source: libcfa/src/concurrency/ready_queue.cfa @ 0583b47b

//
// Cforall Version 1.0.0 Copyright (C) 2019 University of Waterloo
//
// The contents of this file are covered under the licence agreement in the
// file "LICENCE" distributed with Cforall.
//
// ready_queue.cfa --
//
// Author           : Thierry Delisle
// Created On       : Mon Nov dd 16:29:18 2019
// Last Modified By :
// Last Modified On :
// Update Count     :
//

#define __cforall_thread__
// #define __CFA_DEBUG_PRINT_READY_QUEUE__

// #define USE_MPSC

#define USE_RELAXED_FIFO
// #define USE_WORK_STEALING

#include "bits/defs.hfa"
#include "kernel_private.hfa"

#define _GNU_SOURCE
#include "stdlib.hfa"
#include "math.hfa"

#include <unistd.h>

#include "ready_subqueue.hfa"

static const size_t cache_line_size = 64;

#if !defined(__CFA_NO_STATISTICS__)
        #define __STATS(...) __VA_ARGS__
#else
        #define __STATS(...)
#endif

// No overriden function, no environment variable, no define
// fall back to a magic number
#ifndef __CFA_MAX_PROCESSORS__
        #define __CFA_MAX_PROCESSORS__ 1024
#endif

#if   defined(USE_RELAXED_FIFO)
        #define BIAS 4
        #define READYQ_SHARD_FACTOR 4
        #define SEQUENTIAL_SHARD 1
#elif defined(USE_WORK_STEALING)
        #define READYQ_SHARD_FACTOR 2
        #define SEQUENTIAL_SHARD 2
#else
        #error no scheduling strategy selected
#endif

static inline struct $thread * try_pop(struct cluster * cltr, unsigned w __STATS(, __stats_readyQ_pop_t & stats));
static inline struct $thread * try_pop(struct cluster * cltr, unsigned i, unsigned j __STATS(, __stats_readyQ_pop_t & stats));
static inline struct $thread * search(struct cluster * cltr);
static inline [unsigned, bool] idx_from_r(unsigned r, unsigned preferred);


// returns the maximum number of processors the RWLock support
__attribute__((weak)) unsigned __max_processors() {
        const char * max_cores_s = getenv("CFA_MAX_PROCESSORS");
        if(!max_cores_s) {
                __cfadbg_print_nolock(ready_queue, "No CFA_MAX_PROCESSORS in ENV\n");
                return __CFA_MAX_PROCESSORS__;
        }

        char * endptr = 0p;
        long int max_cores_l = strtol(max_cores_s, &endptr, 10);
        if(max_cores_l < 1 || max_cores_l > 65535) {
                __cfadbg_print_nolock(ready_queue, "CFA_MAX_PROCESSORS out of range : %ld\n", max_cores_l);
                return __CFA_MAX_PROCESSORS__;
        }
        if('\0' != *endptr) {
                __cfadbg_print_nolock(ready_queue, "CFA_MAX_PROCESSORS not a decimal number : %s\n", max_cores_s);
                return __CFA_MAX_PROCESSORS__;
        }

        return max_cores_l;
}

//=======================================================================
// Cluster wide reader-writer lock
//=======================================================================
void  ?{}(__scheduler_RWLock_t & this) {
        this.max   = __max_processors();
        this.alloc = 0;
        this.ready = 0;
        this.lock  = false;
        this.data  = alloc(this.max);

        /*paranoid*/ verify( 0 == (((uintptr_t)(this.data    )) % 64) );
        /*paranoid*/ verify( 0 == (((uintptr_t)(this.data + 1)) % 64) );
        /*paranoid*/ verify(__atomic_is_lock_free(sizeof(this.alloc), &this.alloc));
        /*paranoid*/ verify(__atomic_is_lock_free(sizeof(this.ready), &this.ready));

}
void ^?{}(__scheduler_RWLock_t & this) {
        free(this.data);
}

void ?{}( __scheduler_lock_id_t & this, __processor_id_t * proc ) {
        this.handle = proc;
        this.lock   = false;
        #ifdef __CFA_WITH_VERIFY__
                this.owned  = false;
        #endif
}

//=======================================================================
// Lock-Free registering/unregistering of threads
void register_proc_id( struct __processor_id_t * proc ) with(*__scheduler_lock) {
        __cfadbg_print_safe(ready_queue, "Kernel : Registering proc %p for RW-Lock\n", proc);

        // Step - 1 : check if there is already space in the data
        uint_fast32_t s = ready;

        // Check among all the ready
        for(uint_fast32_t i = 0; i < s; i++) {
                __processor_id_t * null = 0p; // Re-write every loop since compare thrashes it
                if( __atomic_load_n(&data[i].handle, (int)__ATOMIC_RELAXED) == null
                        && __atomic_compare_exchange_n( &data[i].handle, &null, proc, false, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST)) {
                        /*paranoid*/ verify(i < ready);
                        /*paranoid*/ verify(0 == (__alignof__(data[i]) % cache_line_size));
                        /*paranoid*/ verify((((uintptr_t)&data[i]) % cache_line_size) == 0);
                        proc->id = i;
                }
        }

        if(max <= alloc) abort("Trying to create more than %ud processors", __scheduler_lock->max);

        // Step - 2 : F&A to get a new spot in the array.
        uint_fast32_t n = __atomic_fetch_add(&alloc, 1, __ATOMIC_SEQ_CST);
        if(max <= n) abort("Trying to create more than %ud processors", __scheduler_lock->max);

        // Step - 3 : Mark space as used and then publish it.
        __scheduler_lock_id_t * storage = (__scheduler_lock_id_t *)&data[n];
        (*storage){ proc };
        while() {
                unsigned copy = n;
                if( __atomic_load_n(&ready, __ATOMIC_RELAXED) == n
                        && __atomic_compare_exchange_n(&ready, &copy, n + 1, true, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST))
                        break;
                Pause();
        }

        __cfadbg_print_safe(ready_queue, "Kernel : Registering proc %p done, id %lu\n", proc, n);

        // Return new spot.
        /*paranoid*/ verify(n < ready);
        /*paranoid*/ verify(__alignof__(data[n]) == (2 * cache_line_size));
        /*paranoid*/ verify((((uintptr_t)&data[n]) % cache_line_size) == 0);
        proc->id = n;
}

void unregister_proc_id( struct __processor_id_t * proc ) with(*__scheduler_lock) {
        unsigned id = proc->id;
        /*paranoid*/ verify(id < ready);
        /*paranoid*/ verify(proc == __atomic_load_n(&data[id].handle, __ATOMIC_RELAXED));
        __atomic_store_n(&data[id].handle, 0p, __ATOMIC_RELEASE);

        __cfadbg_print_safe(ready_queue, "Kernel : Unregister proc %p\n", proc);
}

//-----------------------------------------------------------------------
// Writer side : acquire when changing the ready queue, e.g. adding more
//  queues or removing them.
uint_fast32_t ready_mutate_lock( void ) with(*__scheduler_lock) {
        /* paranoid */ verify( ! __preemption_enabled() );

        // Step 1 : lock global lock
        // It is needed to avoid processors that register mid Critical-Section
        //   to simply lock their own lock and enter.
        __atomic_acquire( &lock );

        // Step 2 : lock per-proc lock
        // Processors that are currently being registered aren't counted
        //   but can't be in read_lock or in the critical section.
        // All other processors are counted
        uint_fast32_t s = ready;
        for(uint_fast32_t i = 0; i < s; i++) {
                __atomic_acquire( &data[i].lock );
        }

        /* paranoid */ verify( ! __preemption_enabled() );
        return s;
}

void ready_mutate_unlock( uint_fast32_t last_s ) with(*__scheduler_lock) {
        /* paranoid */ verify( ! __preemption_enabled() );

        // Step 1 : release local locks
        // This must be done while the global lock is held to avoid
        //   threads that where created mid critical section
        //   to race to lock their local locks and have the writer
        //   immidiately unlock them
        // Alternative solution : return s in write_lock and pass it to write_unlock
        for(uint_fast32_t i = 0; i < last_s; i++) {
                verify(data[i].lock);
                __atomic_store_n(&data[i].lock, (bool)false, __ATOMIC_RELEASE);
        }

        // Step 2 : release global lock
        /*paranoid*/ assert(true == lock);
        __atomic_store_n(&lock, (bool)false, __ATOMIC_RELEASE);

        /* paranoid */ verify( ! __preemption_enabled() );
}

//=======================================================================
// Cforall Ready Queue used for scheduling
//=======================================================================
void ?{}(__ready_queue_t & this) with (this) {
        lanes.data  = 0p;
        lanes.tscs  = 0p;
        lanes.count = 0;
}

void ^?{}(__ready_queue_t & this) with (this) {
        verify( SEQUENTIAL_SHARD == lanes.count );
        free(lanes.data);
        free(lanes.tscs);
}

//-----------------------------------------------------------------------
#if defined(USE_RELAXED_FIFO)
        //-----------------------------------------------------------------------
        // get index from random number with or without bias towards queues
        static inline [unsigned, bool] idx_from_r(unsigned r, unsigned preferred) {
                unsigned i;
                bool local;
                unsigned rlow  = r % BIAS;
                unsigned rhigh = r / BIAS;
                if((0 != rlow) && preferred >= 0) {
                        // (BIAS - 1) out of BIAS chances
                        // Use perferred queues
                        i = preferred + (rhigh % READYQ_SHARD_FACTOR);
                        local = true;
                }
                else {
                        // 1 out of BIAS chances
                        // Use all queues
                        i = rhigh;
                        local = false;
                }
                return [i, local];
        }

        __attribute__((hot)) void push(struct cluster * cltr, struct $thread * thrd) with (cltr->ready_queue) {
                __cfadbg_print_safe(ready_queue, "Kernel : Pushing %p on cluster %p\n", thrd, cltr);

                const bool external = (!kernelTLS().this_processor) || (cltr != kernelTLS().this_processor->cltr);
                /* paranoid */ verify(external || kernelTLS().this_processor->rdq.id < lanes.count );

                // write timestamp
                thrd->link.ts = rdtscl();

                bool local;
                int preferred = external ? -1 : kernelTLS().this_processor->rdq.id;

                // Try to pick a lane and lock it
                unsigned i;
                do {
                        // Pick the index of a lane
                        unsigned r = __tls_rand_fwd();
                        [i, local] = idx_from_r(r, preferred);

                        i %= __atomic_load_n( &lanes.count, __ATOMIC_RELAXED );

                        #if !defined(__CFA_NO_STATISTICS__)
                                if(unlikely(external)) __atomic_fetch_add(&cltr->stats->ready.push.extrn.attempt, 1, __ATOMIC_RELAXED);
                                else if(local) __tls_stats()->ready.push.local.attempt++;
                                else __tls_stats()->ready.push.share.attempt++;
                        #endif

                #if defined(USE_MPSC)
                        // mpsc always succeeds
                } while( false );
                #else
                        // If we can't lock it retry
                } while( !__atomic_try_acquire( &lanes.data[i].lock ) );
                #endif

                // Actually push it
                push(lanes.data[i], thrd);

                #if !defined(USE_MPSC)
                        // Unlock and return
                        __atomic_unlock( &lanes.data[i].lock );
                #endif

                // Mark the current index in the tls rng instance as having an item
                __tls_rand_advance_bck();

                __cfadbg_print_safe(ready_queue, "Kernel : Pushed %p on cluster %p (idx: %u, mask %llu, first %d)\n", thrd, cltr, i, used.mask[0], lane_first);

                // Update statistics
                #if !defined(__CFA_NO_STATISTICS__)
                        if(unlikely(external)) __atomic_fetch_add(&cltr->stats->ready.push.extrn.success, 1, __ATOMIC_RELAXED);
                        else if(local) __tls_stats()->ready.push.local.success++;
                        else __tls_stats()->ready.push.share.success++;
                #endif
        }

        // Pop from the ready queue from a given cluster
        __attribute__((hot)) $thread * pop_fast(struct cluster * cltr) with (cltr->ready_queue) {
                /* paranoid */ verify( lanes.count > 0 );
                /* paranoid */ verify( kernelTLS().this_processor );
                /* paranoid */ verify( kernelTLS().this_processor->rdq.id < lanes.count );

                unsigned count = __atomic_load_n( &lanes.count, __ATOMIC_RELAXED );
                int preferred = kernelTLS().this_processor->rdq.id;


                // As long as the list is not empty, try finding a lane that isn't empty and pop from it
                for(25) {
                        // Pick two lists at random
                        unsigned ri = __tls_rand_bck();
                        unsigned rj = __tls_rand_bck();

                        unsigned i, j;
                        __attribute__((unused)) bool locali, localj;
                        [i, locali] = idx_from_r(ri, preferred);
                        [j, localj] = idx_from_r(rj, preferred);

                        i %= count;
                        j %= count;

                        // try popping from the 2 picked lists
                        struct $thread * thrd = try_pop(cltr, i, j __STATS(, *(locali || localj ? &__tls_stats()->ready.pop.local : &__tls_stats()->ready.pop.help)));
                        if(thrd) {
                                return thrd;
                        }
                }

                // All lanes where empty return 0p
                return 0p;
        }

        __attribute__((hot)) struct $thread * pop_slow(struct cluster * cltr) {
                return search(cltr);
        }
#endif
#if defined(USE_WORK_STEALING)
        __attribute__((hot)) void push(struct cluster * cltr, struct $thread * thrd) with (cltr->ready_queue) {
                __cfadbg_print_safe(ready_queue, "Kernel : Pushing %p on cluster %p\n", thrd, cltr);

                const bool external = (!kernelTLS().this_processor) || (cltr != kernelTLS().this_processor->cltr);
                /* paranoid */ verify(external || kernelTLS().this_processor->rdq.id < lanes.count );

                // write timestamp
                thrd->link.ts = rdtscl();

                // Try to pick a lane and lock it
                unsigned i;
                do {
                        #if !defined(__CFA_NO_STATISTICS__)
                                if(unlikely(external)) __atomic_fetch_add(&cltr->stats->ready.push.extrn.attempt, 1, __ATOMIC_RELAXED);
                                else __tls_stats()->ready.push.local.attempt++;
                        #endif

                        if(unlikely(external)) {
                                i = __tls_rand() % lanes.count;
                        }
                        else {
                                processor * proc = kernelTLS().this_processor;
                                unsigned r = proc->rdq.its++;
                                i =  proc->rdq.id + (r % READYQ_SHARD_FACTOR);
                        }


                #if defined(USE_MPSC)
                        // mpsc always succeeds
                } while( false );
                #else
                        // If we can't lock it retry
                } while( !__atomic_try_acquire( &lanes.data[i].lock ) );
                #endif

                // Actually push it
                push(lanes.data[i], thrd);

                #if !defined(USE_MPSC)
                        // Unlock and return
                        __atomic_unlock( &lanes.data[i].lock );
                #endif

                #if !defined(__CFA_NO_STATISTICS__)
                        if(unlikely(external)) __atomic_fetch_add(&cltr->stats->ready.push.extrn.success, 1, __ATOMIC_RELAXED);
                        else __tls_stats()->ready.push.local.success++;
                #endif

                __cfadbg_print_safe(ready_queue, "Kernel : Pushed %p on cluster %p (idx: %u, mask %llu, first %d)\n", thrd, cltr, i, used.mask[0], lane_first);
        }

        // Pop from the ready queue from a given cluster
        __attribute__((hot)) $thread * pop_fast(struct cluster * cltr) with (cltr->ready_queue) {
                /* paranoid */ verify( lanes.count > 0 );
                /* paranoid */ verify( kernelTLS().this_processor );
                /* paranoid */ verify( kernelTLS().this_processor->rdq.id < lanes.count );

                processor * proc = kernelTLS().this_processor;

                if(proc->rdq.target == -1u) {
                        proc->rdq.target = __tls_rand() % lanes.count;
                        unsigned it1  = proc->rdq.itr;
                        unsigned it2  = proc->rdq.itr + 1;
                        unsigned idx1 = proc->rdq.id + (it1 % READYQ_SHARD_FACTOR);
                        unsigned idx2 = proc->rdq.id + (it2 % READYQ_SHARD_FACTOR);
                        unsigned long long tsc1 = ts(lanes.data[idx1]);
                        unsigned long long tsc2 = ts(lanes.data[idx2]);
                        proc->rdq.cutoff = min(tsc1, tsc2);
                }
                else if(lanes.tscs[proc->rdq.target].tv < proc->rdq.cutoff) {
                        $thread * t = try_pop(cltr, proc->rdq.target __STATS(, __tls_stats()->ready.pop.help));
                        proc->rdq.target = -1u;
                        if(t) return t;
                }

                for(READYQ_SHARD_FACTOR) {
                        unsigned i = proc->rdq.id + (--proc->rdq.itr % READYQ_SHARD_FACTOR);
                        if($thread * t = try_pop(cltr, i __STATS(, __tls_stats()->ready.pop.local))) return t;
                }
                return 0p;
        }

        __attribute__((hot)) struct $thread * pop_slow(struct cluster * cltr) with (cltr->ready_queue) {
                for(25) {
                        unsigned i = __tls_rand() % lanes.count;
                        $thread * t = try_pop(cltr, i __STATS(, __tls_stats()->ready.pop.steal));
                        if(t) return t;
                }

                return search(cltr);
        }
#endif

//=======================================================================
// Various Ready Queue utilities
//=======================================================================
// these function work the same or almost the same
// whether they are using work-stealing or relaxed fifo scheduling

//-----------------------------------------------------------------------
// try to pop from a lane given by index w
static inline struct $thread * try_pop(struct cluster * cltr, unsigned w __STATS(, __stats_readyQ_pop_t & stats)) with (cltr->ready_queue) {
        __STATS( stats.attempt++; )

        // Get relevant elements locally
        __intrusive_lane_t & lane = lanes.data[w];

        // If list looks empty retry
        if( is_empty(lane) ) {
                __STATS( stats.espec++; )
                return 0p;
        }

        // If we can't get the lock retry
        if( !__atomic_try_acquire(&lane.lock) ) {
                __STATS( stats.elock++; )
                return 0p;
        }

        // If list is empty, unlock and retry
        if( is_empty(lane) ) {
                __atomic_unlock(&lane.lock);
                __STATS( stats.eempty++; )
                return 0p;
        }

        // Actually pop the list
        struct $thread * thrd;
        thrd = pop(lane);

        /* paranoid */ verify(thrd);
        /* paranoid */ verify(lane.lock);

        // Unlock and return
        __atomic_unlock(&lane.lock);

        // Update statistics
        __STATS( stats.success++; )

        #if defined(USE_WORK_STEALING)
                lanes.tscs[w].tv = thrd->link.ts;
        #endif

        // return the popped thread
        return thrd;
}

//-----------------------------------------------------------------------
// try to pop from any lanes making sure you don't miss any threads push
// before the start of the function
static inline struct $thread * search(struct cluster * cltr) with (cltr->ready_queue) {
        /* paranoid */ verify( lanes.count > 0 );
        unsigned count = __atomic_load_n( &lanes.count, __ATOMIC_RELAXED );
        unsigned offset = __tls_rand();
        for(i; count) {
                unsigned idx = (offset + i) % count;
                struct $thread * thrd = try_pop(cltr, idx __STATS(, __tls_stats()->ready.pop.search));
                if(thrd) {
                        return thrd;
                }
        }

        // All lanes where empty return 0p
        return 0p;
}

//-----------------------------------------------------------------------
// Check that all the intrusive queues in the data structure are still consistent
static void check( __ready_queue_t & q ) with (q) {
        #if defined(__CFA_WITH_VERIFY__) && !defined(USE_MPSC)
                {
                        for( idx ; lanes.count ) {
                                __intrusive_lane_t & sl = lanes.data[idx];
                                assert(!lanes.data[idx].lock);

                                assert(head(sl)->link.prev == 0p );
                                assert(head(sl)->link.next->link.prev == head(sl) );
                                assert(tail(sl)->link.next == 0p );
                                assert(tail(sl)->link.prev->link.next == tail(sl) );

                                if(is_empty(sl)) {
                                        assert(tail(sl)->link.prev == head(sl));
                                        assert(head(sl)->link.next == tail(sl));
                                } else {
                                        assert(tail(sl)->link.prev != head(sl));
                                        assert(head(sl)->link.next != tail(sl));
                                }
                        }
                }
        #endif
}

//-----------------------------------------------------------------------
// Given 2 indexes, pick the list with the oldest push an try to pop from it
static inline struct $thread * try_pop(struct cluster * cltr, unsigned i, unsigned j __STATS(, __stats_readyQ_pop_t & stats)) with (cltr->ready_queue) {
        // Pick the bet list
        int w = i;
        if( __builtin_expect(!is_empty(lanes.data[j]), true) ) {
                w = (ts(lanes.data[i]) < ts(lanes.data[j])) ? i : j;
        }

        return try_pop(cltr, w __STATS(, stats));
}

// Call this function of the intrusive list was moved using memcpy
// fixes the list so that the pointers back to anchors aren't left dangling
static inline void fix(__intrusive_lane_t & ll) {
        #if !defined(USE_MPSC)
                // if the list is not empty then follow he pointer and fix its reverse
                if(!is_empty(ll)) {
                        head(ll)->link.next->link.prev = head(ll);
                        tail(ll)->link.prev->link.next = tail(ll);
                }
                // Otherwise just reset the list
                else {
                        verify(tail(ll)->link.next == 0p);
                        tail(ll)->link.prev = head(ll);
                        head(ll)->link.next = tail(ll);
                        verify(head(ll)->link.prev == 0p);
                }
        #endif
}

static void assign_list(unsigned & value, dlist(processor, processor) & list, unsigned count) {
        processor * it = &list`first;
        for(unsigned i = 0; i < count; i++) {
                /* paranoid */ verifyf( it, "Unexpected null iterator, at index %u of %u\n", i, count);
                it->rdq.id = value;
                it->rdq.target = -1u;
                value += READYQ_SHARD_FACTOR;
                it = &(*it)`next;
        }
}

static void reassign_cltr_id(struct cluster * cltr) {
        unsigned preferred = 0;
        assign_list(preferred, cltr->procs.actives, cltr->procs.total - cltr->procs.idle);
        assign_list(preferred, cltr->procs.idles  , cltr->procs.idle );
}

static void fix_times( struct cluster * cltr ) with( cltr->ready_queue ) {
        #if defined(USE_WORK_STEALING)
                lanes.tscs = alloc(lanes.count, lanes.tscs`realloc);
                for(i; lanes.count) {
                        lanes.tscs[i].tv = ts(lanes.data[i]);
                }
        #endif
}

// Grow the ready queue
void ready_queue_grow(struct cluster * cltr) {
        size_t ncount;
        int target = cltr->procs.total;

        /* paranoid */ verify( ready_mutate_islocked() );
        __cfadbg_print_safe(ready_queue, "Kernel : Growing ready queue\n");

        // Make sure that everything is consistent
        /* paranoid */ check( cltr->ready_queue );

        // grow the ready queue
        with( cltr->ready_queue ) {
                // Find new count
                // Make sure we always have atleast 1 list
                if(target >= 2) {
                        ncount = target * READYQ_SHARD_FACTOR;
                } else {
                        ncount = SEQUENTIAL_SHARD;
                }

                // Allocate new array (uses realloc and memcpies the data)
                lanes.data = alloc( ncount, lanes.data`realloc );

                // Fix the moved data
                for( idx; (size_t)lanes.count ) {
                        fix(lanes.data[idx]);
                }

                // Construct new data
                for( idx; (size_t)lanes.count ~ ncount) {
                        (lanes.data[idx]){};
                }

                // Update original
                lanes.count = ncount;
        }

        fix_times(cltr);

        reassign_cltr_id(cltr);

        // Make sure that everything is consistent
        /* paranoid */ check( cltr->ready_queue );

        __cfadbg_print_safe(ready_queue, "Kernel : Growing ready queue done\n");

        /* paranoid */ verify( ready_mutate_islocked() );
}

// Shrink the ready queue
void ready_queue_shrink(struct cluster * cltr) {
        /* paranoid */ verify( ready_mutate_islocked() );
        __cfadbg_print_safe(ready_queue, "Kernel : Shrinking ready queue\n");

        // Make sure that everything is consistent
        /* paranoid */ check( cltr->ready_queue );

        int target = cltr->procs.total;

        with( cltr->ready_queue ) {
                // Remember old count
                size_t ocount = lanes.count;

                // Find new count
                // Make sure we always have atleast 1 list
                lanes.count = target >= 2 ? target * READYQ_SHARD_FACTOR: SEQUENTIAL_SHARD;
                /* paranoid */ verify( ocount >= lanes.count );
                /* paranoid */ verify( lanes.count == target * READYQ_SHARD_FACTOR || target < 2 );

                // for printing count the number of displaced threads
                #if defined(__CFA_DEBUG_PRINT__) || defined(__CFA_DEBUG_PRINT_READY_QUEUE__)
                        __attribute__((unused)) size_t displaced = 0;
                #endif

                // redistribute old data
                for( idx; (size_t)lanes.count ~ ocount) {
                        // Lock is not strictly needed but makes checking invariants much easier
                        __attribute__((unused)) bool locked = __atomic_try_acquire(&lanes.data[idx].lock);
                        verify(locked);

                        // As long as we can pop from this lane to push the threads somewhere else in the queue
                        while(!is_empty(lanes.data[idx])) {
                                struct $thread * thrd;
                                thrd = pop(lanes.data[idx]);

                                push(cltr, thrd);

                                // for printing count the number of displaced threads
                                #if defined(__CFA_DEBUG_PRINT__) || defined(__CFA_DEBUG_PRINT_READY_QUEUE__)
                                        displaced++;
                                #endif
                        }

                        // Unlock the lane
                        __atomic_unlock(&lanes.data[idx].lock);

                        // TODO print the queue statistics here

                        ^(lanes.data[idx]){};
                }

                __cfadbg_print_safe(ready_queue, "Kernel : Shrinking ready queue displaced %zu threads\n", displaced);

                // Allocate new array (uses realloc and memcpies the data)
                lanes.data = alloc( lanes.count, lanes.data`realloc );

                // Fix the moved data
                for( idx; (size_t)lanes.count ) {
                        fix(lanes.data[idx]);
                }
        }

        fix_times(cltr);

        reassign_cltr_id(cltr);

        // Make sure that everything is consistent
        /* paranoid */ check( cltr->ready_queue );

        __cfadbg_print_safe(ready_queue, "Kernel : Shrinking ready queue done\n");
        /* paranoid */ verify( ready_mutate_islocked() );
}