Mercurial > trustbridge > nss-cmake-static
view nspr/pr/src/threads/combined/prucpu.c @ 0:1e5118fa0cb1
This is NSS with a Cmake Buildsyste
To compile a static NSS library for Windows we've used the
Chromium-NSS fork and added a Cmake buildsystem to compile
it statically for Windows. See README.chromium for chromium
changes and README.trustbridge for our modifications.
| author | Andre Heinecke <andre.heinecke@intevation.de> |
|---|---|
| date | Mon, 28 Jul 2014 10:47:06 +0200 |
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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "primpl.h" _PRCPU *_pr_primordialCPU = NULL; PRInt32 _pr_md_idle_cpus; /* number of idle cpus */ /* * The idle threads in MxN models increment/decrement _pr_md_idle_cpus. * If _PR_HAVE_ATOMIC_OPS is not defined, they can't use the atomic * increment/decrement routines (which are based on PR_Lock/PR_Unlock), * because PR_Lock asserts that the calling thread is not an idle thread. * So we use a _MDLock to protect _pr_md_idle_cpus. */ #if !defined(_PR_LOCAL_THREADS_ONLY) && !defined(_PR_GLOBAL_THREADS_ONLY) #ifndef _PR_HAVE_ATOMIC_OPS static _MDLock _pr_md_idle_cpus_lock; #endif #endif PRUintn _pr_numCPU; PRInt32 _pr_cpus_exit; PRUint32 _pr_cpu_affinity_mask = 0; #if !defined (_PR_GLOBAL_THREADS_ONLY) static PRUintn _pr_cpuID; static void PR_CALLBACK _PR_CPU_Idle(void *); static _PRCPU *_PR_CreateCPU(void); static PRStatus _PR_StartCPU(_PRCPU *cpu, PRThread *thread); #if !defined(_PR_LOCAL_THREADS_ONLY) static void _PR_RunCPU(void *arg); #endif void _PR_InitCPUs() { PRThread *me = _PR_MD_CURRENT_THREAD(); if (_native_threads_only) return; _pr_cpuID = 0; _MD_NEW_LOCK( &_pr_cpuLock); #if !defined(_PR_LOCAL_THREADS_ONLY) && !defined(_PR_GLOBAL_THREADS_ONLY) #ifndef _PR_HAVE_ATOMIC_OPS _MD_NEW_LOCK(&_pr_md_idle_cpus_lock); #endif #endif #ifdef _PR_LOCAL_THREADS_ONLY #ifdef HAVE_CUSTOM_USER_THREADS _PR_MD_CREATE_PRIMORDIAL_USER_THREAD(me); #endif /* Now start the first CPU. */ _pr_primordialCPU = _PR_CreateCPU(); _pr_numCPU = 1; _PR_StartCPU(_pr_primordialCPU, me); _PR_MD_SET_CURRENT_CPU(_pr_primordialCPU); /* Initialize cpu for current thread (could be different from me) */ _PR_MD_CURRENT_THREAD()->cpu = _pr_primordialCPU; _PR_MD_SET_LAST_THREAD(me); #else /* Combined MxN model */ _pr_primordialCPU = _PR_CreateCPU(); _pr_numCPU = 1; _PR_CreateThread(PR_SYSTEM_THREAD, _PR_RunCPU, _pr_primordialCPU, PR_PRIORITY_NORMAL, PR_GLOBAL_THREAD, PR_UNJOINABLE_THREAD, 0, _PR_IDLE_THREAD); #endif /* _PR_LOCAL_THREADS_ONLY */ _PR_MD_INIT_CPUS(); } #ifdef WINNT /* * Right now this function merely stops the CPUs and does * not do any other cleanup. * * It is only implemented for WINNT because bug 161998 only * affects the WINNT version of NSPR, but it would be nice * to implement this function for other platforms too. */ void _PR_CleanupCPUs(void) { PRUintn i; PRCList *qp; _PRCPU *cpu; _pr_cpus_exit = 1; for (i = 0; i < _pr_numCPU; i++) { _PR_MD_WAKEUP_WAITER(NULL); } for (qp = _PR_CPUQ().next; qp != &_PR_CPUQ(); qp = qp->next) { cpu = _PR_CPU_PTR(qp); _PR_MD_JOIN_THREAD(&cpu->thread->md); } } #endif static _PRCPUQueue *_PR_CreateCPUQueue(void) { PRInt32 index; _PRCPUQueue *cpuQueue; cpuQueue = PR_NEWZAP(_PRCPUQueue); _MD_NEW_LOCK( &cpuQueue->runQLock ); _MD_NEW_LOCK( &cpuQueue->sleepQLock ); _MD_NEW_LOCK( &cpuQueue->miscQLock ); for (index = 0; index < PR_PRIORITY_LAST + 1; index++) PR_INIT_CLIST( &(cpuQueue->runQ[index]) ); PR_INIT_CLIST( &(cpuQueue->sleepQ) ); PR_INIT_CLIST( &(cpuQueue->pauseQ) ); PR_INIT_CLIST( &(cpuQueue->suspendQ) ); PR_INIT_CLIST( &(cpuQueue->waitingToJoinQ) ); cpuQueue->numCPUs = 1; return cpuQueue; } /* * Create a new CPU. * * This function initializes enough of the _PRCPU structure so * that it can be accessed safely by a global thread or another * CPU. This function does not create the native thread that * will run the CPU nor does it initialize the parts of _PRCPU * that must be initialized by that native thread. * * The reason we cannot simply have the native thread create * and fully initialize a new CPU is that we need to be able to * create a usable _pr_primordialCPU in _PR_InitCPUs without * assuming that the primordial CPU thread we created can run * during NSPR initialization. For example, on Windows while * new threads can be created by DllMain, they won't be able * to run during DLL initialization. If NSPR is initialized * by DllMain, the primordial CPU thread won't run until DLL * initialization is finished. */ static _PRCPU *_PR_CreateCPU(void) { _PRCPU *cpu; cpu = PR_NEWZAP(_PRCPU); if (cpu) { cpu->queue = _PR_CreateCPUQueue(); if (!cpu->queue) { PR_DELETE(cpu); return NULL; } } return cpu; } /* * Start a new CPU. * * 'cpu' is a _PRCPU structure created by _PR_CreateCPU(). * 'thread' is the native thread that will run the CPU. * * If this function fails, 'cpu' is destroyed. */ static PRStatus _PR_StartCPU(_PRCPU *cpu, PRThread *thread) { /* ** Start a new cpu. The assumption this code makes is that the ** underlying operating system creates a stack to go with the new ** native thread. That stack will be used by the cpu when pausing. */ PR_ASSERT(!_native_threads_only); cpu->last_clock = PR_IntervalNow(); /* Before we create any threads on this CPU we have to * set the current CPU */ _PR_MD_SET_CURRENT_CPU(cpu); _PR_MD_INIT_RUNNING_CPU(cpu); thread->cpu = cpu; cpu->idle_thread = _PR_CreateThread(PR_SYSTEM_THREAD, _PR_CPU_Idle, (void *)cpu, PR_PRIORITY_NORMAL, PR_LOCAL_THREAD, PR_UNJOINABLE_THREAD, 0, _PR_IDLE_THREAD); if (!cpu->idle_thread) { /* didn't clean up CPU queue XXXMB */ PR_DELETE(cpu); return PR_FAILURE; } PR_ASSERT(cpu->idle_thread->cpu == cpu); cpu->idle_thread->no_sched = 0; cpu->thread = thread; if (_pr_cpu_affinity_mask) PR_SetThreadAffinityMask(thread, _pr_cpu_affinity_mask); /* Created and started a new CPU */ _PR_CPU_LIST_LOCK(); cpu->id = _pr_cpuID++; PR_APPEND_LINK(&cpu->links, &_PR_CPUQ()); _PR_CPU_LIST_UNLOCK(); return PR_SUCCESS; } #if !defined(_PR_GLOBAL_THREADS_ONLY) && !defined(_PR_LOCAL_THREADS_ONLY) /* ** This code is used during a cpu's initial creation. */ static void _PR_RunCPU(void *arg) { _PRCPU *cpu = (_PRCPU *)arg; PRThread *me = _PR_MD_CURRENT_THREAD(); PR_ASSERT(NULL != me); /* * _PR_StartCPU calls _PR_CreateThread to create the * idle thread. Because _PR_CreateThread calls PR_Lock, * the current thread has to remain a global thread * during the _PR_StartCPU call so that it can wait for * the lock if the lock is held by another thread. If * we clear the _PR_GLOBAL_SCOPE flag in * _PR_MD_CREATE_PRIMORDIAL_THREAD, the current thread * will be treated as a local thread and have trouble * waiting for the lock because the CPU is not fully * constructed yet. * * After the CPU is started, it is safe to mark the * current thread as a local thread. */ #ifdef HAVE_CUSTOM_USER_THREADS _PR_MD_CREATE_PRIMORDIAL_USER_THREAD(me); #endif me->no_sched = 1; _PR_StartCPU(cpu, me); #ifdef HAVE_CUSTOM_USER_THREADS me->flags &= (~_PR_GLOBAL_SCOPE); #endif _PR_MD_SET_CURRENT_CPU(cpu); _PR_MD_SET_CURRENT_THREAD(cpu->thread); me->cpu = cpu; while(1) { PRInt32 is; if (!_PR_IS_NATIVE_THREAD(me)) _PR_INTSOFF(is); _PR_MD_START_INTERRUPTS(); _PR_MD_SWITCH_CONTEXT(me); } } #endif static void PR_CALLBACK _PR_CPU_Idle(void *_cpu) { _PRCPU *cpu = (_PRCPU *)_cpu; PRThread *me = _PR_MD_CURRENT_THREAD(); PR_ASSERT(NULL != me); me->cpu = cpu; cpu->idle_thread = me; if (_MD_LAST_THREAD()) _MD_LAST_THREAD()->no_sched = 0; if (!_PR_IS_NATIVE_THREAD(me)) _PR_MD_SET_INTSOFF(0); while(1) { PRInt32 is; PRIntervalTime timeout; if (!_PR_IS_NATIVE_THREAD(me)) _PR_INTSOFF(is); _PR_RUNQ_LOCK(cpu); #if !defined(_PR_LOCAL_THREADS_ONLY) && !defined(_PR_GLOBAL_THREADS_ONLY) #ifdef _PR_HAVE_ATOMIC_OPS _PR_MD_ATOMIC_INCREMENT(&_pr_md_idle_cpus); #else _PR_MD_LOCK(&_pr_md_idle_cpus_lock); _pr_md_idle_cpus++; _PR_MD_UNLOCK(&_pr_md_idle_cpus_lock); #endif /* _PR_HAVE_ATOMIC_OPS */ #endif /* If someone on runq; do a nonblocking PAUSECPU */ if (_PR_RUNQREADYMASK(me->cpu) != 0) { _PR_RUNQ_UNLOCK(cpu); timeout = PR_INTERVAL_NO_WAIT; } else { _PR_RUNQ_UNLOCK(cpu); _PR_SLEEPQ_LOCK(cpu); if (PR_CLIST_IS_EMPTY(&_PR_SLEEPQ(me->cpu))) { timeout = PR_INTERVAL_NO_TIMEOUT; } else { PRThread *wakeThread; wakeThread = _PR_THREAD_PTR(_PR_SLEEPQ(me->cpu).next); timeout = wakeThread->sleep; } _PR_SLEEPQ_UNLOCK(cpu); } /* Wait for an IO to complete */ (void)_PR_MD_PAUSE_CPU(timeout); #ifdef WINNT if (_pr_cpus_exit) { /* _PR_CleanupCPUs tells us to exit */ _PR_MD_END_THREAD(); } #endif #if !defined(_PR_LOCAL_THREADS_ONLY) && !defined(_PR_GLOBAL_THREADS_ONLY) #ifdef _PR_HAVE_ATOMIC_OPS _PR_MD_ATOMIC_DECREMENT(&_pr_md_idle_cpus); #else _PR_MD_LOCK(&_pr_md_idle_cpus_lock); _pr_md_idle_cpus--; _PR_MD_UNLOCK(&_pr_md_idle_cpus_lock); #endif /* _PR_HAVE_ATOMIC_OPS */ #endif _PR_ClockInterrupt(); /* Now schedule any thread that is on the runq * INTS must be OFF when calling PR_Schedule() */ me->state = _PR_RUNNABLE; _PR_MD_SWITCH_CONTEXT(me); if (!_PR_IS_NATIVE_THREAD(me)) _PR_FAST_INTSON(is); } } #endif /* _PR_GLOBAL_THREADS_ONLY */ PR_IMPLEMENT(void) PR_SetConcurrency(PRUintn numCPUs) { #if defined(_PR_GLOBAL_THREADS_ONLY) || defined(_PR_LOCAL_THREADS_ONLY) /* do nothing */ #else /* combined, MxN thread model */ PRUintn newCPU; _PRCPU *cpu; PRThread *thr; if (!_pr_initialized) _PR_ImplicitInitialization(); if (_native_threads_only) return; _PR_CPU_LIST_LOCK(); if (_pr_numCPU < numCPUs) { newCPU = numCPUs - _pr_numCPU; _pr_numCPU = numCPUs; } else newCPU = 0; _PR_CPU_LIST_UNLOCK(); for (; newCPU; newCPU--) { cpu = _PR_CreateCPU(); thr = _PR_CreateThread(PR_SYSTEM_THREAD, _PR_RunCPU, cpu, PR_PRIORITY_NORMAL, PR_GLOBAL_THREAD, PR_UNJOINABLE_THREAD, 0, _PR_IDLE_THREAD); } #endif } PR_IMPLEMENT(_PRCPU *) _PR_GetPrimordialCPU(void) { if (_pr_primordialCPU) return _pr_primordialCPU; else return _PR_MD_CURRENT_CPU(); }