source: src/libcfa/concurrency/monitor.c@ 3c0ec68

//                              -*- 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.
//
// monitor_desc.c --
//
// Author           : Thierry Delisle
// Created On       : Thd Feb 23 12:27:26 2017
// Last Modified By : Thierry Delisle
// Last Modified On : --
// Update Count     : 0
//

#include "monitor"

#include <stdlib>

#include "kernel_private.h"
#include "libhdr.h"

//-----------------------------------------------------------------------------
// Forward declarations
static inline void set_owner( monitor_desc * this, thread_desc * owner );
static inline thread_desc * next_thread( monitor_desc * this );

static inline void lock_all( spinlock ** locks, unsigned short count );
static inline void lock_all( monitor_desc ** source, spinlock ** /*out*/ locks, unsigned short count );
static inline void unlock_all( spinlock ** locks, unsigned short count );
static inline void unlock_all( monitor_desc ** locks, unsigned short count );

static inline void save_recursion   ( monitor_desc ** ctx, unsigned int * /*out*/ recursions, unsigned short count );
static inline void restore_recursion( monitor_desc ** ctx, unsigned int * /*in */ recursions, unsigned short count );

static inline thread_desc * check_condition( __condition_criterion_t * );
static inline void brand_condition( condition * );
static inline unsigned short insert_unique( thread_desc ** thrds, unsigned short end, thread_desc * val );

//-----------------------------------------------------------------------------
// Enter/Leave routines


extern "C" {
        void __enter_monitor_desc(monitor_desc * this) {
                lock( &this->lock );
                thread_desc * thrd = this_thread();

                LIB_DEBUG_PRINT_SAFE("%p Entering %p (o: %p, r: %i)\n", thrd, this, this->owner, this->recursion);

                if( !this->owner ) {
                        //No one has the monitor, just take it
                        set_owner( this, thrd );
                }
                else if( this->owner == thrd) {
                        //We already have the monitor, just not how many times we took it
                        assert( this->recursion > 0 );
                        this->recursion += 1;
                }
                else {
                        //Some one else has the monitor, wait in line for it
                        append( &this->entry_queue, thrd );
                        LIB_DEBUG_PRINT_SAFE("%p Blocking on entry\n", thrd);
                        ScheduleInternal( &this->lock );

                        //ScheduleInternal will unlock spinlock, no need to unlock ourselves
                        return; 
                }

                unlock( &this->lock );
                return;
        }

        // leave pseudo code :
        //      TODO
        void __leave_monitor_desc(monitor_desc * this) {
                lock( &this->lock );

                thread_desc * thrd = this_thread();

                LIB_DEBUG_PRINT_SAFE("%p Leaving %p (o: %p, r: %i)\n", thrd, this, this->owner, this->recursion);
                assertf( thrd == this->owner, "Expected owner to be %p, got %p (r: %i)", thrd, this->owner, this->recursion );

                //Leaving a recursion level, decrement the counter
                this->recursion -= 1;

                //If we haven't left the last level of recursion
                //it means we don't need to do anything
                if( this->recursion != 0) {
                        unlock( &this->lock );
                        return;
                }

                thread_desc * new_owner = next_thread( this );

                //We can now let other threads in safely
                unlock( &this->lock );

                LIB_DEBUG_PRINT_SAFE("Next owner is %p\n", new_owner);

                //We need to wake-up the thread
                ScheduleThread( new_owner );
        }
}

static inline void enter(monitor_desc ** monitors, int count) {
        for(int i = 0; i < count; i++) {
                __enter_monitor_desc( monitors[i] );
        }
}

static inline void leave(monitor_desc ** monitors, int count) {
        for(int i = count - 1; i >= 0; i--) {
                __leave_monitor_desc( monitors[i] );
        }
}

void ?{}( monitor_guard_t * this, monitor_desc ** m, int count ) {
        this->m = m;
        this->count = count;
        qsort(this->m, count);
        enter( this->m, this->count );

        this->prev_mntrs = this_thread()->current_monitors;
        this->prev_count = this_thread()->current_monitor_count;

        this_thread()->current_monitors      = m;
        this_thread()->current_monitor_count = count;
}

void ^?{}( monitor_guard_t * this ) {
        leave( this->m, this->count );

        this_thread()->current_monitors      = this->prev_mntrs;
        this_thread()->current_monitor_count = this->prev_count;
}

void debug_break() __attribute__(( noinline ))
{
        
}

//-----------------------------------------------------------------------------
// Internal scheduling
void wait( condition * this ) {
        LIB_DEBUG_PRINT_SAFE("Waiting\n");

        brand_condition( this );

        //Check that everything is as expected
        assertf( this->monitors != NULL, "Waiting with no monitors (%p)", this->monitors );
        assertf( this->monitor_count != 0, "Waiting with 0 monitors (%i)", this->monitor_count );
        assertf( this->monitor_count < 32u, "Excessive monitor count (%i)", this->monitor_count );

        unsigned short count = this->monitor_count;
        unsigned int recursions[ count ];               //Save the current recursion levels to restore them later
        spinlock *   locks     [ count ];               //We need to pass-in an array of locks to ScheduleInternal

        LIB_DEBUG_PRINT_SAFE("count %i\n", count);

        __condition_node_t waiter;
        waiter.waiting_thread = this_thread();
        waiter.count = count;
        waiter.next = NULL;

        __condition_criterion_t criteria[count];
        for(int i = 0; i < count; i++) {
                criteria[i].ready  = false;
                criteria[i].target = this->monitors[i];
                criteria[i].owner  = &waiter;
                criteria[i].next   = NULL;
                LIB_DEBUG_PRINT_SAFE( "Criterion %p\n", &criteria[i] );
        }

        waiter.criteria = criteria;
        append( &this->blocked, &waiter );

        lock_all( this->monitors, locks, count );
        save_recursion( this->monitors, recursions, count );
        //DON'T unlock, ask the kernel to do it

        //Find the next thread(s) to run
        unsigned short thread_count = 0;
        thread_desc * threads[ count ];
        for(int i = 0; i < count; i++) {
                threads[i] = 0;
        }

        for( int i = 0; i < count; i++) {
                thread_desc * new_owner = next_thread( this->monitors[i] );
                thread_count = insert_unique( threads, thread_count, new_owner );
        }

        LIB_DEBUG_PRINT_SAFE("Will unblock: ");
        for(int i = 0; i < thread_count; i++) {
                LIB_DEBUG_PRINT_SAFE("%p ", threads[i]);
        }
        LIB_DEBUG_PRINT_SAFE("\n");

        // Everything is ready to go to sleep
        ScheduleInternal( locks, count, threads, thread_count );

        debug_break();
        //WE WOKE UP


        //We are back, restore the owners and recursions
        lock_all( locks, count );
        restore_recursion( this->monitors, recursions, count );
        unlock_all( locks, count );
}

void signal( condition * this ) {
        if( !this->blocked.head ) {
                LIB_DEBUG_PRINT_SAFE("Nothing to signal\n");
                return;
        }

        //Check that everything is as expected
        assert( this->monitors );
        assert( this->monitor_count != 0 );

        unsigned short count = this->monitor_count;
        
        //Some more checking in debug
        LIB_DEBUG_DO(
                thread_desc * this_thrd = this_thread();
                if ( this->monitor_count != this_thrd->current_monitor_count ) {
                        abortf( "Signal on condition %p made with different number of monitor(s), expected %i got %i", this, this->monitor_count, this_thrd->current_monitor_count );
                } // if

                for(int i = 0; i < this->monitor_count; i++) {
                        if ( this->monitors[i] != this_thrd->current_monitors[i] ) {
                                abortf( "Signal on condition %p made with different monitor, expected %p got %i", this, this->monitors[i], this_thrd->current_monitors[i] );
                        } // if
                }
        );

        //Lock all the monitors
        lock_all( this->monitors, NULL, count );
        LIB_DEBUG_PRINT_SAFE("Signalling");

        //Pop the head of the waiting queue
        __condition_node_t * node = pop_head( &this->blocked );

        //Add the thread to the proper AS stack
        for(int i = 0; i < count; i++) {
                __condition_criterion_t * crit = &node->criteria[i];
                LIB_DEBUG_PRINT_SAFE(" %p", crit->target);
                assert( !crit->ready );
                push( &crit->target->signal_stack, crit );
        }

        LIB_DEBUG_PRINT_SAFE("\n");

        //Release
        unlock_all( this->monitors, count );
}

void signal_block( condition * this ) {
        if( !this->blocked.head ) {
                LIB_DEBUG_PRINT_SAFE("Nothing to signal\n");
                return;
        }

        //Check that everything is as expected
        assertf( this->monitors != NULL, "Waiting with no monitors (%p)", this->monitors );
        assertf( this->monitor_count != 0, "Waiting with 0 monitors (%i)", this->monitor_count );

        unsigned short count = this->monitor_count;
        unsigned int recursions[ count ];               //Save the current recursion levels to restore them later
        spinlock *   locks     [ count ];               //We need to pass-in an array of locks to ScheduleInternal

        lock_all( this->monitors, locks, count );

        //create creteria
        __condition_node_t waiter;
        waiter.waiting_thread = this_thread();
        waiter.count = count;
        waiter.next = NULL;

        __condition_criterion_t criteria[count];
        for(int i = 0; i < count; i++) {
                LIB_DEBUG_PRINT_SAFE( "Criterion %p\n", &criteria[i] );
                criteria[i].ready  = false;
                criteria[i].owner  = &waiter;
                criteria[i].next   = NULL;
                criteria[i].target = this->monitors[i];
                push( &criteria[i].target->signal_stack, &criteria[i] );
        }

        waiter.criteria = criteria;

        //save contexts
        save_recursion( this->monitors, recursions, count );

        //Find the thread to run
        thread_desc * signallee = pop_head( &this->blocked )->waiting_thread;
        for(int i = 0; i < count; i++) {
                set_owner( this->monitors[i], signallee );
        }

        LIB_DEBUG_PRINT_SAFE( "Waiting on signal block\n" );
        debug_break();

        //Everything is ready to go to sleep
        ScheduleInternal( locks, count, &signallee, 1 );

        debug_break();
        LIB_DEBUG_PRINT_SAFE( "Back from signal block\n" );

        //We are back, restore the owners and recursions
        lock_all( locks, count );
        restore_recursion( this->monitors, recursions, count );
        unlock_all( locks, count );
}

//-----------------------------------------------------------------------------
// Utilities

static inline void set_owner( monitor_desc * this, thread_desc * owner ) {
        //Pass the monitor appropriately
        this->owner = owner;

        //We are passing the monitor to someone else, which means recursion level is not 0
        this->recursion = owner ? 1 : 0;
}

static inline thread_desc * next_thread( monitor_desc * this ) {
        //Check the signaller stack
        __condition_criterion_t * urgent = pop( &this->signal_stack );
        if( urgent ) {
                //The signaller stack is not empty,
                //regardless of if we are ready to baton pass,
                //we need to set the monitor as in use
                set_owner( this,  urgent->owner->waiting_thread );

                return check_condition( urgent );
        }

        // No signaller thread
        // Get the next thread in the entry_queue
        thread_desc * new_owner = pop_head( &this->entry_queue );
        set_owner( this, new_owner );

        return new_owner;
}

static inline void lock_all( spinlock ** locks, unsigned short count ) {
        for( int i = 0; i < count; i++ ) {
                lock( locks[i] );
        }
}

static inline void lock_all( monitor_desc ** source, spinlock ** /*out*/ locks, unsigned short count ) {
        for( int i = 0; i < count; i++ ) {
                spinlock * l = &source[i]->lock;
                lock( l );
                if(locks) locks[i] = l;
        }
}

static inline void unlock_all( spinlock ** locks, unsigned short count ) {
        for( int i = 0; i < count; i++ ) {
                unlock( locks[i] );
        }
}

static inline void unlock_all( monitor_desc ** locks, unsigned short count ) {
        for( int i = 0; i < count; i++ ) {
                unlock( &locks[i]->lock );
        }
}


static inline void save_recursion   ( monitor_desc ** ctx, unsigned int * /*out*/ recursions, unsigned short count ) {
        for( int i = 0; i < count; i++ ) {
                recursions[i] = ctx[i]->recursion;
        }
}

static inline void restore_recursion( monitor_desc ** ctx, unsigned int * /*in */ recursions, unsigned short count ) {
        for( int i = 0; i < count; i++ ) {
                ctx[i]->recursion = recursions[i];
        }
}

// Function has 2 different behavior
// 1 - Marks a monitors as being ready to run
// 2 - Checks if all the monitors are ready to run
//     if so return the thread to run
static inline thread_desc * check_condition( __condition_criterion_t * target ) {
        __condition_node_t * node = target->owner;
        unsigned short count = node->count;
        __condition_criterion_t * criteria = node->criteria;

        bool ready2run = true;

        for(    int i = 0; i < count; i++ ) {

                LIB_DEBUG_PRINT_SAFE( "Checking %p for %p\n", &criteria[i], target );
                if( &criteria[i] == target ) {
                        criteria[i].ready = true;
                        LIB_DEBUG_PRINT_SAFE( "True\n" );
                }

                ready2run = criteria[i].ready && ready2run;
        }

        LIB_DEBUG_PRINT_SAFE( "Runing %i\n", ready2run );
        return ready2run ? node->waiting_thread : NULL;
}

static inline void brand_condition( condition * this ) {
        thread_desc * thrd = this_thread();
        if( !this->monitors ) {
                LIB_DEBUG_PRINT_SAFE("Branding\n");
                assertf( thrd->current_monitors != NULL, "No current monitor to brand condition", thrd->current_monitors );
                this->monitor_count = thrd->current_monitor_count;

                this->monitors = malloc( this->monitor_count * sizeof( *this->monitors ) );
                for( int i = 0; i < this->monitor_count; i++ ) {
                        this->monitors[i] = thrd->current_monitors[i];
                }
        }
}

static inline unsigned short insert_unique( thread_desc ** thrds, unsigned short end, thread_desc * val ) {
        if( !val ) return end;

        for(int i = 0; i <= end; i++) {
                if( thrds[i] == val ) return end;
        }

        thrds[end] = val;
        return end + 1;
}

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

void append( __condition_blocked_queue_t * this, __condition_node_t * c ) {
        assert(this->tail != NULL);
        *this->tail = c;
        this->tail = &c->next;
}

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