source: libcfa/src/concurrency/kernel/startup.cfa @ 218685e

Last change on this file since 218685e was ca0c311, checked in by caparsons <caparson@…>, 17 months ago

added ability to get number of processors constructed on a cluster (not necessarily registered yet)

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File size: 27.5 KB
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1//
2// Cforall Version 1.0.0 Copyright (C) 2020 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// kernel/startup.cfa --
8//
9// Author           : Thierry Delisle
10// Created On       : Thu Jul 30 15:12:54 2020
11// Last Modified By :
12// Last Modified On :
13// Update Count     :
14//
15
16#define __cforall_thread__
17
18// #define __CFA_DEBUG_PRINT_RUNTIME_CORE__
19
20// C Includes
21#include <errno.h>                                                                              // errno
22#include <signal.h>
23#include <string.h>                                                                             // strerror
24#include <unistd.h>
25#include <limits.h>                                                                             // PTHREAD_STACK_MIN
26extern "C" {
27        #include <sys/eventfd.h>                                                        // eventfd
28        #include <sys/mman.h>                                                           // mprotect
29        #include <sys/resource.h>                                                       // getrlimit
30}
31
32// CFA Includes
33#include "kernel/private.hfa"
34#include "iofwd.hfa"
35#include "startup.hfa"                                                                  // STARTUP_PRIORITY_XXX
36#include "limits.hfa"
37#include "math.hfa"
38#include "bits/random.hfa"                                                              // prng
39
40#define CFA_PROCESSOR_USE_MMAP 0
41
42//-----------------------------------------------------------------------------
43// Some assembly required
44#if defined( __i386 )
45        #define CtxGet( ctx ) __asm__ volatile ( \
46                "movl %%esp,%0\n" \
47                "movl %%ebp,%1\n" \
48                : "=rm" (ctx.SP), \
49                  "=rm" (ctx.FP) \
50        )
51#elif defined( __x86_64 )
52        #define CtxGet( ctx ) __asm__ volatile ( \
53                "movq %%rsp,%0\n" \
54                "movq %%rbp,%1\n" \
55                : "=rm" (ctx.SP), \
56                  "=rm" (ctx.FP) \
57        )
58#elif defined( __aarch64__ )
59        #define CtxGet( ctx ) __asm__ volatile ( \
60                "mov %0, sp\n" \
61                "mov %1, fp\n" \
62                : "=rm" (ctx.SP), \
63                  "=rm" (ctx.FP) \
64        )
65#else
66        #error unknown hardware architecture
67#endif
68
69//-----------------------------------------------------------------------------
70// Start and stop routine for the kernel, declared first to make sure they run first
71static void __kernel_startup (void) __attribute__(( constructor( STARTUP_PRIORITY_KERNEL ) ));
72static void __kernel_shutdown(void) __attribute__(( destructor ( STARTUP_PRIORITY_KERNEL ) ));
73
74//-----------------------------------------------------------------------------
75// Static Forward Declarations
76struct current_stack_info_t;
77
78static void * __invoke_processor(void * arg);
79static void __kernel_first_resume( processor * this );
80static void __kernel_last_resume ( processor * this );
81static void init(processor & this, const char name[], cluster & _cltr, thread$ * initT);
82static void deinit(processor & this);
83static void doregister( struct cluster & cltr );
84static void unregister( struct cluster & cltr );
85static void register_tls( processor * this );
86static void unregister_tls( processor * this );
87static void ?{}( coroutine$ & this, current_stack_info_t * info);
88static void ?{}( thread$ & this, current_stack_info_t * info);
89static void ?{}(processorCtx_t & this) {}
90static void ?{}(processorCtx_t & this, processor * proc, current_stack_info_t * info);
91
92#if defined(__CFA_WITH_VERIFY__)
93        static bool verify_fwd_bck_rng(void);
94#endif
95
96//-----------------------------------------------------------------------------
97// Forward Declarations for other modules
98extern void __kernel_alarm_startup(void);
99extern void __kernel_alarm_shutdown(void);
100extern void __cfa_io_start( processor * );
101extern void __cfa_io_stop ( processor * );
102
103//-----------------------------------------------------------------------------
104// Other Forward Declarations
105extern void __wake_proc(processor *);
106extern int cfa_main_returned;                                                   // from interpose.cfa
107size_t __global_random_prime = 4_294_967_291u;
108bool __global_random_mask = false;
109
110//-----------------------------------------------------------------------------
111// Kernel storage
112KERNEL_STORAGE(cluster,              mainCluster);
113KERNEL_STORAGE(processor,            mainProcessor);
114KERNEL_STORAGE(thread$,              mainThread);
115KERNEL_STORAGE(__stack_t,            mainThreadCtx);
116#if !defined(__CFA_NO_STATISTICS__)
117KERNEL_STORAGE(__stats_t, mainProcStats);
118#endif
119
120cluster              * mainCluster libcfa_public;
121processor            * mainProcessor;
122thread$              * mainThread;
123
124extern "C" {
125        struct { __dllist_t(cluster) list; __spinlock_t lock; } __cfa_dbg_global_clusters;
126}
127
128extern size_t __page_size;
129extern int __map_prot;
130
131//-----------------------------------------------------------------------------
132// Global state
133__thread struct KernelThreadData __cfaabi_tls __attribute__ ((tls_model ( "initial-exec" ))) @= {
134        .this_thread : NULL,                                                            // cannot use 0p
135        .this_processor : NULL,
136        .sched_lock : false,
137        .preemption_state : { .disable_count : 1, .enabled : false, .in_progress : false },
138        // random_state uninitialized
139        .ready_rng : { .fwd_seed : 0, .bck_seed : 0 },
140        .this_stats : NULL,
141        #ifdef __CFA_WITH_VERIFY__
142                .in_sched_lock : false,
143                .sched_id : 0,
144        #endif
145};
146
147__scheduler_RWLock_t __scheduler_lock @= { 0 };
148
149//-----------------------------------------------------------------------------
150// Struct to steal stack
151struct current_stack_info_t {
152        __stack_t * storage;  // pointer to stack object
153        void * base;          // base of stack
154        void * limit;         // stack grows towards stack limit
155        void * context;       // address of cfa_context_t
156};
157
158static void ?{}( current_stack_info_t & this ) {
159        __stack_context_t ctx;
160        CtxGet( ctx );
161        this.base = ctx.FP;
162
163        rlimit r;
164        getrlimit( RLIMIT_STACK, &r);
165        size_t size = r.rlim_cur;
166
167        this.limit = (void *)(((intptr_t)this.base) - size);
168        this.context = &storage_mainThreadCtx;
169}
170
171
172extern void heapManagerCtor();
173extern void heapManagerDtor();
174
175//=============================================================================================
176// Kernel Setup logic
177//=============================================================================================
178//-----------------------------------------------------------------------------
179// Kernel boot procedures
180static void __kernel_startup(void) {
181        /* paranoid */ verify( ! __preemption_enabled() );
182        __cfadbg_print_safe(runtime_core, "Kernel : Starting\n");
183
184        __cfa_dbg_global_clusters.list{ __get };
185        __cfa_dbg_global_clusters.lock{};
186
187        /* paranoid */ verify( verify_fwd_bck_rng() );
188
189        // Initialize the global scheduler lock
190        // __scheduler_lock = (__scheduler_RWLock_t*)&storage___scheduler_lock;
191        (__scheduler_lock){};
192
193        // Initialize the main cluster
194        mainCluster = (cluster *)&storage_mainCluster;
195        (*mainCluster){"Main Cluster", 0};
196
197        __cfadbg_print_safe(runtime_core, "Kernel : Main cluster ready\n");
198
199        // Construct the processor context of the main processor
200        void ?{}(processorCtx_t & this, processor * proc) {
201                (this.self){ "Processor" };
202                this.self.starter = 0p;
203                this.proc = proc;
204        }
205
206        void ?{}(processor & this) with( this ) {
207                ( this.terminated ){};
208                ( this.runner ){};
209                init( this, "Main Processor", *mainCluster, 0p );
210                kernel_thread = __cfaabi_pthread_self();
211
212                runner{ &this };
213                __cfadbg_print_safe(runtime_core, "Kernel : constructed main processor context %p\n", &runner);
214        }
215
216        // Initialize the main processor and the main processor ctx
217        // (the coroutine that contains the processing control flow)
218        mainProcessor = (processor *)&storage_mainProcessor;
219        (*mainProcessor){};
220
221        __cfa_io_start( mainProcessor );
222        register_tls( mainProcessor );
223
224        // Start by initializing the main thread
225        // SKULLDUGGERY: the mainThread steals the process main thread
226        // which will then be scheduled by the mainProcessor normally
227        mainThread = (thread$ *)&storage_mainThread;
228        current_stack_info_t info;
229        info.storage = (__stack_t*)&storage_mainThreadCtx;
230        (*mainThread){ &info };
231
232        __cfadbg_print_safe(runtime_core, "Kernel : Main thread ready\n");
233
234        //initialize the global state variables
235        __cfaabi_tls.this_processor = mainProcessor;
236        __cfaabi_tls.this_thread    = mainThread;
237
238        #if !defined( __CFA_NO_STATISTICS__ )
239                __cfaabi_tls.this_stats = (__stats_t *)& storage_mainProcStats;
240                __init_stats( __cfaabi_tls.this_stats );
241        #endif
242        mainProcessor->local_data = &__cfaabi_tls;
243
244        // Enable preemption
245        __kernel_alarm_startup();
246
247        // Add the main thread to the ready queue
248        // once resume is called on mainProcessor->runner the mainThread needs to be scheduled like any normal thread
249        schedule_thread$(mainThread, UNPARK_LOCAL);
250
251        // SKULLDUGGERY: Force a context switch to the main processor to set the main thread's context to the current UNIX
252        // context. Hence, the main thread does not begin through __cfactx_invoke_thread, like all other threads. The trick here is that
253        // mainThread is on the ready queue when this call is made.
254        __kernel_first_resume( __cfaabi_tls.this_processor );
255
256
257        // THE SYSTEM IS NOW COMPLETELY RUNNING
258
259        __cfadbg_print_safe(runtime_core, "Kernel : Started\n--------------------------------------------------\n\n");
260
261        /* paranoid */ verify( ! __preemption_enabled() );
262        enable_interrupts();
263        /* paranoid */ verify( __preemption_enabled() );
264
265}
266
267extern "C"{
268        void pthread_delete_kernel_threads_();
269}
270
271
272static void __kernel_shutdown(void) {
273        if(!cfa_main_returned) return;
274
275        //delete kernel threads for pthread_concurrency
276        pthread_delete_kernel_threads_();
277
278        /* paranoid */ verify( __preemption_enabled() );
279        disable_interrupts();
280        /* paranoid */ verify( ! __preemption_enabled() );
281
282        __cfadbg_print_safe(runtime_core, "\n--------------------------------------------------\nKernel : Shutting down\n");
283
284        // SKULLDUGGERY: Notify the mainProcessor it needs to terminates.
285        // When its coroutine terminates, it return control to the mainThread
286        // which is currently here
287        /* paranoid */ verify( !__atomic_load_n(&mainProcessor->do_terminate, __ATOMIC_ACQUIRE) );
288        __atomic_store_n(&mainProcessor->do_terminate, true, __ATOMIC_RELEASE);
289        __wake_proc( mainProcessor );
290        __kernel_last_resume( __cfaabi_tls.this_processor );
291        mainThread->self_cor.state = Halted;
292
293        // THE SYSTEM IS NOW COMPLETELY STOPPED
294
295        // Disable preemption
296        __kernel_alarm_shutdown();
297
298        #if !defined( __CFA_NO_STATISTICS__ )
299                __stats_t * st = (__stats_t *)& storage_mainProcStats;
300                __tally_stats(mainCluster->stats, st);
301                if( 0 != mainProcessor->print_stats ) {
302                        __print_stats( st, mainProcessor->print_stats, "Processor ", mainProcessor->name, (void*)mainProcessor );
303                }
304                #if defined(CFA_STATS_ARRAY)
305                        __flush_stat( st, "Processor", mainProcessor );
306                #endif
307        #endif
308
309        mainProcessor->local_data = 0p;
310
311        unregister_tls( mainProcessor );
312        __cfa_io_stop( mainProcessor );
313
314        // Destroy the main processor and its context in reverse order of construction
315        // These were manually constructed so we need manually destroy them
316        void ^?{}(processor & this) with( this ){
317                deinit( this );
318
319                /* paranoid */ verify( this.do_terminate == true );
320                __cfadbg_print_safe(runtime_core, "Kernel : destroyed main processor context %p\n", &runner);
321        }
322
323        ^(*mainProcessor){};
324
325        // Final step, destroy the main thread since it is no longer needed
326
327        // Since we provided a stack to this taxk it will not destroy anything
328        /* paranoid */ verify(mainThread->self_cor.stack.storage == (__stack_t*)(((uintptr_t)&storage_mainThreadCtx)| 0x1));
329        ^(*mainThread){};
330
331        ^(*mainCluster){};
332
333        ^(__scheduler_lock){};
334
335        ^(__cfa_dbg_global_clusters.list){};
336        ^(__cfa_dbg_global_clusters.lock){};
337
338        __cfadbg_print_safe(runtime_core, "Kernel : Shutdown complete\n");
339}
340
341//=============================================================================================
342// Kernel Initial Scheduling logic
343//=============================================================================================
344
345// Context invoker for processors
346// This is the entry point for processors (kernel threads) *except* for the main processor
347// It effectively constructs a coroutine by stealing the pthread stack
348static void * __invoke_processor(void * arg) {
349        #if !defined( __CFA_NO_STATISTICS__ )
350                __stats_t local_stats;
351                __init_stats( &local_stats );
352                __cfaabi_tls.this_stats = &local_stats;
353        #endif
354
355        processor * proc = (processor *) arg;
356        __cfaabi_tls.this_processor = proc;
357        __cfaabi_tls.this_thread    = 0p;
358        __cfaabi_tls.preemption_state.[enabled, disable_count] = [false, 1];
359        proc->local_data = &__cfaabi_tls;
360
361        heapManagerCtor();                                                                      // initialize heap
362
363        __cfa_io_start( proc );
364        register_tls( proc );
365
366        // SKULLDUGGERY: We want to create a context for the processor coroutine
367        // which is needed for the 2-step context switch. However, there is no reason
368        // to waste the perfectly valid stack create by pthread.
369        current_stack_info_t info;
370        __stack_t ctx;
371        info.storage = &ctx;
372        (proc->runner){ proc, &info };
373
374        __cfadbg_print_safe(runtime_core, "Coroutine : created stack %p\n", get_coroutine(proc->runner)->stack.storage);
375
376        //Set global state
377        __cfaabi_tls.this_thread = 0p;
378
379        //We now have a proper context from which to schedule threads
380        __cfadbg_print_safe(runtime_core, "Kernel : core %p created (%p, %p)\n", proc, &proc->runner, &ctx);
381
382        // SKULLDUGGERY: Since the coroutine doesn't have its own stack, we can't
383        // resume it to start it like it normally would, it will just context switch
384        // back to here. Instead directly call the main since we already are on the
385        // appropriate stack.
386        get_coroutine(proc->runner)->state = Active;
387        main( proc->runner );
388        get_coroutine(proc->runner)->state = Halted;
389
390        // Main routine of the core returned, the core is now fully terminated
391        __cfadbg_print_safe(runtime_core, "Kernel : core %p main ended (%p)\n", proc, &proc->runner);
392
393        #if !defined(__CFA_NO_STATISTICS__)
394                __tally_stats(proc->cltr->stats, &local_stats);
395                if( 0 != proc->print_stats ) {
396                        __print_stats( &local_stats, proc->print_stats, "Processor ", proc->name, (void*)proc );
397                }
398                #if defined(CFA_STATS_ARRAY)
399                        __flush_stat( &local_stats, "Processor", proc );
400                #endif
401        #endif
402
403        proc->local_data = 0p;
404
405        unregister_tls( proc );
406        __cfa_io_stop( proc );
407
408        heapManagerDtor();                                                                      // de-initialize heap
409
410        return 0p;
411}
412
413static void __kernel_first_resume( processor * this ) {
414        thread$ * src = mainThread;
415        coroutine$ * dst = get_coroutine(this->runner);
416
417        /* paranoid */ verify( ! __preemption_enabled() );
418
419        __cfaabi_tls.this_thread->curr_cor = dst;
420        __stack_prepare( &dst->stack, DEFAULT_STACK_SIZE );
421        __cfactx_start(main, dst, this->runner, __cfactx_invoke_coroutine);
422
423        /* paranoid */ verify( ! __preemption_enabled() );
424
425        dst->last = &src->self_cor;
426        dst->starter = dst->starter ? dst->starter : &src->self_cor;
427
428        // make sure the current state is still correct
429        /* paranoid */ verify(src->state == Ready);
430        src->corctx_flag = true;
431
432        // context switch to specified coroutine
433        verify( dst->context.SP );
434        __cfactx_switch( &src->context, &dst->context );
435        // when __cfactx_switch returns we are back in the src coroutine
436
437        mainThread->curr_cor = &mainThread->self_cor;
438
439        // make sure the current state has been update
440        /* paranoid */ verify(src->state == Active);
441
442        /* paranoid */ verify( ! __preemption_enabled() );
443}
444
445// KERNEL_ONLY
446static void __kernel_last_resume( processor * this ) {
447        coroutine$ * src = &mainThread->self_cor;
448        coroutine$ * dst = get_coroutine(this->runner);
449
450        /* paranoid */ verify( ! __preemption_enabled() );
451        /* paranoid */ verify( dst->starter == src );
452        /* paranoid */ verify( dst->context.SP );
453
454        // SKULLDUGGERY in debug the processors check that the
455        // stack is still within the limit of the stack limits after running a thread.
456        // that check doesn't make sense if we context switch to the processor using the
457        // coroutine semantics. Since this is a special case, use the current context
458        // info to populate these fields.
459        __cfaabi_dbg_debug_do(
460                __stack_context_t ctx;
461                CtxGet( ctx );
462                mainThread->context.SP = ctx.SP;
463                mainThread->context.FP = ctx.FP;
464        )
465
466        // context switch to the processor
467        __cfactx_switch( &src->context, &dst->context );
468}
469
470
471//=============================================================================================
472// Kernel Object Constructors logic
473//=============================================================================================
474//-----------------------------------------------------------------------------
475// Main thread construction
476static void ?{}( coroutine$ & this, current_stack_info_t * info) with( this ) {
477        stack.storage = info->storage;
478        with(*stack.storage) {
479                limit     = info->limit;
480                base      = info->base;
481        }
482        __attribute__((may_alias)) intptr_t * istorage = (intptr_t*) &stack.storage;
483        *istorage |= 0x1;
484        name = "Main Thread";
485        state = Start;
486        starter = 0p;
487        last = 0p;
488        cancellation = 0p;
489}
490
491static void ?{}( thread$ & this, current_stack_info_t * info) with( this ) {
492        ticket = TICKET_RUNNING;
493        state = Start;
494        self_cor{ info };
495        curr_cor = &self_cor;
496        curr_cluster = mainCluster;
497        self_mon.owner = &this;
498        self_mon.recursion = 1;
499        self_mon_p = &self_mon;
500        rdy_link.next = 0p;
501        rdy_link.ts   = MAX;
502        user_link.next = 0p;
503        user_link.prev = 0p;
504        cltr_link.next = 0p;
505        cltr_link.prev = 0p;
506        preferred = ready_queue_new_preferred();
507        last_proc = 0p;
508        PRNG_SET_SEED( random_state,  __global_random_mask ? __global_random_prime : __global_random_prime ^ rdtscl() );
509        #if defined( __CFA_WITH_VERIFY__ )
510                executing = 0p;
511                canary = 0x0D15EA5E0D15EA5Ep;
512        #endif
513
514        doregister(curr_cluster, this);
515
516        monitors{ &self_mon_p, 1, (fptr_t)0 };
517}
518
519//-----------------------------------------------------------------------------
520// Processor
521// Construct the processor context of non-main processors
522static void ?{}(processorCtx_t & this, processor * proc, current_stack_info_t * info) {
523        (this.self){ info };
524        this.proc = proc;
525}
526
527static void init(processor & this, const char name[], cluster & _cltr, thread$ * initT) with( this ) {
528        this.name = name;
529        this.cltr = &_cltr;
530    __atomic_add_fetch( &_cltr.procs.constructed, 1u, __ATOMIC_RELAXED );
531        this.rdq.its = 0;
532        this.rdq.itr = 0;
533        this.rdq.id  = 0;
534        this.rdq.target = MAX;
535        this.rdq.last = MAX;
536        this.rdq.cpu = 0;
537        // this.rdq.cutoff = 0ull;
538        do_terminate = false;
539        preemption_alarm = 0p;
540        pending_preemption = false;
541
542        this.io.ctx = 0p;
543        this.io.pending = false;
544        this.io.dirty   = false;
545
546        this.init.thrd = initT;
547
548        this.local_data = 0p;
549
550        idle_wctx.evfd = eventfd(0, 0);
551        if (idle_wctx.evfd < 0) {
552                abort("KERNEL ERROR: PROCESSOR EVENTFD - %s\n", strerror(errno));
553        }
554
555        idle_wctx.sem = 0;
556        idle_wctx.wake__time = 0;
557
558        // I'm assuming these two are reserved for standard input and output
559        // so I'm using them as sentinels with idle_wctx.
560        /* paranoid */ verify( idle_wctx.evfd != 0 );
561        /* paranoid */ verify( idle_wctx.evfd != 1 );
562
563        #if !defined(__CFA_NO_STATISTICS__)
564                print_stats = 0;
565                print_halts = false;
566        #endif
567
568        __cfadbg_print_safe(runtime_core, "Kernel : core %p created\n", &this);
569}
570
571// Not a ctor, it just preps the destruction but should not destroy members
572static void deinit(processor & this) {
573        close(this.idle_wctx.evfd);
574}
575
576void ?{}(processor & this, const char name[], cluster & _cltr, thread$ * initT) libcfa_public {
577        ( this.terminated ){};
578        ( this.runner ){};
579
580        disable_interrupts();
581                init( this, name, _cltr, initT );
582        enable_interrupts();
583
584        __cfadbg_print_safe(runtime_core, "Kernel : Starting core %p\n", &this);
585
586        this.stack = __create_pthread( &this.kernel_thread, __invoke_processor, (void *)&this );
587}
588
589void ?{}(processor & this, const char name[], cluster & _cltr) libcfa_public {
590        (this){name, _cltr, 0p};
591}
592
593extern size_t __page_size;
594void ^?{}(processor & this) libcfa_public with( this ) {
595        /* paranoid */ verify( !__atomic_load_n(&do_terminate, __ATOMIC_ACQUIRE) );
596        __cfadbg_print_safe(runtime_core, "Kernel : core %p signaling termination\n", &this);
597
598    __atomic_sub_fetch( &this.cltr->procs.constructed, 1u, __ATOMIC_RELAXED );
599
600        __atomic_store_n(&do_terminate, true, __ATOMIC_RELAXED);
601        __disable_interrupts_checked();
602                __wake_proc( &this );
603        __enable_interrupts_checked();
604
605        wait( terminated );
606        /* paranoid */ verify( active_processor() != &this);
607
608        __destroy_pthread( kernel_thread, this.stack, 0p );
609
610        disable_interrupts();
611                deinit( this );
612        enable_interrupts();
613}
614
615//-----------------------------------------------------------------------------
616// Cluster
617static void ?{}(__cluster_proc_list & this) {
618        this.fdw   = 0p;
619        this.idle  = 0;
620    this.constructed = 0;
621        this.total = 0;
622}
623
624void ?{}(cluster & this, const char name[], Duration preemption_rate, unsigned num_io, const io_context_params & io_params) libcfa_public with( this ) {
625        this.name = name;
626        this.preemption_rate = preemption_rate;
627        this.sched.readyQ.data = 0p;
628        this.sched.readyQ.tscs = 0p;
629        this.sched.readyQ.count = 0;
630        this.sched.io.tscs = 0p;
631        this.sched.io.data = 0p;
632        this.sched.caches = 0p;
633
634        #if !defined(__CFA_NO_STATISTICS__)
635                print_stats = 0;
636                stats = alloc();
637                __init_stats( stats );
638        #endif
639
640        threads{};
641
642        io.arbiter = create();
643        io.params = io_params;
644
645        managed.procs = 0p;
646        managed.cnt = 0;
647
648        doregister(this);
649
650        // Lock the RWlock so no-one pushes/pops while we are changing the queue
651        disable_interrupts();
652        uint_fast32_t last_size = ready_mutate_lock();
653
654                // Adjust the ready queue size
655                ready_queue_grow( &this );
656
657        // Unlock the RWlock
658        ready_mutate_unlock( last_size );
659        enable_interrupts( false ); // Don't poll, could be in main cluster
660}
661
662void ^?{}(cluster & this) libcfa_public {
663        set_concurrency( this, 0 );
664
665        destroy(this.io.arbiter);
666
667        // Lock the RWlock so no-one pushes/pops while we are changing the queue
668        disable_interrupts();
669        uint_fast32_t last_size = ready_mutate_lock();
670
671                // Adjust the ready queue size
672                ready_queue_shrink( &this );
673
674        // Unlock the RWlock
675        ready_mutate_unlock( last_size );
676
677        ready_queue_close( &this );
678        /* paranoid */ verify( this.sched.readyQ.data == 0p );
679        /* paranoid */ verify( this.sched.readyQ.tscs == 0p );
680        /* paranoid */ verify( this.sched.readyQ.count == 0 );
681        /* paranoid */ verify( this.sched.io.tscs == 0p );
682        /* paranoid */ verify( this.sched.caches == 0p );
683
684        enable_interrupts( false ); // Don't poll, could be in main cluster
685
686
687        #if !defined(__CFA_NO_STATISTICS__)
688                if( 0 != this.print_stats ) {
689                        __print_stats( this.stats, this.print_stats, "Cluster", this.name, (void*)&this );
690                }
691                #if defined(CFA_STATS_ARRAY)
692                        __flush_stat( this.stats, "Cluster", &this );
693                #endif
694                free( this.stats );
695        #endif
696
697        unregister(this);
698}
699
700//=============================================================================================
701// Miscellaneous Initialization
702//=============================================================================================
703//-----------------------------------------------------------------------------
704// Global Queues
705static void doregister( cluster     & cltr ) {
706        lock      ( __cfa_dbg_global_clusters.lock __cfaabi_dbg_ctx2);
707        push_front( __cfa_dbg_global_clusters.list, cltr );
708        unlock    ( __cfa_dbg_global_clusters.lock );
709}
710
711static void unregister( cluster     & cltr ) {
712        lock  ( __cfa_dbg_global_clusters.lock __cfaabi_dbg_ctx2);
713        remove( __cfa_dbg_global_clusters.list, cltr );
714        unlock( __cfa_dbg_global_clusters.lock );
715}
716
717void doregister( cluster * cltr, thread$ & thrd ) {
718        lock      (cltr->thread_list_lock __cfaabi_dbg_ctx2);
719        cltr->nthreads += 1;
720        insert_first(cltr->threads, thrd);
721        unlock    (cltr->thread_list_lock);
722}
723
724void unregister( cluster * cltr, thread$ & thrd ) {
725        lock  (cltr->thread_list_lock __cfaabi_dbg_ctx2);
726        {
727                tytagref( dlink(thread$), dlink(thread$) ) ?`inner( thread$ & this ) = void;
728                with( DLINK_VIA( thread$, struct __thread_user_link ) )
729                        remove( thrd );
730                cltr->nthreads -= 1;
731        }
732        unlock(cltr->thread_list_lock);
733}
734
735static void register_tls( processor * this ) {
736        // Register and Lock the RWlock so no-one pushes/pops while we are changing the queue
737        uint_fast32_t last_size;
738        [this->unique_id, last_size] = ready_mutate_register();
739
740                this->rdq.cpu = __kernel_getcpu();
741
742                this->cltr->procs.total += 1u;
743                insert_last(this->cltr->procs.actives, *this);
744
745                // Adjust the ready queue size
746                ready_queue_grow( this->cltr );
747
748        // Unlock the RWlock
749        ready_mutate_unlock( last_size );
750}
751
752
753static void unregister_tls( processor * this ) {
754        // Lock the RWlock so no-one pushes/pops while we are changing the queue
755        uint_fast32_t last_size = ready_mutate_lock();
756                this->cltr->procs.total -= 1u;
757                remove(*this);
758
759                // clear the cluster so nothing gets pushed to local queues
760                cluster * cltr = this->cltr;
761                this->cltr = 0p;
762
763                // Adjust the ready queue size
764                ready_queue_shrink( cltr );
765
766        // Unlock the RWlock and unregister: we don't need the read_lock any more
767        ready_mutate_unregister( this->unique_id, last_size );
768}
769
770static void check( int ret, const char func[] ) {
771        if ( ret ) {                                                                            // pthread routines return errno values
772                abort( "%s : internal error, error(%d) %s.", func, ret, strerror( ret ) );
773        } // if
774} // Abort
775
776void * __create_pthread( pthread_t * pthread, void * (*start)(void *), void * arg ) {
777        pthread_attr_t attr;
778
779        check( __cfaabi_pthread_attr_init( &attr ), "pthread_attr_init" ); // initialize attribute
780
781        size_t stacksize = max( PTHREAD_STACK_MIN, DEFAULT_STACK_SIZE );
782
783        void * stack;
784        #if CFA_PROCESSOR_USE_MMAP
785                stacksize = ceiling( stacksize, __page_size ) + __page_size;
786                stack = mmap(0p, stacksize, __map_prot, MAP_PRIVATE | MAP_ANONYMOUS, 0, 0);
787                if(stack == ((void*)-1)) {
788                        abort( "pthread stack creation : internal error, mmap failure, error(%d) %s.", errno, strerror( errno ) );
789                }
790                if ( mprotect( stack, __page_size, PROT_NONE ) == -1 ) {
791                        abort( "pthread stack creation : internal error, mprotect failure, error(%d) %s.", errno, strerror( errno ) );
792                } // if
793        #else
794                __cfaabi_dbg_debug_do(
795                        stack = memalign( __page_size, stacksize + __page_size );
796                        // pthread has no mechanism to create the guard page in user supplied stack.
797                        if ( mprotect( stack, __page_size, PROT_NONE ) == -1 ) {
798                                abort( "mprotect : internal error, mprotect failure, error(%d) %s.", errno, strerror( errno ) );
799                        } // if
800                );
801                __cfaabi_dbg_no_debug_do(
802                        stack = malloc( stacksize );
803                );
804        #endif
805
806        check( __cfaabi_pthread_attr_setstack( &attr, stack, stacksize ), "pthread_attr_setstack" );
807        check( __cfaabi_pthread_create( pthread, &attr, start, arg ), "pthread_create" );
808        return stack;
809}
810
811void __destroy_pthread( pthread_t pthread, void * stack, void ** retval ) {
812        int err = __cfaabi_pthread_join( pthread, retval );
813        if( err != 0 ) abort("KERNEL ERROR: joining pthread %p caused error %s\n", (void*)pthread, strerror(err));
814
815        #if CFA_PROCESSOR_USE_MMAP
816                pthread_attr_t attr;
817
818                check( __cfaabi_pthread_attr_init( &attr ), "pthread_attr_init" ); // initialize attribute
819
820                size_t stacksize;
821                // default stack size, normally defined by shell limit
822                check( __cfaabi_pthread_attr_getstacksize( &attr, &stacksize ), "pthread_attr_getstacksize" );
823                assert( stacksize >= PTHREAD_STACK_MIN );
824                stacksize += __page_size;
825
826                if(munmap(stack, stacksize) == -1) {
827                        abort( "pthread stack destruction : internal error, munmap failure, error(%d) %s.", errno, strerror( errno ) );
828                }
829        #else
830                __cfaabi_dbg_debug_do(
831                        // pthread has no mechanism to create the guard page in user supplied stack.
832                        if ( mprotect( stack, __page_size, __map_prot ) == -1 ) {
833                                abort( "mprotect : internal error, mprotect failure, error(%d) %s.", errno, strerror( errno ) );
834                        } // if
835                );
836                free( stack );
837        #endif
838}
839
840unsigned set_concurrency( cluster & this, unsigned new ) libcfa_public {
841        unsigned old = this.managed.cnt;
842
843        __cfadbg_print_safe(runtime_core, "Kernel : resizing cluster from %u to %u\n", old, (unsigned)new);
844
845        // Delete all the old unneeded procs
846        if(old > new) for(i; (unsigned)new ~ old) {
847                __cfadbg_print_safe(runtime_core, "Kernel : destroying %u\n", i);
848                delete( this.managed.procs[i] );
849        }
850
851        // Allocate new array (uses realloc and memcpies the data)
852        this.managed.procs = alloc( new, this.managed.procs`realloc );
853        this.managed.cnt = new;
854
855        // Create the desired new procs
856        if(old < new) for(i; old ~ new) {
857                __cfadbg_print_safe(runtime_core, "Kernel : constructing %u\n", i);
858                (*(this.managed.procs[i] = alloc())){ this };
859        }
860
861        // return the old count
862        return old;
863}
864
865#if defined(__CFA_WITH_VERIFY__)
866static bool verify_fwd_bck_rng(void) {
867        __cfaabi_tls.ready_rng.fwd_seed = 25214903917_l64u * (rdtscl() ^ (uintptr_t)&verify_fwd_bck_rng);
868
869        unsigned values[10];
870        for(i; 10) {
871                values[i] = __tls_rand_fwd();
872        }
873
874        __tls_rand_advance_bck();
875
876        for ( i; 9 -~= 0 ) {
877                if(values[i] != __tls_rand_bck()) {
878                        return false;
879                }
880        }
881
882        return true;
883}
884#endif
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