source: libcfa/src/concurrency/ready_queue.cfa @ d0cd933

ADTarm-ehast-experimentalenumforall-pointer-decayjacob/cs343-translationnew-ast-unique-exprpthread-emulationqualifiedEnum
Last change on this file since d0cd933 was 32c2c5e, checked in by Thierry Delisle <tdelisle@…>, 4 years ago

Removed unused variables

  • Property mode set to 100644
File size: 18.0 KB
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[7768b8d]1//
2// Cforall Version 1.0.0 Copyright (C) 2019 University of Waterloo
3//
4// The contents of this file are covered under the licence agreement in the
5// file "LICENCE" distributed with Cforall.
6//
7// ready_queue.cfa --
8//
9// Author           : Thierry Delisle
10// Created On       : Mon Nov dd 16:29:18 2019
11// Last Modified By :
12// Last Modified On :
13// Update Count     :
14//
15
16#define __cforall_thread__
[1b143de]17// #define __CFA_DEBUG_PRINT_READY_QUEUE__
[7768b8d]18
[1eb239e4]19// #define USE_SNZI
20
[7768b8d]21#include "bits/defs.hfa"
22#include "kernel_private.hfa"
23
24#define _GNU_SOURCE
25#include "stdlib.hfa"
[61d7bec]26#include "math.hfa"
[7768b8d]27
[04b5cef]28#include <unistd.h>
29
[13c5e19]30#include "snzi.hfa"
31#include "ready_subqueue.hfa"
32
[7768b8d]33static const size_t cache_line_size = 64;
34
[dca5802]35// No overriden function, no environment variable, no define
36// fall back to a magic number
37#ifndef __CFA_MAX_PROCESSORS__
[b388ee81]38        #define __CFA_MAX_PROCESSORS__ 1024
[dca5802]39#endif
[7768b8d]40
[320ec6fc]41#define BIAS 16
[04b5cef]42
[dca5802]43// returns the maximum number of processors the RWLock support
[7768b8d]44__attribute__((weak)) unsigned __max_processors() {
45        const char * max_cores_s = getenv("CFA_MAX_PROCESSORS");
46        if(!max_cores_s) {
[504a7dc]47                __cfadbg_print_nolock(ready_queue, "No CFA_MAX_PROCESSORS in ENV\n");
[dca5802]48                return __CFA_MAX_PROCESSORS__;
[7768b8d]49        }
50
51        char * endptr = 0p;
52        long int max_cores_l = strtol(max_cores_s, &endptr, 10);
53        if(max_cores_l < 1 || max_cores_l > 65535) {
[504a7dc]54                __cfadbg_print_nolock(ready_queue, "CFA_MAX_PROCESSORS out of range : %ld\n", max_cores_l);
[dca5802]55                return __CFA_MAX_PROCESSORS__;
[7768b8d]56        }
57        if('\0' != *endptr) {
[504a7dc]58                __cfadbg_print_nolock(ready_queue, "CFA_MAX_PROCESSORS not a decimal number : %s\n", max_cores_s);
[dca5802]59                return __CFA_MAX_PROCESSORS__;
[7768b8d]60        }
61
62        return max_cores_l;
63}
64
65//=======================================================================
66// Cluster wide reader-writer lock
67//=======================================================================
[b388ee81]68void  ?{}(__scheduler_RWLock_t & this) {
[7768b8d]69        this.max   = __max_processors();
70        this.alloc = 0;
71        this.ready = 0;
72        this.lock  = false;
73        this.data  = alloc(this.max);
74
75        /*paranoid*/ verify( 0 == (((uintptr_t)(this.data    )) % 64) );
76        /*paranoid*/ verify( 0 == (((uintptr_t)(this.data + 1)) % 64) );
77        /*paranoid*/ verify(__atomic_is_lock_free(sizeof(this.alloc), &this.alloc));
78        /*paranoid*/ verify(__atomic_is_lock_free(sizeof(this.ready), &this.ready));
79
80}
[b388ee81]81void ^?{}(__scheduler_RWLock_t & this) {
[7768b8d]82        free(this.data);
83}
84
[9b1dcc2]85void ?{}( __scheduler_lock_id_t & this, __processor_id_t * proc ) {
[7768b8d]86        this.handle = proc;
87        this.lock   = false;
[64a7146]88        #ifdef __CFA_WITH_VERIFY__
89                this.owned  = false;
90        #endif
[7768b8d]91}
92
93//=======================================================================
94// Lock-Free registering/unregistering of threads
[9b1dcc2]95unsigned doregister( struct __processor_id_t * proc ) with(*__scheduler_lock) {
[b388ee81]96        __cfadbg_print_safe(ready_queue, "Kernel : Registering proc %p for RW-Lock\n", proc);
[504a7dc]97
[7768b8d]98        // Step - 1 : check if there is already space in the data
99        uint_fast32_t s = ready;
100
101        // Check among all the ready
102        for(uint_fast32_t i = 0; i < s; i++) {
[9b1dcc2]103                __processor_id_t * null = 0p; // Re-write every loop since compare thrashes it
[7768b8d]104                if( __atomic_load_n(&data[i].handle, (int)__ATOMIC_RELAXED) == null
105                        && __atomic_compare_exchange_n( &data[i].handle, &null, proc, false, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST)) {
106                        /*paranoid*/ verify(i < ready);
[64a7146]107                        /*paranoid*/ verify(0 == (__alignof__(data[i]) % cache_line_size));
[7768b8d]108                        /*paranoid*/ verify((((uintptr_t)&data[i]) % cache_line_size) == 0);
109                        return i;
110                }
111        }
112
[b388ee81]113        if(max <= alloc) abort("Trying to create more than %ud processors", __scheduler_lock->max);
[7768b8d]114
115        // Step - 2 : F&A to get a new spot in the array.
116        uint_fast32_t n = __atomic_fetch_add(&alloc, 1, __ATOMIC_SEQ_CST);
[b388ee81]117        if(max <= n) abort("Trying to create more than %ud processors", __scheduler_lock->max);
[7768b8d]118
119        // Step - 3 : Mark space as used and then publish it.
[9b1dcc2]120        __scheduler_lock_id_t * storage = (__scheduler_lock_id_t *)&data[n];
[7768b8d]121        (*storage){ proc };
[fd9b524]122        while() {
[7768b8d]123                unsigned copy = n;
124                if( __atomic_load_n(&ready, __ATOMIC_RELAXED) == n
125                        && __atomic_compare_exchange_n(&ready, &copy, n + 1, true, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST))
126                        break;
[fd9b524]127                Pause();
[7768b8d]128        }
129
[1b143de]130        __cfadbg_print_safe(ready_queue, "Kernel : Registering proc %p done, id %lu\n", proc, n);
[504a7dc]131
[7768b8d]132        // Return new spot.
133        /*paranoid*/ verify(n < ready);
[37ba662]134        /*paranoid*/ verify(__alignof__(data[n]) == (2 * cache_line_size));
[7768b8d]135        /*paranoid*/ verify((((uintptr_t)&data[n]) % cache_line_size) == 0);
136        return n;
137}
138
[9b1dcc2]139void unregister( struct __processor_id_t * proc ) with(*__scheduler_lock) {
[7768b8d]140        unsigned id = proc->id;
141        /*paranoid*/ verify(id < ready);
142        /*paranoid*/ verify(proc == __atomic_load_n(&data[id].handle, __ATOMIC_RELAXED));
143        __atomic_store_n(&data[id].handle, 0p, __ATOMIC_RELEASE);
[504a7dc]144
145        __cfadbg_print_safe(ready_queue, "Kernel : Unregister proc %p\n", proc);
[7768b8d]146}
147
148//-----------------------------------------------------------------------
149// Writer side : acquire when changing the ready queue, e.g. adding more
150//  queues or removing them.
[b388ee81]151uint_fast32_t ready_mutate_lock( void ) with(*__scheduler_lock) {
[8fc652e0]152        /* paranoid */ verify( ! __preemption_enabled() );
[62502cc4]153
[7768b8d]154        // Step 1 : lock global lock
155        // It is needed to avoid processors that register mid Critical-Section
156        //   to simply lock their own lock and enter.
157        __atomic_acquire( &lock );
158
159        // Step 2 : lock per-proc lock
160        // Processors that are currently being registered aren't counted
161        //   but can't be in read_lock or in the critical section.
162        // All other processors are counted
163        uint_fast32_t s = ready;
164        for(uint_fast32_t i = 0; i < s; i++) {
165                __atomic_acquire( &data[i].lock );
166        }
167
[8fc652e0]168        /* paranoid */ verify( ! __preemption_enabled() );
[7768b8d]169        return s;
170}
171
[b388ee81]172void ready_mutate_unlock( uint_fast32_t last_s ) with(*__scheduler_lock) {
[8fc652e0]173        /* paranoid */ verify( ! __preemption_enabled() );
[62502cc4]174
[7768b8d]175        // Step 1 : release local locks
176        // This must be done while the global lock is held to avoid
177        //   threads that where created mid critical section
178        //   to race to lock their local locks and have the writer
179        //   immidiately unlock them
180        // Alternative solution : return s in write_lock and pass it to write_unlock
181        for(uint_fast32_t i = 0; i < last_s; i++) {
182                verify(data[i].lock);
183                __atomic_store_n(&data[i].lock, (bool)false, __ATOMIC_RELEASE);
184        }
185
186        // Step 2 : release global lock
187        /*paranoid*/ assert(true == lock);
188        __atomic_store_n(&lock, (bool)false, __ATOMIC_RELEASE);
[62502cc4]189
[8fc652e0]190        /* paranoid */ verify( ! __preemption_enabled() );
[7768b8d]191}
192
193//=======================================================================
[13c5e19]194// Cforall Reqdy Queue used for scheduling
[b798713]195//=======================================================================
196void ?{}(__ready_queue_t & this) with (this) {
[28d73c1]197        lanes.data  = 0p;
198        lanes.count = 0;
[b798713]199}
200
201void ^?{}(__ready_queue_t & this) with (this) {
[39fc03e]202        verify( 1 == lanes.count );
[1eb239e4]203        #ifdef USE_SNZI
204                verify( !query( snzi ) );
205        #endif
[dca5802]206        free(lanes.data);
207}
208
[64a7146]209//-----------------------------------------------------------------------
210__attribute__((hot)) bool query(struct cluster * cltr) {
[1eb239e4]211        #ifdef USE_SNZI
212                return query(cltr->ready_queue.snzi);
213        #endif
214        return true;
[64a7146]215}
216
[772411a]217static inline [unsigned, bool] idx_from_r(unsigned r, unsigned preferred) {
218        unsigned i;
219        bool local;
220        #if defined(BIAS)
221                unsigned rlow  = r % BIAS;
222                unsigned rhigh = r / BIAS;
223                if((0 != rlow) && preferred >= 0) {
224                        // (BIAS - 1) out of BIAS chances
225                        // Use perferred queues
226                        i = preferred + (rhigh % 4);
227                        local = true;
228                }
229                else {
230                        // 1 out of BIAS chances
231                        // Use all queues
232                        i = rhigh;
233                        local = false;
234                }
235        #else
236                i = r;
237                local = false;
238        #endif
239        return [i, local];
240}
241
[dca5802]242//-----------------------------------------------------------------------
[504a7dc]243__attribute__((hot)) bool push(struct cluster * cltr, struct $thread * thrd) with (cltr->ready_queue) {
[61d7bec]244        __cfadbg_print_safe(ready_queue, "Kernel : Pushing %p on cluster %p\n", thrd, cltr);
[1b143de]245
[dca5802]246        // write timestamp
[b798713]247        thrd->link.ts = rdtscl();
248
[772411a]249        __attribute__((unused)) bool local;
250        __attribute__((unused)) int preferred;
251        #if defined(BIAS)
252                preferred =
[d72c074]253                        //*
[8fc652e0]254                        kernelTLS().this_processor ? kernelTLS().this_processor->id * 4 : -1;
[d72c074]255                        /*/
256                        thrd->link.preferred * 4;
257                        //*/
[52769ba]258        #endif
259
[dca5802]260        // Try to pick a lane and lock it
261        unsigned i;
262        do {
263                // Pick the index of a lane
[5fe7322]264                // unsigned r = __tls_rand();
265                unsigned r = __tls_rand_fwd();
[772411a]266                [i, local] = idx_from_r(r, preferred);
267
268                #if !defined(__CFA_NO_STATISTICS__)
269                        if(local) {
270                                __tls_stats()->ready.pick.push.local++;
[04b5cef]271                        }
272                #endif
273
274                i %= __atomic_load_n( &lanes.count, __ATOMIC_RELAXED );
[b798713]275
276                #if !defined(__CFA_NO_STATISTICS__)
[8834751]277                        __tls_stats()->ready.pick.push.attempt++;
[b798713]278                #endif
279
280                // If we can't lock it retry
[dca5802]281        } while( !__atomic_try_acquire( &lanes.data[i].lock ) );
[b798713]282
[dca5802]283        bool first = false;
284
285        // Actually push it
[5fe7322]286        #ifdef USE_SNZI
287                bool lane_first =
288        #endif
289
290        push(lanes.data[i], thrd);
[dca5802]291
[1eb239e4]292        #ifdef USE_SNZI
293                // If this lane used to be empty we need to do more
294                if(lane_first) {
295                        // Check if the entire queue used to be empty
296                        first = !query(snzi);
[61d7bec]297
[1eb239e4]298                        // Update the snzi
299                        arrive( snzi, i );
300                }
301        #endif
[dca5802]302
[5fe7322]303        __tls_rand_advance_bck();
304
[dca5802]305        // Unlock and return
306        __atomic_unlock( &lanes.data[i].lock );
307
[1b143de]308        __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);
309
[dca5802]310        // Update statistics
311        #if !defined(__CFA_NO_STATISTICS__)
[52769ba]312                #if defined(BIAS)
313                        if( local ) __tls_stats()->ready.pick.push.lsuccess++;
314                #endif
[8834751]315                __tls_stats()->ready.pick.push.success++;
[dca5802]316        #endif
317
318        // return whether or not the list was empty before this push
319        return first;
[b798713]320}
321
[13c5e19]322static struct $thread * try_pop(struct cluster * cltr, unsigned i, unsigned j);
323static struct $thread * try_pop(struct cluster * cltr, unsigned i);
324
325// Pop from the ready queue from a given cluster
326__attribute__((hot)) $thread * pop(struct cluster * cltr) with (cltr->ready_queue) {
327        /* paranoid */ verify( lanes.count > 0 );
[1eb239e4]328        unsigned count = __atomic_load_n( &lanes.count, __ATOMIC_RELAXED );
[772411a]329        int preferred;
[13c5e19]330        #if defined(BIAS)
331                // Don't bother trying locally too much
[8fc652e0]332                preferred = kernelTLS().this_processor->id * 4;
[13c5e19]333        #endif
334
[772411a]335
[13c5e19]336        // As long as the list is not empty, try finding a lane that isn't empty and pop from it
[1eb239e4]337        #ifdef USE_SNZI
338                while( query(snzi) ) {
339        #else
340                for(25) {
341        #endif
[13c5e19]342                // Pick two lists at random
[5fe7322]343                // unsigned ri = __tls_rand();
344                // unsigned rj = __tls_rand();
345                unsigned ri = __tls_rand_bck();
346                unsigned rj = __tls_rand_bck();
[772411a]347
348                unsigned i, j;
349                __attribute__((unused)) bool locali, localj;
350                [i, locali] = idx_from_r(ri, preferred);
351                [j, localj] = idx_from_r(rj, preferred);
352
353                #if !defined(__CFA_NO_STATISTICS__)
354                        if(locali) {
355                                __tls_stats()->ready.pick.pop.local++;
[13c5e19]356                        }
[772411a]357                        if(localj) {
358                                __tls_stats()->ready.pick.pop.local++;
[13c5e19]359                        }
360                #endif
361
[1eb239e4]362                i %= count;
363                j %= count;
[13c5e19]364
365                // try popping from the 2 picked lists
366                struct $thread * thrd = try_pop(cltr, i, j);
[52769ba]367                if(thrd) {
368                        #if defined(BIAS) && !defined(__CFA_NO_STATISTICS__)
[772411a]369                                if( locali || localj ) __tls_stats()->ready.pick.pop.lsuccess++;
[52769ba]370                        #endif
371                        return thrd;
372                }
[13c5e19]373        }
374
375        // All lanes where empty return 0p
376        return 0p;
377}
378
[1eb239e4]379__attribute__((hot)) struct $thread * pop_slow(struct cluster * cltr) with (cltr->ready_queue) {
380        /* paranoid */ verify( lanes.count > 0 );
381        unsigned count = __atomic_load_n( &lanes.count, __ATOMIC_RELAXED );
382        unsigned offset = __tls_rand();
383        for(i; count) {
384                unsigned idx = (offset + i) % count;
385                struct $thread * thrd = try_pop(cltr, idx);
386                if(thrd) {
387                        return thrd;
388                }
389        }
390
391        // All lanes where empty return 0p
392        return 0p;
393}
394
395
[b798713]396//-----------------------------------------------------------------------
[dca5802]397// Given 2 indexes, pick the list with the oldest push an try to pop from it
[13c5e19]398static inline struct $thread * try_pop(struct cluster * cltr, unsigned i, unsigned j) with (cltr->ready_queue) {
[b798713]399        #if !defined(__CFA_NO_STATISTICS__)
[8834751]400                __tls_stats()->ready.pick.pop.attempt++;
[b798713]401        #endif
402
403        // Pick the bet list
404        int w = i;
[dca5802]405        if( __builtin_expect(!is_empty(lanes.data[j]), true) ) {
406                w = (ts(lanes.data[i]) < ts(lanes.data[j])) ? i : j;
[b798713]407        }
408
[13c5e19]409        return try_pop(cltr, w);
410}
411
412static inline struct $thread * try_pop(struct cluster * cltr, unsigned w) with (cltr->ready_queue) {
[dca5802]413        // Get relevant elements locally
414        __intrusive_lane_t & lane = lanes.data[w];
415
[b798713]416        // If list looks empty retry
[dca5802]417        if( is_empty(lane) ) return 0p;
[b798713]418
419        // If we can't get the lock retry
[dca5802]420        if( !__atomic_try_acquire(&lane.lock) ) return 0p;
[b798713]421
422
423        // If list is empty, unlock and retry
[dca5802]424        if( is_empty(lane) ) {
425                __atomic_unlock(&lane.lock);
[b798713]426                return 0p;
427        }
428
429        // Actually pop the list
[504a7dc]430        struct $thread * thrd;
[343d10e]431        thrd = pop(lane);
[b798713]432
[dca5802]433        /* paranoid */ verify(thrd);
434        /* paranoid */ verify(lane.lock);
[b798713]435
[1eb239e4]436        #ifdef USE_SNZI
437                // If this was the last element in the lane
438                if(emptied) {
439                        depart( snzi, w );
440                }
441        #endif
[b798713]442
443        // Unlock and return
[dca5802]444        __atomic_unlock(&lane.lock);
[b798713]445
[dca5802]446        // Update statistics
[b798713]447        #if !defined(__CFA_NO_STATISTICS__)
[8834751]448                __tls_stats()->ready.pick.pop.success++;
[b798713]449        #endif
450
[d72c074]451        // Update the thread bias
452        thrd->link.preferred = w / 4;
453
[dca5802]454        // return the popped thread
[b798713]455        return thrd;
456}
[13c5e19]457//-----------------------------------------------------------------------
[b798713]458
[13c5e19]459bool remove_head(struct cluster * cltr, struct $thread * thrd) with (cltr->ready_queue) {
460        for(i; lanes.count) {
461                __intrusive_lane_t & lane = lanes.data[i];
[b798713]462
[13c5e19]463                bool removed = false;
[04b5cef]464
[13c5e19]465                __atomic_acquire(&lane.lock);
466                        if(head(lane)->link.next == thrd) {
467                                $thread * pthrd;
[343d10e]468                                pthrd = pop(lane);
[04b5cef]469
[13c5e19]470                                /* paranoid */ verify( pthrd == thrd );
[61d7bec]471
[13c5e19]472                                removed = true;
[1eb239e4]473                                #ifdef USE_SNZI
474                                        if(emptied) {
475                                                depart( snzi, i );
476                                        }
477                                #endif
[13c5e19]478                        }
479                __atomic_unlock(&lane.lock);
[b798713]480
[13c5e19]481                if( removed ) return true;
482        }
483        return false;
[b798713]484}
485
486//-----------------------------------------------------------------------
487
488static void check( __ready_queue_t & q ) with (q) {
489        #if defined(__CFA_WITH_VERIFY__)
490                {
[dca5802]491                        for( idx ; lanes.count ) {
492                                __intrusive_lane_t & sl = lanes.data[idx];
493                                assert(!lanes.data[idx].lock);
[b798713]494
495                                assert(head(sl)->link.prev == 0p );
496                                assert(head(sl)->link.next->link.prev == head(sl) );
497                                assert(tail(sl)->link.next == 0p );
498                                assert(tail(sl)->link.prev->link.next == tail(sl) );
499
500                                if(sl.before.link.ts == 0l) {
501                                        assert(tail(sl)->link.prev == head(sl));
502                                        assert(head(sl)->link.next == tail(sl));
[1b143de]503                                } else {
504                                        assert(tail(sl)->link.prev != head(sl));
505                                        assert(head(sl)->link.next != tail(sl));
[b798713]506                                }
507                        }
508                }
509        #endif
510}
511
512// Call this function of the intrusive list was moved using memcpy
[dca5802]513// fixes the list so that the pointers back to anchors aren't left dangling
514static inline void fix(__intrusive_lane_t & ll) {
515        // if the list is not empty then follow he pointer and fix its reverse
516        if(!is_empty(ll)) {
[b798713]517                head(ll)->link.next->link.prev = head(ll);
518                tail(ll)->link.prev->link.next = tail(ll);
519        }
520        // Otherwise just reset the list
521        else {
[dca5802]522                verify(tail(ll)->link.next == 0p);
[b798713]523                tail(ll)->link.prev = head(ll);
524                head(ll)->link.next = tail(ll);
[dca5802]525                verify(head(ll)->link.prev == 0p);
[b798713]526        }
527}
528
[dca5802]529// Grow the ready queue
[320ec6fc]530void ready_queue_grow  (struct cluster * cltr, int target) {
[64a7146]531        /* paranoid */ verify( ready_mutate_islocked() );
[504a7dc]532        __cfadbg_print_safe(ready_queue, "Kernel : Growing ready queue\n");
[b798713]533
[dca5802]534        // Make sure that everything is consistent
535        /* paranoid */ check( cltr->ready_queue );
536
537        // grow the ready queue
[b798713]538        with( cltr->ready_queue ) {
[1eb239e4]539                #ifdef USE_SNZI
540                        ^(snzi){};
541                #endif
[b798713]542
[39fc03e]543                // Find new count
544                // Make sure we always have atleast 1 list
545                size_t ncount = target >= 2 ? target * 4: 1;
[b798713]546
[dca5802]547                // Allocate new array (uses realloc and memcpies the data)
[ceb7db8]548                lanes.data = alloc( ncount, lanes.data`realloc );
[b798713]549
550                // Fix the moved data
[dca5802]551                for( idx; (size_t)lanes.count ) {
552                        fix(lanes.data[idx]);
[b798713]553                }
554
555                // Construct new data
[dca5802]556                for( idx; (size_t)lanes.count ~ ncount) {
557                        (lanes.data[idx]){};
[b798713]558                }
559
560                // Update original
[dca5802]561                lanes.count = ncount;
562
[1eb239e4]563                #ifdef USE_SNZI
564                        // Re-create the snzi
565                        snzi{ log2( lanes.count / 8 ) };
566                        for( idx; (size_t)lanes.count ) {
567                                if( !is_empty(lanes.data[idx]) ) {
568                                        arrive(snzi, idx);
569                                }
[61d7bec]570                        }
[1eb239e4]571                #endif
[b798713]572        }
573
574        // Make sure that everything is consistent
[dca5802]575        /* paranoid */ check( cltr->ready_queue );
576
[504a7dc]577        __cfadbg_print_safe(ready_queue, "Kernel : Growing ready queue done\n");
[dca5802]578
[64a7146]579        /* paranoid */ verify( ready_mutate_islocked() );
[b798713]580}
581
[dca5802]582// Shrink the ready queue
[320ec6fc]583void ready_queue_shrink(struct cluster * cltr, int target) {
[64a7146]584        /* paranoid */ verify( ready_mutate_islocked() );
[504a7dc]585        __cfadbg_print_safe(ready_queue, "Kernel : Shrinking ready queue\n");
[dca5802]586
587        // Make sure that everything is consistent
588        /* paranoid */ check( cltr->ready_queue );
589
[b798713]590        with( cltr->ready_queue ) {
[1eb239e4]591                #ifdef USE_SNZI
592                        ^(snzi){};
593                #endif
[61d7bec]594
[39fc03e]595                // Remember old count
[dca5802]596                size_t ocount = lanes.count;
[b798713]597
[39fc03e]598                // Find new count
599                // Make sure we always have atleast 1 list
600                lanes.count = target >= 2 ? target * 4: 1;
601                /* paranoid */ verify( ocount >= lanes.count );
[320ec6fc]602                /* paranoid */ verify( lanes.count == target * 4 || target < 2 );
[dca5802]603
604                // for printing count the number of displaced threads
[504a7dc]605                #if defined(__CFA_DEBUG_PRINT__) || defined(__CFA_DEBUG_PRINT_READY_QUEUE__)
[dca5802]606                        __attribute__((unused)) size_t displaced = 0;
607                #endif
[b798713]608
609                // redistribute old data
[dca5802]610                for( idx; (size_t)lanes.count ~ ocount) {
611                        // Lock is not strictly needed but makes checking invariants much easier
[1b143de]612                        __attribute__((unused)) bool locked = __atomic_try_acquire(&lanes.data[idx].lock);
[b798713]613                        verify(locked);
[dca5802]614
615                        // As long as we can pop from this lane to push the threads somewhere else in the queue
616                        while(!is_empty(lanes.data[idx])) {
[504a7dc]617                                struct $thread * thrd;
[343d10e]618                                thrd = pop(lanes.data[idx]);
[dca5802]619
[b798713]620                                push(cltr, thrd);
[dca5802]621
622                                // for printing count the number of displaced threads
[504a7dc]623                                #if defined(__CFA_DEBUG_PRINT__) || defined(__CFA_DEBUG_PRINT_READY_QUEUE__)
[dca5802]624                                        displaced++;
625                                #endif
[b798713]626                        }
627
[dca5802]628                        // Unlock the lane
629                        __atomic_unlock(&lanes.data[idx].lock);
[b798713]630
631                        // TODO print the queue statistics here
632
[dca5802]633                        ^(lanes.data[idx]){};
[b798713]634                }
635
[504a7dc]636                __cfadbg_print_safe(ready_queue, "Kernel : Shrinking ready queue displaced %zu threads\n", displaced);
[c84b4be]637
[dca5802]638                // Allocate new array (uses realloc and memcpies the data)
[ceb7db8]639                lanes.data = alloc( lanes.count, lanes.data`realloc );
[b798713]640
641                // Fix the moved data
[dca5802]642                for( idx; (size_t)lanes.count ) {
643                        fix(lanes.data[idx]);
[b798713]644                }
[c84b4be]645
[1eb239e4]646                #ifdef USE_SNZI
647                        // Re-create the snzi
648                        snzi{ log2( lanes.count / 8 ) };
649                        for( idx; (size_t)lanes.count ) {
650                                if( !is_empty(lanes.data[idx]) ) {
651                                        arrive(snzi, idx);
652                                }
[61d7bec]653                        }
[1eb239e4]654                #endif
[b798713]655        }
656
657        // Make sure that everything is consistent
[dca5802]658        /* paranoid */ check( cltr->ready_queue );
659
[504a7dc]660        __cfadbg_print_safe(ready_queue, "Kernel : Shrinking ready queue done\n");
[64a7146]661        /* paranoid */ verify( ready_mutate_islocked() );
[fd9b524]662}
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