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/*
* Copyright ( c ) 2018 - 2020 , Andreas Kling < kling @ serenityos . org >
* All rights reserved .
*
* Redistribution and use in source and binary forms , with or without
* modification , are permitted provided that the following conditions are met :
*
* 1. Redistributions of source code must retain the above copyright notice , this
* list of conditions and the following disclaimer .
*
* 2. Redistributions in binary form must reproduce the above copyright notice ,
* this list of conditions and the following disclaimer in the documentation
* and / or other materials provided with the distribution .
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS " AS IS "
* AND ANY EXPRESS OR IMPLIED WARRANTIES , INCLUDING , BUT NOT LIMITED TO , THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED . IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT , INDIRECT , INCIDENTAL , SPECIAL , EXEMPLARY , OR CONSEQUENTIAL
* DAMAGES ( INCLUDING , BUT NOT LIMITED TO , PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES ; LOSS OF USE , DATA , OR PROFITS ; OR BUSINESS INTERRUPTION ) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY , WHETHER IN CONTRACT , STRICT LIABILITY ,
* OR TORT ( INCLUDING NEGLIGENCE OR OTHERWISE ) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE , EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE .
*/
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# include <AK/Demangle.h>
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# include <AK/StringBuilder.h>
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# include <Kernel/Arch/i386/CPU.h>
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# include <Kernel/FileSystem/FileDescription.h>
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# include <Kernel/KSyms.h>
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# include <Kernel/Process.h>
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# include <Kernel/Profiling.h>
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# include <Kernel/Scheduler.h>
# include <Kernel/Thread.h>
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# include <Kernel/ThreadTracer.h>
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# include <Kernel/TimerQueue.h>
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# include <Kernel/VM/MemoryManager.h>
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# include <Kernel/VM/PageDirectory.h>
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# include <Kernel/VM/ProcessPagingScope.h>
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# include <LibC/signal_numbers.h>
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# include <LibELF/Loader.h>
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//#define SIGNAL_DEBUG
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//#define THREAD_DEBUG
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namespace Kernel {
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Thread : : Thread ( NonnullRefPtr < Process > process )
: m_process ( move ( process ) )
, m_name ( m_process - > name ( ) )
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{
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if ( m_process - > m_thread_count . fetch_add ( 1 , AK : : MemoryOrder : : memory_order_acq_rel ) = = 0 ) {
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// First thread gets TID == PID
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m_tid = m_process - > pid ( ) . value ( ) ;
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} else {
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m_tid = Process : : allocate_pid ( ) . value ( ) ;
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}
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# ifdef THREAD_DEBUG
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dbg ( ) < < " Created new thread " < < m_process - > name ( ) < < " ( " < < m_process - > pid ( ) . value ( ) < < " : " < < m_tid . value ( ) < < " ) " ;
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# endif
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set_default_signal_dispositions ( ) ;
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m_fpu_state = ( FPUState * ) kmalloc_aligned ( sizeof ( FPUState ) , 16 ) ;
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reset_fpu_state ( ) ;
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memset ( & m_tss , 0 , sizeof ( m_tss ) ) ;
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m_tss . iomapbase = sizeof ( TSS32 ) ;
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// Only IF is set when a process boots.
m_tss . eflags = 0x0202 ;
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if ( m_process - > is_ring0 ( ) ) {
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m_tss . cs = GDT_SELECTOR_CODE0 ;
m_tss . ds = GDT_SELECTOR_DATA0 ;
m_tss . es = GDT_SELECTOR_DATA0 ;
m_tss . fs = GDT_SELECTOR_PROC ;
m_tss . ss = GDT_SELECTOR_DATA0 ;
m_tss . gs = 0 ;
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} else {
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m_tss . cs = GDT_SELECTOR_CODE3 | 3 ;
m_tss . ds = GDT_SELECTOR_DATA3 | 3 ;
m_tss . es = GDT_SELECTOR_DATA3 | 3 ;
m_tss . fs = GDT_SELECTOR_DATA3 | 3 ;
m_tss . ss = GDT_SELECTOR_DATA3 | 3 ;
m_tss . gs = GDT_SELECTOR_TLS | 3 ;
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}
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m_tss . cr3 = m_process - > page_directory ( ) . cr3 ( ) ;
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m_kernel_stack_region = MM . allocate_kernel_region ( default_kernel_stack_size , String : : format ( " Kernel Stack (Thread %d) " , m_tid . value ( ) ) , Region : : Access : : Read | Region : : Access : : Write , false , true ) ;
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m_kernel_stack_region - > set_stack ( true ) ;
m_kernel_stack_base = m_kernel_stack_region - > vaddr ( ) . get ( ) ;
m_kernel_stack_top = m_kernel_stack_region - > vaddr ( ) . offset ( default_kernel_stack_size ) . get ( ) & 0xfffffff8u ;
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if ( m_process - > is_ring0 ( ) ) {
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m_tss . esp = m_tss . esp0 = m_kernel_stack_top ;
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} else {
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// Ring 3 processes get a separate stack for ring 0.
// The ring 3 stack will be assigned by exec().
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m_tss . ss0 = GDT_SELECTOR_DATA0 ;
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m_tss . esp0 = m_kernel_stack_top ;
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}
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if ( m_process - > pid ( ) ! = 0 )
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Scheduler : : init_thread ( * this ) ;
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}
Thread : : ~ Thread ( )
{
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kfree_aligned ( m_fpu_state ) ;
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auto thread_cnt_before = m_process - > m_thread_count . fetch_sub ( 1 , AK : : MemoryOrder : : memory_order_acq_rel ) ;
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ASSERT ( thread_cnt_before ! = 0 ) ;
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}
void Thread : : unblock ( )
{
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ASSERT ( m_lock . own_lock ( ) ) ;
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m_blocker = nullptr ;
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if ( Thread : : current ( ) = = this ) {
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set_state ( Thread : : Running ) ;
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return ;
}
ASSERT ( m_state ! = Thread : : Runnable & & m_state ! = Thread : : Running ) ;
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set_state ( Thread : : Runnable ) ;
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}
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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void Thread : : set_should_die ( )
{
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if ( m_should_die ) {
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# ifdef THREAD_DEBUG
dbg ( ) < < * this < < " Should already die " ;
# endif
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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return ;
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}
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ScopedCritical critical ;
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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// Remember that we should die instead of returning to
// the userspace.
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{
ScopedSpinLock lock ( g_scheduler_lock ) ;
m_should_die = true ;
// NOTE: Even the current thread can technically be in "Stopped"
// state! This is the case when another thread sent a SIGSTOP to
// it while it was running and it calls e.g. exit() before
// the scheduler gets involved again.
if ( is_stopped ( ) ) {
// If we were stopped, we need to briefly resume so that
// the kernel stacks can clean up. We won't ever return back
// to user mode, though
resume_from_stopped ( ) ;
}
}
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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if ( is_blocked ( ) ) {
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ScopedSpinLock lock ( m_lock ) ;
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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ASSERT ( m_blocker ! = nullptr ) ;
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// We're blocked in the kernel.
m_blocker - > set_interrupted_by_death ( ) ;
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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unblock ( ) ;
}
}
void Thread : : die_if_needed ( )
{
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ASSERT ( Thread : : current ( ) = = this ) ;
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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if ( ! m_should_die )
return ;
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unlock_process_if_locked ( ) ;
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ScopedCritical critical ;
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set_should_die ( ) ;
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// Flag a context switch. Because we're in a critical section,
// Scheduler::yield will actually only mark a pending scontext switch
// Simply leaving the critical section would not necessarily trigger
// a switch.
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Scheduler : : yield ( ) ;
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// Now leave the critical section so that we can also trigger the
// actual context switch
u32 prev_flags ;
Processor : : current ( ) . clear_critical ( prev_flags , false ) ;
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dbg ( ) < < " die_if_needed returned form clear_critical!!! in irq: " < < Processor : : current ( ) . in_irq ( ) ;
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// We should never get here, but the scoped scheduler lock
// will be released by Scheduler::context_switch again
ASSERT_NOT_REACHED ( ) ;
Kernel: Unwind kernel stacks before dying
While executing in the kernel, a thread can acquire various resources
that need cleanup, such as locks and references to RefCounted objects.
This cleanup normally happens on the exit path, such as in destructors
for various RAII guards. But we weren't calling those exit paths when
killing threads that have been executing in the kernel, such as threads
blocked on reading or sleeping, thus causing leaks.
This commit changes how killing threads works. Now, instead of killing
a thread directly, one is supposed to call thread->set_should_die(),
which will unblock it and make it unwind the stack if it is blocked
in the kernel. Then, just before returning to the userspace, the thread
will automatically die.
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}
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void Thread : : yield_without_holding_big_lock ( )
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{
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bool did_unlock = unlock_process_if_locked ( ) ;
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Scheduler : : yield ( ) ;
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relock_process ( did_unlock ) ;
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}
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bool Thread : : unlock_process_if_locked ( )
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{
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return process ( ) . big_lock ( ) . force_unlock_if_locked ( ) ;
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}
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void Thread : : relock_process ( bool did_unlock )
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{
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if ( did_unlock )
process ( ) . big_lock ( ) . lock ( ) ;
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}
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u64 Thread : : sleep ( u64 ticks )
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{
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ASSERT ( state ( ) = = Thread : : Running ) ;
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u64 wakeup_time = g_uptime + ticks ;
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auto ret = Thread : : current ( ) - > block < Thread : : SleepBlocker > ( nullptr , wakeup_time ) ;
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if ( wakeup_time > g_uptime ) {
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ASSERT ( ret . was_interrupted ( ) ) ;
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}
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return wakeup_time ;
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}
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u64 Thread : : sleep_until ( u64 wakeup_time )
{
ASSERT ( state ( ) = = Thread : : Running ) ;
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auto ret = Thread : : current ( ) - > block < Thread : : SleepBlocker > ( nullptr , wakeup_time ) ;
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if ( wakeup_time > g_uptime )
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ASSERT ( ret . was_interrupted ( ) ) ;
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return wakeup_time ;
}
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const char * Thread : : state_string ( ) const
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{
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switch ( state ( ) ) {
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case Thread : : Invalid :
return " Invalid " ;
case Thread : : Runnable :
return " Runnable " ;
case Thread : : Running :
return " Running " ;
case Thread : : Dying :
return " Dying " ;
case Thread : : Dead :
return " Dead " ;
case Thread : : Stopped :
return " Stopped " ;
case Thread : : Skip1SchedulerPass :
return " Skip1 " ;
case Thread : : Skip0SchedulerPasses :
return " Skip0 " ;
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case Thread : : Queued :
return " Queued " ;
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case Thread : : Blocked :
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ASSERT ( m_blocker ! = nullptr ) ;
return m_blocker - > state_string ( ) ;
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}
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klog ( ) < < " Thread::state_string(): Invalid state: " < < state ( ) ;
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ASSERT_NOT_REACHED ( ) ;
return nullptr ;
}
void Thread : : finalize ( )
{
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ASSERT ( Thread : : current ( ) = = g_finalizer ) ;
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ASSERT ( Thread : : current ( ) ! = this ) ;
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# ifdef THREAD_DEBUG
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dbg ( ) < < " Finalizing thread " < < * this ;
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# endif
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set_state ( Thread : : State : : Dead ) ;
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if ( m_joiner ) {
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ScopedSpinLock lock ( m_joiner - > m_lock ) ;
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ASSERT ( m_joiner - > m_joinee = = this ) ;
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static_cast < JoinBlocker * > ( m_joiner - > m_blocker ) - > set_joinee_exit_value ( m_exit_value ) ;
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static_cast < JoinBlocker * > ( m_joiner - > m_blocker ) - > set_interrupted_by_death ( ) ;
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m_joiner - > m_joinee = nullptr ;
// NOTE: We clear the joiner pointer here as well, to be tidy.
m_joiner = nullptr ;
}
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if ( m_dump_backtrace_on_finalization )
dbg ( ) < < backtrace_impl ( ) ;
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}
void Thread : : finalize_dying_threads ( )
{
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ASSERT ( Thread : : current ( ) = = g_finalizer ) ;
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Vector < Thread * , 32 > dying_threads ;
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{
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ScopedSpinLock lock ( g_scheduler_lock ) ;
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for_each_in_state ( Thread : : State : : Dying , [ & ] ( Thread & thread ) {
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if ( thread . is_finalizable ( ) )
dying_threads . append ( & thread ) ;
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return IterationDecision : : Continue ;
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} ) ;
}
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for ( auto * thread : dying_threads ) {
auto & process = thread - > process ( ) ;
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thread - > finalize ( ) ;
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delete thread ;
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if ( process . m_thread_count . load ( AK : : MemoryOrder : : memory_order_consume ) = = 0 )
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process . finalize ( ) ;
}
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}
bool Thread : : tick ( )
{
+ + m_ticks ;
if ( tss ( ) . cs & 3 )
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+ + m_process - > m_ticks_in_user ;
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else
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+ + m_process - > m_ticks_in_kernel ;
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return - - m_ticks_left ;
}
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void Thread : : send_signal ( u8 signal , [[maybe_unused]] Process * sender )
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{
ASSERT ( signal < 32 ) ;
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InterruptDisabler disabler ;
// FIXME: Figure out what to do for masked signals. Should we also ignore them here?
if ( should_ignore_signal ( signal ) ) {
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# ifdef SIGNAL_DEBUG
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dbg ( ) < < " Signal " < < signal < < " was ignored by " < < process ( ) ;
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# endif
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return ;
}
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# ifdef SIGNAL_DEBUG
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if ( sender )
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dbg ( ) < < " Signal: " < < * sender < < " sent " < < signal < < " to " < < process ( ) ;
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else
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dbg ( ) < < " Signal: Kernel sent " < < signal < < " to " < < process ( ) ;
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# endif
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ScopedSpinLock lock ( g_scheduler_lock ) ;
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m_pending_signals | = 1 < < ( signal - 1 ) ;
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}
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// Certain exceptions, such as SIGSEGV and SIGILL, put a
// thread into a state where the signal handler must be
// invoked immediately, otherwise it will continue to fault.
// This function should be used in an exception handler to
// ensure that when the thread resumes, it's executing in
// the appropriate signal handler.
void Thread : : send_urgent_signal_to_self ( u8 signal )
{
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ASSERT ( Thread : : current ( ) = = this ) ;
ScopedSpinLock lock ( g_scheduler_lock ) ;
if ( dispatch_signal ( signal ) = = ShouldUnblockThread : : No )
Scheduler : : yield ( ) ;
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}
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ShouldUnblockThread Thread : : dispatch_one_pending_signal ( )
{
ASSERT_INTERRUPTS_DISABLED ( ) ;
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u32 signal_candidates = m_pending_signals & ~ m_signal_mask ;
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ASSERT ( signal_candidates ) ;
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u8 signal = 1 ;
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for ( ; signal < 32 ; + + signal ) {
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if ( signal_candidates & ( 1 < < ( signal - 1 ) ) ) {
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break ;
}
}
return dispatch_signal ( signal ) ;
}
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enum class DefaultSignalAction {
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Terminate ,
Ignore ,
DumpCore ,
Stop ,
Continue ,
} ;
Kernel: Mark compilation-unit-only functions as static
This enables a nice warning in case a function becomes dead code. Also, in case
of signal_trampoline_dummy, marking it external (non-static) prevents it from
being 'optimized away', which would lead to surprising and weird linker errors.
I found these places by using -Wmissing-declarations.
The Kernel still shows these issues, which I think are false-positives,
but don't want to touch:
- Kernel/Arch/i386/CPU.cpp:1081:17: void Kernel::enter_thread_context(Kernel::Thread*, Kernel::Thread*)
- Kernel/Arch/i386/CPU.cpp:1170:17: void Kernel::context_first_init(Kernel::Thread*, Kernel::Thread*, Kernel::TrapFrame*)
- Kernel/Arch/i386/CPU.cpp:1304:16: u32 Kernel::do_init_context(Kernel::Thread*, u32)
- Kernel/Arch/i386/CPU.cpp:1347:17: void Kernel::pre_init_finished()
- Kernel/Arch/i386/CPU.cpp:1360:17: void Kernel::post_init_finished()
No idea, not gonna touch it.
- Kernel/init.cpp:104:30: void Kernel::init()
- Kernel/init.cpp:167:30: void Kernel::init_ap(u32, Kernel::Processor*)
- Kernel/init.cpp:184:17: void Kernel::init_finished(u32)
Called by boot.S.
- Kernel/init.cpp:383:16: int Kernel::__cxa_atexit(void (*)(void*), void*, void*)
- Kernel/StdLib.cpp:285:19: void __cxa_pure_virtual()
- Kernel/StdLib.cpp:300:19: void __stack_chk_fail()
- Kernel/StdLib.cpp:305:19: void __stack_chk_fail_local()
Not sure how to tell the compiler that the compiler is already using them.
Also, maybe __cxa_atexit should go into StdLib.cpp?
- Kernel/Modules/TestModule.cpp:31:17: void module_init()
- Kernel/Modules/TestModule.cpp:40:17: void module_fini()
Could maybe go into a new header. This would also provide type-checking for new modules.
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static DefaultSignalAction default_signal_action ( u8 signal )
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{
ASSERT ( signal & & signal < NSIG ) ;
switch ( signal ) {
case SIGHUP :
case SIGINT :
case SIGKILL :
case SIGPIPE :
case SIGALRM :
case SIGUSR1 :
case SIGUSR2 :
case SIGVTALRM :
case SIGSTKFLT :
case SIGIO :
case SIGPROF :
case SIGTERM :
case SIGPWR :
return DefaultSignalAction : : Terminate ;
case SIGCHLD :
case SIGURG :
case SIGWINCH :
return DefaultSignalAction : : Ignore ;
case SIGQUIT :
case SIGILL :
case SIGTRAP :
case SIGABRT :
case SIGBUS :
case SIGFPE :
case SIGSEGV :
case SIGXCPU :
case SIGXFSZ :
case SIGSYS :
return DefaultSignalAction : : DumpCore ;
case SIGCONT :
return DefaultSignalAction : : Continue ;
case SIGSTOP :
case SIGTSTP :
case SIGTTIN :
case SIGTTOU :
return DefaultSignalAction : : Stop ;
}
ASSERT_NOT_REACHED ( ) ;
}
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bool Thread : : should_ignore_signal ( u8 signal ) const
{
ASSERT ( signal < 32 ) ;
auto & action = m_signal_action_data [ signal ] ;
if ( action . handler_or_sigaction . is_null ( ) )
return default_signal_action ( signal ) = = DefaultSignalAction : : Ignore ;
if ( action . handler_or_sigaction . as_ptr ( ) = = SIG_IGN )
return true ;
return false ;
}
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bool Thread : : has_signal_handler ( u8 signal ) const
{
ASSERT ( signal < 32 ) ;
auto & action = m_signal_action_data [ signal ] ;
return ! action . handler_or_sigaction . is_null ( ) ;
}
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static void push_value_on_user_stack ( u32 * stack , u32 data )
{
* stack - = 4 ;
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copy_to_user ( ( u32 * ) * stack , & data ) ;
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}
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void Thread : : resume_from_stopped ( )
{
ASSERT ( is_stopped ( ) ) ;
ASSERT ( m_stop_state ! = State : : Invalid ) ;
set_state ( m_stop_state ) ;
m_stop_state = State : : Invalid ;
// make sure SemiPermanentBlocker is unblocked
if ( m_state ! = Thread : : Runnable & & m_state ! = Thread : : Running ) {
ScopedSpinLock lock ( m_lock ) ;
if ( m_blocker & & m_blocker - > is_reason_signal ( ) )
unblock ( ) ;
}
}
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ShouldUnblockThread Thread : : dispatch_signal ( u8 signal )
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{
ASSERT_INTERRUPTS_DISABLED ( ) ;
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ASSERT ( g_scheduler_lock . is_locked ( ) ) ;
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ASSERT ( signal > 0 & & signal < = 32 ) ;
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ASSERT ( ! process ( ) . is_ring0 ( ) ) ;
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# ifdef SIGNAL_DEBUG
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klog ( ) < < " signal: dispatch signal " < < signal < < " to " < < * this ;
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# endif
auto & action = m_signal_action_data [ signal ] ;
// FIXME: Implement SA_SIGINFO signal handlers.
ASSERT ( ! ( action . flags & SA_SIGINFO ) ) ;
// Mark this signal as handled.
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m_pending_signals & = ~ ( 1 < < ( signal - 1 ) ) ;
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if ( signal = = SIGSTOP ) {
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if ( ! is_stopped ( ) ) {
m_stop_signal = SIGSTOP ;
set_state ( State : : Stopped ) ;
}
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return ShouldUnblockThread : : No ;
}
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if ( signal = = SIGCONT & & is_stopped ( ) ) {
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resume_from_stopped ( ) ;
} else {
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auto * thread_tracer = tracer ( ) ;
if ( thread_tracer ! = nullptr ) {
// when a thread is traced, it should be stopped whenever it receives a signal
// the tracer is notified of this by using waitpid()
// only "pending signals" from the tracer are sent to the tracee
if ( ! thread_tracer - > has_pending_signal ( signal ) ) {
m_stop_signal = signal ;
// make sure SemiPermanentBlocker is unblocked
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ScopedSpinLock lock ( m_lock ) ;
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if ( m_blocker & & m_blocker - > is_reason_signal ( ) )
unblock ( ) ;
set_state ( Stopped ) ;
return ShouldUnblockThread : : No ;
}
thread_tracer - > unset_signal ( signal ) ;
}
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}
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auto handler_vaddr = action . handler_or_sigaction ;
if ( handler_vaddr . is_null ( ) ) {
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switch ( default_signal_action ( signal ) ) {
case DefaultSignalAction : : Stop :
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m_stop_signal = signal ;
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set_state ( Stopped ) ;
return ShouldUnblockThread : : No ;
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case DefaultSignalAction : : DumpCore :
process ( ) . for_each_thread ( [ ] ( auto & thread ) {
thread . set_dump_backtrace_on_finalization ( ) ;
return IterationDecision : : Continue ;
} ) ;
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[[fallthrough]] ;
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case DefaultSignalAction : : Terminate :
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m_process - > terminate_due_to_signal ( signal ) ;
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return ShouldUnblockThread : : No ;
case DefaultSignalAction : : Ignore :
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ASSERT_NOT_REACHED ( ) ;
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case DefaultSignalAction : : Continue :
return ShouldUnblockThread : : Yes ;
}
ASSERT_NOT_REACHED ( ) ;
}
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if ( handler_vaddr . as_ptr ( ) = = SIG_IGN ) {
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# ifdef SIGNAL_DEBUG
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klog ( ) < < " signal: " < < * this < < " ignored signal " < < signal ;
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# endif
return ShouldUnblockThread : : Yes ;
}
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ProcessPagingScope paging_scope ( m_process ) ;
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u32 old_signal_mask = m_signal_mask ;
u32 new_signal_mask = action . mask ;
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if ( action . flags & SA_NODEFER )
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new_signal_mask & = ~ ( 1 < < ( signal - 1 ) ) ;
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else
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new_signal_mask | = 1 < < ( signal - 1 ) ;
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m_signal_mask | = new_signal_mask ;
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auto setup_stack = [ & ] < typename ThreadState > ( ThreadState state , u32 * stack ) {
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u32 old_esp = * stack ;
u32 ret_eip = state . eip ;
u32 ret_eflags = state . eflags ;
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# ifdef SIGNAL_DEBUG
klog ( ) < < " signal: setting up user stack to return to eip: " < < String : : format ( " %p " , ret_eip ) < < " esp: " < < String : : format ( " %p " , old_esp ) ;
# endif
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// Align the stack to 16 bytes.
// Note that we push 56 bytes (4 * 14) on to the stack,
// so we need to account for this here.
u32 stack_alignment = ( * stack - 56 ) % 16 ;
* stack - = stack_alignment ;
push_value_on_user_stack ( stack , ret_eflags ) ;
push_value_on_user_stack ( stack , ret_eip ) ;
push_value_on_user_stack ( stack , state . eax ) ;
push_value_on_user_stack ( stack , state . ecx ) ;
push_value_on_user_stack ( stack , state . edx ) ;
push_value_on_user_stack ( stack , state . ebx ) ;
push_value_on_user_stack ( stack , old_esp ) ;
push_value_on_user_stack ( stack , state . ebp ) ;
push_value_on_user_stack ( stack , state . esi ) ;
push_value_on_user_stack ( stack , state . edi ) ;
// PUSH old_signal_mask
push_value_on_user_stack ( stack , old_signal_mask ) ;
push_value_on_user_stack ( stack , signal ) ;
push_value_on_user_stack ( stack , handler_vaddr . get ( ) ) ;
push_value_on_user_stack ( stack , 0 ) ; //push fake return address
ASSERT ( ( * stack % 16 ) = = 0 ) ;
} ;
// We now place the thread state on the userspace stack.
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// Note that we use a RegisterState.
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// Conversely, when the thread isn't blocking the RegisterState may not be
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// valid (fork, exec etc) but the tss will, so we use that instead.
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auto & regs = get_register_dump_from_stack ( ) ;
u32 * stack = & regs . userspace_esp ;
setup_stack ( regs , stack ) ;
regs . eip = g_return_to_ring3_from_signal_trampoline . get ( ) ;
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# ifdef SIGNAL_DEBUG
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klog ( ) < < " signal: Okay, " < < * this < < " { " < < state_string ( ) < < " } has been primed with signal handler " < < String : : format ( " %w " , m_tss . cs ) < < " : " < < String : : format ( " %x " , m_tss . eip ) < < " to deliver " < < signal ;
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# endif
return ShouldUnblockThread : : Yes ;
}
void Thread : : set_default_signal_dispositions ( )
{
// FIXME: Set up all the right default actions. See signal(7).
memset ( & m_signal_action_data , 0 , sizeof ( m_signal_action_data ) ) ;
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m_signal_action_data [ SIGCHLD ] . handler_or_sigaction = VirtualAddress ( SIG_IGN ) ;
m_signal_action_data [ SIGWINCH ] . handler_or_sigaction = VirtualAddress ( SIG_IGN ) ;
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}
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void Thread : : push_value_on_stack ( FlatPtr value )
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{
m_tss . esp - = 4 ;
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FlatPtr * stack_ptr = ( FlatPtr * ) m_tss . esp ;
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copy_to_user ( stack_ptr , & value ) ;
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}
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RegisterState & Thread : : get_register_dump_from_stack ( )
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{
// The userspace registers should be stored at the top of the stack
// We have to subtract 2 because the processor decrements the kernel
// stack before pushing the args.
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return * ( RegisterState * ) ( kernel_stack_top ( ) - sizeof ( RegisterState ) ) ;
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}
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u32 Thread : : make_userspace_stack_for_main_thread ( Vector < String > arguments , Vector < String > environment , Vector < AuxiliaryValue > auxv )
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{
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auto * region = m_process - > allocate_region ( VirtualAddress ( ) , default_userspace_stack_size , " Stack (Main thread) " , PROT_READ | PROT_WRITE , false ) ;
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ASSERT ( region ) ;
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region - > set_stack ( true ) ;
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u32 new_esp = region - > vaddr ( ) . offset ( default_userspace_stack_size ) . get ( ) ;
// FIXME: This is weird, we put the argument contents at the base of the stack,
// and the argument pointers at the top? Why?
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char * stack_base = ( char * ) region - > vaddr ( ) . get ( ) ;
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int argc = arguments . size ( ) ;
char * * argv = ( char * * ) stack_base ;
char * * env = argv + arguments . size ( ) + 1 ;
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auxv_t * auxvp = ( auxv_t * ) ( ( char * ) ( env + environment . size ( ) + 1 ) ) ;
char * bufptr = stack_base + ( sizeof ( char * ) * ( arguments . size ( ) + 1 ) ) + ( sizeof ( char * ) * ( environment . size ( ) + 1 ) + ( sizeof ( auxv_t ) * auxv . size ( ) ) ) ;
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SmapDisabler disabler ;
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for ( size_t i = 0 ; i < arguments . size ( ) ; + + i ) {
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argv [ i ] = bufptr ;
memcpy ( bufptr , arguments [ i ] . characters ( ) , arguments [ i ] . length ( ) ) ;
bufptr + = arguments [ i ] . length ( ) ;
* ( bufptr + + ) = ' \0 ' ;
}
argv [ arguments . size ( ) ] = nullptr ;
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for ( size_t i = 0 ; i < environment . size ( ) ; + + i ) {
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env [ i ] = bufptr ;
memcpy ( bufptr , environment [ i ] . characters ( ) , environment [ i ] . length ( ) ) ;
bufptr + = environment [ i ] . length ( ) ;
* ( bufptr + + ) = ' \0 ' ;
}
env [ environment . size ( ) ] = nullptr ;
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for ( size_t i = 0 ; i < auxv . size ( ) ; + + i ) {
* auxvp = auxv [ i ] . auxv ;
if ( ! auxv [ i ] . optional_string . is_empty ( ) ) {
auxvp - > a_un . a_ptr = bufptr ;
memcpy ( bufptr , auxv [ i ] . optional_string . characters ( ) , auxv [ i ] . optional_string . length ( ) ) ;
bufptr + = auxv [ i ] . optional_string . length ( ) ;
* ( bufptr + + ) = ' \0 ' ;
}
+ + auxvp ;
}
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auto push_on_new_stack = [ & new_esp ] ( u32 value ) {
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new_esp - = 4 ;
u32 * stack_ptr = ( u32 * ) new_esp ;
* stack_ptr = value ;
} ;
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// NOTE: The stack needs to be 16-byte aligned.
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push_on_new_stack ( ( FlatPtr ) env ) ;
push_on_new_stack ( ( FlatPtr ) argv ) ;
push_on_new_stack ( ( FlatPtr ) argc ) ;
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push_on_new_stack ( 0 ) ;
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ASSERT ( ( FlatPtr ) new_esp % 16 = = 0 ) ;
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return new_esp ;
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}
Thread * Thread : : clone ( Process & process )
{
auto * clone = new Thread ( process ) ;
memcpy ( clone - > m_signal_action_data , m_signal_action_data , sizeof ( m_signal_action_data ) ) ;
clone - > m_signal_mask = m_signal_mask ;
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memcpy ( clone - > m_fpu_state , m_fpu_state , sizeof ( FPUState ) ) ;
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clone - > m_thread_specific_data = m_thread_specific_data ;
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clone - > m_thread_specific_region_size = m_thread_specific_region_size ;
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return clone ;
}
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void Thread : : set_state ( State new_state )
{
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ScopedSpinLock lock ( g_scheduler_lock ) ;
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if ( new_state = = m_state )
return ;
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if ( new_state = = Blocked ) {
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// we should always have a Blocker while blocked
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ASSERT ( m_blocker ! = nullptr ) ;
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}
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if ( new_state = = Stopped ) {
m_stop_state = m_state ;
}
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auto previous_state = m_state ;
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m_state = new_state ;
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# ifdef THREAD_DEBUG
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dbg ( ) < < " Set Thread " < < * this < < " state to " < < state_string ( ) ;
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# endif
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if ( m_process - > pid ( ) ! = 0 ) {
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update_state_for_thread ( previous_state ) ;
ASSERT ( g_scheduler_data - > has_thread ( * this ) ) ;
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}
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if ( m_state = = Dying ) {
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ASSERT ( previous_state ! = Queued ) ;
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if ( this ! = Thread : : current ( ) & & is_finalizable ( ) ) {
// Some other thread set this thread to Dying, notify the
// finalizer right away as it can be cleaned up now
Scheduler : : notify_finalizer ( ) ;
}
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}
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}
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void Thread : : update_state_for_thread ( Thread : : State previous_state )
{
ASSERT_INTERRUPTS_DISABLED ( ) ;
ASSERT ( g_scheduler_data ) ;
ASSERT ( g_scheduler_lock . own_lock ( ) ) ;
auto & previous_list = g_scheduler_data - > thread_list_for_state ( previous_state ) ;
auto & list = g_scheduler_data - > thread_list_for_state ( state ( ) ) ;
if ( & previous_list ! = & list ) {
previous_list . remove ( * this ) ;
}
if ( list . contains ( * this ) )
return ;
list . append ( * this ) ;
}
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String Thread : : backtrace ( )
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{
return backtrace_impl ( ) ;
}
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struct RecognizedSymbol {
u32 address ;
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const KernelSymbol * symbol { nullptr } ;
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} ;
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static bool symbolicate ( const RecognizedSymbol & symbol , const Process & process , StringBuilder & builder , Process : : ELFBundle * elf_bundle )
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{
if ( ! symbol . address )
return false ;
bool mask_kernel_addresses = ! process . is_superuser ( ) ;
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if ( ! symbol . symbol ) {
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if ( ! is_user_address ( VirtualAddress ( symbol . address ) ) ) {
builder . append ( " 0xdeadc0de \n " ) ;
} else {
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if ( elf_bundle & & elf_bundle - > elf_loader - > has_symbols ( ) )
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builder . appendf ( " %p %s \n " , symbol . address , elf_bundle - > elf_loader - > symbolicate ( symbol . address ) . characters ( ) ) ;
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else
builder . appendf ( " %p \n " , symbol . address ) ;
}
return true ;
}
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unsigned offset = symbol . address - symbol . symbol - > address ;
if ( symbol . symbol - > address = = g_highest_kernel_symbol_address & & offset > 4096 ) {
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builder . appendf ( " %p \n " , mask_kernel_addresses ? 0xdeadc0de : symbol . address ) ;
} else {
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builder . appendf ( " %p %s +%u \n " , mask_kernel_addresses ? 0xdeadc0de : symbol . address , demangle ( symbol . symbol - > name ) . characters ( ) , offset ) ;
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}
return true ;
}
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String Thread : : backtrace_impl ( )
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{
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Vector < RecognizedSymbol , 128 > recognized_symbols ;
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auto & process = const_cast < Process & > ( this - > process ( ) ) ;
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auto elf_bundle = process . elf_bundle ( ) ;
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ProcessPagingScope paging_scope ( process ) ;
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// To prevent a context switch involving this thread, which may happen
// on another processor, we need to acquire the scheduler lock while
// walking the stack
{
ScopedSpinLock lock ( g_scheduler_lock ) ;
FlatPtr stack_ptr , eip ;
if ( Processor : : get_context_frame_ptr ( * this , stack_ptr , eip ) ) {
recognized_symbols . append ( { eip , symbolicate_kernel_address ( eip ) } ) ;
for ( ; ; ) {
if ( ! process . validate_read_from_kernel ( VirtualAddress ( stack_ptr ) , sizeof ( void * ) * 2 ) )
break ;
FlatPtr retaddr ;
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if ( is_user_range ( VirtualAddress ( stack_ptr ) , sizeof ( FlatPtr ) * 2 ) ) {
copy_from_user ( & retaddr , & ( ( FlatPtr * ) stack_ptr ) [ 1 ] ) ;
recognized_symbols . append ( { retaddr , symbolicate_kernel_address ( retaddr ) } ) ;
copy_from_user ( & stack_ptr , ( FlatPtr * ) stack_ptr ) ;
} else {
memcpy ( & retaddr , & ( ( FlatPtr * ) stack_ptr ) [ 1 ] , sizeof ( FlatPtr ) ) ;
recognized_symbols . append ( { retaddr , symbolicate_kernel_address ( retaddr ) } ) ;
memcpy ( & stack_ptr , ( FlatPtr * ) stack_ptr , sizeof ( FlatPtr ) ) ;
}
}
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}
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}
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StringBuilder builder ;
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for ( auto & symbol : recognized_symbols ) {
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if ( ! symbolicate ( symbol , process , builder , elf_bundle . ptr ( ) ) )
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break ;
}
return builder . to_string ( ) ;
}
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Vector < FlatPtr > Thread : : raw_backtrace ( FlatPtr ebp , FlatPtr eip ) const
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{
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InterruptDisabler disabler ;
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auto & process = const_cast < Process & > ( this - > process ( ) ) ;
ProcessPagingScope paging_scope ( process ) ;
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Vector < FlatPtr , Profiling : : max_stack_frame_count > backtrace ;
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backtrace . append ( eip ) ;
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for ( FlatPtr * stack_ptr = ( FlatPtr * ) ebp ; process . validate_read_from_kernel ( VirtualAddress ( stack_ptr ) , sizeof ( FlatPtr ) * 2 ) & & MM . can_read_without_faulting ( process , VirtualAddress ( stack_ptr ) , sizeof ( FlatPtr ) * 2 ) ; stack_ptr = ( FlatPtr * ) * stack_ptr ) {
FlatPtr retaddr = stack_ptr [ 1 ] ;
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backtrace . append ( retaddr ) ;
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if ( backtrace . size ( ) = = Profiling : : max_stack_frame_count )
break ;
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}
return backtrace ;
}
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void Thread : : make_thread_specific_region ( Badge < Process > )
{
size_t thread_specific_region_alignment = max ( process ( ) . m_master_tls_alignment , alignof ( ThreadSpecificData ) ) ;
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m_thread_specific_region_size = align_up_to ( process ( ) . m_master_tls_size , thread_specific_region_alignment ) + sizeof ( ThreadSpecificData ) ;
auto * region = process ( ) . allocate_region ( { } , m_thread_specific_region_size , " Thread-specific " , PROT_READ | PROT_WRITE , true ) ;
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SmapDisabler disabler ;
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auto * thread_specific_data = ( ThreadSpecificData * ) region - > vaddr ( ) . offset ( align_up_to ( process ( ) . m_master_tls_size , thread_specific_region_alignment ) ) . as_ptr ( ) ;
auto * thread_local_storage = ( u8 * ) ( ( u8 * ) thread_specific_data ) - align_up_to ( process ( ) . m_master_tls_size , process ( ) . m_master_tls_alignment ) ;
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m_thread_specific_data = VirtualAddress ( thread_specific_data ) ;
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thread_specific_data - > self = thread_specific_data ;
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if ( process ( ) . m_master_tls_size )
memcpy ( thread_local_storage , process ( ) . m_master_tls_region - > vaddr ( ) . as_ptr ( ) , process ( ) . m_master_tls_size ) ;
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}
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const LogStream & operator < < ( const LogStream & stream , const Thread & value )
{
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return stream < < value . process ( ) . name ( ) < < " ( " < < value . pid ( ) . value ( ) < < " : " < < value . tid ( ) . value ( ) < < " ) " ;
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}
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Thread : : BlockResult Thread : : wait_on ( WaitQueue & queue , const char * reason , timeval * timeout , Atomic < bool > * lock , Thread * beneficiary )
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{
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auto * current_thread = Thread : : current ( ) ;
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TimerId timer_id { } ;
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bool did_unlock ;
{
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ScopedCritical critical ;
// We need to be in a critical section *and* then also acquire the
// scheduler lock. The only way acquiring the scheduler lock could
// block us is if another core were to be holding it, in which case
// we need to wait until the scheduler lock is released again
{
ScopedSpinLock sched_lock ( g_scheduler_lock ) ;
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if ( ! queue . enqueue ( * current_thread ) ) {
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// The WaitQueue was already requested to wake someone when
// nobody was waiting. So return right away as we shouldn't
// be waiting
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// The API contract guarantees we return with interrupts enabled,
// regardless of how we got called
critical . set_interrupt_flag_on_destruction ( true ) ;
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return BlockResult : : NotBlocked ;
}
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did_unlock = unlock_process_if_locked ( ) ;
if ( lock )
* lock = false ;
set_state ( State : : Queued ) ;
m_wait_reason = reason ;
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if ( timeout ) {
timer_id = TimerQueue : : the ( ) . add_timer ( * timeout , [ & ] ( ) {
wake_from_queue ( ) ;
} ) ;
}
// Yield and wait for the queue to wake us up again.
if ( beneficiary )
Scheduler : : donate_to ( beneficiary , reason ) ;
else
Scheduler : : yield ( ) ;
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}
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// Clearing the critical section may trigger the context switch
// flagged by calling Scheduler::donate_to or Scheduler::yield
// above. We have to do it this way because we intentionally
// leave the critical section here to be able to switch contexts.
u32 prev_flags ;
u32 prev_crit = Processor : : current ( ) . clear_critical ( prev_flags , true ) ;
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// We've unblocked, relock the process if needed and carry on.
relock_process ( did_unlock ) ;
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// NOTE: We may be on a differenct CPU now!
Processor : : current ( ) . restore_critical ( prev_crit , prev_flags ) ;
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// This looks counter productive, but we may not actually leave
// the critical section we just restored. It depends on whether
// we were in one while being called.
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if ( current_thread - > should_die ( ) ) {
// We're being unblocked so that we can clean up. We shouldn't
// be in Dying state until we're about to return back to user mode
ASSERT ( current_thread - > state ( ) = = Thread : : Running ) ;
# ifdef THREAD_DEBUG
dbg ( ) < < " Dying thread " < < * current_thread < < " was unblocked " ;
# endif
}
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}
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BlockResult result ( BlockResult : : WokeNormally ) ;
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{
// To be able to look at m_wait_queue_node we once again need the
// scheduler lock, which is held when we insert into the queue
ScopedSpinLock sched_lock ( g_scheduler_lock ) ;
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// If our thread was still in the queue, we timed out
if ( queue . dequeue ( * current_thread ) )
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result = BlockResult : : InterruptedByTimeout ;
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// Make sure we cancel the timer if woke normally.
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if ( timeout & & ! result . was_interrupted ( ) )
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TimerQueue : : the ( ) . cancel_timer ( timer_id ) ;
}
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// The API contract guarantees we return with interrupts enabled,
// regardless of how we got called
sti ( ) ;
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return result ;
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}
void Thread : : wake_from_queue ( )
{
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ScopedSpinLock lock ( g_scheduler_lock ) ;
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ASSERT ( state ( ) = = State : : Queued ) ;
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m_wait_reason = nullptr ;
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if ( this ! = Thread : : current ( ) )
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set_state ( State : : Runnable ) ;
else
set_state ( State : : Running ) ;
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}
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Thread * Thread : : from_tid ( ThreadID tid )
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{
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InterruptDisabler disabler ;
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Thread * found_thread = nullptr ;
Thread : : for_each ( [ & ] ( auto & thread ) {
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if ( thread . tid ( ) = = tid ) {
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found_thread = & thread ;
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return IterationDecision : : Break ;
}
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return IterationDecision : : Continue ;
} ) ;
return found_thread ;
}
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void Thread : : reset_fpu_state ( )
{
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memcpy ( m_fpu_state , & Processor : : current ( ) . clean_fpu_state ( ) , sizeof ( FPUState ) ) ;
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}
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void Thread : : start_tracing_from ( ProcessID tracer )
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{
m_tracer = ThreadTracer : : create ( tracer ) ;
}
void Thread : : stop_tracing ( )
{
m_tracer = nullptr ;
}
void Thread : : tracer_trap ( const RegisterState & regs )
{
ASSERT ( m_tracer . ptr ( ) ) ;
m_tracer - > set_regs ( regs ) ;
send_urgent_signal_to_self ( SIGTRAP ) ;
}
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const Thread : : Blocker & Thread : : blocker ( ) const
{
ASSERT ( m_blocker ) ;
return * m_blocker ;
}
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}