source: src/libcfa/concurrency/kernel.c @ 7d4f6ed

//                              -*- Mode: CFA -*-
//
// Cforall Version 1.0.0 Copyright (C) 2016 University of Waterloo
//
// The contents of this file are covered under the licence agreement in the
// file "LICENCE" distributed with Cforall.
//
// kernel.c --
//
// Author           : Thierry Delisle
// Created On       : Tue Jan 17 12:27:26 2017
// Last Modified By : Thierry Delisle
// Last Modified On : --
// Update Count     : 0
//

#include "startup.h"

//Start and stop routine for the kernel, declared first to make sure they run first
void kernel_startup(void)  __attribute__(( constructor( STARTUP_PRIORITY_KERNEL ) ));
void kernel_shutdown(void) __attribute__(( destructor ( STARTUP_PRIORITY_KERNEL ) ));

//Header
#include "kernel_private.h"

//C Includes
#include <stddef.h>
extern "C" {
#include <stdio.h>
#include <fenv.h>
#include <sys/resource.h>
#include <signal.h>
#include <unistd.h>
}

//CFA Includes
#include "libhdr.h"
#include "preemption.h"

//Private includes
#define __CFA_INVOKE_PRIVATE__
#include "invoke.h"

//-----------------------------------------------------------------------------
// Kernel storage
#define KERNEL_STORAGE(T,X) static char X##_storage[sizeof(T)]

KERNEL_STORAGE(processorCtx_t, systemProcessorCtx);
KERNEL_STORAGE(cluster, systemCluster);
KERNEL_STORAGE(system_proc_t, systemProcessor);
KERNEL_STORAGE(thread_desc, mainThread);
KERNEL_STORAGE(machine_context_t, mainThread_context);

cluster * systemCluster;
system_proc_t * systemProcessor;
thread_desc * mainThread;

//-----------------------------------------------------------------------------
// Global state

thread_local processor * this_processor;

coroutine_desc * this_coroutine(void) {
        return this_processor->current_coroutine;
}

thread_desc * this_thread(void) {
        return this_processor->current_thread;
}

//-----------------------------------------------------------------------------
// Main thread construction
struct current_stack_info_t {
        machine_context_t ctx;  
        unsigned int size;              // size of stack
        void *base;                             // base of stack
        void *storage;                  // pointer to stack
        void *limit;                    // stack grows towards stack limit
        void *context;                  // address of cfa_context_t
        void *top;                              // address of top of storage
};

void ?{}( current_stack_info_t * this ) {
        CtxGet( &this->ctx );
        this->base = this->ctx.FP;
        this->storage = this->ctx.SP;

        rlimit r;
        getrlimit( RLIMIT_STACK, &r);
        this->size = r.rlim_cur;

        this->limit = (void *)(((intptr_t)this->base) - this->size);
        this->context = &mainThread_context_storage;
        this->top = this->base;
}

void ?{}( coStack_t * this, current_stack_info_t * info) {
        this->size = info->size;
        this->storage = info->storage;
        this->limit = info->limit;
        this->base = info->base;
        this->context = info->context;
        this->top = info->top;
        this->userStack = true;
}

void ?{}( coroutine_desc * this, current_stack_info_t * info) {
        (&this->stack){ info }; 
        this->name = "Main Thread";
        this->errno_ = 0;
        this->state = Start;
}

void ?{}( thread_desc * this, current_stack_info_t * info) {
        (&this->cor){ info };
}

//-----------------------------------------------------------------------------
// Processor coroutine
void ?{}(processorCtx_t * this, processor * proc) {
        (&this->__cor){ "Processor" };
        this->proc = proc;
        proc->runner = this;
}

void ?{}(processorCtx_t * this, processor * proc, current_stack_info_t * info) {
        (&this->__cor){ info };
        this->proc = proc;
        proc->runner = this;
}

void ?{}(processor * this) {
        this{ systemCluster };
}

void ?{}(processor * this, cluster * cltr) {
        this->cltr = cltr;
        this->current_coroutine = NULL;
        this->current_thread = NULL;
        (&this->terminated){};
        this->is_terminated = false;
        this->preemption_alarm = NULL;
        this->preemption = default_preemption();
        this->disable_preempt_count = 1;                //Start with interrupts disabled
        this->pending_preemption = false;

        start( this );
}

void ?{}(processor * this, cluster * cltr, processorCtx_t * runner) {
        this->cltr = cltr;
        this->current_coroutine = NULL;
        this->current_thread = NULL;
        (&this->terminated){};
        this->is_terminated = false;
        this->disable_preempt_count = 0;
        this->pending_preemption = false;

        this->runner = runner;
        LIB_DEBUG_PRINT_SAFE("Kernel : constructing processor context %p\n", runner);
        runner{ this };
}

void ?{}(system_proc_t * this, cluster * cltr, processorCtx_t * runner) {
        (&this->alarms){};
        (&this->alarm_lock){};
        this->pending_alarm = false;

        (&this->proc){ cltr, runner };
}

void ^?{}(processor * this) {
        if( ! this->is_terminated ) {
                LIB_DEBUG_PRINT_SAFE("Kernel : core %p signaling termination\n", this);
                this->is_terminated = true;
                wait( &this->terminated );
        }
}

void ?{}(cluster * this) {
        ( &this->ready_queue ){};
        ( &this->lock ){};
}

void ^?{}(cluster * this) {
        
}

//=============================================================================================
// Kernel Scheduling logic
//=============================================================================================
//Main of the processor contexts
void main(processorCtx_t * runner) {
        processor * this = runner->proc;

        LIB_DEBUG_PRINT_SAFE("Kernel : core %p starting\n", this);

        {
                // Setup preemption data
                preemption_scope scope = { this };

                LIB_DEBUG_PRINT_SAFE("Kernel : core %p started\n", this);

                thread_desc * readyThread = NULL;
                for( unsigned int spin_count = 0; ! this->is_terminated; spin_count++ ) 
                {
                        readyThread = nextThread( this->cltr );

                        if(readyThread)
                        {
                                runThread(this, readyThread);

                                //Some actions need to be taken from the kernel
                                finishRunning(this);

                                spin_count = 0;
                        }
                        else
                        {
                                spin(this, &spin_count);
                        }
                }

                LIB_DEBUG_PRINT_SAFE("Kernel : core %p stopping\n", this);
        }

        signal( &this->terminated );
        LIB_DEBUG_PRINT_SAFE("Kernel : core %p terminated\n", this);
}

// runThread runs a thread by context switching 
// from the processor coroutine to the target thread 
void runThread(processor * this, thread_desc * dst) {
        coroutine_desc * proc_cor = get_coroutine(this->runner);
        coroutine_desc * thrd_cor = get_coroutine(dst);
        
        //Reset the terminating actions here
        this->finish.action_code = No_Action;

        //Update global state
        this->current_thread = dst;

        // Context Switch to the thread
        ThreadCtxSwitch(proc_cor, thrd_cor);
        // when ThreadCtxSwitch returns we are back in the processor coroutine
}

// Once a thread has finished running, some of 
// its final actions must be executed from the kernel
void finishRunning(processor * this) {
        if( this->finish.action_code == Release ) {
                unlock( this->finish.lock );
        }
        else if( this->finish.action_code == Schedule ) {
                ScheduleThread( this->finish.thrd );
        }
        else if( this->finish.action_code == Release_Schedule ) {
                unlock( this->finish.lock );            
                ScheduleThread( this->finish.thrd );
        }
        else if( this->finish.action_code == Release_Multi ) {
                for(int i = 0; i < this->finish.lock_count; i++) {
                        unlock( this->finish.locks[i] );
                }
        }
        else if( this->finish.action_code == Release_Multi_Schedule ) {
                for(int i = 0; i < this->finish.lock_count; i++) {
                        unlock( this->finish.locks[i] );
                }
                for(int i = 0; i < this->finish.thrd_count; i++) {
                        ScheduleThread( this->finish.thrds[i] );
                }
        }
        else {
                assert(this->finish.action_code == No_Action);
        }
}

// Handles spinning logic
// TODO : find some strategy to put cores to sleep after some time
void spin(processor * this, unsigned int * spin_count) {
        (*spin_count)++;
}

// Context invoker for processors
// This is the entry point for processors (kernel threads)
// It effectively constructs a coroutine by stealing the pthread stack
void * CtxInvokeProcessor(void * arg) {
        processor * proc = (processor *) arg;
        this_processor = proc;
        // SKULLDUGGERY: We want to create a context for the processor coroutine
        // which is needed for the 2-step context switch. However, there is no reason
        // to waste the perfectly valid stack create by pthread. 
        current_stack_info_t info;
        machine_context_t ctx;
        info.context = &ctx;
        processorCtx_t proc_cor_storage = { proc, &info };

        LIB_DEBUG_PRINT_SAFE("Coroutine : created stack %p\n", proc_cor_storage.__cor.stack.base);

        //Set global state
        proc->current_coroutine = &proc->runner->__cor;
        proc->current_thread = NULL;

        //We now have a proper context from which to schedule threads
        LIB_DEBUG_PRINT_SAFE("Kernel : core %p created (%p, %p)\n", proc, proc->runner, &ctx);

        // SKULLDUGGERY: Since the coroutine doesn't have its own stack, we can't 
        // resume it to start it like it normally would, it will just context switch 
        // back to here. Instead directly call the main since we already are on the 
        // appropriate stack.
        proc_cor_storage.__cor.state = Active;
        main( &proc_cor_storage );
        proc_cor_storage.__cor.state = Halted;

        // Main routine of the core returned, the core is now fully terminated
        LIB_DEBUG_PRINT_SAFE("Kernel : core %p main ended (%p)\n", proc, proc->runner); 

        return NULL;
}

void start(processor * this) {
        LIB_DEBUG_PRINT_SAFE("Kernel : Starting core %p\n", this);
        
        pthread_create( &this->kernel_thread, NULL, CtxInvokeProcessor, (void*)this );

        LIB_DEBUG_PRINT_SAFE("Kernel : core %p started\n", this);       
}

//-----------------------------------------------------------------------------
// Scheduler routines
void ScheduleThread( thread_desc * thrd ) {
        if( !thrd ) return;

        verifyf( thrd->next == NULL, "Expected null got %p", thrd->next );
        
        lock( &systemProcessor->proc.cltr->lock );
        append( &systemProcessor->proc.cltr->ready_queue, thrd );
        unlock( &systemProcessor->proc.cltr->lock );
}

thread_desc * nextThread(cluster * this) {
        lock( &this->lock );
        thread_desc * head = pop_head( &this->ready_queue );
        unlock( &this->lock );
        return head;
}

void ScheduleInternal() {
        suspend();
}

void ScheduleInternal( spinlock * lock ) {
        this_processor->finish.action_code = Release;
        this_processor->finish.lock = lock;
        suspend();
}

void ScheduleInternal( thread_desc * thrd ) {
        this_processor->finish.action_code = Schedule;
        this_processor->finish.thrd = thrd;
        suspend();
}

void ScheduleInternal( spinlock * lock, thread_desc * thrd ) {
        this_processor->finish.action_code = Release_Schedule;
        this_processor->finish.lock = lock;
        this_processor->finish.thrd = thrd;
        suspend();
}

void ScheduleInternal(spinlock ** locks, unsigned short count) {
        this_processor->finish.action_code = Release_Multi;
        this_processor->finish.locks = locks;
        this_processor->finish.lock_count = count;
        suspend();
}

void ScheduleInternal(spinlock ** locks, unsigned short lock_count, thread_desc ** thrds, unsigned short thrd_count) {
        this_processor->finish.action_code = Release_Multi_Schedule;
        this_processor->finish.locks = locks;
        this_processor->finish.lock_count = lock_count;
        this_processor->finish.thrds = thrds;
        this_processor->finish.thrd_count = thrd_count;
        suspend();
}

//=============================================================================================
// Kernel Setup logic
//=============================================================================================
//-----------------------------------------------------------------------------
// Kernel boot procedures
void kernel_startup(void) {
        LIB_DEBUG_PRINT_SAFE("Kernel : Starting\n");    

        // Start by initializing the main thread
        // SKULLDUGGERY: the mainThread steals the process main thread 
        // which will then be scheduled by the systemProcessor normally
        mainThread = (thread_desc *)&mainThread_storage;
        current_stack_info_t info;
        mainThread{ &info };

        LIB_DEBUG_PRINT_SAFE("Kernel : Main thread ready\n");

        // Enable preemption
        kernel_start_preemption();

        // Initialize the system cluster
        systemCluster = (cluster *)&systemCluster_storage;
        systemCluster{};

        LIB_DEBUG_PRINT_SAFE("Kernel : System cluster ready\n");

        // Initialize the system processor and the system processor ctx
        // (the coroutine that contains the processing control flow)
        systemProcessor = (system_proc_t *)&systemProcessor_storage;
        systemProcessor{ systemCluster, (processorCtx_t *)&systemProcessorCtx_storage };

        // Add the main thread to the ready queue 
        // once resume is called on systemProcessor->runner the mainThread needs to be scheduled like any normal thread
        ScheduleThread(mainThread);

        //initialize the global state variables
        this_processor = &systemProcessor->proc;
        this_processor->current_thread = mainThread;
        this_processor->current_coroutine = &mainThread->cor;

        // SKULLDUGGERY: Force a context switch to the system processor to set the main thread's context to the current UNIX
        // context. Hence, the main thread does not begin through CtxInvokeThread, like all other threads. The trick here is that
        // mainThread is on the ready queue when this call is made. 
        resume( systemProcessor->proc.runner );



        // THE SYSTEM IS NOW COMPLETELY RUNNING
        LIB_DEBUG_PRINT_SAFE("Kernel : Started\n--------------------------------------------------\n\n");
}

void kernel_shutdown(void) {
        LIB_DEBUG_PRINT_SAFE("\n--------------------------------------------------\nKernel : Shutting down\n");

        // SKULLDUGGERY: Notify the systemProcessor it needs to terminates.
        // When its coroutine terminates, it return control to the mainThread
        // which is currently here
        systemProcessor->proc.is_terminated = true;
        suspend();

        // THE SYSTEM IS NOW COMPLETELY STOPPED

        // Destroy the system processor and its context in reverse order of construction
        // These were manually constructed so we need manually destroy them
        ^(systemProcessor->proc.runner){};
        ^(systemProcessor){};

        // Final step, destroy the main thread since it is no longer needed
        // Since we provided a stack to this taxk it will not destroy anything
        ^(mainThread){};

        LIB_DEBUG_PRINT_SAFE("Kernel : Shutdown complete\n");   
}

static spinlock kernel_abort_lock;
static spinlock kernel_debug_lock;
static bool kernel_abort_called = false;

void * kernel_abort    (void) __attribute__ ((__nothrow__)) {
        // abort cannot be recursively entered by the same or different processors because all signal handlers return when
        // the globalAbort flag is true.
        lock( &kernel_abort_lock );

        // first task to abort ?
        if ( !kernel_abort_called ) {                   // not first task to abort ?
                kernel_abort_called = true;
                unlock( &kernel_abort_lock );
        } 
        else {
                unlock( &kernel_abort_lock );
                
                sigset_t mask;
                sigemptyset( &mask );
                sigaddset( &mask, SIGALRM );                    // block SIGALRM signals
                sigaddset( &mask, SIGUSR1 );                    // block SIGUSR1 signals
                sigsuspend( &mask );                            // block the processor to prevent further damage during abort
                _exit( EXIT_FAILURE );                          // if processor unblocks before it is killed, terminate it              
        }

        return this_thread();
}

void kernel_abort_msg( void * kernel_data, char * abort_text, int abort_text_size ) {
        thread_desc * thrd = kernel_data;

        int len = snprintf( abort_text, abort_text_size, "Error occurred while executing task %.256s (%p)", thrd->cor.name, thrd );
        __lib_debug_write( STDERR_FILENO, abort_text, len );

        if ( thrd != this_coroutine() ) {
                len = snprintf( abort_text, abort_text_size, " in coroutine %.256s (%p).\n", this_coroutine()->name, this_coroutine() );
                __lib_debug_write( STDERR_FILENO, abort_text, len );
        } 
        else {
                __lib_debug_write( STDERR_FILENO, ".\n", 2 );
        }
}

extern "C" {
        void __lib_debug_acquire() {
                lock(&kernel_debug_lock);
        }

        void __lib_debug_release() {
                unlock(&kernel_debug_lock);
        }
}

//=============================================================================================
// Kernel Utilities
//=============================================================================================
//-----------------------------------------------------------------------------
// Locks
void ?{}( spinlock * this ) {
        this->lock = 0;
}
void ^?{}( spinlock * this ) {

}

bool try_lock( spinlock * this ) {
        return this->lock == 0 && __sync_lock_test_and_set_4( &this->lock, 1 ) == 0;
}

void lock( spinlock * this ) {
        for ( unsigned int i = 1;; i += 1 ) {
                if ( this->lock == 0 && __sync_lock_test_and_set_4( &this->lock, 1 ) == 0 ) break;
        }
}

void unlock( spinlock * this ) {
        __sync_lock_release_4( &this->lock );
}

void ?{}( signal_once * this ) {
        this->cond = false;
}
void ^?{}( signal_once * this ) {

}

void wait( signal_once * this ) {
        lock( &this->lock );
        if( !this->cond ) {
                append( &this->blocked, this_thread() );
                ScheduleInternal( &this->lock );
                lock( &this->lock );
        }
        unlock( &this->lock );
}

void signal( signal_once * this ) {
        lock( &this->lock );
        {
                this->cond = true;

                thread_desc * it;
                while( it = pop_head( &this->blocked) ) {
                        ScheduleThread( it );
                }
        }
        unlock( &this->lock );
}

//-----------------------------------------------------------------------------
// Queues
void ?{}( __thread_queue_t * this ) {
        this->head = NULL;
        this->tail = &this->head;
}

void append( __thread_queue_t * this, thread_desc * t ) {
        verify(this->tail != NULL);
        *this->tail = t;
        this->tail = &t->next;
}

thread_desc * pop_head( __thread_queue_t * this ) {
        thread_desc * head = this->head;
        if( head ) {
                this->head = head->next;
                if( !head->next ) {
                        this->tail = &this->head;
                }
                head->next = NULL;
        }       
        return head;
}

void ?{}( __condition_stack_t * this ) {
        this->top = NULL;
}

void push( __condition_stack_t * this, __condition_criterion_t * t ) {
        verify( !t->next );
        t->next = this->top;
        this->top = t;
}

__condition_criterion_t * pop( __condition_stack_t * this ) {
        __condition_criterion_t * top = this->top;
        if( top ) {
                this->top = top->next;
                top->next = NULL;
        }       
        return top;
}
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