14: d0 00 60 04 ld [ %g1 + 4 ], %o0
}
sibling->color = parent->color;
2008d18: c2 07 60 0c ld [ %i5 + 0xc ], %g1
parent->color = RBT_BLACK;
sibling->child[!dir]->color = RBT_BLACK;
2008d1c: b7 2e e0 02 sll %i3, 2, %i3
sibling->color = RBT_RED;
sibling->child[dir]->color = RBT_BLACK;
_RBTree_Rotate(sibling, !dir);
sibling = parent->child[!dir];
}
sibling->color = parent->color;
2008d20: c2 22 20 0c st %g1, [ %o0 + 0xc ]
parent->color = RBT_BLACK;
sibling->child[!dir]->color = RBT_BLACK;
2008d24: 90 02 00 1b add %o0, %i3, %o0
2008d28: c2 02 20 04 ld [ %o0 + 4 ], %g1
sibling->child[dir]->color = RBT_BLACK;
_RBTree_Rotate(sibling, !dir);
sibling = parent->child[!dir];
}
sibling->color = parent->color;
parent->color = RBT_BLACK;
2008d2c: c0 27 60 0c clr [ %i5 + 0xc ]
sibling->child[!dir]->color = RBT_BLACK;
2008d30: c0 20 60 0c clr [ %g1 + 0xc ]
_RBTree_Rotate(parent, dir);
2008d34: 90 10 00 1d mov %i5, %o0
2008d38: 7f ff ff 81 call 2008b3c <_RBTree_Rotate>
2008d3c: 92 10 00 1c mov %i4, %o1
break; /* done */
2008d40: 10 80 00 0b b 2008d6c <_RBTree_Extract_validate_unprotected+0x1b4>
2008d44: c2 06 00 00 ld [ %i0 ], %g1
if(!parent->parent) return;
sibling = _RBTree_Sibling(the_node);
/* continue to correct tree as long as the_node is black and not the root */
while (!_RBTree_Is_red(the_node) && parent->parent) {
2008d48: c2 06 20 0c ld [ %i0 + 0xc ], %g1
2008d4c: 80 a0 60 01 cmp %g1, 1
2008d50: 22 80 00 07 be,a 2008d6c <_RBTree_Extract_validate_unprotected+0x1b4>
2008d54: c2 06 00 00 ld [ %i0 ], %g1
2008d58: c2 07 40 00 ld [ %i5 ], %g1
2008d5c: 80 a0 60 00 cmp %g1, 0
2008d60: 12 bf ff a0 bne 2008be0 <_RBTree_Extract_validate_unprotected+0x28>
2008d64: 80 a2 20 00 cmp %o0, 0
sibling->child[!dir]->color = RBT_BLACK;
_RBTree_Rotate(parent, dir);
break; /* done */
}
} /* while */
if(!the_node->parent->parent) the_node->color = RBT_BLACK;
2008d68: c2 06 00 00 ld [ %i0 ], %g1
2008d6c: c2 00 40 00 ld [ %g1 ], %g1
2008d70: 80 a0 60 00 cmp %g1, 0
2008d74: 12 80 00 0a bne 2008d9c <_RBTree_Extract_validate_unprotected+0x1e4>
2008d78: 01 00 00 00 nop
2008d7c: c0 26 20 0c clr [ %i0 + 0xc ]
2008d80: 81 c7 e0 08 ret
2008d84: 81 e8 00 00 restore
parent->color = RBT_BLACK;
break;
}
the_node = parent; /* done if parent is red */
parent = the_node->parent;
sibling = _RBTree_Sibling(the_node);
2008d88: 90 10 00 1d mov %i5, %o0
2008d8c: 7f ff ff 5b call 2008af8 <_RBTree_Sibling>
2008d90: b0 10 00 1d mov %i5, %i0
2008d94: 10 bf ff ed b 2008d48 <_RBTree_Extract_validate_unprotected+0x190>
2008d98: ba 10 00 1c mov %i4, %i5
2008d9c: 81 c7 e0 08 ret
2008da0: 81 e8 00 00 restore
02008ff4 <_RBTree_Find>:
RBTree_Node *_RBTree_Find(
RBTree_Control *the_rbtree,
RBTree_Node *search_node
)
{
2008ff4: 9d e3 bf a0 save %sp, -96, %sp
ISR_Level level;
RBTree_Node *return_node;
return_node = NULL;
_ISR_Disable( level );
2008ff8: 7f ff e8 15 call 200304c <sparc_disable_interrupts>
2008ffc: ba 10 00 18 mov %i0, %i5
2009000: b8 10 00 08 mov %o0, %i4
RTEMS_INLINE_ROUTINE RBTree_Node *_RBTree_Find_unprotected(
RBTree_Control *the_rbtree,
RBTree_Node *the_node
)
{
RBTree_Node* iter_node = the_rbtree->root;
2009004: 10 80 00 0d b 2009038 <_RBTree_Find+0x44>
2009008: f0 06 20 04 ld [ %i0 + 4 ], %i0
int compare_result;
while (iter_node) {
compare_result = the_rbtree->compare_function(the_node, iter_node);
200900c: 90 10 00 19 mov %i1, %o0
2009010: 9f c0 40 00 call %g1
2009014: 92 10 00 18 mov %i0, %o1
if (compare_result == 0) {
2009018: 80 a2 20 00 cmp %o0, 0
200901c: 02 80 00 0a be 2009044 <_RBTree_Find+0x50>
2009020: 90 38 00 08 xnor %g0, %o0, %o0
return(iter_node);
}
RBTree_Direction dir = (compare_result != -1);
2009024: 80 a0 00 08 cmp %g0, %o0
2009028: 82 40 20 00 addx %g0, 0, %g1
iter_node = iter_node->child[dir];
200902c: 83 28 60 02 sll %g1, 2, %g1
2009030: b0 06 00 01 add %i0, %g1, %i0
2009034: f0 06 20 04 ld [ %i0 + 4 ], %i0
RBTree_Node *the_node
)
{
RBTree_Node* iter_node = the_rbtree->root;
int compare_result;
while (iter_node) {
2009038: 80 a6 20 00 cmp %i0, 0
200903c: 32 bf ff f4 bne,a 200900c <_RBTree_Find+0x18> <== ALWAYS TAKEN
2009040: c2 07 60 10 ld [ %i5 + 0x10 ], %g1
return_node = _RBTree_Find_unprotected( the_rbtree, search_node );
_ISR_Enable( level );
2009044: 7f ff e8 06 call 200305c <sparc_enable_interrupts>
2009048: 90 10 00 1c mov %i4, %o0
return return_node;
}
200904c: 81 c7 e0 08 ret
2009050: 81 e8 00 00 restore
020092e8 <_RBTree_Initialize>:
void *compare_function,
void *starting_address,
size_t number_nodes,
size_t node_size
)
{
20092e8: 9d e3 bf a0 save %sp, -96, %sp
size_t count;
RBTree_Node *next;
/* TODO: Error message? */
if (!the_rbtree) return;
20092ec: 80 a6 20 00 cmp %i0, 0
20092f0: 02 80 00 0f be 200932c <_RBTree_Initialize+0x44> <== NEVER TAKEN
20092f4: 01 00 00 00 nop
RTEMS_INLINE_ROUTINE void _RBTree_Initialize_empty(
RBTree_Control *the_rbtree,
void *compare_function
)
{
the_rbtree->permanent_null = NULL;
20092f8: c0 26 00 00 clr [ %i0 ]
the_rbtree->root = NULL;
20092fc: c0 26 20 04 clr [ %i0 + 4 ]
the_rbtree->first[0] = NULL;
2009300: c0 26 20 08 clr [ %i0 + 8 ]
the_rbtree->first[1] = NULL;
2009304: c0 26 20 0c clr [ %i0 + 0xc ]
/* could do sanity checks here */
_RBTree_Initialize_empty(the_rbtree, compare_function);
count = number_nodes;
next = starting_address;
while ( count-- ) {
2009308: 10 80 00 06 b 2009320 <_RBTree_Initialize+0x38>
200930c: f2 26 20 10 st %i1, [ %i0 + 0x10 ]
_RBTree_Insert(the_rbtree, next);
2009310: 90 10 00 18 mov %i0, %o0
2009314: 7f ff ff ec call 20092c4 <_RBTree_Insert>
2009318: b4 06 80 1c add %i2, %i4, %i2
* node_size - size of node in bytes
*
* Output parameters: NONE
*/
void _RBTree_Initialize(
200931c: b6 06 ff ff add %i3, -1, %i3
/* could do sanity checks here */
_RBTree_Initialize_empty(the_rbtree, compare_function);
count = number_nodes;
next = starting_address;
while ( count-- ) {
2009320: 80 a6 e0 00 cmp %i3, 0
2009324: 12 bf ff fb bne 2009310 <_RBTree_Initialize+0x28>
2009328: 92 10 00 1a mov %i2, %o1
200932c: 81 c7 e0 08 ret
2009330: 81 e8 00 00 restore
020025cc <_RBTree_Sibling>:
*/
RTEMS_INLINE_ROUTINE RBTree_Node *_RBTree_Sibling(
RBTree_Node *the_node
)
{
if(!the_node) return NULL;
20025cc: 80 a2 20 00 cmp %o0, 0
20025d0: 02 80 00 0e be 2002608 <_RBTree_Sibling+0x3c>
20025d4: 82 10 20 00 clr %g1
if(!(the_node->parent)) return NULL;
20025d8: c4 02 00 00 ld [ %o0 ], %g2
20025dc: 80 a0 a0 00 cmp %g2, 0
20025e0: 02 80 00 0a be 2002608 <_RBTree_Sibling+0x3c> <== NEVER TAKEN
20025e4: 01 00 00 00 nop
if(!(the_node->parent->parent)) return NULL;
20025e8: c6 00 80 00 ld [ %g2 ], %g3
20025ec: 80 a0 e0 00 cmp %g3, 0
20025f0: 02 80 00 06 be 2002608 <_RBTree_Sibling+0x3c>
20025f4: 01 00 00 00 nop
if(the_node == the_node->parent->child[RBT_LEFT])
20025f8: c2 00 a0 04 ld [ %g2 + 4 ], %g1
20025fc: 80 a2 00 01 cmp %o0, %g1
2002600: 22 80 00 02 be,a 2002608 <_RBTree_Sibling+0x3c>
2002604: c2 00 a0 08 ld [ %g2 + 8 ], %g1
return the_node->parent->child[RBT_RIGHT];
else
return the_node->parent->child[RBT_LEFT];
}
2002608: 81 c3 e0 08 retl
200260c: 90 10 00 01 mov %g1, %o0
0200910c <_RBTree_Validate_insert_unprotected>:
* append operation.
*/
void _RBTree_Validate_insert_unprotected(
RBTree_Node *the_node
)
{
200910c: 9d e3 bf a0 save %sp, -96, %sp
RBTree_Node *u,*g;
/* note: the insert root case is handled already */
/* if the parent is black, nothing needs to be done
* otherwise may need to loop a few times */
while (_RBTree_Is_red(_RBTree_Parent(the_node))) {
2009110: 10 80 00 1f b 200918c <_RBTree_Validate_insert_unprotected+0x80>
2009114: b6 10 20 01 mov 1, %i3
)
{
if(!the_node) return NULL;
if(!(the_node->parent)) return NULL;
if(!(the_node->parent->parent)) return NULL;
if(!(the_node->parent->parent->parent)) return NULL;
2009118: 80 a0 60 00 cmp %g1, 0
200911c: 02 80 00 27 be 20091b8 <_RBTree_Validate_insert_unprotected+0xac><== NEVER TAKEN
2009120: c2 07 60 04 ld [ %i5 + 4 ], %g1
{
if(!the_node) return NULL;
if(!(the_node->parent)) return NULL;
if(!(the_node->parent->parent)) return NULL;
if(the_node == the_node->parent->child[RBT_LEFT])
2009124: 80 a2 00 01 cmp %o0, %g1
2009128: 22 80 00 02 be,a 2009130 <_RBTree_Validate_insert_unprotected+0x24>
200912c: c2 07 60 08 ld [ %i5 + 8 ], %g1
*/
RTEMS_INLINE_ROUTINE bool _RBTree_Is_red(
const RBTree_Node *the_node
)
{
return (the_node && the_node->color == RBT_RED);
2009130: 80 a0 60 00 cmp %g1, 0
2009134: 22 80 00 21 be,a 20091b8 <_RBTree_Validate_insert_unprotected+0xac>
2009138: c2 07 60 04 ld [ %i5 + 4 ], %g1
200913c: c4 00 60 0c ld [ %g1 + 0xc ], %g2
2009140: 80 a0 a0 01 cmp %g2, 1
2009144: 32 80 00 1d bne,a 20091b8 <_RBTree_Validate_insert_unprotected+0xac>
2009148: c2 07 60 04 ld [ %i5 + 4 ], %g1
u = _RBTree_Parent_sibling(the_node);
g = the_node->parent->parent;
/* if uncle is red, repaint uncle/parent black and grandparent red */
if(_RBTree_Is_red(u)) {
the_node->parent->color = RBT_BLACK;
200914c: c0 22 20 0c clr [ %o0 + 0xc ]
u->color = RBT_BLACK;
2009150: c0 20 60 0c clr [ %g1 + 0xc ]
g->color = RBT_RED;
2009154: c4 27 60 0c st %g2, [ %i5 + 0xc ]
2009158: 10 80 00 0d b 200918c <_RBTree_Validate_insert_unprotected+0x80>
200915c: b0 10 00 1d mov %i5, %i0
RBTree_Direction dir = the_node != the_node->parent->child[0];
RBTree_Direction pdir = the_node->parent != g->child[0];
/* ensure node is on the same branch direction as parent */
if (dir != pdir) {
_RBTree_Rotate(the_node->parent, pdir);
2009160: 7f ff ff cc call 2009090 <_RBTree_Rotate>
2009164: 92 10 00 1c mov %i4, %o1
the_node = the_node->child[pdir];
2009168: 83 2f 20 02 sll %i4, 2, %g1
200916c: b0 06 00 01 add %i0, %g1, %i0
2009170: f0 06 20 04 ld [ %i0 + 4 ], %i0
}
the_node->parent->color = RBT_BLACK;
2009174: c2 06 00 00 ld [ %i0 ], %g1
g->color = RBT_RED;
/* now rotate grandparent in the other branch direction (toward uncle) */
_RBTree_Rotate(g, (1-pdir));
2009178: 90 10 00 1d mov %i5, %o0
/* ensure node is on the same branch direction as parent */
if (dir != pdir) {
_RBTree_Rotate(the_node->parent, pdir);
the_node = the_node->child[pdir];
}
the_node->parent->color = RBT_BLACK;
200917c: c0 20 60 0c clr [ %g1 + 0xc ]
g->color = RBT_RED;
2009180: f6 27 60 0c st %i3, [ %i5 + 0xc ]
/* now rotate grandparent in the other branch direction (toward uncle) */
_RBTree_Rotate(g, (1-pdir));
2009184: 7f ff ff c3 call 2009090 <_RBTree_Rotate>
2009188: 92 26 c0 1c sub %i3, %i4, %o1
ISR_Level level;
_ISR_Disable( level );
_RBTree_Insert_unprotected( tree, node );
_ISR_Enable( level );
}
200918c: d0 06 00 00 ld [ %i0 ], %o0
*/
RTEMS_INLINE_ROUTINE RBTree_Node *_RBTree_Parent(
RBTree_Node *the_node
)
{
if (!the_node->parent->parent) return NULL;
2009190: fa 02 00 00 ld [ %o0 ], %i5
2009194: 80 a7 60 00 cmp %i5, 0
2009198: 22 80 00 14 be,a 20091e8 <_RBTree_Validate_insert_unprotected+0xdc>
200919c: c0 26 20 0c clr [ %i0 + 0xc ]
*/
RTEMS_INLINE_ROUTINE bool _RBTree_Is_red(
const RBTree_Node *the_node
)
{
return (the_node && the_node->color == RBT_RED);
20091a0: c2 02 20 0c ld [ %o0 + 0xc ], %g1
20091a4: 80 a0 60 01 cmp %g1, 1
20091a8: 12 80 00 10 bne 20091e8 <_RBTree_Validate_insert_unprotected+0xdc>
20091ac: 01 00 00 00 nop
)
{
if(!the_node) return NULL;
if(!(the_node->parent)) return NULL;
if(!(the_node->parent->parent)) return NULL;
if(!(the_node->parent->parent->parent)) return NULL;
20091b0: 10 bf ff da b 2009118 <_RBTree_Validate_insert_unprotected+0xc>
20091b4: c2 07 40 00 ld [ %i5 ], %g1
u->color = RBT_BLACK;
g->color = RBT_RED;
the_node = g;
} else { /* if uncle is black */
RBTree_Direction dir = the_node != the_node->parent->child[0];
RBTree_Direction pdir = the_node->parent != g->child[0];
20091b8: 82 1a 00 01 xor %o0, %g1, %g1
20091bc: 80 a0 00 01 cmp %g0, %g1
the_node->parent->color = RBT_BLACK;
u->color = RBT_BLACK;
g->color = RBT_RED;
the_node = g;
} else { /* if uncle is black */
RBTree_Direction dir = the_node != the_node->parent->child[0];
20091c0: c2 02 20 04 ld [ %o0 + 4 ], %g1
RBTree_Direction pdir = the_node->parent != g->child[0];
20091c4: b8 40 20 00 addx %g0, 0, %i4
the_node->parent->color = RBT_BLACK;
u->color = RBT_BLACK;
g->color = RBT_RED;
the_node = g;
} else { /* if uncle is black */
RBTree_Direction dir = the_node != the_node->parent->child[0];
20091c8: 82 1e 00 01 xor %i0, %g1, %g1
20091cc: 80 a0 00 01 cmp %g0, %g1
20091d0: 82 40 20 00 addx %g0, 0, %g1
RBTree_Direction pdir = the_node->parent != g->child[0];
/* ensure node is on the same branch direction as parent */
if (dir != pdir) {
20091d4: 80 a0 40 1c cmp %g1, %i4
20091d8: 12 bf ff e2 bne 2009160 <_RBTree_Validate_insert_unprotected+0x54>
20091dc: 01 00 00 00 nop
_RBTree_Rotate(the_node->parent, pdir);
the_node = the_node->child[pdir];
}
the_node->parent->color = RBT_BLACK;
20091e0: 10 bf ff e6 b 2009178 <_RBTree_Validate_insert_unprotected+0x6c>
20091e4: c2 06 00 00 ld [ %i0 ], %g1
20091e8: 81 c7 e0 08 ret
20091ec: 81 e8 00 00 restore
0200ba60 <_RTEMS_tasks_Post_switch_extension>:
*/
void _RTEMS_tasks_Post_switch_extension(
Thread_Control *executing
)
{
200ba60: 9d e3 bf 98 save %sp, -104, %sp
RTEMS_API_Control *api;
ASR_Information *asr;
rtems_signal_set signal_set;
Modes_Control prev_mode;
api = executing->API_Extensions[ THREAD_API_RTEMS ];
200ba64: fa 06 21 58 ld [ %i0 + 0x158 ], %i5
if ( !api )
200ba68: 80 a7 60 00 cmp %i5, 0
200ba6c: 02 80 00 1c be 200badc <_RTEMS_tasks_Post_switch_extension+0x7c><== NEVER TAKEN
200ba70: 01 00 00 00 nop
* Signal Processing
*/
asr = &api->Signal;
_ISR_Disable( level );
200ba74: 7f ff d9 c2 call 200217c <sparc_disable_interrupts>
200ba78: 01 00 00 00 nop
signal_set = asr->signals_posted;
200ba7c: f6 07 60 14 ld [ %i5 + 0x14 ], %i3
asr->signals_posted = 0;
200ba80: c0 27 60 14 clr [ %i5 + 0x14 ]
_ISR_Enable( level );
200ba84: 7f ff d9 c2 call 200218c <sparc_enable_interrupts>
200ba88: 01 00 00 00 nop
if ( !signal_set ) /* similar to _ASR_Are_signals_pending( asr ) */
200ba8c: 80 a6 e0 00 cmp %i3, 0
200ba90: 02 80 00 13 be 200badc <_RTEMS_tasks_Post_switch_extension+0x7c>
200ba94: 94 07 bf fc add %fp, -4, %o2
return;
asr->nest_level += 1;
200ba98: c2 07 60 1c ld [ %i5 + 0x1c ], %g1
rtems_task_mode( asr->mode_set, RTEMS_ALL_MODE_MASKS, &prev_mode );
200ba9c: d0 07 60 10 ld [ %i5 + 0x10 ], %o0
if ( !signal_set ) /* similar to _ASR_Are_signals_pending( asr ) */
return;
asr->nest_level += 1;
200baa0: 82 00 60 01 inc %g1
200baa4: c2 27 60 1c st %g1, [ %i5 + 0x1c ]
rtems_task_mode( asr->mode_set, RTEMS_ALL_MODE_MASKS, &prev_mode );
200baa8: 39 00 00 3f sethi %hi(0xfc00), %i4
200baac: 40 00 07 3b call 200d798 <rtems_task_mode>
200bab0: 92 17 23 ff or %i4, 0x3ff, %o1 ! ffff <PROM_START+0xffff>
(*asr->handler)( signal_set );
200bab4: c2 07 60 0c ld [ %i5 + 0xc ], %g1
200bab8: 9f c0 40 00 call %g1
200babc: 90 10 00 1b mov %i3, %o0
asr->nest_level -= 1;
200bac0: c2 07 60 1c ld [ %i5 + 0x1c ], %g1
rtems_task_mode( prev_mode, RTEMS_ALL_MODE_MASKS, &prev_mode );
200bac4: d0 07 bf fc ld [ %fp + -4 ], %o0
asr->nest_level += 1;
rtems_task_mode( asr->mode_set, RTEMS_ALL_MODE_MASKS, &prev_mode );
(*asr->handler)( signal_set );
asr->nest_level -= 1;
200bac8: 82 00 7f ff add %g1, -1, %g1
rtems_task_mode( prev_mode, RTEMS_ALL_MODE_MASKS, &prev_mode );
200bacc: 92 17 23 ff or %i4, 0x3ff, %o1
asr->nest_level += 1;
rtems_task_mode( asr->mode_set, RTEMS_ALL_MODE_MASKS, &prev_mode );
(*asr->handler)( signal_set );
asr->nest_level -= 1;
200bad0: c2 27 60 1c st %g1, [ %i5 + 0x1c ]
rtems_task_mode( prev_mode, RTEMS_ALL_MODE_MASKS, &prev_mode );
200bad4: 40 00 07 31 call 200d798 <rtems_task_mode>
200bad8: 94 07 bf fc add %fp, -4, %o2
200badc: 81 c7 e0 08 ret
200bae0: 81 e8 00 00 restore
020076c8 <_Rate_monotonic_Timeout>:
void _Rate_monotonic_Timeout(
Objects_Id id,
void *ignored
)
{
20076c8: 9d e3 bf 98 save %sp, -104, %sp
20076cc: 11 00 80 74 sethi %hi(0x201d000), %o0
20076d0: 92 10 00 18 mov %i0, %o1
20076d4: 90 12 21 c4 or %o0, 0x1c4, %o0
20076d8: 40 00 07 be call 20095d0 <_Objects_Get>
20076dc: 94 07 bf fc add %fp, -4, %o2
/*
* When we get here, the Timer is already off the chain so we do not
* have to worry about that -- hence no _Watchdog_Remove().
*/
the_period = _Rate_monotonic_Get( id, &location );
switch ( location ) {
20076e0: c2 07 bf fc ld [ %fp + -4 ], %g1
20076e4: 80 a0 60 00 cmp %g1, 0
20076e8: 12 80 00 25 bne 200777c <_Rate_monotonic_Timeout+0xb4> <== NEVER TAKEN
20076ec: ba 10 00 08 mov %o0, %i5
case OBJECTS_LOCAL:
the_thread = the_period->owner;
20076f0: d0 02 20 40 ld [ %o0 + 0x40 ], %o0
if ( _States_Is_waiting_for_period( the_thread->current_state ) &&
20076f4: 03 00 00 10 sethi %hi(0x4000), %g1
*/
RTEMS_INLINE_ROUTINE bool _States_Is_waiting_for_period (
States_Control the_states
)
{
return (the_states & STATES_WAITING_FOR_PERIOD);
20076f8: c4 02 20 10 ld [ %o0 + 0x10 ], %g2
20076fc: 80 88 80 01 btst %g2, %g1
2007700: 22 80 00 0b be,a 200772c <_Rate_monotonic_Timeout+0x64>
2007704: c2 07 60 38 ld [ %i5 + 0x38 ], %g1
2007708: c4 02 20 20 ld [ %o0 + 0x20 ], %g2
200770c: c2 07 60 08 ld [ %i5 + 8 ], %g1
2007710: 80 a0 80 01 cmp %g2, %g1
2007714: 32 80 00 06 bne,a 200772c <_Rate_monotonic_Timeout+0x64>
2007718: c2 07 60 38 ld [ %i5 + 0x38 ], %g1
RTEMS_INLINE_ROUTINE void _Thread_Unblock (
Thread_Control *the_thread
)
{
_Thread_Clear_state( the_thread, STATES_BLOCKED );
200771c: 13 04 00 ff sethi %hi(0x1003fc00), %o1
2007720: 40 00 0a 6e call 200a0d8 <_Thread_Clear_state>
2007724: 92 12 63 f8 or %o1, 0x3f8, %o1 ! 1003fff8 <RAM_END+0xdc3fff8>
2007728: 30 80 00 06 b,a 2007740 <_Rate_monotonic_Timeout+0x78>
_Thread_Unblock( the_thread );
_Rate_monotonic_Initiate_statistics( the_period );
_Watchdog_Insert_ticks( &the_period->Timer, the_period->next_length );
} else if ( the_period->state == RATE_MONOTONIC_OWNER_IS_BLOCKING ) {
200772c: 80 a0 60 01 cmp %g1, 1
2007730: 12 80 00 0d bne 2007764 <_Rate_monotonic_Timeout+0x9c>
2007734: 82 10 20 04 mov 4, %g1
the_period->state = RATE_MONOTONIC_EXPIRED_WHILE_BLOCKING;
2007738: 82 10 20 03 mov 3, %g1
200773c: c2 27 60 38 st %g1, [ %i5 + 0x38 ]
_Rate_monotonic_Initiate_statistics( the_period );
2007740: 7f ff fe 70 call 2007100 <_Rate_monotonic_Initiate_statistics>
2007744: 90 10 00 1d mov %i5, %o0
Watchdog_Control *the_watchdog,
Watchdog_Interval units
)
{
the_watchdog->initial = units;
2007748: c2 07 60 3c ld [ %i5 + 0x3c ], %g1
_Watchdog_Insert( &_Watchdog_Ticks_chain, the_watchdog );
200774c: 11 00 80 74 sethi %hi(0x201d000), %o0
Watchdog_Control *the_watchdog,
Watchdog_Interval units
)
{
the_watchdog->initial = units;
2007750: c2 27 60 1c st %g1, [ %i5 + 0x1c ]
_Watchdog_Insert( &_Watchdog_Ticks_chain, the_watchdog );
2007754: 90 12 23 ec or %o0, 0x3ec, %o0
2007758: 40 00 0f 04 call 200b368 <_Watchdog_Insert>
200775c: 92 07 60 10 add %i5, 0x10, %o1
2007760: 30 80 00 02 b,a 2007768 <_Rate_monotonic_Timeout+0xa0>
_Watchdog_Insert_ticks( &the_period->Timer, the_period->next_length );
} else
the_period->state = RATE_MONOTONIC_EXPIRED;
2007764: c2 27 60 38 st %g1, [ %i5 + 0x38 ]
*
* This routine decrements the thread dispatch level.
*/
RTEMS_INLINE_ROUTINE uint32_t _Thread_Dispatch_decrement_disable_level(void)
{
_Thread_Dispatch_disable_level--;
2007768: 03 00 80 74 sethi %hi(0x201d000), %g1
200776c: c4 00 63 30 ld [ %g1 + 0x330 ], %g2 ! 201d330 <_Thread_Dispatch_disable_level>
2007770: 84 00 bf ff add %g2, -1, %g2
2007774: c4 20 63 30 st %g2, [ %g1 + 0x330 ]
return _Thread_Dispatch_disable_level;
2007778: c2 00 63 30 ld [ %g1 + 0x330 ], %g1
200777c: 81 c7 e0 08 ret
2007780: 81 e8 00 00 restore
02007160 <_TOD_Validate>:
*/
bool _TOD_Validate(
const rtems_time_of_day *the_tod
)
{
2007160: 9d e3 bf a0 save %sp, -96, %sp
uint32_t days_in_month;
uint32_t ticks_per_second;
ticks_per_second = TOD_MICROSECONDS_PER_SECOND /
rtems_configuration_get_microseconds_per_tick();
2007164: 03 00 80 73 sethi %hi(0x201cc00), %g1
(the_tod->hour >= TOD_HOURS_PER_DAY) ||
(the_tod->month == 0) ||
(the_tod->month > TOD_MONTHS_PER_YEAR) ||
(the_tod->year < TOD_BASE_YEAR) ||
(the_tod->day == 0) )
return false;
2007168: ba 10 20 00 clr %i5
uint32_t days_in_month;
uint32_t ticks_per_second;
ticks_per_second = TOD_MICROSECONDS_PER_SECOND /
rtems_configuration_get_microseconds_per_tick();
if ((!the_tod) ||
200716c: 80 a6 20 00 cmp %i0, 0
2007170: 02 80 00 2b be 200721c <_TOD_Validate+0xbc> <== NEVER TAKEN
2007174: d2 00 63 38 ld [ %g1 + 0x338 ], %o1
)
{
uint32_t days_in_month;
uint32_t ticks_per_second;
ticks_per_second = TOD_MICROSECONDS_PER_SECOND /
2007178: 11 00 03 d0 sethi %hi(0xf4000), %o0
200717c: 40 00 46 65 call 2018b10 <.udiv>
2007180: 90 12 22 40 or %o0, 0x240, %o0 ! f4240 <PROM_START+0xf4240>
rtems_configuration_get_microseconds_per_tick();
if ((!the_tod) ||
2007184: c2 06 20 18 ld [ %i0 + 0x18 ], %g1
2007188: 80 a0 40 08 cmp %g1, %o0
200718c: 3a 80 00 25 bcc,a 2007220 <_TOD_Validate+0xc0>
2007190: b0 0f 60 01 and %i5, 1, %i0
(the_tod->ticks >= ticks_per_second) ||
2007194: c2 06 20 14 ld [ %i0 + 0x14 ], %g1
2007198: 80 a0 60 3b cmp %g1, 0x3b
200719c: 38 80 00 21 bgu,a 2007220 <_TOD_Validate+0xc0>
20071a0: b0 0f 60 01 and %i5, 1, %i0
(the_tod->second >= TOD_SECONDS_PER_MINUTE) ||
20071a4: c2 06 20 10 ld [ %i0 + 0x10 ], %g1
20071a8: 80 a0 60 3b cmp %g1, 0x3b
20071ac: 38 80 00 1d bgu,a 2007220 <_TOD_Validate+0xc0>
20071b0: b0 0f 60 01 and %i5, 1, %i0
(the_tod->minute >= TOD_MINUTES_PER_HOUR) ||
20071b4: c2 06 20 0c ld [ %i0 + 0xc ], %g1
20071b8: 80 a0 60 17 cmp %g1, 0x17
20071bc: 38 80 00 19 bgu,a 2007220 <_TOD_Validate+0xc0>
20071c0: b0 0f 60 01 and %i5, 1, %i0
(the_tod->hour >= TOD_HOURS_PER_DAY) ||
(the_tod->month == 0) ||
20071c4: c2 06 20 04 ld [ %i0 + 4 ], %g1
rtems_configuration_get_microseconds_per_tick();
if ((!the_tod) ||
(the_tod->ticks >= ticks_per_second) ||
(the_tod->second >= TOD_SECONDS_PER_MINUTE) ||
(the_tod->minute >= TOD_MINUTES_PER_HOUR) ||
(the_tod->hour >= TOD_HOURS_PER_DAY) ||
20071c8: 80 a0 60 00 cmp %g1, 0
20071cc: 02 80 00 14 be 200721c <_TOD_Validate+0xbc> <== NEVER TAKEN
20071d0: 80 a0 60 0c cmp %g1, 0xc
(the_tod->month == 0) ||
20071d4: 38 80 00 13 bgu,a 2007220 <_TOD_Validate+0xc0>
20071d8: b0 0f 60 01 and %i5, 1, %i0
(the_tod->month > TOD_MONTHS_PER_YEAR) ||
(the_tod->year < TOD_BASE_YEAR) ||
20071dc: c6 06 00 00 ld [ %i0 ], %g3
(the_tod->ticks >= ticks_per_second) ||
(the_tod->second >= TOD_SECONDS_PER_MINUTE) ||
(the_tod->minute >= TOD_MINUTES_PER_HOUR) ||
(the_tod->hour >= TOD_HOURS_PER_DAY) ||
(the_tod->month == 0) ||
(the_tod->month > TOD_MONTHS_PER_YEAR) ||
20071e0: 80 a0 e7 c3 cmp %g3, 0x7c3
20071e4: 28 80 00 0f bleu,a 2007220 <_TOD_Validate+0xc0>
20071e8: b0 0f 60 01 and %i5, 1, %i0
(the_tod->year < TOD_BASE_YEAR) ||
(the_tod->day == 0) )
20071ec: c4 06 20 08 ld [ %i0 + 8 ], %g2
(the_tod->second >= TOD_SECONDS_PER_MINUTE) ||
(the_tod->minute >= TOD_MINUTES_PER_HOUR) ||
(the_tod->hour >= TOD_HOURS_PER_DAY) ||
(the_tod->month == 0) ||
(the_tod->month > TOD_MONTHS_PER_YEAR) ||
(the_tod->year < TOD_BASE_YEAR) ||
20071f0: 80 a0 a0 00 cmp %g2, 0
20071f4: 02 80 00 0a be 200721c <_TOD_Validate+0xbc> <== NEVER TAKEN
20071f8: 80 88 e0 03 btst 3, %g3
20071fc: 07 00 80 6f sethi %hi(0x201bc00), %g3
(the_tod->day == 0) )
return false;
if ( (the_tod->year % 4) == 0 )
2007200: 12 80 00 03 bne 200720c <_TOD_Validate+0xac>
2007204: 86 10 e0 48 or %g3, 0x48, %g3 ! 201bc48 <_TOD_Days_per_month>
days_in_month = _TOD_Days_per_month[ 1 ][ the_tod->month ];
2007208: 82 00 60 0d add %g1, 0xd, %g1
else
days_in_month = _TOD_Days_per_month[ 0 ][ the_tod->month ];
200720c: 83 28 60 02 sll %g1, 2, %g1
2007210: c2 00 c0 01 ld [ %g3 + %g1 ], %g1
* false - if the the_tod is invalid
*
* NOTE: This routine only works for leap-years through 2099.
*/
bool _TOD_Validate(
2007214: 80 a0 40 02 cmp %g1, %g2
2007218: ba 60 3f ff subx %g0, -1, %i5
if ( the_tod->day > days_in_month )
return false;
return true;
}
200721c: b0 0f 60 01 and %i5, 1, %i0
2007220: 81 c7 e0 08 ret
2007224: 81 e8 00 00 restore
02008790 <_Thread_Change_priority>:
void _Thread_Change_priority(
Thread_Control *the_thread,
Priority_Control new_priority,
bool prepend_it
)
{
2008790: 9d e3 bf a0 save %sp, -96, %sp
States_Control state, original_state;
/*
* Save original state
*/
original_state = the_thread->current_state;
2008794: f8 06 20 10 ld [ %i0 + 0x10 ], %i4
/*
* Set a transient state for the thread so it is pulled off the Ready chains.
* This will prevent it from being scheduled no matter what happens in an
* ISR.
*/
_Thread_Set_transient( the_thread );
2008798: 40 00 03 56 call 20094f0 <_Thread_Set_transient>
200879c: 90 10 00 18 mov %i0, %o0
/*
* Do not bother recomputing all the priority related information if
* we are not REALLY changing priority.
*/
if ( the_thread->current_priority != new_priority )
20087a0: c2 06 20 14 ld [ %i0 + 0x14 ], %g1
20087a4: 80 a0 40 19 cmp %g1, %i1
20087a8: 02 80 00 05 be 20087bc <_Thread_Change_priority+0x2c>
20087ac: ba 10 00 18 mov %i0, %i5
_Thread_Set_priority( the_thread, new_priority );
20087b0: 90 10 00 18 mov %i0, %o0
20087b4: 40 00 03 36 call 200948c <_Thread_Set_priority>
20087b8: 92 10 00 19 mov %i1, %o1
_ISR_Disable( level );
20087bc: 7f ff e6 70 call 200217c <sparc_disable_interrupts>
20087c0: 01 00 00 00 nop
20087c4: b6 10 00 08 mov %o0, %i3
/*
* If the thread has more than STATES_TRANSIENT set, then it is blocked,
* If it is blocked on a thread queue, then we need to requeue it.
*/
state = the_thread->current_state;
20087c8: f2 07 60 10 ld [ %i5 + 0x10 ], %i1
if ( state != STATES_TRANSIENT ) {
20087cc: 80 a6 60 04 cmp %i1, 4
20087d0: 02 80 00 10 be 2008810 <_Thread_Change_priority+0x80>
20087d4: b8 0f 20 04 and %i4, 4, %i4
/* Only clear the transient state if it wasn't set already */
if ( ! _States_Is_transient( original_state ) )
20087d8: 80 a7 20 00 cmp %i4, 0
20087dc: 12 80 00 03 bne 20087e8 <_Thread_Change_priority+0x58> <== NEVER TAKEN
20087e0: 82 0e 7f fb and %i1, -5, %g1
the_thread->current_state = _States_Clear( STATES_TRANSIENT, state );
20087e4: c2 27 60 10 st %g1, [ %i5 + 0x10 ]
_ISR_Enable( level );
20087e8: 7f ff e6 69 call 200218c <sparc_enable_interrupts>
20087ec: 90 10 00 1b mov %i3, %o0
if ( _States_Is_waiting_on_thread_queue( state ) ) {
20087f0: 03 00 00 ef sethi %hi(0x3bc00), %g1
20087f4: 82 10 62 e0 or %g1, 0x2e0, %g1 ! 3bee0 <PROM_START+0x3bee0>
20087f8: 80 8e 40 01 btst %i1, %g1
20087fc: 02 80 00 29 be 20088a0 <_Thread_Change_priority+0x110>
2008800: 01 00 00 00 nop
_Thread_queue_Requeue( the_thread->Wait.queue, the_thread );
2008804: f0 07 60 44 ld [ %i5 + 0x44 ], %i0
2008808: 40 00 02 f3 call 20093d4 <_Thread_queue_Requeue>
200880c: 93 e8 00 1d restore %g0, %i5, %o1
}
return;
}
/* Only clear the transient state if it wasn't set already */
if ( ! _States_Is_transient( original_state ) ) {
2008810: 80 a7 20 00 cmp %i4, 0
2008814: 12 80 00 0b bne 2008840 <_Thread_Change_priority+0xb0> <== NEVER TAKEN
2008818: 03 00 80 6a sethi %hi(0x201a800), %g1
* Interrupts are STILL disabled.
* We now know the thread will be in the READY state when we remove
* the TRANSIENT state. So we have to place it on the appropriate
* Ready Queue with interrupts off.
*/
the_thread->current_state = _States_Clear( STATES_TRANSIENT, state );
200881c: c0 27 60 10 clr [ %i5 + 0x10 ]
if ( prepend_it )
2008820: 80 a6 a0 00 cmp %i2, 0
2008824: 02 80 00 04 be 2008834 <_Thread_Change_priority+0xa4>
2008828: 82 10 60 b4 or %g1, 0xb4, %g1
*/
RTEMS_INLINE_ROUTINE void _Scheduler_Enqueue_first(
Thread_Control *the_thread
)
{
_Scheduler.Operations.enqueue_first( the_thread );
200882c: 10 80 00 03 b 2008838 <_Thread_Change_priority+0xa8>
2008830: c2 00 60 28 ld [ %g1 + 0x28 ], %g1
*/
RTEMS_INLINE_ROUTINE void _Scheduler_Enqueue(
Thread_Control *the_thread
)
{
_Scheduler.Operations.enqueue( the_thread );
2008834: c2 00 60 24 ld [ %g1 + 0x24 ], %g1
2008838: 9f c0 40 00 call %g1
200883c: 90 10 00 1d mov %i5, %o0
_Scheduler_Enqueue_first( the_thread );
else
_Scheduler_Enqueue( the_thread );
}
_ISR_Flash( level );
2008840: 7f ff e6 53 call 200218c <sparc_enable_interrupts>
2008844: 90 10 00 1b mov %i3, %o0
2008848: 7f ff e6 4d call 200217c <sparc_disable_interrupts>
200884c: 01 00 00 00 nop
2008850: b0 10 00 08 mov %o0, %i0
* This kernel routine implements the scheduling decision logic for
* the scheduler. It does NOT dispatch.
*/
RTEMS_INLINE_ROUTINE void _Scheduler_Schedule( void )
{
_Scheduler.Operations.schedule();
2008854: 03 00 80 6a sethi %hi(0x201a800), %g1
2008858: c2 00 60 bc ld [ %g1 + 0xbc ], %g1 ! 201a8bc <_Scheduler+0x8>
200885c: 9f c0 40 00 call %g1
2008860: 01 00 00 00 nop
* is also the heir thread, and false otherwise.
*/
RTEMS_INLINE_ROUTINE bool _Thread_Is_executing_also_the_heir( void )
{
return ( _Thread_Executing == _Thread_Heir );
2008864: 03 00 80 6d sethi %hi(0x201b400), %g1
2008868: 82 10 62 dc or %g1, 0x2dc, %g1 ! 201b6dc <_Per_CPU_Information>
200886c: c4 00 60 0c ld [ %g1 + 0xc ], %g2
* We altered the set of thread priorities. So let's figure out
* who is the heir and if we need to switch to them.
*/
_Scheduler_Schedule();
if ( !_Thread_Is_executing_also_the_heir() &&
2008870: c6 00 60 10 ld [ %g1 + 0x10 ], %g3
2008874: 80 a0 80 03 cmp %g2, %g3
2008878: 02 80 00 08 be 2008898 <_Thread_Change_priority+0x108>
200887c: 01 00 00 00 nop
2008880: c4 08 a0 74 ldub [ %g2 + 0x74 ], %g2
2008884: 80 a0 a0 00 cmp %g2, 0
2008888: 02 80 00 04 be 2008898 <_Thread_Change_priority+0x108>
200888c: 01 00 00 00 nop
_Thread_Executing->is_preemptible )
_Thread_Dispatch_necessary = true;
2008890: 84 10 20 01 mov 1, %g2 ! 1 <PROM_START+0x1>
2008894: c4 28 60 18 stb %g2, [ %g1 + 0x18 ]
_ISR_Enable( level );
2008898: 7f ff e6 3d call 200218c <sparc_enable_interrupts>
200889c: 81 e8 00 00 restore
20088a0: 81 c7 e0 08 ret
20088a4: 81 e8 00 00 restore
02008a94 <_Thread_Delay_ended>:
void _Thread_Delay_ended(
Objects_Id id,
void *ignored __attribute__((unused))
)
{
2008a94: 9d e3 bf 98 save %sp, -104, %sp
Thread_Control *the_thread;
Objects_Locations location;
the_thread = _Thread_Get( id, &location );
2008a98: 90 10 00 18 mov %i0, %o0
2008a9c: 40 00 00 6e call 2008c54 <_Thread_Get>
2008aa0: 92 07 bf fc add %fp, -4, %o1
switch ( location ) {
2008aa4: c2 07 bf fc ld [ %fp + -4 ], %g1
2008aa8: 80 a0 60 00 cmp %g1, 0
2008aac: 12 80 00 09 bne 2008ad0 <_Thread_Delay_ended+0x3c> <== NEVER TAKEN
2008ab0: 13 04 00 00 sethi %hi(0x10000000), %o1
#if defined(RTEMS_MULTIPROCESSING)
case OBJECTS_REMOTE: /* impossible */
#endif
break;
case OBJECTS_LOCAL:
_Thread_Clear_state(
2008ab4: 7f ff ff 7d call 20088a8 <_Thread_Clear_state>
2008ab8: 92 12 60 18 or %o1, 0x18, %o1 ! 10000018 <RAM_END+0xdc00018>
*
* This routine decrements the thread dispatch level.
*/
RTEMS_INLINE_ROUTINE uint32_t _Thread_Dispatch_decrement_disable_level(void)
{
_Thread_Dispatch_disable_level--;
2008abc: 03 00 80 6d sethi %hi(0x201b400), %g1
2008ac0: c4 00 60 b0 ld [ %g1 + 0xb0 ], %g2 ! 201b4b0 <_Thread_Dispatch_disable_level>
2008ac4: 84 00 bf ff add %g2, -1, %g2
2008ac8: c4 20 60 b0 st %g2, [ %g1 + 0xb0 ]
return _Thread_Dispatch_disable_level;
2008acc: c2 00 60 b0 ld [ %g1 + 0xb0 ], %g1
2008ad0: 81 c7 e0 08 ret
2008ad4: 81 e8 00 00 restore
02008ad8 <_Thread_Dispatch>:
* INTERRUPT LATENCY:
* dispatch thread
* no dispatch thread
*/
void _Thread_Dispatch( void )
{
2008ad8: 9d e3 bf 90 save %sp, -112, %sp
*
* This rountine increments the thread dispatch level
*/
RTEMS_INLINE_ROUTINE uint32_t _Thread_Dispatch_increment_disable_level(void)
{
_Thread_Dispatch_disable_level++;
2008adc: 03 00 80 6d sethi %hi(0x201b400), %g1
2008ae0: c4 00 60 b0 ld [ %g1 + 0xb0 ], %g2 ! 201b4b0 <_Thread_Dispatch_disable_level>
2008ae4: 84 00 a0 01 inc %g2
2008ae8: c4 20 60 b0 st %g2, [ %g1 + 0xb0 ]
return _Thread_Dispatch_disable_level;
2008aec: c2 00 60 b0 ld [ %g1 + 0xb0 ], %g1
#endif
/*
* Now determine if we need to perform a dispatch on the current CPU.
*/
executing = _Thread_Executing;
2008af0: 33 00 80 6d sethi %hi(0x201b400), %i1
2008af4: b4 16 62 dc or %i1, 0x2dc, %i2 ! 201b6dc <_Per_CPU_Information>
_ISR_Disable( level );
2008af8: 7f ff e5 a1 call 200217c <sparc_disable_interrupts>
2008afc: fa 06 a0 0c ld [ %i2 + 0xc ], %i5
#if __RTEMS_ADA__
executing->rtems_ada_self = rtems_ada_self;
rtems_ada_self = heir->rtems_ada_self;
#endif
if ( heir->budget_algorithm == THREAD_CPU_BUDGET_ALGORITHM_RESET_TIMESLICE )
heir->cpu_time_budget = _Thread_Ticks_per_timeslice;
2008b00: 21 00 80 6d sethi %hi(0x201b400), %l0
#ifndef __RTEMS_USE_TICKS_FOR_STATISTICS__
{
Timestamp_Control uptime, ran;
_TOD_Get_uptime( &uptime );
_Timestamp_Subtract(
2008b04: b4 06 a0 1c add %i2, 0x1c, %i2
#endif
/*
* Switch libc's task specific data.
*/
if ( _Thread_libc_reent ) {
2008b08: 31 00 80 6d sethi %hi(0x201b400), %i0
/*
* Now determine if we need to perform a dispatch on the current CPU.
*/
executing = _Thread_Executing;
_ISR_Disable( level );
while ( _Thread_Dispatch_necessary == true ) {
2008b0c: 10 80 00 38 b 2008bec <_Thread_Dispatch+0x114>
2008b10: 37 00 80 6d sethi %hi(0x201b400), %i3
heir = _Thread_Heir;
_Thread_Dispatch_necessary = false;
2008b14: c0 28 60 18 clrb [ %g1 + 0x18 ]
/*
* When the heir and executing are the same, then we are being
* requested to do the post switch dispatching. This is normally
* done to dispatch signals.
*/
if ( heir == executing )
2008b18: 80 a7 00 1d cmp %i4, %i5
2008b1c: 02 80 00 39 be 2008c00 <_Thread_Dispatch+0x128>
2008b20: f8 20 60 0c st %i4, [ %g1 + 0xc ]
*/
#if __RTEMS_ADA__
executing->rtems_ada_self = rtems_ada_self;
rtems_ada_self = heir->rtems_ada_self;
#endif
if ( heir->budget_algorithm == THREAD_CPU_BUDGET_ALGORITHM_RESET_TIMESLICE )
2008b24: c2 07 20 7c ld [ %i4 + 0x7c ], %g1
2008b28: 80 a0 60 01 cmp %g1, 1
2008b2c: 12 80 00 03 bne 2008b38 <_Thread_Dispatch+0x60>
2008b30: c2 04 20 14 ld [ %l0 + 0x14 ], %g1
heir->cpu_time_budget = _Thread_Ticks_per_timeslice;
2008b34: c2 27 20 78 st %g1, [ %i4 + 0x78 ]
_ISR_Enable( level );
2008b38: 7f ff e5 95 call 200218c <sparc_enable_interrupts>
2008b3c: 01 00 00 00 nop
#ifndef __RTEMS_USE_TICKS_FOR_STATISTICS__
{
Timestamp_Control uptime, ran;
_TOD_Get_uptime( &uptime );
2008b40: 40 00 0c c1 call 200be44 <_TOD_Get_uptime>
2008b44: 90 07 bf f0 add %fp, -16, %o0
_Timestamp_Subtract(
2008b48: 90 10 00 1a mov %i2, %o0
2008b4c: 92 07 bf f0 add %fp, -16, %o1
2008b50: 40 00 02 db call 20096bc <_Timespec_Subtract>
2008b54: 94 07 bf f8 add %fp, -8, %o2
&_Thread_Time_of_last_context_switch,
&uptime,
&ran
);
_Timestamp_Add_to( &executing->cpu_time_used, &ran );
2008b58: 90 07 60 84 add %i5, 0x84, %o0
2008b5c: 40 00 02 bf call 2009658 <_Timespec_Add_to>
2008b60: 92 07 bf f8 add %fp, -8, %o1
_Thread_Time_of_last_context_switch = uptime;
2008b64: c4 07 bf f0 ld [ %fp + -16 ], %g2
#endif
/*
* Switch libc's task specific data.
*/
if ( _Thread_libc_reent ) {
2008b68: c2 06 21 38 ld [ %i0 + 0x138 ], %g1
&_Thread_Time_of_last_context_switch,
&uptime,
&ran
);
_Timestamp_Add_to( &executing->cpu_time_used, &ran );
_Thread_Time_of_last_context_switch = uptime;
2008b6c: c4 26 80 00 st %g2, [ %i2 ]
2008b70: c4 07 bf f4 ld [ %fp + -12 ], %g2
#endif
/*
* Switch libc's task specific data.
*/
if ( _Thread_libc_reent ) {
2008b74: 80 a0 60 00 cmp %g1, 0
2008b78: 02 80 00 06 be 2008b90 <_Thread_Dispatch+0xb8> <== NEVER TAKEN
2008b7c: c4 26 a0 04 st %g2, [ %i2 + 4 ]
executing->libc_reent = *_Thread_libc_reent;
2008b80: c4 00 40 00 ld [ %g1 ], %g2
2008b84: c4 27 61 54 st %g2, [ %i5 + 0x154 ]
*_Thread_libc_reent = heir->libc_reent;
2008b88: c4 07 21 54 ld [ %i4 + 0x154 ], %g2
2008b8c: c4 20 40 00 st %g2, [ %g1 ]
}
_User_extensions_Thread_switch( executing, heir );
2008b90: 90 10 00 1d mov %i5, %o0
2008b94: 40 00 03 78 call 2009974 <_User_extensions_Thread_switch>
2008b98: 92 10 00 1c mov %i4, %o1
if ( executing->fp_context != NULL )
_Context_Save_fp( &executing->fp_context );
#endif
#endif
_Context_Switch( &executing->Registers, &heir->Registers );
2008b9c: 90 07 60 c8 add %i5, 0xc8, %o0
2008ba0: 40 00 04 9e call 2009e18 <_CPU_Context_switch>
2008ba4: 92 07 20 c8 add %i4, 0xc8, %o1
#if ( CPU_HARDWARE_FP == TRUE ) || ( CPU_SOFTWARE_FP == TRUE )
#if ( CPU_USE_DEFERRED_FP_SWITCH == TRUE )
if ( (executing->fp_context != NULL) &&
2008ba8: c2 07 61 50 ld [ %i5 + 0x150 ], %g1
2008bac: 80 a0 60 00 cmp %g1, 0
2008bb0: 02 80 00 0c be 2008be0 <_Thread_Dispatch+0x108>
2008bb4: d0 06 e1 34 ld [ %i3 + 0x134 ], %o0
2008bb8: 80 a7 40 08 cmp %i5, %o0
2008bbc: 02 80 00 09 be 2008be0 <_Thread_Dispatch+0x108>
2008bc0: 80 a2 20 00 cmp %o0, 0
!_Thread_Is_allocated_fp( executing ) ) {
if ( _Thread_Allocated_fp != NULL )
2008bc4: 02 80 00 04 be 2008bd4 <_Thread_Dispatch+0xfc>
2008bc8: 01 00 00 00 nop
_Context_Save_fp( &_Thread_Allocated_fp->fp_context );
2008bcc: 40 00 04 59 call 2009d30 <_CPU_Context_save_fp>
2008bd0: 90 02 21 50 add %o0, 0x150, %o0
_Context_Restore_fp( &executing->fp_context );
2008bd4: 40 00 04 74 call 2009da4 <_CPU_Context_restore_fp>
2008bd8: 90 07 61 50 add %i5, 0x150, %o0
_Thread_Allocated_fp = executing;
2008bdc: fa 26 e1 34 st %i5, [ %i3 + 0x134 ]
if ( executing->fp_context != NULL )
_Context_Restore_fp( &executing->fp_context );
#endif
#endif
executing = _Thread_Executing;
2008be0: 82 16 62 dc or %i1, 0x2dc, %g1
_ISR_Disable( level );
2008be4: 7f ff e5 66 call 200217c <sparc_disable_interrupts>
2008be8: fa 00 60 0c ld [ %g1 + 0xc ], %i5
/*
* Now determine if we need to perform a dispatch on the current CPU.
*/
executing = _Thread_Executing;
_ISR_Disable( level );
while ( _Thread_Dispatch_necessary == true ) {
2008bec: 82 16 62 dc or %i1, 0x2dc, %g1
2008bf0: c4 08 60 18 ldub [ %g1 + 0x18 ], %g2
2008bf4: 80 a0 a0 00 cmp %g2, 0
2008bf8: 32 bf ff c7 bne,a 2008b14 <_Thread_Dispatch+0x3c>
2008bfc: f8 00 60 10 ld [ %g1 + 0x10 ], %i4
* This routine sets thread dispatch level to the
* value passed in.
*/
RTEMS_INLINE_ROUTINE uint32_t _Thread_Dispatch_set_disable_level(uint32_t value)
{
_Thread_Dispatch_disable_level = value;
2008c00: 03 00 80 6d sethi %hi(0x201b400), %g1
2008c04: c0 20 60 b0 clr [ %g1 + 0xb0 ] ! 201b4b0 <_Thread_Dispatch_disable_level>
}
post_switch:
_Thread_Dispatch_set_disable_level( 0 );
_ISR_Enable( level );
2008c08: 7f ff e5 61 call 200218c <sparc_enable_interrupts>
2008c0c: 01 00 00 00 nop
_API_extensions_Run_postswitch();
2008c10: 7f ff f8 5a call 2006d78 <_API_extensions_Run_postswitch>
2008c14: 01 00 00 00 nop
}
2008c18: 81 c7 e0 08 ret
2008c1c: 81 e8 00 00 restore
0200dac8 <_Thread_Handler>:
*
* Output parameters: NONE
*/
void _Thread_Handler( void )
{
200dac8: 9d e3 bf a0 save %sp, -96, %sp
#if defined(EXECUTE_GLOBAL_CONSTRUCTORS)
static char doneConstructors;
char doneCons;
#endif
executing = _Thread_Executing;
200dacc: 03 00 80 6d sethi %hi(0x201b400), %g1
200dad0: fa 00 62 e8 ld [ %g1 + 0x2e8 ], %i5 ! 201b6e8 <_Per_CPU_Information+0xc>
/*
* Some CPUs need to tinker with the call frame or registers when the
* thread actually begins to execute for the first time. This is a
* hook point where the port gets a shot at doing whatever it requires.
*/
_Context_Initialization_at_thread_begin();
200dad4: 3f 00 80 36 sethi %hi(0x200d800), %i7
200dad8: be 17 e2 c8 or %i7, 0x2c8, %i7 ! 200dac8 <_Thread_Handler>
/*
* have to put level into a register for those cpu's that use
* inline asm here
*/
level = executing->Start.isr_level;
200dadc: d0 07 60 ac ld [ %i5 + 0xac ], %o0
_ISR_Set_level(level);
200dae0: 7f ff d1 ab call 200218c <sparc_enable_interrupts>
200dae4: 91 2a 20 08 sll %o0, 8, %o0
#if defined(EXECUTE_GLOBAL_CONSTRUCTORS)
doneCons = doneConstructors;
200dae8: 03 00 80 6c sethi %hi(0x201b000), %g1
doneConstructors = 1;
200daec: 84 10 20 01 mov 1, %g2
level = executing->Start.isr_level;
_ISR_Set_level(level);
#if defined(EXECUTE_GLOBAL_CONSTRUCTORS)
doneCons = doneConstructors;
200daf0: f8 08 61 70 ldub [ %g1 + 0x170 ], %i4
doneConstructors = 1;
200daf4: c4 28 61 70 stb %g2, [ %g1 + 0x170 ]
#endif
#if ( CPU_HARDWARE_FP == TRUE ) || ( CPU_SOFTWARE_FP == TRUE )
#if ( CPU_USE_DEFERRED_FP_SWITCH == TRUE )
if ( (executing->fp_context != NULL) &&
200daf8: c2 07 61 50 ld [ %i5 + 0x150 ], %g1
200dafc: 80 a0 60 00 cmp %g1, 0
200db00: 02 80 00 0c be 200db30 <_Thread_Handler+0x68>
200db04: 03 00 80 6d sethi %hi(0x201b400), %g1
#if ( CPU_HARDWARE_FP == TRUE ) || ( CPU_SOFTWARE_FP == TRUE )
RTEMS_INLINE_ROUTINE bool _Thread_Is_allocated_fp (
const Thread_Control *the_thread
)
{
return ( the_thread == _Thread_Allocated_fp );
200db08: d0 00 61 34 ld [ %g1 + 0x134 ], %o0 ! 201b534 <_Thread_Allocated_fp>
200db0c: 80 a7 40 08 cmp %i5, %o0
200db10: 02 80 00 08 be 200db30 <_Thread_Handler+0x68>
200db14: 80 a2 20 00 cmp %o0, 0
!_Thread_Is_allocated_fp( executing ) ) {
if ( _Thread_Allocated_fp != NULL )
200db18: 22 80 00 06 be,a 200db30 <_Thread_Handler+0x68>
200db1c: fa 20 61 34 st %i5, [ %g1 + 0x134 ]
_Context_Save_fp( &_Thread_Allocated_fp->fp_context );
200db20: 7f ff f0 84 call 2009d30 <_CPU_Context_save_fp>
200db24: 90 02 21 50 add %o0, 0x150, %o0
_Thread_Allocated_fp = executing;
200db28: 03 00 80 6d sethi %hi(0x201b400), %g1
200db2c: fa 20 61 34 st %i5, [ %g1 + 0x134 ] ! 201b534 <_Thread_Allocated_fp>
/*
* Take care that 'begin' extensions get to complete before
* 'switch' extensions can run. This means must keep dispatch
* disabled until all 'begin' extensions complete.
*/
_User_extensions_Thread_begin( executing );
200db30: 7f ff ef 22 call 20097b8 <_User_extensions_Thread_begin>
200db34: 90 10 00 1d mov %i5, %o0
/*
* At this point, the dispatch disable level BETTER be 1.
*/
_Thread_Enable_dispatch();
200db38: 7f ff ec 3a call 2008c20 <_Thread_Enable_dispatch>
200db3c: b9 2f 20 18 sll %i4, 0x18, %i4
/*
* _init could be a weak symbol and we SHOULD test it but it isn't
* in any configuration I know of and it generates a warning on every
* RTEMS target configuration. --joel (12 May 2007)
*/
if (!doneCons) /* && (volatile void *)_init) */ {
200db40: 80 a7 20 00 cmp %i4, 0
200db44: 32 80 00 05 bne,a 200db58 <_Thread_Handler+0x90>
200db48: c2 07 60 94 ld [ %i5 + 0x94 ], %g1
INIT_NAME ();
200db4c: 40 00 33 0f call 201a788 <_init>
200db50: 01 00 00 00 nop
#endif
}
#endif
if ( executing->Start.prototype == THREAD_START_NUMERIC ) {
200db54: c2 07 60 94 ld [ %i5 + 0x94 ], %g1
200db58: 80 a0 60 00 cmp %g1, 0
200db5c: 12 80 00 06 bne 200db74 <_Thread_Handler+0xac> <== NEVER TAKEN
200db60: 01 00 00 00 nop
executing->Wait.return_argument =
(*(Thread_Entry_numeric) executing->Start.entry_point)(
200db64: c2 07 60 90 ld [ %i5 + 0x90 ], %g1
200db68: 9f c0 40 00 call %g1
200db6c: d0 07 60 9c ld [ %i5 + 0x9c ], %o0
}
#endif
if ( executing->Start.prototype == THREAD_START_NUMERIC ) {
executing->Wait.return_argument =
200db70: d0 27 60 28 st %o0, [ %i5 + 0x28 ]
* was placed in return_argument. This assumed that if it returned
* anything (which is not supporting in all APIs), then it would be
* able to fit in a (void *).
*/
_User_extensions_Thread_exitted( executing );
200db74: 7f ff ef 22 call 20097fc <_User_extensions_Thread_exitted>
200db78: 90 10 00 1d mov %i5, %o0
_Internal_error_Occurred(
200db7c: 90 10 20 00 clr %o0
200db80: 92 10 20 01 mov 1, %o1
200db84: 7f ff e7 20 call 2007804 <_Internal_error_Occurred>
200db88: 94 10 20 05 mov 5, %o2
02008d04 <_Thread_Initialize>:
Thread_CPU_budget_algorithms budget_algorithm,
Thread_CPU_budget_algorithm_callout budget_callout,
uint32_t isr_level,
Objects_Name name
)
{
2008d04: 9d e3 bf a0 save %sp, -96, %sp
2008d08: c2 07 a0 6c ld [ %fp + 0x6c ], %g1
2008d0c: f4 0f a0 5f ldub [ %fp + 0x5f ], %i2
2008d10: e0 00 40 00 ld [ %g1 ], %l0
/*
* Zero out all the allocated memory fields
*/
for ( i=0 ; i <= THREAD_API_LAST ; i++ )
the_thread->API_Extensions[i] = NULL;
2008d14: c0 26 61 58 clr [ %i1 + 0x158 ]
2008d18: c0 26 61 5c clr [ %i1 + 0x15c ]
extensions_area = NULL;
the_thread->libc_reent = NULL;
2008d1c: c0 26 61 54 clr [ %i1 + 0x154 ]
/*
* Allocate and Initialize the stack for this thread.
*/
#if !defined(RTEMS_SCORE_THREAD_ENABLE_USER_PROVIDED_STACK_VIA_API)
actual_stack_size = _Thread_Stack_Allocate( the_thread, stack_size );
2008d20: 90 10 00 19 mov %i1, %o0
2008d24: 40 00 02 02 call 200952c <_Thread_Stack_Allocate>
2008d28: 92 10 00 1b mov %i3, %o1
if ( !actual_stack_size || actual_stack_size < stack_size )
2008d2c: 80 a2 00 1b cmp %o0, %i3
2008d30: 0a 80 00 61 bcs 2008eb4 <_Thread_Initialize+0x1b0>
2008d34: 80 a2 20 00 cmp %o0, 0
2008d38: 02 80 00 5f be 2008eb4 <_Thread_Initialize+0x1b0> <== NEVER TAKEN
2008d3c: 80 a7 20 00 cmp %i4, 0
Stack_Control *the_stack,
void *starting_address,
size_t size
)
{
the_stack->area = starting_address;
2008d40: c2 06 60 c0 ld [ %i1 + 0xc0 ], %g1
the_stack->size = size;
2008d44: d0 26 60 b4 st %o0, [ %i1 + 0xb4 ]
Stack_Control *the_stack,
void *starting_address,
size_t size
)
{
the_stack->area = starting_address;
2008d48: c2 26 60 b8 st %g1, [ %i1 + 0xb8 ]
/*
* Allocate the floating point area for this thread
*/
#if ( CPU_HARDWARE_FP == TRUE ) || ( CPU_SOFTWARE_FP == TRUE )
if ( is_fp ) {
2008d4c: 02 80 00 07 be 2008d68 <_Thread_Initialize+0x64>
2008d50: b6 10 20 00 clr %i3
fp_area = _Workspace_Allocate( CONTEXT_FP_SIZE );
2008d54: 40 00 03 db call 2009cc0 <_Workspace_Allocate>
2008d58: 90 10 20 88 mov 0x88, %o0
if ( !fp_area )
2008d5c: b6 92 20 00 orcc %o0, 0, %i3
2008d60: 02 80 00 46 be 2008e78 <_Thread_Initialize+0x174>
2008d64: b8 10 20 00 clr %i4
#endif
/*
* Allocate the extensions area for this thread
*/
if ( _Thread_Maximum_extensions ) {
2008d68: 03 00 80 6d sethi %hi(0x201b400), %g1
2008d6c: d0 00 61 44 ld [ %g1 + 0x144 ], %o0 ! 201b544 <_Thread_Maximum_extensions>
fp_area = _Workspace_Allocate( CONTEXT_FP_SIZE );
if ( !fp_area )
goto failed;
fp_area = _Context_Fp_start( fp_area, 0 );
}
the_thread->fp_context = fp_area;
2008d70: f6 26 61 50 st %i3, [ %i1 + 0x150 ]
the_thread->Start.fp_context = fp_area;
2008d74: f6 26 60 bc st %i3, [ %i1 + 0xbc ]
Watchdog_Service_routine_entry routine,
Objects_Id id,
void *user_data
)
{
the_watchdog->state = WATCHDOG_INACTIVE;
2008d78: c0 26 60 50 clr [ %i1 + 0x50 ]
the_watchdog->routine = routine;
2008d7c: c0 26 60 64 clr [ %i1 + 0x64 ]
the_watchdog->id = id;
2008d80: c0 26 60 68 clr [ %i1 + 0x68 ]
the_watchdog->user_data = user_data;
2008d84: c0 26 60 6c clr [ %i1 + 0x6c ]
#endif
/*
* Allocate the extensions area for this thread
*/
if ( _Thread_Maximum_extensions ) {
2008d88: 80 a2 20 00 cmp %o0, 0
2008d8c: 02 80 00 08 be 2008dac <_Thread_Initialize+0xa8>
2008d90: b8 10 20 00 clr %i4
extensions_area = _Workspace_Allocate(
2008d94: 90 02 20 01 inc %o0
2008d98: 40 00 03 ca call 2009cc0 <_Workspace_Allocate>
2008d9c: 91 2a 20 02 sll %o0, 2, %o0
(_Thread_Maximum_extensions + 1) * sizeof( void * )
);
if ( !extensions_area )
2008da0: b8 92 20 00 orcc %o0, 0, %i4
2008da4: 22 80 00 36 be,a 2008e7c <_Thread_Initialize+0x178>
2008da8: b4 10 20 00 clr %i2
* if they are linked to the thread. An extension user may
* create the extension long after tasks have been created
* so they cannot rely on the thread create user extension
* call.
*/
if ( the_thread->extensions ) {
2008dac: 80 a7 20 00 cmp %i4, 0
2008db0: 02 80 00 0c be 2008de0 <_Thread_Initialize+0xdc>
2008db4: f8 26 61 60 st %i4, [ %i1 + 0x160 ]
for ( i = 0; i <= _Thread_Maximum_extensions ; i++ )
2008db8: 03 00 80 6d sethi %hi(0x201b400), %g1
2008dbc: c4 00 61 44 ld [ %g1 + 0x144 ], %g2 ! 201b544 <_Thread_Maximum_extensions>
2008dc0: 10 80 00 05 b 2008dd4 <_Thread_Initialize+0xd0>
2008dc4: 82 10 20 00 clr %g1
the_thread->extensions[i] = NULL;
2008dc8: 87 28 60 02 sll %g1, 2, %g3
* create the extension long after tasks have been created
* so they cannot rely on the thread create user extension
* call.
*/
if ( the_thread->extensions ) {
for ( i = 0; i <= _Thread_Maximum_extensions ; i++ )
2008dcc: 82 00 60 01 inc %g1
the_thread->extensions[i] = NULL;
2008dd0: c0 21 00 03 clr [ %g4 + %g3 ]
* create the extension long after tasks have been created
* so they cannot rely on the thread create user extension
* call.
*/
if ( the_thread->extensions ) {
for ( i = 0; i <= _Thread_Maximum_extensions ; i++ )
2008dd4: 80 a0 40 02 cmp %g1, %g2
2008dd8: 28 bf ff fc bleu,a 2008dc8 <_Thread_Initialize+0xc4>
2008ddc: c8 06 61 60 ld [ %i1 + 0x160 ], %g4
/*
* General initialization
*/
the_thread->Start.is_preemptible = is_preemptible;
the_thread->Start.budget_algorithm = budget_algorithm;
2008de0: c2 07 a0 60 ld [ %fp + 0x60 ], %g1
/*
* General initialization
*/
the_thread->Start.is_preemptible = is_preemptible;
2008de4: f4 2e 60 a0 stb %i2, [ %i1 + 0xa0 ]
the_thread->Start.budget_algorithm = budget_algorithm;
2008de8: c2 26 60 a4 st %g1, [ %i1 + 0xa4 ]
the_thread->Start.budget_callout = budget_callout;
2008dec: c2 07 a0 64 ld [ %fp + 0x64 ], %g1
}
the_thread->Start.isr_level = isr_level;
the_thread->current_state = STATES_DORMANT;
the_thread->Wait.queue = NULL;
2008df0: c0 26 60 44 clr [ %i1 + 0x44 ]
* General initialization
*/
the_thread->Start.is_preemptible = is_preemptible;
the_thread->Start.budget_algorithm = budget_algorithm;
the_thread->Start.budget_callout = budget_callout;
2008df4: c2 26 60 a8 st %g1, [ %i1 + 0xa8 ]
case THREAD_CPU_BUDGET_ALGORITHM_CALLOUT:
break;
#endif
}
the_thread->Start.isr_level = isr_level;
2008df8: c2 07 a0 68 ld [ %fp + 0x68 ], %g1
the_thread->current_state = STATES_DORMANT;
the_thread->Wait.queue = NULL;
the_thread->resource_count = 0;
2008dfc: c0 26 60 1c clr [ %i1 + 0x1c ]
case THREAD_CPU_BUDGET_ALGORITHM_CALLOUT:
break;
#endif
}
the_thread->Start.isr_level = isr_level;
2008e00: c2 26 60 ac st %g1, [ %i1 + 0xac ]
the_thread->current_state = STATES_DORMANT;
2008e04: 82 10 20 01 mov 1, %g1
2008e08: c2 26 60 10 st %g1, [ %i1 + 0x10 ]
*/
RTEMS_INLINE_ROUTINE void* _Scheduler_Allocate(
Thread_Control *the_thread
)
{
return _Scheduler.Operations.allocate( the_thread );
2008e0c: 03 00 80 6a sethi %hi(0x201a800), %g1
2008e10: c2 00 60 cc ld [ %g1 + 0xcc ], %g1 ! 201a8cc <_Scheduler+0x18>
the_thread->Wait.queue = NULL;
the_thread->resource_count = 0;
the_thread->real_priority = priority;
2008e14: fa 26 60 18 st %i5, [ %i1 + 0x18 ]
the_thread->Start.initial_priority = priority;
2008e18: fa 26 60 b0 st %i5, [ %i1 + 0xb0 ]
2008e1c: 9f c0 40 00 call %g1
2008e20: 90 10 00 19 mov %i1, %o0
sched =_Scheduler_Allocate( the_thread );
if ( !sched )
2008e24: b4 92 20 00 orcc %o0, 0, %i2
2008e28: 02 80 00 15 be 2008e7c <_Thread_Initialize+0x178>
2008e2c: 90 10 00 19 mov %i1, %o0
goto failed;
_Thread_Set_priority( the_thread, priority );
2008e30: 40 00 01 97 call 200948c <_Thread_Set_priority>
2008e34: 92 10 00 1d mov %i5, %o1
#if defined(RTEMS_DEBUG)
if ( index > information->maximum )
return;
#endif
information->local_table[ index ] = the_object;
2008e38: c4 06 20 1c ld [ %i0 + 0x1c ], %g2
Objects_Information *information,
Objects_Control *the_object,
Objects_Name name
)
{
_Objects_Set_local_object(
2008e3c: c2 16 60 0a lduh [ %i1 + 0xa ], %g1
/*
* Initialize the CPU usage statistics
*/
#ifndef __RTEMS_USE_TICKS_FOR_STATISTICS__
_Timestamp_Set_to_zero( &the_thread->cpu_time_used );
2008e40: c0 26 60 84 clr [ %i1 + 0x84 ]
2008e44: c0 26 60 88 clr [ %i1 + 0x88 ]
#if defined(RTEMS_DEBUG)
if ( index > information->maximum )
return;
#endif
information->local_table[ index ] = the_object;
2008e48: 83 28 60 02 sll %g1, 2, %g1
2008e4c: f2 20 80 01 st %i1, [ %g2 + %g1 ]
information,
_Objects_Get_index( the_object->id ),
the_object
);
the_object->name = name;
2008e50: e0 26 60 0c st %l0, [ %i1 + 0xc ]
* enabled when we get here. We want to be able to run the
* user extensions with dispatching enabled. The Allocator
* Mutex provides sufficient protection to let the user extensions
* run safely.
*/
extension_status = _User_extensions_Thread_create( the_thread );
2008e54: 90 10 00 19 mov %i1, %o0
2008e58: 40 00 02 8a call 2009880 <_User_extensions_Thread_create>
2008e5c: b0 10 20 01 mov 1, %i0
if ( extension_status )
2008e60: 80 8a 20 ff btst 0xff, %o0
2008e64: 02 80 00 06 be 2008e7c <_Thread_Initialize+0x178>
2008e68: 01 00 00 00 nop
2008e6c: b0 0e 20 01 and %i0, 1, %i0
2008e70: 81 c7 e0 08 ret
2008e74: 81 e8 00 00 restore
size_t actual_stack_size = 0;
void *stack = NULL;
#if ( CPU_HARDWARE_FP == TRUE ) || ( CPU_SOFTWARE_FP == TRUE )
void *fp_area;
#endif
void *sched = NULL;
2008e78: b4 10 20 00 clr %i2
extension_status = _User_extensions_Thread_create( the_thread );
if ( extension_status )
return true;
failed:
_Workspace_Free( the_thread->libc_reent );
2008e7c: 40 00 03 99 call 2009ce0 <_Workspace_Free>
2008e80: d0 06 61 54 ld [ %i1 + 0x154 ], %o0
for ( i=0 ; i <= THREAD_API_LAST ; i++ )
_Workspace_Free( the_thread->API_Extensions[i] );
2008e84: 40 00 03 97 call 2009ce0 <_Workspace_Free>
2008e88: d0 06 61 58 ld [ %i1 + 0x158 ], %o0
2008e8c: 40 00 03 95 call 2009ce0 <_Workspace_Free>
2008e90: d0 06 61 5c ld [ %i1 + 0x15c ], %o0
_Workspace_Free( extensions_area );
2008e94: 40 00 03 93 call 2009ce0 <_Workspace_Free>
2008e98: 90 10 00 1c mov %i4, %o0
#if ( CPU_HARDWARE_FP == TRUE ) || ( CPU_SOFTWARE_FP == TRUE )
_Workspace_Free( fp_area );
2008e9c: 40 00 03 91 call 2009ce0 <_Workspace_Free>
2008ea0: 90 10 00 1b mov %i3, %o0
#endif
_Workspace_Free( sched );
2008ea4: 40 00 03 8f call 2009ce0 <_Workspace_Free>
2008ea8: 90 10 00 1a mov %i2, %o0
_Thread_Stack_Free( the_thread );
2008eac: 40 00 01 b7 call 2009588 <_Thread_Stack_Free>
2008eb0: 90 10 00 19 mov %i1, %o0
* Allocate and Initialize the stack for this thread.
*/
#if !defined(RTEMS_SCORE_THREAD_ENABLE_USER_PROVIDED_STACK_VIA_API)
actual_stack_size = _Thread_Stack_Allocate( the_thread, stack_size );
if ( !actual_stack_size || actual_stack_size < stack_size )
return false; /* stack allocation failed */
2008eb4: b0 10 20 00 clr %i0
_Workspace_Free( sched );
_Thread_Stack_Free( the_thread );
return false;
}
2008eb8: b0 0e 20 01 and %i0, 1, %i0
2008ebc: 81 c7 e0 08 ret
2008ec0: 81 e8 00 00 restore
020093d4 <_Thread_queue_Requeue>:
void _Thread_queue_Requeue(
Thread_queue_Control *the_thread_queue,
Thread_Control *the_thread
)
{
20093d4: 9d e3 bf 98 save %sp, -104, %sp
/*
* Just in case the thread really wasn't blocked on a thread queue
* when we get here.
*/
if ( !the_thread_queue )
20093d8: 80 a6 20 00 cmp %i0, 0
20093dc: 02 80 00 19 be 2009440 <_Thread_queue_Requeue+0x6c> <== NEVER TAKEN
20093e0: 01 00 00 00 nop
/*
* If queueing by FIFO, there is nothing to do. This only applies to
* priority blocking discipline.
*/
if ( the_thread_queue->discipline == THREAD_QUEUE_DISCIPLINE_PRIORITY ) {
20093e4: f8 06 20 34 ld [ %i0 + 0x34 ], %i4
20093e8: 80 a7 20 01 cmp %i4, 1
20093ec: 12 80 00 15 bne 2009440 <_Thread_queue_Requeue+0x6c> <== NEVER TAKEN
20093f0: 01 00 00 00 nop
Thread_queue_Control *tq = the_thread_queue;
ISR_Level level;
ISR_Level level_ignored;
_ISR_Disable( level );
20093f4: 7f ff e3 62 call 200217c <sparc_disable_interrupts>
20093f8: 01 00 00 00 nop
20093fc: ba 10 00 08 mov %o0, %i5
2009400: c4 06 60 10 ld [ %i1 + 0x10 ], %g2
if ( _States_Is_waiting_on_thread_queue( the_thread->current_state ) ) {
2009404: 03 00 00 ef sethi %hi(0x3bc00), %g1
2009408: 82 10 62 e0 or %g1, 0x2e0, %g1 ! 3bee0 <PROM_START+0x3bee0>
200940c: 80 88 80 01 btst %g2, %g1
2009410: 02 80 00 0a be 2009438 <_Thread_queue_Requeue+0x64> <== NEVER TAKEN
2009414: 90 10 00 18 mov %i0, %o0
_Thread_queue_Enter_critical_section( tq );
_Thread_queue_Extract_priority_helper( tq, the_thread, true );
2009418: 92 10 00 19 mov %i1, %o1
200941c: 94 10 20 01 mov 1, %o2
2009420: 40 00 0b f8 call 200c400 <_Thread_queue_Extract_priority_helper>
2009424: f8 26 20 30 st %i4, [ %i0 + 0x30 ]
(void) _Thread_queue_Enqueue_priority( tq, the_thread, &level_ignored );
2009428: 90 10 00 18 mov %i0, %o0
200942c: 92 10 00 19 mov %i1, %o1
2009430: 7f ff ff 50 call 2009170 <_Thread_queue_Enqueue_priority>
2009434: 94 07 bf fc add %fp, -4, %o2
}
_ISR_Enable( level );
2009438: 7f ff e3 55 call 200218c <sparc_enable_interrupts>
200943c: 90 10 00 1d mov %i5, %o0
2009440: 81 c7 e0 08 ret
2009444: 81 e8 00 00 restore
02009448 <_Thread_queue_Timeout>:
void _Thread_queue_Timeout(
Objects_Id id,
void *ignored __attribute__((unused))
)
{
2009448: 9d e3 bf 98 save %sp, -104, %sp
Thread_Control *the_thread;
Objects_Locations location;
the_thread = _Thread_Get( id, &location );
200944c: 90 10 00 18 mov %i0, %o0
2009450: 7f ff fe 01 call 2008c54 <_Thread_Get>
2009454: 92 07 bf fc add %fp, -4, %o1
switch ( location ) {
2009458: c2 07 bf fc ld [ %fp + -4 ], %g1
200945c: 80 a0 60 00 cmp %g1, 0
2009460: 12 80 00 09 bne 2009484 <_Thread_queue_Timeout+0x3c> <== NEVER TAKEN
2009464: 01 00 00 00 nop
#if defined(RTEMS_MULTIPROCESSING)
case OBJECTS_REMOTE: /* impossible */
#endif
break;
case OBJECTS_LOCAL:
_Thread_queue_Process_timeout( the_thread );
2009468: 40 00 0c 1d call 200c4dc <_Thread_queue_Process_timeout>
200946c: 01 00 00 00 nop
*
* This routine decrements the thread dispatch level.
*/
RTEMS_INLINE_ROUTINE uint32_t _Thread_Dispatch_decrement_disable_level(void)
{
_Thread_Dispatch_disable_level--;
2009470: 03 00 80 6d sethi %hi(0x201b400), %g1
2009474: c4 00 60 b0 ld [ %g1 + 0xb0 ], %g2 ! 201b4b0 <_Thread_Dispatch_disable_level>
2009478: 84 00 bf ff add %g2, -1, %g2
200947c: c4 20 60 b0 st %g2, [ %g1 + 0xb0 ]
return _Thread_Dispatch_disable_level;
2009480: c2 00 60 b0 ld [ %g1 + 0xb0 ], %g1
2009484: 81 c7 e0 08 ret
2009488: 81 e8 00 00 restore
0201718c <_Timer_server_Body>:
* @a arg points to the corresponding timer server control block.
*/
static rtems_task _Timer_server_Body(
rtems_task_argument arg
)
{
201718c: 9d e3 bf 88 save %sp, -120, %sp
static void _Timer_server_Process_interval_watchdogs(
Timer_server_Watchdogs *watchdogs,
Chain_Control *fire_chain
)
{
Watchdog_Interval snapshot = _Watchdog_Ticks_since_boot;
2017190: 27 00 80 e8 sethi %hi(0x203a000), %l3
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *tail = _Chain_Tail( the_chain );
head->next = tail;
2017194: a8 07 bf e8 add %fp, -24, %l4
2017198: a4 07 bf ec add %fp, -20, %l2
201719c: b6 07 bf f4 add %fp, -12, %i3
20171a0: b4 07 bf f8 add %fp, -8, %i2
20171a4: e4 27 bf e8 st %l2, [ %fp + -24 ]
head->previous = NULL;
20171a8: c0 27 bf ec clr [ %fp + -20 ]
tail->previous = head;
20171ac: e8 27 bf f0 st %l4, [ %fp + -16 ]
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *tail = _Chain_Tail( the_chain );
head->next = tail;
20171b0: f4 27 bf f4 st %i2, [ %fp + -12 ]
head->previous = NULL;
20171b4: c0 27 bf f8 clr [ %fp + -8 ]
tail->previous = head;
20171b8: f6 27 bf fc st %i3, [ %fp + -4 ]
*/
Watchdog_Interval delta = snapshot - watchdogs->last_snapshot;
watchdogs->last_snapshot = snapshot;
_Watchdog_Adjust_to_chain( &watchdogs->Chain, delta, fire_chain );
20171bc: b2 06 20 30 add %i0, 0x30, %i1
/*
* The current TOD is before the last TOD which indicates that
* TOD has been set backwards.
*/
delta = last_snapshot - snapshot;
_Watchdog_Adjust( &watchdogs->Chain, WATCHDOG_BACKWARD, delta );
20171c0: b8 06 20 68 add %i0, 0x68, %i4
static void _Timer_server_Stop_interval_system_watchdog(
Timer_server_Control *ts
)
{
_Watchdog_Remove( &ts->Interval_watchdogs.System_watchdog );
20171c4: a2 06 20 08 add %i0, 8, %l1
static void _Timer_server_Stop_tod_system_watchdog(
Timer_server_Control *ts
)
{
_Watchdog_Remove( &ts->TOD_watchdogs.System_watchdog );
20171c8: a0 06 20 40 add %i0, 0x40, %l0
{
/*
* Afterwards all timer inserts are directed to this chain and the interval
* and TOD chains will be no more modified by other parties.
*/
ts->insert_chain = insert_chain;
20171cc: e8 26 20 78 st %l4, [ %i0 + 0x78 ]
static void _Timer_server_Process_tod_watchdogs(
Timer_server_Watchdogs *watchdogs,
Chain_Control *fire_chain
)
{
Watchdog_Interval snapshot = (Watchdog_Interval) _TOD_Seconds_since_epoch();
20171d0: 2b 00 80 e8 sethi %hi(0x203a000), %l5
static void _Timer_server_Process_interval_watchdogs(
Timer_server_Watchdogs *watchdogs,
Chain_Control *fire_chain
)
{
Watchdog_Interval snapshot = _Watchdog_Ticks_since_boot;
20171d4: c2 04 e0 ac ld [ %l3 + 0xac ], %g1
/*
* We assume adequate unsigned arithmetic here.
*/
Watchdog_Interval delta = snapshot - watchdogs->last_snapshot;
20171d8: d2 06 20 3c ld [ %i0 + 0x3c ], %o1
watchdogs->last_snapshot = snapshot;
_Watchdog_Adjust_to_chain( &watchdogs->Chain, delta, fire_chain );
20171dc: 94 10 00 1b mov %i3, %o2
/*
* We assume adequate unsigned arithmetic here.
*/
Watchdog_Interval delta = snapshot - watchdogs->last_snapshot;
watchdogs->last_snapshot = snapshot;
20171e0: c2 26 20 3c st %g1, [ %i0 + 0x3c ]
_Watchdog_Adjust_to_chain( &watchdogs->Chain, delta, fire_chain );
20171e4: 90 10 00 19 mov %i1, %o0
20171e8: 40 00 11 77 call 201b7c4 <_Watchdog_Adjust_to_chain>
20171ec: 92 20 40 09 sub %g1, %o1, %o1
Timer_server_Watchdogs *watchdogs,
Chain_Control *fire_chain
)
{
Watchdog_Interval snapshot = (Watchdog_Interval) _TOD_Seconds_since_epoch();
Watchdog_Interval last_snapshot = watchdogs->last_snapshot;
20171f0: d4 06 20 74 ld [ %i0 + 0x74 ], %o2
static void _Timer_server_Process_tod_watchdogs(
Timer_server_Watchdogs *watchdogs,
Chain_Control *fire_chain
)
{
Watchdog_Interval snapshot = (Watchdog_Interval) _TOD_Seconds_since_epoch();
20171f4: fa 05 60 2c ld [ %l5 + 0x2c ], %i5
/*
* Process the seconds chain. Start by checking that the Time
* of Day (TOD) has not been set backwards. If it has then
* we want to adjust the watchdogs->Chain to indicate this.
*/
if ( snapshot > last_snapshot ) {
20171f8: 80 a7 40 0a cmp %i5, %o2
20171fc: 08 80 00 06 bleu 2017214 <_Timer_server_Body+0x88>
2017200: 92 27 40 0a sub %i5, %o2, %o1
/*
* This path is for normal forward movement and cases where the
* TOD has been set forward.
*/
delta = snapshot - last_snapshot;
_Watchdog_Adjust_to_chain( &watchdogs->Chain, delta, fire_chain );
2017204: 90 10 00 1c mov %i4, %o0
2017208: 40 00 11 6f call 201b7c4 <_Watchdog_Adjust_to_chain>
201720c: 94 10 00 1b mov %i3, %o2
2017210: 30 80 00 06 b,a 2017228 <_Timer_server_Body+0x9c>
} else if ( snapshot < last_snapshot ) {
2017214: 1a 80 00 05 bcc 2017228 <_Timer_server_Body+0x9c>
2017218: 90 10 00 1c mov %i4, %o0
/*
* The current TOD is before the last TOD which indicates that
* TOD has been set backwards.
*/
delta = last_snapshot - snapshot;
_Watchdog_Adjust( &watchdogs->Chain, WATCHDOG_BACKWARD, delta );
201721c: 92 10 20 01 mov 1, %o1
2017220: 40 00 11 42 call 201b728 <_Watchdog_Adjust>
2017224: 94 22 80 1d sub %o2, %i5, %o2
}
watchdogs->last_snapshot = snapshot;
2017228: fa 26 20 74 st %i5, [ %i0 + 0x74 ]
}
static void _Timer_server_Process_insertions( Timer_server_Control *ts )
{
while ( true ) {
Timer_Control *timer = (Timer_Control *) _Chain_Get( ts->insert_chain );
201722c: d0 06 20 78 ld [ %i0 + 0x78 ], %o0
2017230: 40 00 02 bd call 2017d24 <_Chain_Get>
2017234: 01 00 00 00 nop
if ( timer == NULL ) {
2017238: 92 92 20 00 orcc %o0, 0, %o1
201723c: 02 80 00 0c be 201726c <_Timer_server_Body+0xe0>
2017240: 01 00 00 00 nop
static void _Timer_server_Insert_timer(
Timer_server_Control *ts,
Timer_Control *timer
)
{
if ( timer->the_class == TIMER_INTERVAL_ON_TASK ) {
2017244: c2 02 60 38 ld [ %o1 + 0x38 ], %g1
2017248: 80 a0 60 01 cmp %g1, 1
201724c: 02 80 00 05 be 2017260 <_Timer_server_Body+0xd4>
2017250: 90 10 00 19 mov %i1, %o0
_Watchdog_Insert( &ts->Interval_watchdogs.Chain, &timer->Ticker );
} else if ( timer->the_class == TIMER_TIME_OF_DAY_ON_TASK ) {
2017254: 80 a0 60 03 cmp %g1, 3
2017258: 12 bf ff f5 bne 201722c <_Timer_server_Body+0xa0> <== NEVER TAKEN
201725c: 90 10 00 1c mov %i4, %o0
_Watchdog_Insert( &ts->TOD_watchdogs.Chain, &timer->Ticker );
2017260: 40 00 11 8b call 201b88c <_Watchdog_Insert>
2017264: 92 02 60 10 add %o1, 0x10, %o1
2017268: 30 bf ff f1 b,a 201722c <_Timer_server_Body+0xa0>
* of zero it will be processed in the next iteration of the timer server
* body loop.
*/
_Timer_server_Process_insertions( ts );
_ISR_Disable( level );
201726c: 7f ff e3 95 call 20100c0 <sparc_disable_interrupts>
2017270: 01 00 00 00 nop
if ( _Chain_Is_empty( insert_chain ) ) {
2017274: c2 07 bf e8 ld [ %fp + -24 ], %g1
2017278: 80 a0 40 12 cmp %g1, %l2
201727c: 12 80 00 0a bne 20172a4 <_Timer_server_Body+0x118> <== NEVER TAKEN
2017280: 01 00 00 00 nop
ts->insert_chain = NULL;
2017284: c0 26 20 78 clr [ %i0 + 0x78 ]
_ISR_Enable( level );
2017288: 7f ff e3 92 call 20100d0 <sparc_enable_interrupts>
201728c: 01 00 00 00 nop
_Chain_Initialize_empty( &fire_chain );
while ( true ) {
_Timer_server_Get_watchdogs_that_fire_now( ts, &insert_chain, &fire_chain );
if ( !_Chain_Is_empty( &fire_chain ) ) {
2017290: c2 07 bf f4 ld [ %fp + -12 ], %g1
2017294: 80 a0 40 1a cmp %g1, %i2
2017298: 12 80 00 06 bne 20172b0 <_Timer_server_Body+0x124>
201729c: 01 00 00 00 nop
20172a0: 30 80 00 18 b,a 2017300 <_Timer_server_Body+0x174>
ts->insert_chain = NULL;
_ISR_Enable( level );
break;
} else {
_ISR_Enable( level );
20172a4: 7f ff e3 8b call 20100d0 <sparc_enable_interrupts> <== NOT EXECUTED
20172a8: 01 00 00 00 nop <== NOT EXECUTED
20172ac: 30 bf ff ca b,a 20171d4 <_Timer_server_Body+0x48> <== NOT EXECUTED
/*
* It is essential that interrupts are disable here since an interrupt
* service routine may remove a watchdog from the chain.
*/
_ISR_Disable( level );
20172b0: 7f ff e3 84 call 20100c0 <sparc_disable_interrupts>
20172b4: 01 00 00 00 nop
*/
RTEMS_INLINE_ROUTINE const Chain_Node *_Chain_Immutable_first(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_head( the_chain )->next;
20172b8: fa 07 bf f4 ld [ %fp + -12 ], %i5
*/
RTEMS_INLINE_ROUTINE Chain_Node *_Chain_Get_unprotected(
Chain_Control *the_chain
)
{
if ( !_Chain_Is_empty(the_chain))
20172bc: 80 a7 40 1a cmp %i5, %i2
20172c0: 02 80 00 0d be 20172f4 <_Timer_server_Body+0x168>
20172c4: 01 00 00 00 nop
Chain_Control *the_chain
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *old_first = head->next;
Chain_Node *new_first = old_first->next;
20172c8: c2 07 40 00 ld [ %i5 ], %g1
head->next = new_first;
new_first->previous = head;
20172cc: f6 20 60 04 st %i3, [ %g1 + 4 ]
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *old_first = head->next;
Chain_Node *new_first = old_first->next;
head->next = new_first;
20172d0: c2 27 bf f4 st %g1, [ %fp + -12 ]
watchdog = (Watchdog_Control *) _Chain_Get_unprotected( &fire_chain );
if ( watchdog != NULL ) {
watchdog->state = WATCHDOG_INACTIVE;
20172d4: c0 27 60 08 clr [ %i5 + 8 ]
_ISR_Enable( level );
20172d8: 7f ff e3 7e call 20100d0 <sparc_enable_interrupts>
20172dc: 01 00 00 00 nop
/*
* The timer server may block here and wait for resources or time.
* The system watchdogs are inactive and will remain inactive since
* the active flag of the timer server is true.
*/
(*watchdog->routine)( watchdog->id, watchdog->user_data );
20172e0: c2 07 60 1c ld [ %i5 + 0x1c ], %g1
20172e4: d0 07 60 20 ld [ %i5 + 0x20 ], %o0
20172e8: 9f c0 40 00 call %g1
20172ec: d2 07 60 24 ld [ %i5 + 0x24 ], %o1
}
20172f0: 30 bf ff f0 b,a 20172b0 <_Timer_server_Body+0x124>
watchdog = (Watchdog_Control *) _Chain_Get_unprotected( &fire_chain );
if ( watchdog != NULL ) {
watchdog->state = WATCHDOG_INACTIVE;
_ISR_Enable( level );
} else {
_ISR_Enable( level );
20172f4: 7f ff e3 77 call 20100d0 <sparc_enable_interrupts>
20172f8: 01 00 00 00 nop
20172fc: 30 bf ff b4 b,a 20171cc <_Timer_server_Body+0x40>
* the active flag of the timer server is true.
*/
(*watchdog->routine)( watchdog->id, watchdog->user_data );
}
} else {
ts->active = false;
2017300: c0 2e 20 7c clrb [ %i0 + 0x7c ]
/*
* Block until there is something to do.
*/
_Thread_Disable_dispatch();
2017304: 7f ff ff 73 call 20170d0 <_Thread_Disable_dispatch>
2017308: 01 00 00 00 nop
_Thread_Set_state( ts->thread, STATES_DELAYING );
201730c: d0 06 00 00 ld [ %i0 ], %o0
2017310: 40 00 0f 92 call 201b158 <_Thread_Set_state>
2017314: 92 10 20 08 mov 8, %o1
_Timer_server_Reset_interval_system_watchdog( ts );
2017318: 7f ff ff 75 call 20170ec <_Timer_server_Reset_interval_system_watchdog>
201731c: 90 10 00 18 mov %i0, %o0
_Timer_server_Reset_tod_system_watchdog( ts );
2017320: 7f ff ff 87 call 201713c <_Timer_server_Reset_tod_system_watchdog>
2017324: 90 10 00 18 mov %i0, %o0
_Thread_Enable_dispatch();
2017328: 40 00 0d 46 call 201a840 <_Thread_Enable_dispatch>
201732c: 01 00 00 00 nop
ts->active = true;
2017330: 82 10 20 01 mov 1, %g1 ! 1 <PROM_START+0x1>
static void _Timer_server_Stop_interval_system_watchdog(
Timer_server_Control *ts
)
{
_Watchdog_Remove( &ts->Interval_watchdogs.System_watchdog );
2017334: 90 10 00 11 mov %l1, %o0
_Thread_Set_state( ts->thread, STATES_DELAYING );
_Timer_server_Reset_interval_system_watchdog( ts );
_Timer_server_Reset_tod_system_watchdog( ts );
_Thread_Enable_dispatch();
ts->active = true;
2017338: c2 2e 20 7c stb %g1, [ %i0 + 0x7c ]
static void _Timer_server_Stop_interval_system_watchdog(
Timer_server_Control *ts
)
{
_Watchdog_Remove( &ts->Interval_watchdogs.System_watchdog );
201733c: 40 00 11 ae call 201b9f4 <_Watchdog_Remove>
2017340: 01 00 00 00 nop
static void _Timer_server_Stop_tod_system_watchdog(
Timer_server_Control *ts
)
{
_Watchdog_Remove( &ts->TOD_watchdogs.System_watchdog );
2017344: 40 00 11 ac call 201b9f4 <_Watchdog_Remove>
2017348: 90 10 00 10 mov %l0, %o0
201734c: 30 bf ff a0 b,a 20171cc <_Timer_server_Body+0x40>
02017350 <_Timer_server_Schedule_operation_method>:
static void _Timer_server_Schedule_operation_method(
Timer_server_Control *ts,
Timer_Control *timer
)
{
2017350: 9d e3 bf a0 save %sp, -96, %sp
if ( ts->insert_chain == NULL ) {
2017354: c2 06 20 78 ld [ %i0 + 0x78 ], %g1
2017358: 80 a0 60 00 cmp %g1, 0
201735c: 12 80 00 49 bne 2017480 <_Timer_server_Schedule_operation_method+0x130>
2017360: ba 10 00 19 mov %i1, %i5
* is the reference point for the delta chain. Thus if we do not update the
* reference point we have to add DT to the initial delta of the watchdog
* being inserted. This could result in an integer overflow.
*/
_Thread_Disable_dispatch();
2017364: 7f ff ff 5b call 20170d0 <_Thread_Disable_dispatch>
2017368: 01 00 00 00 nop
if ( timer->the_class == TIMER_INTERVAL_ON_TASK ) {
201736c: c2 06 60 38 ld [ %i1 + 0x38 ], %g1
2017370: 80 a0 60 01 cmp %g1, 1
2017374: 12 80 00 1f bne 20173f0 <_Timer_server_Schedule_operation_method+0xa0>
2017378: 80 a0 60 03 cmp %g1, 3
/*
* We have to advance the last known ticks value of the server and update
* the watchdog chain accordingly.
*/
_ISR_Disable( level );
201737c: 7f ff e3 51 call 20100c0 <sparc_disable_interrupts>
2017380: 01 00 00 00 nop
snapshot = _Watchdog_Ticks_since_boot;
2017384: 03 00 80 e8 sethi %hi(0x203a000), %g1
2017388: c4 00 60 ac ld [ %g1 + 0xac ], %g2 ! 203a0ac <_Watchdog_Ticks_since_boot>
*/
RTEMS_INLINE_ROUTINE const Chain_Node *_Chain_Immutable_first(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_head( the_chain )->next;
201738c: c2 06 20 30 ld [ %i0 + 0x30 ], %g1
last_snapshot = ts->Interval_watchdogs.last_snapshot;
2017390: c8 06 20 3c ld [ %i0 + 0x3c ], %g4
RTEMS_INLINE_ROUTINE bool _Chain_Is_empty(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_first( the_chain )
== _Chain_Immutable_tail( the_chain );
2017394: 86 06 20 34 add %i0, 0x34, %g3
if ( !_Chain_Is_empty( &ts->Interval_watchdogs.Chain ) ) {
2017398: 80 a0 40 03 cmp %g1, %g3
201739c: 02 80 00 08 be 20173bc <_Timer_server_Schedule_operation_method+0x6c>
20173a0: 88 20 80 04 sub %g2, %g4, %g4
/*
* We assume adequate unsigned arithmetic here.
*/
delta = snapshot - last_snapshot;
delta_interval = first_watchdog->delta_interval;
20173a4: de 00 60 10 ld [ %g1 + 0x10 ], %o7
if (delta_interval > delta) {
20173a8: 80 a3 c0 04 cmp %o7, %g4
20173ac: 08 80 00 03 bleu 20173b8 <_Timer_server_Schedule_operation_method+0x68>
20173b0: 86 10 20 00 clr %g3
delta_interval -= delta;
20173b4: 86 23 c0 04 sub %o7, %g4, %g3
} else {
delta_interval = 0;
}
first_watchdog->delta_interval = delta_interval;
20173b8: c6 20 60 10 st %g3, [ %g1 + 0x10 ]
}
ts->Interval_watchdogs.last_snapshot = snapshot;
20173bc: c4 26 20 3c st %g2, [ %i0 + 0x3c ]
_ISR_Enable( level );
20173c0: 7f ff e3 44 call 20100d0 <sparc_enable_interrupts>
20173c4: 01 00 00 00 nop
_Watchdog_Insert( &ts->Interval_watchdogs.Chain, &timer->Ticker );
20173c8: 90 06 20 30 add %i0, 0x30, %o0
20173cc: 40 00 11 30 call 201b88c <_Watchdog_Insert>
20173d0: 92 07 60 10 add %i5, 0x10, %o1
if ( !ts->active ) {
20173d4: c2 0e 20 7c ldub [ %i0 + 0x7c ], %g1
20173d8: 80 a0 60 00 cmp %g1, 0
20173dc: 12 80 00 27 bne 2017478 <_Timer_server_Schedule_operation_method+0x128>
20173e0: 01 00 00 00 nop
_Timer_server_Reset_interval_system_watchdog( ts );
20173e4: 7f ff ff 42 call 20170ec <_Timer_server_Reset_interval_system_watchdog>
20173e8: 90 10 00 18 mov %i0, %o0
20173ec: 30 80 00 23 b,a 2017478 <_Timer_server_Schedule_operation_method+0x128>
}
} else if ( timer->the_class == TIMER_TIME_OF_DAY_ON_TASK ) {
20173f0: 12 80 00 22 bne 2017478 <_Timer_server_Schedule_operation_method+0x128>
20173f4: 01 00 00 00 nop
/*
* We have to advance the last known seconds value of the server and update
* the watchdog chain accordingly.
*/
_ISR_Disable( level );
20173f8: 7f ff e3 32 call 20100c0 <sparc_disable_interrupts>
20173fc: 01 00 00 00 nop
*/
RTEMS_INLINE_ROUTINE const Chain_Node *_Chain_Immutable_first(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_head( the_chain )->next;
2017400: c4 06 20 68 ld [ %i0 + 0x68 ], %g2
snapshot = (Watchdog_Interval) _TOD_Seconds_since_epoch();
last_snapshot = ts->TOD_watchdogs.last_snapshot;
2017404: de 06 20 74 ld [ %i0 + 0x74 ], %o7
/*
* We have to advance the last known seconds value of the server and update
* the watchdog chain accordingly.
*/
_ISR_Disable( level );
snapshot = (Watchdog_Interval) _TOD_Seconds_since_epoch();
2017408: 03 00 80 e8 sethi %hi(0x203a000), %g1
RTEMS_INLINE_ROUTINE bool _Chain_Is_empty(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_first( the_chain )
== _Chain_Immutable_tail( the_chain );
201740c: 86 06 20 6c add %i0, 0x6c, %g3
last_snapshot = ts->TOD_watchdogs.last_snapshot;
if ( !_Chain_Is_empty( &ts->TOD_watchdogs.Chain ) ) {
2017410: 80 a0 80 03 cmp %g2, %g3
2017414: 02 80 00 0d be 2017448 <_Timer_server_Schedule_operation_method+0xf8>
2017418: c2 00 60 2c ld [ %g1 + 0x2c ], %g1
first_watchdog = _Watchdog_First( &ts->TOD_watchdogs.Chain );
delta_interval = first_watchdog->delta_interval;
201741c: c8 00 a0 10 ld [ %g2 + 0x10 ], %g4
if ( snapshot > last_snapshot ) {
2017420: 80 a0 40 0f cmp %g1, %o7
}
} else {
/*
* Someone put us in the past.
*/
delta = last_snapshot - snapshot;
2017424: 86 01 00 0f add %g4, %o7, %g3
snapshot = (Watchdog_Interval) _TOD_Seconds_since_epoch();
last_snapshot = ts->TOD_watchdogs.last_snapshot;
if ( !_Chain_Is_empty( &ts->TOD_watchdogs.Chain ) ) {
first_watchdog = _Watchdog_First( &ts->TOD_watchdogs.Chain );
delta_interval = first_watchdog->delta_interval;
if ( snapshot > last_snapshot ) {
2017428: 08 80 00 07 bleu 2017444 <_Timer_server_Schedule_operation_method+0xf4>
201742c: 86 20 c0 01 sub %g3, %g1, %g3
/*
* We advanced in time.
*/
delta = snapshot - last_snapshot;
2017430: 9e 20 40 0f sub %g1, %o7, %o7
if (delta_interval > delta) {
2017434: 80 a1 00 0f cmp %g4, %o7
2017438: 08 80 00 03 bleu 2017444 <_Timer_server_Schedule_operation_method+0xf4><== NEVER TAKEN
201743c: 86 10 20 00 clr %g3
delta_interval -= delta;
2017440: 86 21 00 0f sub %g4, %o7, %g3
* Someone put us in the past.
*/
delta = last_snapshot - snapshot;
delta_interval += delta;
}
first_watchdog->delta_interval = delta_interval;
2017444: c6 20 a0 10 st %g3, [ %g2 + 0x10 ]
}
ts->TOD_watchdogs.last_snapshot = snapshot;
2017448: c2 26 20 74 st %g1, [ %i0 + 0x74 ]
_ISR_Enable( level );
201744c: 7f ff e3 21 call 20100d0 <sparc_enable_interrupts>
2017450: 01 00 00 00 nop
_Watchdog_Insert( &ts->TOD_watchdogs.Chain, &timer->Ticker );
2017454: 90 06 20 68 add %i0, 0x68, %o0
2017458: 40 00 11 0d call 201b88c <_Watchdog_Insert>
201745c: 92 07 60 10 add %i5, 0x10, %o1
if ( !ts->active ) {
2017460: c2 0e 20 7c ldub [ %i0 + 0x7c ], %g1
2017464: 80 a0 60 00 cmp %g1, 0
2017468: 12 80 00 04 bne 2017478 <_Timer_server_Schedule_operation_method+0x128>
201746c: 01 00 00 00 nop
_Timer_server_Reset_tod_system_watchdog( ts );
2017470: 7f ff ff 33 call 201713c <_Timer_server_Reset_tod_system_watchdog>
2017474: 90 10 00 18 mov %i0, %o0
}
}
_Thread_Enable_dispatch();
2017478: 40 00 0c f2 call 201a840 <_Thread_Enable_dispatch>
201747c: 81 e8 00 00 restore
* server is not preemptible, so we must be in interrupt context here. No
* thread dispatch will happen until the timer server finishes its
* critical section. We have to use the protected chain methods because
* we may be interrupted by a higher priority interrupt.
*/
_Chain_Append( ts->insert_chain, &timer->Object.Node );
2017480: f0 06 20 78 ld [ %i0 + 0x78 ], %i0
2017484: 40 00 02 14 call 2017cd4 <_Chain_Append>
2017488: 81 e8 00 00 restore
02009700 <_User_extensions_Handler_initialization>:
#include <rtems/score/userext.h>
#include <rtems/score/wkspace.h>
#include <string.h>
void _User_extensions_Handler_initialization(void)
{
2009700: 9d e3 bf a0 save %sp, -96, %sp
User_extensions_Control *extension;
uint32_t i;
uint32_t number_of_extensions;
User_extensions_Table *initial_extensions;
number_of_extensions = Configuration.number_of_initial_extensions;
2009704: 03 00 80 69 sethi %hi(0x201a400), %g1
2009708: 82 10 63 cc or %g1, 0x3cc, %g1 ! 201a7cc <Configuration>
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *tail = _Chain_Tail( the_chain );
head->next = tail;
200970c: 05 00 80 6d sethi %hi(0x201b400), %g2
initial_extensions = Configuration.User_extension_table;
2009710: f4 00 60 3c ld [ %g1 + 0x3c ], %i2
User_extensions_Control *extension;
uint32_t i;
uint32_t number_of_extensions;
User_extensions_Table *initial_extensions;
number_of_extensions = Configuration.number_of_initial_extensions;
2009714: f6 00 60 38 ld [ %g1 + 0x38 ], %i3
2009718: 82 10 a2 98 or %g2, 0x298, %g1
200971c: 86 00 60 04 add %g1, 4, %g3
head->previous = NULL;
2009720: c0 20 60 04 clr [ %g1 + 4 ]
tail->previous = head;
2009724: c2 20 60 08 st %g1, [ %g1 + 8 ]
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *tail = _Chain_Tail( the_chain );
head->next = tail;
2009728: c6 20 a2 98 st %g3, [ %g2 + 0x298 ]
200972c: 05 00 80 6d sethi %hi(0x201b400), %g2
2009730: 82 10 a0 b4 or %g2, 0xb4, %g1 ! 201b4b4 <_User_extensions_Switches_list>
2009734: 86 00 60 04 add %g1, 4, %g3
head->previous = NULL;
2009738: c0 20 60 04 clr [ %g1 + 4 ]
)
{
Chain_Node *head = _Chain_Head( the_chain );
Chain_Node *tail = _Chain_Tail( the_chain );
head->next = tail;
200973c: c6 20 a0 b4 st %g3, [ %g2 + 0xb4 ]
initial_extensions = Configuration.User_extension_table;
_Chain_Initialize_empty( &_User_extensions_List );
_Chain_Initialize_empty( &_User_extensions_Switches_list );
if ( initial_extensions ) {
2009740: 80 a6 a0 00 cmp %i2, 0
2009744: 02 80 00 1b be 20097b0 <_User_extensions_Handler_initialization+0xb0><== NEVER TAKEN
2009748: c2 20 60 08 st %g1, [ %g1 + 8 ]
extension = (User_extensions_Control *)
_Workspace_Allocate_or_fatal_error(
number_of_extensions * sizeof( User_extensions_Control )
200974c: 83 2e e0 02 sll %i3, 2, %g1
2009750: bb 2e e0 04 sll %i3, 4, %i5
2009754: ba 27 40 01 sub %i5, %g1, %i5
2009758: ba 07 40 1b add %i5, %i3, %i5
200975c: bb 2f 60 02 sll %i5, 2, %i5
_Chain_Initialize_empty( &_User_extensions_List );
_Chain_Initialize_empty( &_User_extensions_Switches_list );
if ( initial_extensions ) {
extension = (User_extensions_Control *)
2009760: 40 00 01 66 call 2009cf8 <_Workspace_Allocate_or_fatal_error>
2009764: 90 10 00 1d mov %i5, %o0
_Workspace_Allocate_or_fatal_error(
number_of_extensions * sizeof( User_extensions_Control )
);
memset (
2009768: 94 10 00 1d mov %i5, %o2
_Chain_Initialize_empty( &_User_extensions_List );
_Chain_Initialize_empty( &_User_extensions_Switches_list );
if ( initial_extensions ) {
extension = (User_extensions_Control *)
200976c: b8 10 00 08 mov %o0, %i4
_Workspace_Allocate_or_fatal_error(
number_of_extensions * sizeof( User_extensions_Control )
);
memset (
2009770: 92 10 20 00 clr %o1
2009774: 40 00 13 de call 200e6ec <memset>
2009778: ba 10 20 00 clr %i5
extension,
0,
number_of_extensions * sizeof( User_extensions_Control )
);
for ( i = 0 ; i < number_of_extensions ; i++ ) {
200977c: 10 80 00 0b b 20097a8 <_User_extensions_Handler_initialization+0xa8>
2009780: 80 a7 40 1b cmp %i5, %i3
RTEMS_INLINE_ROUTINE void _User_extensions_Add_set_with_table(
User_extensions_Control *extension,
const User_extensions_Table *extension_table
)
{
extension->Callouts = *extension_table;
2009784: 90 07 20 14 add %i4, 0x14, %o0
2009788: 92 06 80 09 add %i2, %o1, %o1
200978c: 40 00 13 9c call 200e5fc <memcpy>
2009790: 94 10 20 20 mov 0x20, %o2
_User_extensions_Add_set( extension );
2009794: 90 10 00 1c mov %i4, %o0
2009798: 40 00 0b 75 call 200c56c <_User_extensions_Add_set>
200979c: ba 07 60 01 inc %i5
_User_extensions_Add_set_with_table (extension, &initial_extensions[i]);
extension++;
20097a0: b8 07 20 34 add %i4, 0x34, %i4
extension,
0,
number_of_extensions * sizeof( User_extensions_Control )
);
for ( i = 0 ; i < number_of_extensions ; i++ ) {
20097a4: 80 a7 40 1b cmp %i5, %i3
20097a8: 12 bf ff f7 bne 2009784 <_User_extensions_Handler_initialization+0x84>
20097ac: 93 2f 60 05 sll %i5, 5, %o1
20097b0: 81 c7 e0 08 ret
20097b4: 81 e8 00 00 restore
0200b470 <_Watchdog_Adjust>:
void _Watchdog_Adjust(
Chain_Control *header,
Watchdog_Adjust_directions direction,
Watchdog_Interval units
)
{
200b470: 9d e3 bf a0 save %sp, -96, %sp
ISR_Level level;
_ISR_Disable( level );
200b474: 7f ff de e1 call 2002ff8 <sparc_disable_interrupts>
200b478: ba 10 00 18 mov %i0, %i5
*/
RTEMS_INLINE_ROUTINE const Chain_Node *_Chain_Immutable_first(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_head( the_chain )->next;
200b47c: c2 06 00 00 ld [ %i0 ], %g1
RTEMS_INLINE_ROUTINE bool _Chain_Is_empty(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_first( the_chain )
== _Chain_Immutable_tail( the_chain );
200b480: b8 06 20 04 add %i0, 4, %i4
* hence the compiler must not assume *header to remain
* unmodified across that call.
*
* Till Straumann, 7/2003
*/
if ( !_Chain_Is_empty( header ) ) {
200b484: 80 a0 40 1c cmp %g1, %i4
200b488: 02 80 00 1f be 200b504 <_Watchdog_Adjust+0x94>
200b48c: 80 a6 60 00 cmp %i1, 0
switch ( direction ) {
200b490: 02 80 00 1a be 200b4f8 <_Watchdog_Adjust+0x88>
200b494: b6 10 20 01 mov 1, %i3
200b498: 80 a6 60 01 cmp %i1, 1
200b49c: 12 80 00 1a bne 200b504 <_Watchdog_Adjust+0x94> <== NEVER TAKEN
200b4a0: 01 00 00 00 nop
case WATCHDOG_BACKWARD:
_Watchdog_First( header )->delta_interval += units;
200b4a4: c4 00 60 10 ld [ %g1 + 0x10 ], %g2
200b4a8: 10 80 00 07 b 200b4c4 <_Watchdog_Adjust+0x54>
200b4ac: b4 00 80 1a add %g2, %i2, %i2
break;
case WATCHDOG_FORWARD:
while ( units ) {
if ( units < _Watchdog_First( header )->delta_interval ) {
200b4b0: c4 00 60 10 ld [ %g1 + 0x10 ], %g2
200b4b4: 80 a6 80 02 cmp %i2, %g2
200b4b8: 3a 80 00 05 bcc,a 200b4cc <_Watchdog_Adjust+0x5c>
200b4bc: f6 20 60 10 st %i3, [ %g1 + 0x10 ]
_Watchdog_First( header )->delta_interval -= units;
200b4c0: b4 20 80 1a sub %g2, %i2, %i2
break;
200b4c4: 10 80 00 10 b 200b504 <_Watchdog_Adjust+0x94>
200b4c8: f4 20 60 10 st %i2, [ %g1 + 0x10 ]
} else {
units -= _Watchdog_First( header )->delta_interval;
200b4cc: b4 26 80 02 sub %i2, %g2, %i2
_Watchdog_First( header )->delta_interval = 1;
_ISR_Enable( level );
200b4d0: 7f ff de ce call 2003008 <sparc_enable_interrupts>
200b4d4: 01 00 00 00 nop
_Watchdog_Tickle( header );
200b4d8: 40 00 00 90 call 200b718 <_Watchdog_Tickle>
200b4dc: 90 10 00 1d mov %i5, %o0
_ISR_Disable( level );
200b4e0: 7f ff de c6 call 2002ff8 <sparc_disable_interrupts>
200b4e4: 01 00 00 00 nop
if ( _Chain_Is_empty( header ) )
200b4e8: c2 07 40 00 ld [ %i5 ], %g1
200b4ec: 80 a0 40 1c cmp %g1, %i4
200b4f0: 02 80 00 05 be 200b504 <_Watchdog_Adjust+0x94>
200b4f4: 01 00 00 00 nop
switch ( direction ) {
case WATCHDOG_BACKWARD:
_Watchdog_First( header )->delta_interval += units;
break;
case WATCHDOG_FORWARD:
while ( units ) {
200b4f8: 80 a6 a0 00 cmp %i2, 0
200b4fc: 32 bf ff ed bne,a 200b4b0 <_Watchdog_Adjust+0x40> <== ALWAYS TAKEN
200b500: c2 07 40 00 ld [ %i5 ], %g1
}
break;
}
}
_ISR_Enable( level );
200b504: 7f ff de c1 call 2003008 <sparc_enable_interrupts>
200b508: 91 e8 00 08 restore %g0, %o0, %o0
02009b18 <_Watchdog_Remove>:
*/
Watchdog_States _Watchdog_Remove(
Watchdog_Control *the_watchdog
)
{
2009b18: 9d e3 bf a0 save %sp, -96, %sp
ISR_Level level;
Watchdog_States previous_state;
Watchdog_Control *next_watchdog;
_ISR_Disable( level );
2009b1c: 7f ff e1 98 call 200217c <sparc_disable_interrupts>
2009b20: ba 10 00 18 mov %i0, %i5
previous_state = the_watchdog->state;
2009b24: f0 06 20 08 ld [ %i0 + 8 ], %i0
switch ( previous_state ) {
2009b28: 80 a6 20 01 cmp %i0, 1
2009b2c: 22 80 00 1d be,a 2009ba0 <_Watchdog_Remove+0x88>
2009b30: c0 27 60 08 clr [ %i5 + 8 ]
2009b34: 0a 80 00 1c bcs 2009ba4 <_Watchdog_Remove+0x8c>
2009b38: 03 00 80 6d sethi %hi(0x201b400), %g1
2009b3c: 80 a6 20 03 cmp %i0, 3
2009b40: 18 80 00 19 bgu 2009ba4 <_Watchdog_Remove+0x8c> <== NEVER TAKEN
2009b44: 01 00 00 00 nop
2009b48: c2 07 40 00 ld [ %i5 ], %g1
break;
case WATCHDOG_ACTIVE:
case WATCHDOG_REMOVE_IT:
the_watchdog->state = WATCHDOG_INACTIVE;
2009b4c: c0 27 60 08 clr [ %i5 + 8 ]
next_watchdog = _Watchdog_Next( the_watchdog );
if ( _Watchdog_Next(next_watchdog) )
2009b50: c4 00 40 00 ld [ %g1 ], %g2
2009b54: 80 a0 a0 00 cmp %g2, 0
2009b58: 02 80 00 07 be 2009b74 <_Watchdog_Remove+0x5c>
2009b5c: 05 00 80 6d sethi %hi(0x201b400), %g2
next_watchdog->delta_interval += the_watchdog->delta_interval;
2009b60: c6 00 60 10 ld [ %g1 + 0x10 ], %g3
2009b64: c4 07 60 10 ld [ %i5 + 0x10 ], %g2
2009b68: 84 00 c0 02 add %g3, %g2, %g2
2009b6c: c4 20 60 10 st %g2, [ %g1 + 0x10 ]
if ( _Watchdog_Sync_count )
2009b70: 05 00 80 6d sethi %hi(0x201b400), %g2
2009b74: c4 00 a1 b8 ld [ %g2 + 0x1b8 ], %g2 ! 201b5b8 <_Watchdog_Sync_count>
2009b78: 80 a0 a0 00 cmp %g2, 0
2009b7c: 22 80 00 07 be,a 2009b98 <_Watchdog_Remove+0x80>
2009b80: c4 07 60 04 ld [ %i5 + 4 ], %g2
_Watchdog_Sync_level = _ISR_Nest_level;
2009b84: 05 00 80 6d sethi %hi(0x201b400), %g2
2009b88: c6 00 a2 e4 ld [ %g2 + 0x2e4 ], %g3 ! 201b6e4 <_Per_CPU_Information+0x8>
2009b8c: 05 00 80 6d sethi %hi(0x201b400), %g2
2009b90: c6 20 a1 58 st %g3, [ %g2 + 0x158 ] ! 201b558 <_Watchdog_Sync_level>
{
Chain_Node *next;
Chain_Node *previous;
next = the_node->next;
previous = the_node->previous;
2009b94: c4 07 60 04 ld [ %i5 + 4 ], %g2
next->previous = previous;
2009b98: c4 20 60 04 st %g2, [ %g1 + 4 ]
previous->next = next;
2009b9c: c2 20 80 00 st %g1, [ %g2 ]
_Chain_Extract_unprotected( &the_watchdog->Node );
break;
}
the_watchdog->stop_time = _Watchdog_Ticks_since_boot;
2009ba0: 03 00 80 6d sethi %hi(0x201b400), %g1
2009ba4: c2 00 61 bc ld [ %g1 + 0x1bc ], %g1 ! 201b5bc <_Watchdog_Ticks_since_boot>
2009ba8: c2 27 60 18 st %g1, [ %i5 + 0x18 ]
_ISR_Enable( level );
2009bac: 7f ff e1 78 call 200218c <sparc_enable_interrupts>
2009bb0: 01 00 00 00 nop
return( previous_state );
}
2009bb4: 81 c7 e0 08 ret
2009bb8: 81 e8 00 00 restore
0200ac68 <_Watchdog_Report_chain>:
void _Watchdog_Report_chain(
const char *name,
Chain_Control *header
)
{
200ac68: 9d e3 bf a0 save %sp, -96, %sp
ISR_Level level;
Chain_Node *node;
_ISR_Disable( level );
200ac6c: 7f ff df b3 call 2002b38 <sparc_disable_interrupts>
200ac70: ba 10 00 18 mov %i0, %i5
200ac74: b0 10 00 08 mov %o0, %i0
printk( "Watchdog Chain: %s %p\n", name, header );
200ac78: 11 00 80 6d sethi %hi(0x201b400), %o0
200ac7c: 94 10 00 19 mov %i1, %o2
200ac80: 90 12 21 00 or %o0, 0x100, %o0
200ac84: 7f ff e6 63 call 2004610 <printk>
200ac88: 92 10 00 1d mov %i5, %o1
*/
RTEMS_INLINE_ROUTINE const Chain_Node *_Chain_Immutable_first(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_head( the_chain )->next;
200ac8c: f8 06 40 00 ld [ %i1 ], %i4
RTEMS_INLINE_ROUTINE bool _Chain_Is_empty(
const Chain_Control *the_chain
)
{
return _Chain_Immutable_first( the_chain )
== _Chain_Immutable_tail( the_chain );
200ac90: b2 06 60 04 add %i1, 4, %i1
if ( !_Chain_Is_empty( header ) ) {
200ac94: 80 a7 00 19 cmp %i4, %i1
200ac98: 12 80 00 04 bne 200aca8 <_Watchdog_Report_chain+0x40>
200ac9c: 92 10 00 1c mov %i4, %o1
_Watchdog_Report( NULL, watch );
}
printk( "== end of %s \n", name );
} else {
printk( "Chain is empty\n" );
200aca0: 10 80 00 0d b 200acd4 <_Watchdog_Report_chain+0x6c>
200aca4: 11 00 80 6d sethi %hi(0x201b400), %o0
node != _Chain_Tail(header) ;
node = node->next )
{
Watchdog_Control *watch = (Watchdog_Control *) node;
_Watchdog_Report( NULL, watch );
200aca8: 40 00 00 0f call 200ace4 <_Watchdog_Report>
200acac: 90 10 20 00 clr %o0
_ISR_Disable( level );
printk( "Watchdog Chain: %s %p\n", name, header );
if ( !_Chain_Is_empty( header ) ) {
for ( node = _Chain_First( header ) ;
node != _Chain_Tail(header) ;
node = node->next )
200acb0: f8 07 00 00 ld [ %i4 ], %i4
Chain_Node *node;
_ISR_Disable( level );
printk( "Watchdog Chain: %s %p\n", name, header );
if ( !_Chain_Is_empty( header ) ) {
for ( node = _Chain_First( header ) ;
200acb4: 80 a7 00 19 cmp %i4, %i1
200acb8: 12 bf ff fc bne 200aca8 <_Watchdog_Report_chain+0x40> <== NEVER TAKEN
200acbc: 92 10 00 1c mov %i4, %o1
{
Watchdog_Control *watch = (Watchdog_Control *) node;
_Watchdog_Report( NULL, watch );
}
printk( "== end of %s \n", name );
200acc0: 11 00 80 6d sethi %hi(0x201b400), %o0
200acc4: 92 10 00 1d mov %i5, %o1
200acc8: 7f ff e6 52 call 2004610 <printk>
200accc: 90 12 21 18 or %o0, 0x118, %o0
200acd0: 30 80 00 03 b,a 200acdc <_Watchdog_Report_chain+0x74>
} else {
printk( "Chain is empty\n" );
200acd4: 7f ff e6 4f call 2004610 <printk>
200acd8: 90 12 21 28 or %o0, 0x128, %o0
}
_ISR_Enable( level );
200acdc: 7f ff df 9b call 2002b48 <sparc_enable_interrupts>
200ace0: 81 e8 00 00 restore
02006d20 <rtems_chain_get_with_wait>:
rtems_chain_control *chain,
rtems_event_set events,
rtems_interval timeout,
rtems_chain_node **node_ptr
)
{
2006d20: 9d e3 bf 98 save %sp, -104, %sp
2006d24: 10 80 00 09 b 2006d48 <rtems_chain_get_with_wait+0x28>
2006d28: ba 10 00 18 mov %i0, %i5
while (
sc == RTEMS_SUCCESSFUL
&& (node = rtems_chain_get( chain )) == NULL
) {
rtems_event_set out;
sc = rtems_event_receive(
2006d2c: 92 10 20 00 clr %o1
2006d30: 94 10 00 1a mov %i2, %o2
2006d34: 7f ff fd 03 call 2006140 <rtems_event_receive>
2006d38: 96 07 bf fc add %fp, -4, %o3
)
{
rtems_status_code sc = RTEMS_SUCCESSFUL;
rtems_chain_node *node = NULL;
while (
2006d3c: 80 a2 20 00 cmp %o0, 0
2006d40: 32 80 00 09 bne,a 2006d64 <rtems_chain_get_with_wait+0x44><== ALWAYS TAKEN
2006d44: f8 26 c0 00 st %i4, [ %i3 ]
*/
RTEMS_INLINE_ROUTINE rtems_chain_node *rtems_chain_get(
rtems_chain_control *the_chain
)
{
return _Chain_Get( the_chain );
2006d48: 40 00 01 62 call 20072d0 <_Chain_Get>
2006d4c: 90 10 00 1d mov %i5, %o0
sc == RTEMS_SUCCESSFUL
&& (node = rtems_chain_get( chain )) == NULL
2006d50: b8 92 20 00 orcc %o0, 0, %i4
2006d54: 02 bf ff f6 be 2006d2c <rtems_chain_get_with_wait+0xc>
2006d58: 90 10 00 19 mov %i1, %o0
2006d5c: 90 10 20 00 clr %o0
timeout,
&out
);
}
*node_ptr = node;
2006d60: f8 26 c0 00 st %i4, [ %i3 ]
return sc;
}
2006d64: 81 c7 e0 08 ret
2006d68: 91 e8 00 08 restore %g0, %o0, %o0
02009014 <rtems_iterate_over_all_threads>:
#include <rtems/system.h>
#include <rtems/score/thread.h>
void rtems_iterate_over_all_threads(rtems_per_thread_routine routine)
{
2009014: 9d e3 bf a0 save %sp, -96, %sp
uint32_t i;
uint32_t api_index;
Thread_Control *the_thread;
Objects_Information *information;
if ( !routine )
2009018: 80 a6 20 00 cmp %i0, 0
200901c: 02 80 00 1e be 2009094 <rtems_iterate_over_all_threads+0x80><== NEVER TAKEN
2009020: ba 10 20 01 mov 1, %i5
return;
for ( api_index = 1 ; api_index <= OBJECTS_APIS_LAST ; api_index++ ) {
#if !defined(RTEMS_POSIX_API) || defined(RTEMS_DEBUG)
if ( !_Objects_Information_table[ api_index ] )
2009024: 35 00 80 77 sethi %hi(0x201dc00), %i2
#endif
#include <rtems/system.h>
#include <rtems/score/thread.h>
void rtems_iterate_over_all_threads(rtems_per_thread_routine routine)
2009028: 83 2f 60 02 sll %i5, 2, %g1
if ( !routine )
return;
for ( api_index = 1 ; api_index <= OBJECTS_APIS_LAST ; api_index++ ) {
#if !defined(RTEMS_POSIX_API) || defined(RTEMS_DEBUG)
if ( !_Objects_Information_table[ api_index ] )
200902c: 84 16 a3 48 or %i2, 0x348, %g2
2009030: c2 00 80 01 ld [ %g2 + %g1 ], %g1
2009034: 80 a0 60 00 cmp %g1, 0
2009038: 22 80 00 14 be,a 2009088 <rtems_iterate_over_all_threads+0x74>
200903c: ba 07 60 01 inc %i5
continue;
#endif
information = _Objects_Information_table[ api_index ][ 1 ];
2009040: f6 00 60 04 ld [ %g1 + 4 ], %i3
if ( !information )
2009044: 80 a6 e0 00 cmp %i3, 0
2009048: 12 80 00 0b bne 2009074 <rtems_iterate_over_all_threads+0x60>
200904c: b8 10 20 01 mov 1, %i4
Objects_Information *information;
if ( !routine )
return;
for ( api_index = 1 ; api_index <= OBJECTS_APIS_LAST ; api_index++ ) {
2009050: 10 80 00 0e b 2009088 <rtems_iterate_over_all_threads+0x74>
2009054: ba 07 60 01 inc %i5
information = _Objects_Information_table[ api_index ][ 1 ];
if ( !information )
continue;
for ( i=1 ; i <= information->maximum ; i++ ) {
the_thread = (Thread_Control *)information->local_table[ i ];
2009058: 83 2f 20 02 sll %i4, 2, %g1
200905c: d0 00 80 01 ld [ %g2 + %g1 ], %o0
if ( !the_thread )
2009060: 80 a2 20 00 cmp %o0, 0
2009064: 02 80 00 04 be 2009074 <rtems_iterate_over_all_threads+0x60>
2009068: b8 07 20 01 inc %i4
continue;
(*routine)(the_thread);
200906c: 9f c6 00 00 call %i0
2009070: 01 00 00 00 nop
information = _Objects_Information_table[ api_index ][ 1 ];
if ( !information )
continue;
for ( i=1 ; i <= information->maximum ; i++ ) {
2009074: c2 16 e0 10 lduh [ %i3 + 0x10 ], %g1
2009078: 80 a7 00 01 cmp %i4, %g1
200907c: 28 bf ff f7 bleu,a 2009058 <rtems_iterate_over_all_threads+0x44>
2009080: c4 06 e0 1c ld [ %i3 + 0x1c ], %g2
Objects_Information *information;
if ( !routine )
return;
for ( api_index = 1 ; api_index <= OBJECTS_APIS_LAST ; api_index++ ) {
2009084: ba 07 60 01 inc %i5
2009088: 80 a7 60 04 cmp %i5, 4
200908c: 12 bf ff e8 bne 200902c <rtems_iterate_over_all_threads+0x18>
2009090: 83 2f 60 02 sll %i5, 2, %g1
2009094: 81 c7 e0 08 ret
2009098: 81 e8 00 00 restore
02014b6c <rtems_partition_create>:
uint32_t length,
uint32_t buffer_size,
rtems_attribute attribute_set,
rtems_id *id
)
{
2014b6c: 9d e3 bf a0 save %sp, -96, %sp
register Partition_Control *the_partition;
if ( !rtems_is_name_valid( name ) )
2014b70: 80 a6 20 00 cmp %i0, 0
2014b74: 02 80 00 39 be 2014c58 <rtems_partition_create+0xec>
2014b78: 82 10 20 03 mov 3, %g1
return RTEMS_INVALID_NAME;
if ( !starting_address )
2014b7c: 80 a6 60 00 cmp %i1, 0
2014b80: 02 80 00 36 be 2014c58 <rtems_partition_create+0xec>
2014b84: 82 10 20 09 mov 9, %g1
return RTEMS_INVALID_ADDRESS;
if ( !id )
2014b88: 80 a7 60 00 cmp %i5, 0
2014b8c: 02 80 00 33 be 2014c58 <rtems_partition_create+0xec> <== NEVER TAKEN
2014b90: 80 a6 e0 00 cmp %i3, 0
return RTEMS_INVALID_ADDRESS;
if ( length == 0 || buffer_size == 0 || length < buffer_size ||
2014b94: 02 80 00 31 be 2014c58 <rtems_partition_create+0xec>
2014b98: 82 10 20 08 mov 8, %g1
2014b9c: 80 a6 a0 00 cmp %i2, 0
2014ba0: 02 80 00 2e be 2014c58 <rtems_partition_create+0xec>
2014ba4: 80 a6 80 1b cmp %i2, %i3
2014ba8: 0a 80 00 2c bcs 2014c58 <rtems_partition_create+0xec>
2014bac: 80 8e e0 07 btst 7, %i3
2014bb0: 12 80 00 2a bne 2014c58 <rtems_partition_create+0xec>
2014bb4: 80 8e 60 07 btst 7, %i1
!_Partition_Is_buffer_size_aligned( buffer_size ) )
return RTEMS_INVALID_SIZE;
if ( !_Addresses_Is_aligned( starting_address ) )
2014bb8: 12 80 00 28 bne 2014c58 <rtems_partition_create+0xec>
2014bbc: 82 10 20 09 mov 9, %g1
*
* This rountine increments the thread dispatch level
*/
RTEMS_INLINE_ROUTINE uint32_t _Thread_Dispatch_increment_disable_level(void)
{
_Thread_Dispatch_disable_level++;
2014bc0: 03 00 80 e7 sethi %hi(0x2039c00), %g1
2014bc4: c4 00 63 a0 ld [ %g1 + 0x3a0 ], %g2 ! 2039fa0 <_Thread_Dispatch_disable_level>
2014bc8: 84 00 a0 01 inc %g2
2014bcc: c4 20 63 a0 st %g2, [ %g1 + 0x3a0 ]
return _Thread_Dispatch_disable_level;
2014bd0: c2 00 63 a0 ld [ %g1 + 0x3a0 ], %g1
* This function allocates a partition control block from
* the inactive chain of free partition control blocks.
*/
RTEMS_INLINE_ROUTINE Partition_Control *_Partition_Allocate ( void )
{
return (Partition_Control *) _Objects_Allocate( &_Partition_Information );
2014bd4: 23 00 80 e7 sethi %hi(0x2039c00), %l1
2014bd8: 40 00 12 2f call 2019494 <_Objects_Allocate>
2014bdc: 90 14 61 b4 or %l1, 0x1b4, %o0 ! 2039db4 <_Partition_Information>
_Thread_Disable_dispatch(); /* prevents deletion */
the_partition = _Partition_Allocate();
if ( !the_partition ) {
2014be0: a0 92 20 00 orcc %o0, 0, %l0
2014be4: 32 80 00 06 bne,a 2014bfc <rtems_partition_create+0x90>
2014be8: f8 24 20 1c st %i4, [ %l0 + 0x1c ]
_Thread_Enable_dispatch();
2014bec: 40 00 17 15 call 201a840 <_Thread_Enable_dispatch>
2014bf0: 01 00 00 00 nop
return RTEMS_TOO_MANY;
2014bf4: 10 80 00 19 b 2014c58 <rtems_partition_create+0xec>
2014bf8: 82 10 20 05 mov 5, %g1 ! 5 <PROM_START+0x5>
the_partition->buffer_size = buffer_size;
the_partition->attribute_set = attribute_set;
the_partition->number_of_used_blocks = 0;
_Chain_Initialize( &the_partition->Memory, starting_address,
length / buffer_size, buffer_size );
2014bfc: 92 10 00 1b mov %i3, %o1
_Thread_Enable_dispatch();
return RTEMS_TOO_MANY;
}
#endif
the_partition->starting_address = starting_address;
2014c00: f2 24 20 10 st %i1, [ %l0 + 0x10 ]
the_partition->length = length;
2014c04: f4 24 20 14 st %i2, [ %l0 + 0x14 ]
the_partition->buffer_size = buffer_size;
2014c08: f6 24 20 18 st %i3, [ %l0 + 0x18 ]
the_partition->attribute_set = attribute_set;
the_partition->number_of_used_blocks = 0;
2014c0c: c0 24 20 20 clr [ %l0 + 0x20 ]
_Chain_Initialize( &the_partition->Memory, starting_address,
length / buffer_size, buffer_size );
2014c10: 40 00 54 fa call 2029ff8 <.udiv>
2014c14: 90 10 00 1a mov %i2, %o0
the_partition->length = length;
the_partition->buffer_size = buffer_size;
the_partition->attribute_set = attribute_set;
the_partition->number_of_used_blocks = 0;
_Chain_Initialize( &the_partition->Memory, starting_address,
2014c18: 92 10 00 19 mov %i1, %o1
length / buffer_size, buffer_size );
2014c1c: 94 10 00 08 mov %o0, %o2
the_partition->length = length;
the_partition->buffer_size = buffer_size;
the_partition->attribute_set = attribute_set;
the_partition->number_of_used_blocks = 0;
_Chain_Initialize( &the_partition->Memory, starting_address,
2014c20: 96 10 00 1b mov %i3, %o3
2014c24: b8 04 20 24 add %l0, 0x24, %i4
2014c28: 40 00 0c 4e call 2017d60 <_Chain_Initialize>
2014c2c: 90 10 00 1c mov %i4, %o0
Objects_Information *information,
Objects_Control *the_object,
Objects_Name name
)
{
_Objects_Set_local_object(
2014c30: c4 14 20 0a lduh [ %l0 + 0xa ], %g2
);
#endif
_Thread_Enable_dispatch();
return RTEMS_SUCCESSFUL;
}
2014c34: a2 14 61 b4 or %l1, 0x1b4, %l1
#if defined(RTEMS_DEBUG)
if ( index > information->maximum )
return;
#endif
information->local_table[ index ] = the_object;
2014c38: c6 04 60 1c ld [ %l1 + 0x1c ], %g3
Objects_Information *information,
Objects_Control *the_object,
Objects_Name name
)
{
_Objects_Set_local_object(
2014c3c: c2 04 20 08 ld [ %l0 + 8 ], %g1
#if defined(RTEMS_DEBUG)
if ( index > information->maximum )
return;
#endif
information->local_table[ index ] = the_object;
2014c40: 85 28 a0 02 sll %g2, 2, %g2
2014c44: e0 20 c0 02 st %l0, [ %g3 + %g2 ]
information,
_Objects_Get_index( the_object->id ),
the_object
);
the_object->name = name;
2014c48: f0 24 20 0c st %i0, [ %l0 + 0xc ]
name,
0 /* Not used */
);
#endif
_Thread_Enable_dispatch();
2014c4c: 40 00 16 fd call 201a840 <_Thread_Enable_dispatch>
2014c50: c2 27 40 00 st %g1, [ %i5 ]
return RTEMS_SUCCESSFUL;
2014c54: 82 10 20 00 clr %g1
}
2014c58: 81 c7 e0 08 ret
2014c5c: 91 e8 00 01 restore %g0, %g1, %o0
02007258 <rtems_rate_monotonic_period>:
rtems_status_code rtems_rate_monotonic_period(
rtems_id id,
rtems_interval length
)
{
2007258: 9d e3 bf 98 save %sp, -104, %sp
RTEMS_INLINE_ROUTINE Rate_monotonic_Control *_Rate_monotonic_Get (
Objects_Id id,
Objects_Locations *location
)
{
return (Rate_monotonic_Control *)
200725c: 11 00 80 74 sethi %hi(0x201d000), %o0
2007260: 92 10 00 18 mov %i0, %o1
2007264: 90 12 21 c4 or %o0, 0x1c4, %o0
2007268: 40 00 08 da call 20095d0 <_Objects_Get>
200726c: 94 07 bf fc add %fp, -4, %o2
rtems_rate_monotonic_period_states local_state;
ISR_Level level;
the_period = _Rate_monotonic_Get( id, &location );
switch ( location ) {
2007270: c2 07 bf fc ld [ %fp + -4 ], %g1
2007274: 80 a0 60 00 cmp %g1, 0
2007278: 12 80 00 65 bne 200740c <rtems_rate_monotonic_period+0x1b4>
200727c: ba 10 00 08 mov %o0, %i5
RTEMS_INLINE_ROUTINE bool _Thread_Is_executing (
const Thread_Control *the_thread
)
{
return ( the_thread == _Thread_Executing );
2007280: 37 00 80 75 sethi %hi(0x201d400), %i3
case OBJECTS_LOCAL:
if ( !_Thread_Is_executing( the_period->owner ) ) {
2007284: c4 02 20 40 ld [ %o0 + 0x40 ], %g2
2007288: b6 16 e1 5c or %i3, 0x15c, %i3
200728c: c2 06 e0 0c ld [ %i3 + 0xc ], %g1
2007290: 80 a0 80 01 cmp %g2, %g1
2007294: 02 80 00 06 be 20072ac <rtems_rate_monotonic_period+0x54>
2007298: 80 a6 60 00 cmp %i1, 0
_Thread_Enable_dispatch();
200729c: 40 00 0c 6d call 200a450 <_Thread_Enable_dispatch>
20072a0: b0 10 20 17 mov 0x17, %i0
return RTEMS_NOT_OWNER_OF_RESOURCE;
20072a4: 81 c7 e0 08 ret
20072a8: 81 e8 00 00 restore
}
if ( length == RTEMS_PERIOD_STATUS ) {
20072ac: 12 80 00 0d bne 20072e0 <rtems_rate_monotonic_period+0x88>
20072b0: 01 00 00 00 nop
switch ( the_period->state ) {
20072b4: c2 02 20 38 ld [ %o0 + 0x38 ], %g1
20072b8: 80 a0 60 04 cmp %g1, 4
20072bc: 18 80 00 05 bgu 20072d0 <rtems_rate_monotonic_period+0x78><== NEVER TAKEN
20072c0: b0 10 20 00 clr %i0
case OBJECTS_ERROR:
break;
}
return RTEMS_INVALID_ID;
}
20072c4: 05 00 80 6c sethi %hi(0x201b000), %g2
20072c8: 84 10 a2 08 or %g2, 0x208, %g2 ! 201b208 <CSWTCH.2>
20072cc: f0 08 80 01 ldub [ %g2 + %g1 ], %i0
case RATE_MONOTONIC_ACTIVE:
default: /* unreached -- only to remove warnings */
return_value = RTEMS_SUCCESSFUL;
break;
}
_Thread_Enable_dispatch();
20072d0: 40 00 0c 60 call 200a450 <_Thread_Enable_dispatch>
20072d4: 01 00 00 00 nop
return( return_value );
20072d8: 81 c7 e0 08 ret
20072dc: 81 e8 00 00 restore
}
_ISR_Disable( level );
20072e0: 7f ff ee ef call 2002e9c <sparc_disable_interrupts>
20072e4: 01 00 00 00 nop
20072e8: b4 10 00 08 mov %o0, %i2
if ( the_period->state == RATE_MONOTONIC_INACTIVE ) {
20072ec: f8 07 60 38 ld [ %i5 + 0x38 ], %i4
20072f0: 80 a7 20 00 cmp %i4, 0
20072f4: 12 80 00 15 bne 2007348 <rtems_rate_monotonic_period+0xf0>
20072f8: 80 a7 20 02 cmp %i4, 2
_ISR_Enable( level );
20072fc: 7f ff ee ec call 2002eac <sparc_enable_interrupts>
2007300: 01 00 00 00 nop
/*
* Baseline statistics information for the beginning of a period.
*/
_Rate_monotonic_Initiate_statistics( the_period );
2007304: 7f ff ff 7f call 2007100 <_Rate_monotonic_Initiate_statistics>
2007308: 90 10 00 1d mov %i5, %o0
the_period->state = RATE_MONOTONIC_ACTIVE;
200730c: 82 10 20 02 mov 2, %g1
2007310: c2 27 60 38 st %g1, [ %i5 + 0x38 ]
Objects_Id id,
void *user_data
)
{
the_watchdog->state = WATCHDOG_INACTIVE;
the_watchdog->routine = routine;
2007314: 03 00 80 1d sethi %hi(0x2007400), %g1
2007318: 82 10 62 c8 or %g1, 0x2c8, %g1 ! 20076c8 <_Rate_monotonic_Timeout>
Watchdog_Service_routine_entry routine,
Objects_Id id,
void *user_data
)
{
the_watchdog->state = WATCHDOG_INACTIVE;
200731c: c0 27 60 18 clr [ %i5 + 0x18 ]
the_watchdog->routine = routine;
2007320: c2 27 60 2c st %g1, [ %i5 + 0x2c ]
the_watchdog->id = id;
2007324: f0 27 60 30 st %i0, [ %i5 + 0x30 ]
the_watchdog->user_data = user_data;
2007328: c0 27 60 34 clr [ %i5 + 0x34 ]
_Rate_monotonic_Timeout,
id,
NULL
);
the_period->next_length = length;
200732c: f2 27 60 3c st %i1, [ %i5 + 0x3c ]
Watchdog_Control *the_watchdog,
Watchdog_Interval units
)
{
the_watchdog->initial = units;
2007330: f2 27 60 1c st %i1, [ %i5 + 0x1c ]
_Watchdog_Insert( &_Watchdog_Ticks_chain, the_watchdog );
2007334: 11 00 80 74 sethi %hi(0x201d000), %o0
2007338: 92 07 60 10 add %i5, 0x10, %o1
200733c: 40 00 10 0b call 200b368 <_Watchdog_Insert>
2007340: 90 12 23 ec or %o0, 0x3ec, %o0
2007344: 30 80 00 1b b,a 20073b0 <rtems_rate_monotonic_period+0x158>
_Watchdog_Insert_ticks( &the_period->Timer, length );
_Thread_Enable_dispatch();
return RTEMS_SUCCESSFUL;
}
if ( the_period->state == RATE_MONOTONIC_ACTIVE ) {
2007348: 12 80 00 1e bne 20073c0 <rtems_rate_monotonic_period+0x168>
200734c: 80 a7 20 04 cmp %i4, 4
/*
* Update statistics from the concluding period.
*/
_Rate_monotonic_Update_statistics( the_period );
2007350: 7f ff ff 86 call 2007168 <_Rate_monotonic_Update_statistics>
2007354: 90 10 00 1d mov %i5, %o0
/*
* This tells the _Rate_monotonic_Timeout that this task is
* in the process of blocking on the period and that we
* may be changing the length of the next period.
*/
the_period->state = RATE_MONOTONIC_OWNER_IS_BLOCKING;
2007358: 82 10 20 01 mov 1, %g1
the_period->next_length = length;
200735c: f2 27 60 3c st %i1, [ %i5 + 0x3c ]
/*
* This tells the _Rate_monotonic_Timeout that this task is
* in the process of blocking on the period and that we
* may be changing the length of the next period.
*/
the_period->state = RATE_MONOTONIC_OWNER_IS_BLOCKING;
2007360: c2 27 60 38 st %g1, [ %i5 + 0x38 ]
the_period->next_length = length;
_ISR_Enable( level );
2007364: 7f ff ee d2 call 2002eac <sparc_enable_interrupts>
2007368: 90 10 00 1a mov %i2, %o0
_Thread_Executing->Wait.id = the_period->Object.id;
200736c: d0 06 e0 0c ld [ %i3 + 0xc ], %o0
2007370: c2 07 60 08 ld [ %i5 + 8 ], %g1
_Thread_Set_state( _Thread_Executing, STATES_WAITING_FOR_PERIOD );
2007374: 13 00 00 10 sethi %hi(0x4000), %o1
2007378: 40 00 0e 59 call 200acdc <_Thread_Set_state>
200737c: c2 22 20 20 st %g1, [ %o0 + 0x20 ]
/*
* Did the watchdog timer expire while we were actually blocking
* on it?
*/
_ISR_Disable( level );
2007380: 7f ff ee c7 call 2002e9c <sparc_disable_interrupts>
2007384: 01 00 00 00 nop
local_state = the_period->state;
2007388: f4 07 60 38 ld [ %i5 + 0x38 ], %i2
the_period->state = RATE_MONOTONIC_ACTIVE;
200738c: f8 27 60 38 st %i4, [ %i5 + 0x38 ]
_ISR_Enable( level );
2007390: 7f ff ee c7 call 2002eac <sparc_enable_interrupts>
2007394: 01 00 00 00 nop
/*
* If it did, then we want to unblock ourself and continue as
* if nothing happen. The period was reset in the timeout routine.
*/
if ( local_state == RATE_MONOTONIC_EXPIRED_WHILE_BLOCKING )
2007398: 80 a6 a0 03 cmp %i2, 3
200739c: 12 80 00 05 bne 20073b0 <rtems_rate_monotonic_period+0x158>
20073a0: 01 00 00 00 nop
_Thread_Clear_state( _Thread_Executing, STATES_WAITING_FOR_PERIOD );
20073a4: d0 06 e0 0c ld [ %i3 + 0xc ], %o0
20073a8: 40 00 0b 4c call 200a0d8 <_Thread_Clear_state>
20073ac: 13 00 00 10 sethi %hi(0x4000), %o1
_Thread_Enable_dispatch();
20073b0: 40 00 0c 28 call 200a450 <_Thread_Enable_dispatch>
20073b4: b0 10 20 00 clr %i0
return RTEMS_SUCCESSFUL;
20073b8: 81 c7 e0 08 ret
20073bc: 81 e8 00 00 restore
}
if ( the_period->state == RATE_MONOTONIC_EXPIRED ) {
20073c0: 12 bf ff b9 bne 20072a4 <rtems_rate_monotonic_period+0x4c><== NEVER TAKEN
20073c4: b0 10 20 04 mov 4, %i0
/*
* Update statistics from the concluding period
*/
_Rate_monotonic_Update_statistics( the_period );
20073c8: 7f ff ff 68 call 2007168 <_Rate_monotonic_Update_statistics>
20073cc: 90 10 00 1d mov %i5, %o0
_ISR_Enable( level );
20073d0: 7f ff ee b7 call 2002eac <sparc_enable_interrupts>
20073d4: 90 10 00 1a mov %i2, %o0
the_period->state = RATE_MONOTONIC_ACTIVE;
20073d8: 82 10 20 02 mov 2, %g1
20073dc: 92 07 60 10 add %i5, 0x10, %o1
20073e0: 11 00 80 74 sethi %hi(0x201d000), %o0
20073e4: 90 12 23 ec or %o0, 0x3ec, %o0 ! 201d3ec <_Watchdog_Ticks_chain>
20073e8: c2 27 60 38 st %g1, [ %i5 + 0x38 ]
the_period->next_length = length;
20073ec: f2 27 60 3c st %i1, [ %i5 + 0x3c ]
Watchdog_Control *the_watchdog,
Watchdog_Interval units
)
{
the_watchdog->initial = units;
20073f0: f2 27 60 1c st %i1, [ %i5 + 0x1c ]
_Watchdog_Insert( &_Watchdog_Ticks_chain, the_watchdog );
20073f4: 40 00 0f dd call 200b368 <_Watchdog_Insert>
20073f8: b0 10 20 06 mov 6, %i0
_Watchdog_Insert_ticks( &the_period->Timer, length );
_Thread_Enable_dispatch();
20073fc: 40 00 0c 15 call 200a450 <_Thread_Enable_dispatch>
2007400: 01 00 00 00 nop
return RTEMS_TIMEOUT;
2007404: 81 c7 e0 08 ret
2007408: 81 e8 00 00 restore
#endif
case OBJECTS_ERROR:
break;
}
return RTEMS_INVALID_ID;
200740c: b0 10 20 04 mov 4, %i0
}
2007410: 81 c7 e0 08 ret
2007414: 81 e8 00 00 restore
02007418 <rtems_rate_monotonic_report_statistics_with_plugin>:
*/
void rtems_rate_monotonic_report_statistics_with_plugin(
void *context,
rtems_printk_plugin_t print
)
{
2007418: 9d e3 bf 38 save %sp, -200, %sp
rtems_id id;
rtems_rate_monotonic_period_statistics the_stats;
rtems_rate_monotonic_period_status the_status;
char name[5];
if ( !print )
200741c: 80 a6 60 00 cmp %i1, 0
2007420: 02 80 00 75 be 20075f4 <rtems_rate_monotonic_report_statistics_with_plugin+0x1dc><== NEVER TAKEN
2007424: 90 10 00 18 mov %i0, %o0
return;
(*print)( context, "Period information by period\n" );
2007428: 13 00 80 6c sethi %hi(0x201b000), %o1
200742c: 9f c6 40 00 call %i1
2007430: 92 12 62 10 or %o1, 0x210, %o1 ! 201b210 <CSWTCH.2+0x8>
#ifndef __RTEMS_USE_TICKS_FOR_STATISTICS__
(*print)( context, "--- CPU times are in seconds ---\n" );
2007434: 90 10 00 18 mov %i0, %o0
2007438: 13 00 80 6c sethi %hi(0x201b000), %o1
200743c: 9f c6 40 00 call %i1
2007440: 92 12 62 30 or %o1, 0x230, %o1 ! 201b230 <CSWTCH.2+0x28>
(*print)( context, "--- Wall times are in seconds ---\n" );
2007444: 90 10 00 18 mov %i0, %o0
2007448: 13 00 80 6c sethi %hi(0x201b000), %o1
200744c: 9f c6 40 00 call %i1
2007450: 92 12 62 58 or %o1, 0x258, %o1 ! 201b258 <CSWTCH.2+0x50>
Be sure to test the various cases.
(*print)( context,"\
1234567890123456789012345678901234567890123456789012345678901234567890123456789\
\n");
*/
(*print)( context, " ID OWNER COUNT MISSED "
2007454: 90 10 00 18 mov %i0, %o0
2007458: 13 00 80 6c sethi %hi(0x201b000), %o1
200745c: 9f c6 40 00 call %i1
2007460: 92 12 62 80 or %o1, 0x280, %o1 ! 201b280 <CSWTCH.2+0x78>
#ifndef __RTEMS_USE_TICKS_FOR_STATISTICS__
" "
#endif
" WALL TIME\n"
);
(*print)( context, " "
2007464: 90 10 00 18 mov %i0, %o0
2007468: 13 00 80 6c sethi %hi(0x201b000), %o1
200746c: 9f c6 40 00 call %i1
2007470: 92 12 62 d0 or %o1, 0x2d0, %o1 ! 201b2d0 <CSWTCH.2+0xc8>
/*
* Cycle through all possible ids and try to report on each one. If it
* is a period that is inactive, we just get an error back. No big deal.
*/
for ( id=_Rate_monotonic_Information.minimum_id ;
2007474: 03 00 80 74 sethi %hi(0x201d000), %g1
rtems_object_get_name( the_status.owner, sizeof(name), name );
/*
* Print part of report line that is not dependent on granularity
*/
(*print)( context,
2007478: 21 00 80 6c sethi %hi(0x201b000), %l0
struct timespec *min_cpu = &the_stats.min_cpu_time;
struct timespec *max_cpu = &the_stats.max_cpu_time;
struct timespec *total_cpu = &the_stats.total_cpu_time;
_Timespec_Divide_by_integer( total_cpu, the_stats.count, &cpu_average );
(*print)( context,
200747c: 35 00 80 6c sethi %hi(0x201b000), %i2
struct timespec *min_wall = &the_stats.min_wall_time;
struct timespec *max_wall = &the_stats.max_wall_time;
struct timespec *total_wall = &the_stats.total_wall_time;
_Timespec_Divide_by_integer(total_wall, the_stats.count, &wall_average);
(*print)( context,
2007480: 37 00 80 6c sethi %hi(0x201b000), %i3
/*
* If the count is zero, don't print statistics
*/
if (the_stats.count == 0) {
(*print)( context, "\n" );
2007484: 39 00 80 69 sethi %hi(0x201a400), %i4
/*
* Cycle through all possible ids and try to report on each one. If it
* is a period that is inactive, we just get an error back. No big deal.
*/
for ( id=_Rate_monotonic_Information.minimum_id ;
2007488: fa 00 61 cc ld [ %g1 + 0x1cc ], %i5
rtems_object_get_name( the_status.owner, sizeof(name), name );
/*
* Print part of report line that is not dependent on granularity
*/
(*print)( context,
200748c: a0 14 23 20 or %l0, 0x320, %l0
struct timespec *min_cpu = &the_stats.min_cpu_time;
struct timespec *max_cpu = &the_stats.max_cpu_time;
struct timespec *total_cpu = &the_stats.total_cpu_time;
_Timespec_Divide_by_integer( total_cpu, the_stats.count, &cpu_average );
(*print)( context,
2007490: b4 16 a3 38 or %i2, 0x338, %i2
struct timespec *min_wall = &the_stats.min_wall_time;
struct timespec *max_wall = &the_stats.max_wall_time;
struct timespec *total_wall = &the_stats.total_wall_time;
_Timespec_Divide_by_integer(total_wall, the_stats.count, &wall_average);
(*print)( context,
2007494: b6 16 e3 58 or %i3, 0x358, %i3
/*
* Cycle through all possible ids and try to report on each one. If it
* is a period that is inactive, we just get an error back. No big deal.
*/
for ( id=_Rate_monotonic_Information.minimum_id ;
2007498: 10 80 00 52 b 20075e0 <rtems_rate_monotonic_report_statistics_with_plugin+0x1c8>
200749c: b8 17 20 98 or %i4, 0x98, %i4
id <= _Rate_monotonic_Information.maximum_id ;
id++ ) {
status = rtems_rate_monotonic_get_statistics( id, &the_stats );
20074a0: 40 00 17 8b call 200d2cc <rtems_rate_monotonic_get_statistics>
20074a4: 92 07 bf a0 add %fp, -96, %o1
if ( status != RTEMS_SUCCESSFUL )
20074a8: 80 a2 20 00 cmp %o0, 0
20074ac: 32 80 00 4d bne,a 20075e0 <rtems_rate_monotonic_report_statistics_with_plugin+0x1c8>
20074b0: ba 07 60 01 inc %i5
#if defined(RTEMS_DEBUG)
status = rtems_rate_monotonic_get_status( id, &the_status );
if ( status != RTEMS_SUCCESSFUL )
continue;
#else
(void) rtems_rate_monotonic_get_status( id, &the_status );
20074b4: 92 07 bf d8 add %fp, -40, %o1
20074b8: 40 00 17 b2 call 200d380 <rtems_rate_monotonic_get_status>
20074bc: 90 10 00 1d mov %i5, %o0
#endif
rtems_object_get_name( the_status.owner, sizeof(name), name );
20074c0: d0 07 bf d8 ld [ %fp + -40 ], %o0
20074c4: 92 10 20 05 mov 5, %o1
20074c8: 40 00 00 af call 2007784 <rtems_object_get_name>
20074cc: 94 07 bf f8 add %fp, -8, %o2
/*
* Print part of report line that is not dependent on granularity
*/
(*print)( context,
20074d0: d8 1f bf a0 ldd [ %fp + -96 ], %o4
20074d4: 92 10 00 10 mov %l0, %o1
20074d8: 90 10 00 18 mov %i0, %o0
20074dc: 94 10 00 1d mov %i5, %o2
20074e0: 9f c6 40 00 call %i1
20074e4: 96 07 bf f8 add %fp, -8, %o3
);
/*
* If the count is zero, don't print statistics
*/
if (the_stats.count == 0) {
20074e8: d2 07 bf a0 ld [ %fp + -96 ], %o1
20074ec: 80 a2 60 00 cmp %o1, 0
20074f0: 12 80 00 07 bne 200750c <rtems_rate_monotonic_report_statistics_with_plugin+0xf4>
20074f4: 94 07 bf f0 add %fp, -16, %o2
(*print)( context, "\n" );
20074f8: 90 10 00 18 mov %i0, %o0
20074fc: 9f c6 40 00 call %i1
2007500: 92 10 00 1c mov %i4, %o1
continue;
2007504: 10 80 00 37 b 20075e0 <rtems_rate_monotonic_report_statistics_with_plugin+0x1c8>
2007508: ba 07 60 01 inc %i5
struct timespec cpu_average;
struct timespec *min_cpu = &the_stats.min_cpu_time;
struct timespec *max_cpu = &the_stats.max_cpu_time;
struct timespec *total_cpu = &the_stats.total_cpu_time;
_Timespec_Divide_by_integer( total_cpu, the_stats.count, &cpu_average );
200750c: 40 00 0e 78 call 200aeec <_Timespec_Divide_by_integer>
2007510: 90 07 bf b8 add %fp, -72, %o0
(*print)( context,
2007514: d0 07 bf ac ld [ %fp + -84 ], %o0
2007518: 40 00 43 b4 call 20183e8 <.div>
200751c: 92 10 23 e8 mov 0x3e8, %o1
2007520: a6 10 00 08 mov %o0, %l3
2007524: d0 07 bf b4 ld [ %fp + -76 ], %o0
2007528: 40 00 43 b0 call 20183e8 <.div>
200752c: 92 10 23 e8 mov 0x3e8, %o1
2007530: c2 07 bf f0 ld [ %fp + -16 ], %g1
2007534: a2 10 00 08 mov %o0, %l1
2007538: d0 07 bf f4 ld [ %fp + -12 ], %o0
200753c: e8 07 bf a8 ld [ %fp + -88 ], %l4
2007540: e4 07 bf b0 ld [ %fp + -80 ], %l2
2007544: c2 23 a0 5c st %g1, [ %sp + 0x5c ]
2007548: 40 00 43 a8 call 20183e8 <.div>
200754c: 92 10 23 e8 mov 0x3e8, %o1
2007550: 96 10 00 13 mov %l3, %o3
2007554: 98 10 00 12 mov %l2, %o4
2007558: 9a 10 00 11 mov %l1, %o5
200755c: 94 10 00 14 mov %l4, %o2
2007560: d0 23 a0 60 st %o0, [ %sp + 0x60 ]
2007564: 92 10 00 1a mov %i2, %o1
2007568: 9f c6 40 00 call %i1
200756c: 90 10 00 18 mov %i0, %o0
struct timespec wall_average;
struct timespec *min_wall = &the_stats.min_wall_time;
struct timespec *max_wall = &the_stats.max_wall_time;
struct timespec *total_wall = &the_stats.total_wall_time;
_Timespec_Divide_by_integer(total_wall, the_stats.count, &wall_average);
2007570: d2 07 bf a0 ld [ %fp + -96 ], %o1
2007574: 94 07 bf f0 add %fp, -16, %o2
2007578: 40 00 0e 5d call 200aeec <_Timespec_Divide_by_integer>
200757c: 90 07 bf d0 add %fp, -48, %o0
(*print)( context,
2007580: d0 07 bf c4 ld [ %fp + -60 ], %o0
2007584: 40 00 43 99 call 20183e8 <.div>
2007588: 92 10 23 e8 mov 0x3e8, %o1
200758c: a6 10 00 08 mov %o0, %l3
2007590: d0 07 bf cc ld [ %fp + -52 ], %o0
2007594: 40 00 43 95 call 20183e8 <.div>
2007598: 92 10 23 e8 mov 0x3e8, %o1
200759c: c2 07 bf f0 ld [ %fp + -16 ], %g1
20075a0: a2 10 00 08 mov %o0, %l1
20075a4: d0 07 bf f4 ld [ %fp + -12 ], %o0
20075a8: e8 07 bf c0 ld [ %fp + -64 ], %l4
20075ac: e4 07 bf c8 ld [ %fp + -56 ], %l2
20075b0: 92 10 23 e8 mov 0x3e8, %o1
20075b4: 40 00 43 8d call 20183e8 <.div>
20075b8: c2 23 a0 5c st %g1, [ %sp + 0x5c ]
20075bc: 92 10 00 1b mov %i3, %o1
20075c0: d0 23 a0 60 st %o0, [ %sp + 0x60 ]
20075c4: 94 10 00 14 mov %l4, %o2
20075c8: 90 10 00 18 mov %i0, %o0
20075cc: 96 10 00 13 mov %l3, %o3
20075d0: 98 10 00 12 mov %l2, %o4
20075d4: 9f c6 40 00 call %i1
20075d8: 9a 10 00 11 mov %l1, %o5
* Cycle through all possible ids and try to report on each one. If it
* is a period that is inactive, we just get an error back. No big deal.
*/
for ( id=_Rate_monotonic_Information.minimum_id ;
id <= _Rate_monotonic_Information.maximum_id ;
id++ ) {
20075dc: ba 07 60 01 inc %i5
/*
* Cycle through all possible ids and try to report on each one. If it
* is a period that is inactive, we just get an error back. No big deal.
*/
for ( id=_Rate_monotonic_Information.minimum_id ;
id <= _Rate_monotonic_Information.maximum_id ;
20075e0: 03 00 80 74 sethi %hi(0x201d000), %g1
/*
* Cycle through all possible ids and try to report on each one. If it
* is a period that is inactive, we just get an error back. No big deal.
*/
for ( id=_Rate_monotonic_Information.minimum_id ;
20075e4: c2 00 61 d0 ld [ %g1 + 0x1d0 ], %g1 ! 201d1d0 <_Rate_monotonic_Information+0xc>
20075e8: 80 a7 40 01 cmp %i5, %g1
20075ec: 08 bf ff ad bleu 20074a0 <rtems_rate_monotonic_report_statistics_with_plugin+0x88>
20075f0: 90 10 00 1d mov %i5, %o0
20075f4: 81 c7 e0 08 ret
20075f8: 81 e8 00 00 restore
020160dc <rtems_signal_send>:
rtems_status_code rtems_signal_send(
rtems_id id,
rtems_signal_set signal_set
)
{
20160dc: 9d e3 bf 98 save %sp, -104, %sp
20160e0: 90 10 00 18 mov %i0, %o0
register Thread_Control *the_thread;
Objects_Locations location;
RTEMS_API_Control *api;
ASR_Information *asr;
if ( !signal_set )
20160e4: 80 a6 60 00 cmp %i1, 0
20160e8: 02 80 00 2e be 20161a0 <rtems_signal_send+0xc4>
20160ec: b0 10 20 0a mov 0xa, %i0
return RTEMS_INVALID_NUMBER;
the_thread = _Thread_Get( id, &location );
20160f0: 40 00 11 e1 call 201a874 <_Thread_Get>
20160f4: 92 07 bf fc add %fp, -4, %o1
switch ( location ) {
20160f8: c2 07 bf fc ld [ %fp + -4 ], %g1
ASR_Information *asr;
if ( !signal_set )
return RTEMS_INVALID_NUMBER;
the_thread = _Thread_Get( id, &location );
20160fc: b8 10 00 08 mov %o0, %i4
switch ( location ) {
2016100: 80 a0 60 00 cmp %g1, 0
2016104: 12 80 00 27 bne 20161a0 <rtems_signal_send+0xc4>
2016108: b0 10 20 04 mov 4, %i0
case OBJECTS_LOCAL:
api = the_thread->API_Extensions[ THREAD_API_RTEMS ];
201610c: fa 02 21 58 ld [ %o0 + 0x158 ], %i5
asr = &api->Signal;
if ( ! _ASR_Is_null_handler( asr->handler ) ) {
2016110: c2 07 60 0c ld [ %i5 + 0xc ], %g1
2016114: 80 a0 60 00 cmp %g1, 0
2016118: 02 80 00 24 be 20161a8 <rtems_signal_send+0xcc>
201611c: 01 00 00 00 nop
if ( asr->is_enabled ) {
2016120: c2 0f 60 08 ldub [ %i5 + 8 ], %g1
2016124: 80 a0 60 00 cmp %g1, 0
2016128: 02 80 00 15 be 201617c <rtems_signal_send+0xa0>
201612c: 01 00 00 00 nop
rtems_signal_set *signal_set
)
{
ISR_Level _level;
_ISR_Disable( _level );
2016130: 7f ff e7 e4 call 20100c0 <sparc_disable_interrupts>
2016134: 01 00 00 00 nop
*signal_set |= signals;
2016138: c2 07 60 14 ld [ %i5 + 0x14 ], %g1
201613c: b2 10 40 19 or %g1, %i1, %i1
2016140: f2 27 60 14 st %i1, [ %i5 + 0x14 ]
_ISR_Enable( _level );
2016144: 7f ff e7 e3 call 20100d0 <sparc_enable_interrupts>
2016148: 01 00 00 00 nop
_ASR_Post_signals( signal_set, &asr->signals_posted );
if ( _ISR_Is_in_progress() && _Thread_Is_executing( the_thread ) )
201614c: 03 00 80 e8 sethi %hi(0x203a000), %g1
2016150: 82 10 61 d4 or %g1, 0x1d4, %g1 ! 203a1d4 <_Per_CPU_Information>
2016154: c4 00 60 08 ld [ %g1 + 8 ], %g2
2016158: 80 a0 a0 00 cmp %g2, 0
201615c: 02 80 00 0f be 2016198 <rtems_signal_send+0xbc>
2016160: 01 00 00 00 nop
2016164: c4 00 60 0c ld [ %g1 + 0xc ], %g2
2016168: 80 a7 00 02 cmp %i4, %g2
201616c: 12 80 00 0b bne 2016198 <rtems_signal_send+0xbc> <== NEVER TAKEN
2016170: 84 10 20 01 mov 1, %g2
_Thread_Dispatch_necessary = true;
2016174: c4 28 60 18 stb %g2, [ %g1 + 0x18 ]
2016178: 30 80 00 08 b,a 2016198 <rtems_signal_send+0xbc>
rtems_signal_set *signal_set
)
{
ISR_Level _level;
_ISR_Disable( _level );
201617c: 7f ff e7 d1 call 20100c0 <sparc_disable_interrupts>
2016180: 01 00 00 00 nop
*signal_set |= signals;
2016184: c2 07 60 18 ld [ %i5 + 0x18 ], %g1
2016188: b2 10 40 19 or %g1, %i1, %i1
201618c: f2 27 60 18 st %i1, [ %i5 + 0x18 ]
_ISR_Enable( _level );
2016190: 7f ff e7 d0 call 20100d0 <sparc_enable_interrupts>
2016194: 01 00 00 00 nop
} else {
_ASR_Post_signals( signal_set, &asr->signals_pending );
}
_Thread_Enable_dispatch();
2016198: 40 00 11 aa call 201a840 <_Thread_Enable_dispatch>
201619c: b0 10 20 00 clr %i0 ! 0 <PROM_START>
return RTEMS_SUCCESSFUL;
20161a0: 81 c7 e0 08 ret
20161a4: 81 e8 00 00 restore
}
_Thread_Enable_dispatch();
20161a8: 40 00 11 a6 call 201a840 <_Thread_Enable_dispatch>
20161ac: b0 10 20 0b mov 0xb, %i0
return RTEMS_NOT_DEFINED;
20161b0: 81 c7 e0 08 ret
20161b4: 81 e8 00 00 restore
0200d798 <rtems_task_mode>:
rtems_status_code rtems_task_mode(
rtems_mode mode_set,
rtems_mode mask,
rtems_mode *previous_mode_set
)
{
200d798: 9d e3 bf a0 save %sp, -96, %sp
ASR_Information *asr;
bool is_asr_enabled = false;
bool needs_asr_dispatching = false;
rtems_mode old_mode;
if ( !previous_mode_set )
200d79c: 80 a6 a0 00 cmp %i2, 0
200d7a0: 02 80 00 5a be 200d908 <rtems_task_mode+0x170>
200d7a4: 82 10 20 09 mov 9, %g1
return RTEMS_INVALID_ADDRESS;
executing = _Thread_Executing;
200d7a8: 03 00 80 6d sethi %hi(0x201b400), %g1
200d7ac: f8 00 62 e8 ld [ %g1 + 0x2e8 ], %i4 ! 201b6e8 <_Per_CPU_Information+0xc>
api = executing->API_Extensions[ THREAD_API_RTEMS ];
asr = &api->Signal;
old_mode = (executing->is_preemptible) ? RTEMS_PREEMPT : RTEMS_NO_PREEMPT;
200d7b0: c2 0f 20 74 ldub [ %i4 + 0x74 ], %g1
if ( !previous_mode_set )
return RTEMS_INVALID_ADDRESS;
executing = _Thread_Executing;
api = executing->API_Extensions[ THREAD_API_RTEMS ];
200d7b4: fa 07 21 58 ld [ %i4 + 0x158 ], %i5
asr = &api->Signal;
old_mode = (executing->is_preemptible) ? RTEMS_PREEMPT : RTEMS_NO_PREEMPT;
200d7b8: 80 a0 00 01 cmp %g0, %g1
if ( executing->budget_algorithm == THREAD_CPU_BUDGET_ALGORITHM_NONE )
200d7bc: c2 07 20 7c ld [ %i4 + 0x7c ], %g1
executing = _Thread_Executing;
api = executing->API_Extensions[ THREAD_API_RTEMS ];
asr = &api->Signal;
old_mode = (executing->is_preemptible) ? RTEMS_PREEMPT : RTEMS_NO_PREEMPT;
200d7c0: b6 60 3f ff subx %g0, -1, %i3
if ( executing->budget_algorithm == THREAD_CPU_BUDGET_ALGORITHM_NONE )
200d7c4: 80 a0 60 00 cmp %g1, 0
200d7c8: 02 80 00 03 be 200d7d4 <rtems_task_mode+0x3c>
200d7cc: b7 2e e0 08 sll %i3, 8, %i3
old_mode |= RTEMS_NO_TIMESLICE;
else
old_mode |= RTEMS_TIMESLICE;
200d7d0: b6 16 e2 00 or %i3, 0x200, %i3
old_mode |= (asr->is_enabled) ? RTEMS_ASR : RTEMS_NO_ASR;
200d7d4: c2 0f 60 08 ldub [ %i5 + 8 ], %g1
200d7d8: 80 a0 00 01 cmp %g0, %g1
old_mode |= _ISR_Get_level();
200d7dc: 7f ff f1 ea call 2009f84 <_CPU_ISR_Get_level>
200d7e0: a0 60 3f ff subx %g0, -1, %l0
if ( executing->budget_algorithm == THREAD_CPU_BUDGET_ALGORITHM_NONE )
old_mode |= RTEMS_NO_TIMESLICE;
else
old_mode |= RTEMS_TIMESLICE;
old_mode |= (asr->is_enabled) ? RTEMS_ASR : RTEMS_NO_ASR;
200d7e4: a1 2c 20 0a sll %l0, 0xa, %l0
200d7e8: a0 14 00 08 or %l0, %o0, %l0
old_mode |= _ISR_Get_level();
200d7ec: b6 14 00 1b or %l0, %i3, %i3
*previous_mode_set = old_mode;
/*
* These are generic thread scheduling characteristics.
*/
if ( mask & RTEMS_PREEMPT_MASK )
200d7f0: 80 8e 61 00 btst 0x100, %i1
200d7f4: 02 80 00 06 be 200d80c <rtems_task_mode+0x74>
200d7f8: f6 26 80 00 st %i3, [ %i2 ]
*/
RTEMS_INLINE_ROUTINE bool _Modes_Is_preempt (
Modes_Control mode_set
)
{
return (mode_set & RTEMS_PREEMPT_MASK) == RTEMS_PREEMPT;
200d7fc: 82 0e 21 00 and %i0, 0x100, %g1
executing->is_preemptible = _Modes_Is_preempt(mode_set) ? true : false;
200d800: 80 a0 00 01 cmp %g0, %g1
200d804: 82 60 3f ff subx %g0, -1, %g1
200d808: c2 2f 20 74 stb %g1, [ %i4 + 0x74 ]
if ( mask & RTEMS_TIMESLICE_MASK ) {
200d80c: 80 8e 62 00 btst 0x200, %i1
200d810: 02 80 00 0b be 200d83c <rtems_task_mode+0xa4>
200d814: 80 8e 60 0f btst 0xf, %i1
if ( _Modes_Is_timeslice(mode_set) ) {
200d818: 80 8e 22 00 btst 0x200, %i0
200d81c: 22 80 00 07 be,a 200d838 <rtems_task_mode+0xa0>
200d820: c0 27 20 7c clr [ %i4 + 0x7c ]
executing->budget_algorithm = THREAD_CPU_BUDGET_ALGORITHM_RESET_TIMESLICE;
200d824: 82 10 20 01 mov 1, %g1
200d828: c2 27 20 7c st %g1, [ %i4 + 0x7c ]
executing->cpu_time_budget = _Thread_Ticks_per_timeslice;
200d82c: 03 00 80 6d sethi %hi(0x201b400), %g1
200d830: c2 00 60 14 ld [ %g1 + 0x14 ], %g1 ! 201b414 <_Thread_Ticks_per_timeslice>
200d834: c2 27 20 78 st %g1, [ %i4 + 0x78 ]
}
/*
* Set the new interrupt level
*/
if ( mask & RTEMS_INTERRUPT_MASK )
200d838: 80 8e 60 0f btst 0xf, %i1
200d83c: 02 80 00 06 be 200d854 <rtems_task_mode+0xbc>
200d840: 80 8e 64 00 btst 0x400, %i1
*/
RTEMS_INLINE_ROUTINE ISR_Level _Modes_Get_interrupt_level (
Modes_Control mode_set
)
{
return ( mode_set & RTEMS_INTERRUPT_MASK );
200d844: 90 0e 20 0f and %i0, 0xf, %o0
*/
RTEMS_INLINE_ROUTINE void _Modes_Set_interrupt_level (
Modes_Control mode_set
)
{
_ISR_Set_level( _Modes_Get_interrupt_level( mode_set ) );
200d848: 7f ff d2 51 call 200218c <sparc_enable_interrupts>
200d84c: 91 2a 20 08 sll %o0, 8, %o0
* This is specific to the RTEMS API
*/
is_asr_enabled = false;
needs_asr_dispatching = false;
if ( mask & RTEMS_ASR_MASK ) {
200d850: 80 8e 64 00 btst 0x400, %i1
200d854: 02 80 00 14 be 200d8a4 <rtems_task_mode+0x10c>
200d858: 88 10 20 00 clr %g4
is_asr_enabled = _Modes_Is_asr_disabled( mode_set ) ? false : true;
if ( is_asr_enabled != asr->is_enabled ) {
200d85c: c4 0f 60 08 ldub [ %i5 + 8 ], %g2
*/
RTEMS_INLINE_ROUTINE bool _Modes_Is_asr_disabled (
Modes_Control mode_set
)
{
return (mode_set & RTEMS_ASR_MASK) == RTEMS_NO_ASR;
200d860: b0 0e 24 00 and %i0, 0x400, %i0
* Output:
* *previous_mode_set - previous mode set
* always return RTEMS_SUCCESSFUL;
*/
rtems_status_code rtems_task_mode(
200d864: 80 a0 00 18 cmp %g0, %i0
200d868: 82 60 3f ff subx %g0, -1, %g1
is_asr_enabled = false;
needs_asr_dispatching = false;
if ( mask & RTEMS_ASR_MASK ) {
is_asr_enabled = _Modes_Is_asr_disabled( mode_set ) ? false : true;
if ( is_asr_enabled != asr->is_enabled ) {
200d86c: 80 a0 40 02 cmp %g1, %g2
200d870: 22 80 00 0e be,a 200d8a8 <rtems_task_mode+0x110>
200d874: 03 00 80 6d sethi %hi(0x201b400), %g1
)
{
rtems_signal_set _signals;
ISR_Level _level;
_ISR_Disable( _level );
200d878: 7f ff d2 41 call 200217c <sparc_disable_interrupts>
200d87c: c2 2f 60 08 stb %g1, [ %i5 + 8 ]
_signals = information->signals_pending;
200d880: c2 07 60 18 ld [ %i5 + 0x18 ], %g1
information->signals_pending = information->signals_posted;
200d884: c4 07 60 14 ld [ %i5 + 0x14 ], %g2
information->signals_posted = _signals;
200d888: c2 27 60 14 st %g1, [ %i5 + 0x14 ]
rtems_signal_set _signals;
ISR_Level _level;
_ISR_Disable( _level );
_signals = information->signals_pending;
information->signals_pending = information->signals_posted;
200d88c: c4 27 60 18 st %g2, [ %i5 + 0x18 ]
information->signals_posted = _signals;
_ISR_Enable( _level );
200d890: 7f ff d2 3f call 200218c <sparc_enable_interrupts>
200d894: 01 00 00 00 nop
asr->is_enabled = is_asr_enabled;
_ASR_Swap_signals( asr );
if ( _ASR_Are_signals_pending( asr ) ) {
200d898: c2 07 60 14 ld [ %i5 + 0x14 ], %g1
/*
* This is specific to the RTEMS API
*/
is_asr_enabled = false;
needs_asr_dispatching = false;
200d89c: 80 a0 00 01 cmp %g0, %g1
200d8a0: 88 40 20 00 addx %g0, 0, %g4
needs_asr_dispatching = true;
}
}
}
if ( _System_state_Is_up( _System_state_Get() ) ) {
200d8a4: 03 00 80 6d sethi %hi(0x201b400), %g1
200d8a8: c4 00 62 04 ld [ %g1 + 0x204 ], %g2 ! 201b604 <_System_state_Current>
200d8ac: 80 a0 a0 03 cmp %g2, 3
200d8b0: 12 80 00 16 bne 200d908 <rtems_task_mode+0x170>
200d8b4: 82 10 20 00 clr %g1
bool are_signals_pending
)
{
Thread_Control *executing;
executing = _Thread_Executing;
200d8b8: 07 00 80 6d sethi %hi(0x201b400), %g3
if ( are_signals_pending ||
200d8bc: 80 89 20 ff btst 0xff, %g4
bool are_signals_pending
)
{
Thread_Control *executing;
executing = _Thread_Executing;
200d8c0: 86 10 e2 dc or %g3, 0x2dc, %g3
if ( are_signals_pending ||
200d8c4: 12 80 00 0a bne 200d8ec <rtems_task_mode+0x154>
200d8c8: c4 00 e0 0c ld [ %g3 + 0xc ], %g2
200d8cc: c6 00 e0 10 ld [ %g3 + 0x10 ], %g3
200d8d0: 80 a0 80 03 cmp %g2, %g3
200d8d4: 02 80 00 0d be 200d908 <rtems_task_mode+0x170>
200d8d8: 01 00 00 00 nop
(!_Thread_Is_heir( executing ) && executing->is_preemptible) ) {
200d8dc: c4 08 a0 74 ldub [ %g2 + 0x74 ], %g2
200d8e0: 80 a0 a0 00 cmp %g2, 0
200d8e4: 02 80 00 09 be 200d908 <rtems_task_mode+0x170> <== NEVER TAKEN
200d8e8: 01 00 00 00 nop
_Thread_Dispatch_necessary = true;
200d8ec: 84 10 20 01 mov 1, %g2 ! 1 <PROM_START+0x1>
200d8f0: 03 00 80 6d sethi %hi(0x201b400), %g1
200d8f4: 82 10 62 dc or %g1, 0x2dc, %g1 ! 201b6dc <_Per_CPU_Information>
200d8f8: c4 28 60 18 stb %g2, [ %g1 + 0x18 ]
if (_Thread_Evaluate_is_dispatch_needed( needs_asr_dispatching ) )
_Thread_Dispatch();
200d8fc: 7f ff ec 77 call 2008ad8 <_Thread_Dispatch>
200d900: 01 00 00 00 nop
}
return RTEMS_SUCCESSFUL;
200d904: 82 10 20 00 clr %g1 ! 0 <PROM_START>
}
200d908: 81 c7 e0 08 ret
200d90c: 91 e8 00 01 restore %g0, %g1, %o0
0200aa28 <rtems_task_set_priority>:
rtems_status_code rtems_task_set_priority(
rtems_id id,
rtems_task_priority new_priority,
rtems_task_priority *old_priority
)
{
200aa28: 9d e3 bf 98 save %sp, -104, %sp
register Thread_Control *the_thread;
Objects_Locations location;
if ( new_priority != RTEMS_CURRENT_PRIORITY &&
200aa2c: 80 a6 60 00 cmp %i1, 0
200aa30: 02 80 00 07 be 200aa4c <rtems_task_set_priority+0x24>
200aa34: 90 10 00 18 mov %i0, %o0
RTEMS_INLINE_ROUTINE bool _RTEMS_tasks_Priority_is_valid (
rtems_task_priority the_priority
)
{
return ( ( the_priority >= RTEMS_MINIMUM_PRIORITY ) &&
( the_priority <= RTEMS_MAXIMUM_PRIORITY ) );
200aa38: 03 00 80 61 sethi %hi(0x2018400), %g1
200aa3c: c2 08 62 9c ldub [ %g1 + 0x29c ], %g1 ! 201869c <rtems_maximum_priority>
200aa40: 80 a6 40 01 cmp %i1, %g1
200aa44: 18 80 00 1c bgu 200aab4 <rtems_task_set_priority+0x8c>
200aa48: b0 10 20 13 mov 0x13, %i0
!_RTEMS_tasks_Priority_is_valid( new_priority ) )
return RTEMS_INVALID_PRIORITY;
if ( !old_priority )
200aa4c: 80 a6 a0 00 cmp %i2, 0
200aa50: 02 80 00 19 be 200aab4 <rtems_task_set_priority+0x8c>
200aa54: b0 10 20 09 mov 9, %i0
return RTEMS_INVALID_ADDRESS;
the_thread = _Thread_Get( id, &location );
200aa58: 40 00 09 4f call 200cf94 <_Thread_Get>
200aa5c: 92 07 bf fc add %fp, -4, %o1
switch ( location ) {
200aa60: c2 07 bf fc ld [ %fp + -4 ], %g1
200aa64: 80 a0 60 00 cmp %g1, 0
200aa68: 12 80 00 13 bne 200aab4 <rtems_task_set_priority+0x8c>
200aa6c: b0 10 20 04 mov 4, %i0
case OBJECTS_LOCAL:
/* XXX need helper to "convert" from core priority */
*old_priority = the_thread->current_priority;
200aa70: c2 02 20 14 ld [ %o0 + 0x14 ], %g1
if ( new_priority != RTEMS_CURRENT_PRIORITY ) {
200aa74: 80 a6 60 00 cmp %i1, 0
200aa78: 02 80 00 0d be 200aaac <rtems_task_set_priority+0x84>
200aa7c: c2 26 80 00 st %g1, [ %i2 ]
the_thread->real_priority = new_priority;
if ( the_thread->resource_count == 0 ||
200aa80: c2 02 20 1c ld [ %o0 + 0x1c ], %g1
200aa84: 80 a0 60 00 cmp %g1, 0
200aa88: 02 80 00 06 be 200aaa0 <rtems_task_set_priority+0x78>
200aa8c: f2 22 20 18 st %i1, [ %o0 + 0x18 ]
200aa90: c2 02 20 14 ld [ %o0 + 0x14 ], %g1
200aa94: 80 a0 40 19 cmp %g1, %i1
200aa98: 08 80 00 05 bleu 200aaac <rtems_task_set_priority+0x84> <== ALWAYS TAKEN
200aa9c: 01 00 00 00 nop
the_thread->current_priority > new_priority )
_Thread_Change_priority( the_thread, new_priority, false );
200aaa0: 92 10 00 19 mov %i1, %o1
200aaa4: 40 00 08 0b call 200cad0 <_Thread_Change_priority>
200aaa8: 94 10 20 00 clr %o2
}
_Thread_Enable_dispatch();
200aaac: 40 00 09 2d call 200cf60 <_Thread_Enable_dispatch>
200aab0: b0 10 20 00 clr %i0
return RTEMS_SUCCESSFUL;
200aab4: 81 c7 e0 08 ret
200aab8: 81 e8 00 00 restore
02016ae4 <rtems_timer_cancel>:
*/
rtems_status_code rtems_timer_cancel(
rtems_id id
)
{
2016ae4: 9d e3 bf 98 save %sp, -104, %sp
RTEMS_INLINE_ROUTINE Timer_Control *_Timer_Get (
Objects_Id id,
Objects_Locations *location
)
{
return (Timer_Control *)
2016ae8: 11 00 80 e8 sethi %hi(0x203a000), %o0
2016aec: 92 10 00 18 mov %i0, %o1
2016af0: 90 12 22 74 or %o0, 0x274, %o0
2016af4: 40 00 0b b3 call 20199c0 <_Objects_Get>
2016af8: 94 07 bf fc add %fp, -4, %o2
Timer_Control *the_timer;
Objects_Locations location;
the_timer = _Timer_Get( id, &location );
switch ( location ) {
2016afc: c2 07 bf fc ld [ %fp + -4 ], %g1
2016b00: 80 a0 60 00 cmp %g1, 0
2016b04: 12 80 00 0c bne 2016b34 <rtems_timer_cancel+0x50>
2016b08: 01 00 00 00 nop
case OBJECTS_LOCAL:
if ( !_Timer_Is_dormant_class( the_timer->the_class ) )
2016b0c: c2 02 20 38 ld [ %o0 + 0x38 ], %g1
2016b10: 80 a0 60 04 cmp %g1, 4
2016b14: 02 80 00 04 be 2016b24 <rtems_timer_cancel+0x40> <== NEVER TAKEN
2016b18: 01 00 00 00 nop
(void) _Watchdog_Remove( &the_timer->Ticker );
2016b1c: 40 00 13 b6 call 201b9f4 <_Watchdog_Remove>
2016b20: 90 02 20 10 add %o0, 0x10, %o0
_Thread_Enable_dispatch();
2016b24: 40 00 0f 47 call 201a840 <_Thread_Enable_dispatch>
2016b28: b0 10 20 00 clr %i0
return RTEMS_SUCCESSFUL;
2016b2c: 81 c7 e0 08 ret
2016b30: 81 e8 00 00 restore
case OBJECTS_ERROR:
break;
}
return RTEMS_INVALID_ID;
}
2016b34: 81 c7 e0 08 ret
2016b38: 91 e8 20 04 restore %g0, 4, %o0
02016fe0 <rtems_timer_server_fire_when>:
rtems_id id,
rtems_time_of_day *wall_time,
rtems_timer_service_routine_entry routine,
void *user_data
)
{
2016fe0: 9d e3 bf 98 save %sp, -104, %sp
Timer_Control *the_timer;
Objects_Locations location;
rtems_interval seconds;
Timer_server_Control *timer_server = _Timer_server;
2016fe4: 03 00 80 e8 sethi %hi(0x203a000), %g1
2016fe8: f8 00 62 b4 ld [ %g1 + 0x2b4 ], %i4 ! 203a2b4 <_Timer_server>
rtems_id id,
rtems_time_of_day *wall_time,
rtems_timer_service_routine_entry routine,
void *user_data
)
{
2016fec: ba 10 00 18 mov %i0, %i5
Timer_Control *the_timer;
Objects_Locations location;
rtems_interval seconds;
Timer_server_Control *timer_server = _Timer_server;
if ( !timer_server )
2016ff0: 80 a7 20 00 cmp %i4, 0
2016ff4: 02 80 00 32 be 20170bc <rtems_timer_server_fire_when+0xdc>
2016ff8: b0 10 20 0e mov 0xe, %i0
return RTEMS_INCORRECT_STATE;
if ( !_TOD_Is_set )
2016ffc: 03 00 80 e7 sethi %hi(0x2039c00), %g1
2017000: c2 08 63 b0 ldub [ %g1 + 0x3b0 ], %g1 ! 2039fb0 <_TOD_Is_set>
2017004: 80 a0 60 00 cmp %g1, 0
2017008: 02 80 00 2d be 20170bc <rtems_timer_server_fire_when+0xdc><== NEVER TAKEN
201700c: b0 10 20 0b mov 0xb, %i0
return RTEMS_NOT_DEFINED;
if ( !routine )
2017010: 80 a6 a0 00 cmp %i2, 0
2017014: 02 80 00 2a be 20170bc <rtems_timer_server_fire_when+0xdc>
2017018: b0 10 20 09 mov 9, %i0
return RTEMS_INVALID_ADDRESS;
if ( !_TOD_Validate( wall_time ) )
201701c: 90 10 00 19 mov %i1, %o0
2017020: 7f ff f4 11 call 2014064 <_TOD_Validate>
2017024: b0 10 20 14 mov 0x14, %i0
2017028: 80 8a 20 ff btst 0xff, %o0
201702c: 02 80 00 27 be 20170c8 <rtems_timer_server_fire_when+0xe8>
2017030: 01 00 00 00 nop
return RTEMS_INVALID_CLOCK;
seconds = _TOD_To_seconds( wall_time );
2017034: 7f ff f3 d8 call 2013f94 <_TOD_To_seconds>
2017038: 90 10 00 19 mov %i1, %o0
if ( seconds <= _TOD_Seconds_since_epoch() )
201703c: 21 00 80 e8 sethi %hi(0x203a000), %l0
2017040: c2 04 20 2c ld [ %l0 + 0x2c ], %g1 ! 203a02c <_TOD_Now>
2017044: 80 a2 00 01 cmp %o0, %g1
2017048: 08 80 00 1d bleu 20170bc <rtems_timer_server_fire_when+0xdc>
201704c: b2 10 00 08 mov %o0, %i1
2017050: 11 00 80 e8 sethi %hi(0x203a000), %o0
2017054: 92 10 00 1d mov %i5, %o1
2017058: 90 12 22 74 or %o0, 0x274, %o0
201705c: 40 00 0a 59 call 20199c0 <_Objects_Get>
2017060: 94 07 bf fc add %fp, -4, %o2
return RTEMS_INVALID_CLOCK;
the_timer = _Timer_Get( id, &location );
switch ( location ) {
2017064: c2 07 bf fc ld [ %fp + -4 ], %g1
2017068: 80 a0 60 00 cmp %g1, 0
201706c: 12 80 00 16 bne 20170c4 <rtems_timer_server_fire_when+0xe4>
2017070: b0 10 00 08 mov %o0, %i0
case OBJECTS_LOCAL:
(void) _Watchdog_Remove( &the_timer->Ticker );
2017074: 40 00 12 60 call 201b9f4 <_Watchdog_Remove>
2017078: 90 02 20 10 add %o0, 0x10, %o0
the_timer->the_class = TIMER_TIME_OF_DAY_ON_TASK;
201707c: 82 10 20 03 mov 3, %g1
2017080: c2 26 20 38 st %g1, [ %i0 + 0x38 ]
_Watchdog_Initialize( &the_timer->Ticker, routine, id, user_data );
the_timer->Ticker.initial = seconds - _TOD_Seconds_since_epoch();
2017084: c2 04 20 2c ld [ %l0 + 0x2c ], %g1
(*timer_server->schedule_operation)( timer_server, the_timer );
2017088: 92 10 00 18 mov %i0, %o1
case OBJECTS_LOCAL:
(void) _Watchdog_Remove( &the_timer->Ticker );
the_timer->the_class = TIMER_TIME_OF_DAY_ON_TASK;
_Watchdog_Initialize( &the_timer->Ticker, routine, id, user_data );
the_timer->Ticker.initial = seconds - _TOD_Seconds_since_epoch();
201708c: b2 26 40 01 sub %i1, %g1, %i1
(*timer_server->schedule_operation)( timer_server, the_timer );
2017090: c2 07 20 04 ld [ %i4 + 4 ], %g1
2017094: 90 10 00 1c mov %i4, %o0
Watchdog_Service_routine_entry routine,
Objects_Id id,
void *user_data
)
{
the_watchdog->state = WATCHDOG_INACTIVE;
2017098: c0 26 20 18 clr [ %i0 + 0x18 ]
the_watchdog->routine = routine;
201709c: f4 26 20 2c st %i2, [ %i0 + 0x2c ]
the_watchdog->id = id;
20170a0: fa 26 20 30 st %i5, [ %i0 + 0x30 ]
the_watchdog->user_data = user_data;
20170a4: f6 26 20 34 st %i3, [ %i0 + 0x34 ]
case OBJECTS_LOCAL:
(void) _Watchdog_Remove( &the_timer->Ticker );
the_timer->the_class = TIMER_TIME_OF_DAY_ON_TASK;
_Watchdog_Initialize( &the_timer->Ticker, routine, id, user_data );
the_timer->Ticker.initial = seconds - _TOD_Seconds_since_epoch();
20170a8: f2 26 20 1c st %i1, [ %i0 + 0x1c ]
(*timer_server->schedule_operation)( timer_server, the_timer );
20170ac: 9f c0 40 00 call %g1
20170b0: b0 10 20 00 clr %i0
_Thread_Enable_dispatch();
20170b4: 40 00 0d e3 call 201a840 <_Thread_Enable_dispatch>
20170b8: 01 00 00 00 nop
return RTEMS_SUCCESSFUL;
20170bc: 81 c7 e0 08 ret
20170c0: 81 e8 00 00 restore
#endif
case OBJECTS_ERROR:
break;
}
return RTEMS_INVALID_ID;
20170c4: b0 10 20 04 mov 4, %i0
}
20170c8: 81 c7 e0 08 ret
20170cc: 81 e8 00 00 restore