xref: /freebsd/contrib/llvm-project/openmp/runtime/src/kmp_alloc.cpp (revision ebacd8013fe5f7fdf9f6a5b286f6680dd2891036)
1 /*
2  * kmp_alloc.cpp -- private/shared dynamic memory allocation and management
3  */
4 
5 //===----------------------------------------------------------------------===//
6 //
7 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
8 // See https://llvm.org/LICENSE.txt for license information.
9 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
10 //
11 //===----------------------------------------------------------------------===//
12 
13 #include "kmp.h"
14 #include "kmp_io.h"
15 #include "kmp_wrapper_malloc.h"
16 
17 // Disable bget when it is not used
18 #if KMP_USE_BGET
19 
20 /* Thread private buffer management code */
21 
22 typedef int (*bget_compact_t)(size_t, int);
23 typedef void *(*bget_acquire_t)(size_t);
24 typedef void (*bget_release_t)(void *);
25 
26 /* NOTE: bufsize must be a signed datatype */
27 
28 #if KMP_OS_WINDOWS
29 #if KMP_ARCH_X86 || KMP_ARCH_ARM
30 typedef kmp_int32 bufsize;
31 #else
32 typedef kmp_int64 bufsize;
33 #endif
34 #else
35 typedef ssize_t bufsize;
36 #endif // KMP_OS_WINDOWS
37 
38 /* The three modes of operation are, fifo search, lifo search, and best-fit */
39 
40 typedef enum bget_mode {
41   bget_mode_fifo = 0,
42   bget_mode_lifo = 1,
43   bget_mode_best = 2
44 } bget_mode_t;
45 
46 static void bpool(kmp_info_t *th, void *buffer, bufsize len);
47 static void *bget(kmp_info_t *th, bufsize size);
48 static void *bgetz(kmp_info_t *th, bufsize size);
49 static void *bgetr(kmp_info_t *th, void *buffer, bufsize newsize);
50 static void brel(kmp_info_t *th, void *buf);
51 static void bectl(kmp_info_t *th, bget_compact_t compact,
52                   bget_acquire_t acquire, bget_release_t release,
53                   bufsize pool_incr);
54 
55 /* BGET CONFIGURATION */
56 /* Buffer allocation size quantum: all buffers allocated are a
57    multiple of this size.  This MUST be a power of two. */
58 
59 /* On IA-32 architecture with  Linux* OS, malloc() does not
60    ensure 16 byte alignment */
61 
62 #if KMP_ARCH_X86 || !KMP_HAVE_QUAD
63 
64 #define SizeQuant 8
65 #define AlignType double
66 
67 #else
68 
69 #define SizeQuant 16
70 #define AlignType _Quad
71 
72 #endif
73 
74 // Define this symbol to enable the bstats() function which calculates the
75 // total free space in the buffer pool, the largest available buffer, and the
76 // total space currently allocated.
77 #define BufStats 1
78 
79 #ifdef KMP_DEBUG
80 
81 // Define this symbol to enable the bpoold() function which dumps the buffers
82 // in a buffer pool.
83 #define BufDump 1
84 
85 // Define this symbol to enable the bpoolv() function for validating a buffer
86 // pool.
87 #define BufValid 1
88 
89 // Define this symbol to enable the bufdump() function which allows dumping the
90 // contents of an allocated or free buffer.
91 #define DumpData 1
92 
93 #ifdef NOT_USED_NOW
94 
95 // Wipe free buffers to a guaranteed pattern of garbage to trip up miscreants
96 // who attempt to use pointers into released buffers.
97 #define FreeWipe 1
98 
99 // Use a best fit algorithm when searching for space for an allocation request.
100 // This uses memory more efficiently, but allocation will be much slower.
101 #define BestFit 1
102 
103 #endif /* NOT_USED_NOW */
104 #endif /* KMP_DEBUG */
105 
106 static bufsize bget_bin_size[] = {
107     0,
108     //    1 << 6,    /* .5 Cache line */
109     1 << 7, /* 1 Cache line, new */
110     1 << 8, /* 2 Cache lines */
111     1 << 9, /* 4 Cache lines, new */
112     1 << 10, /* 8 Cache lines */
113     1 << 11, /* 16 Cache lines, new */
114     1 << 12, 1 << 13, /* new */
115     1 << 14, 1 << 15, /* new */
116     1 << 16, 1 << 17, 1 << 18, 1 << 19, 1 << 20, /*  1MB */
117     1 << 21, /*  2MB */
118     1 << 22, /*  4MB */
119     1 << 23, /*  8MB */
120     1 << 24, /* 16MB */
121     1 << 25, /* 32MB */
122 };
123 
124 #define MAX_BGET_BINS (int)(sizeof(bget_bin_size) / sizeof(bufsize))
125 
126 struct bfhead;
127 
128 //  Declare the interface, including the requested buffer size type, bufsize.
129 
130 /* Queue links */
131 typedef struct qlinks {
132   struct bfhead *flink; /* Forward link */
133   struct bfhead *blink; /* Backward link */
134 } qlinks_t;
135 
136 /* Header in allocated and free buffers */
137 typedef struct bhead2 {
138   kmp_info_t *bthr; /* The thread which owns the buffer pool */
139   bufsize prevfree; /* Relative link back to previous free buffer in memory or
140                        0 if previous buffer is allocated.  */
141   bufsize bsize; /* Buffer size: positive if free, negative if allocated. */
142 } bhead2_t;
143 
144 /* Make sure the bhead structure is a multiple of SizeQuant in size. */
145 typedef union bhead {
146   KMP_ALIGN(SizeQuant)
147   AlignType b_align;
148   char b_pad[sizeof(bhead2_t) + (SizeQuant - (sizeof(bhead2_t) % SizeQuant))];
149   bhead2_t bb;
150 } bhead_t;
151 #define BH(p) ((bhead_t *)(p))
152 
153 /*  Header in directly allocated buffers (by acqfcn) */
154 typedef struct bdhead {
155   bufsize tsize; /* Total size, including overhead */
156   bhead_t bh; /* Common header */
157 } bdhead_t;
158 #define BDH(p) ((bdhead_t *)(p))
159 
160 /* Header in free buffers */
161 typedef struct bfhead {
162   bhead_t bh; /* Common allocated/free header */
163   qlinks_t ql; /* Links on free list */
164 } bfhead_t;
165 #define BFH(p) ((bfhead_t *)(p))
166 
167 typedef struct thr_data {
168   bfhead_t freelist[MAX_BGET_BINS];
169 #if BufStats
170   size_t totalloc; /* Total space currently allocated */
171   long numget, numrel; /* Number of bget() and brel() calls */
172   long numpblk; /* Number of pool blocks */
173   long numpget, numprel; /* Number of block gets and rels */
174   long numdget, numdrel; /* Number of direct gets and rels */
175 #endif /* BufStats */
176 
177   /* Automatic expansion block management functions */
178   bget_compact_t compfcn;
179   bget_acquire_t acqfcn;
180   bget_release_t relfcn;
181 
182   bget_mode_t mode; /* what allocation mode to use? */
183 
184   bufsize exp_incr; /* Expansion block size */
185   bufsize pool_len; /* 0: no bpool calls have been made
186                        -1: not all pool blocks are the same size
187                        >0: (common) block size for all bpool calls made so far
188                     */
189   bfhead_t *last_pool; /* Last pool owned by this thread (delay deallocation) */
190 } thr_data_t;
191 
192 /*  Minimum allocation quantum: */
193 #define QLSize (sizeof(qlinks_t))
194 #define SizeQ ((SizeQuant > QLSize) ? SizeQuant : QLSize)
195 #define MaxSize                                                                \
196   (bufsize)(                                                                   \
197       ~(((bufsize)(1) << (sizeof(bufsize) * CHAR_BIT - 1)) | (SizeQuant - 1)))
198 // Maximum for the requested size.
199 
200 /* End sentinel: value placed in bsize field of dummy block delimiting
201    end of pool block.  The most negative number which will  fit  in  a
202    bufsize, defined in a way that the compiler will accept. */
203 
204 #define ESent                                                                  \
205   ((bufsize)(-(((((bufsize)1) << ((int)sizeof(bufsize) * 8 - 2)) - 1) * 2) - 2))
206 
207 /* Thread Data management routines */
208 static int bget_get_bin(bufsize size) {
209   // binary chop bins
210   int lo = 0, hi = MAX_BGET_BINS - 1;
211 
212   KMP_DEBUG_ASSERT(size > 0);
213 
214   while ((hi - lo) > 1) {
215     int mid = (lo + hi) >> 1;
216     if (size < bget_bin_size[mid])
217       hi = mid - 1;
218     else
219       lo = mid;
220   }
221 
222   KMP_DEBUG_ASSERT((lo >= 0) && (lo < MAX_BGET_BINS));
223 
224   return lo;
225 }
226 
227 static void set_thr_data(kmp_info_t *th) {
228   int i;
229   thr_data_t *data;
230 
231   data = (thr_data_t *)((!th->th.th_local.bget_data)
232                             ? __kmp_allocate(sizeof(*data))
233                             : th->th.th_local.bget_data);
234 
235   memset(data, '\0', sizeof(*data));
236 
237   for (i = 0; i < MAX_BGET_BINS; ++i) {
238     data->freelist[i].ql.flink = &data->freelist[i];
239     data->freelist[i].ql.blink = &data->freelist[i];
240   }
241 
242   th->th.th_local.bget_data = data;
243   th->th.th_local.bget_list = 0;
244 #if !USE_CMP_XCHG_FOR_BGET
245 #ifdef USE_QUEUING_LOCK_FOR_BGET
246   __kmp_init_lock(&th->th.th_local.bget_lock);
247 #else
248   __kmp_init_bootstrap_lock(&th->th.th_local.bget_lock);
249 #endif /* USE_LOCK_FOR_BGET */
250 #endif /* ! USE_CMP_XCHG_FOR_BGET */
251 }
252 
253 static thr_data_t *get_thr_data(kmp_info_t *th) {
254   thr_data_t *data;
255 
256   data = (thr_data_t *)th->th.th_local.bget_data;
257 
258   KMP_DEBUG_ASSERT(data != 0);
259 
260   return data;
261 }
262 
263 /* Walk the free list and release the enqueued buffers */
264 static void __kmp_bget_dequeue(kmp_info_t *th) {
265   void *p = TCR_SYNC_PTR(th->th.th_local.bget_list);
266 
267   if (p != 0) {
268 #if USE_CMP_XCHG_FOR_BGET
269     {
270       volatile void *old_value = TCR_SYNC_PTR(th->th.th_local.bget_list);
271       while (!KMP_COMPARE_AND_STORE_PTR(&th->th.th_local.bget_list,
272                                         CCAST(void *, old_value), nullptr)) {
273         KMP_CPU_PAUSE();
274         old_value = TCR_SYNC_PTR(th->th.th_local.bget_list);
275       }
276       p = CCAST(void *, old_value);
277     }
278 #else /* ! USE_CMP_XCHG_FOR_BGET */
279 #ifdef USE_QUEUING_LOCK_FOR_BGET
280     __kmp_acquire_lock(&th->th.th_local.bget_lock, __kmp_gtid_from_thread(th));
281 #else
282     __kmp_acquire_bootstrap_lock(&th->th.th_local.bget_lock);
283 #endif /* USE_QUEUING_LOCK_FOR_BGET */
284 
285     p = (void *)th->th.th_local.bget_list;
286     th->th.th_local.bget_list = 0;
287 
288 #ifdef USE_QUEUING_LOCK_FOR_BGET
289     __kmp_release_lock(&th->th.th_local.bget_lock, __kmp_gtid_from_thread(th));
290 #else
291     __kmp_release_bootstrap_lock(&th->th.th_local.bget_lock);
292 #endif
293 #endif /* USE_CMP_XCHG_FOR_BGET */
294 
295     /* Check again to make sure the list is not empty */
296     while (p != 0) {
297       void *buf = p;
298       bfhead_t *b = BFH(((char *)p) - sizeof(bhead_t));
299 
300       KMP_DEBUG_ASSERT(b->bh.bb.bsize != 0);
301       KMP_DEBUG_ASSERT(((kmp_uintptr_t)TCR_PTR(b->bh.bb.bthr) & ~1) ==
302                        (kmp_uintptr_t)th); // clear possible mark
303       KMP_DEBUG_ASSERT(b->ql.blink == 0);
304 
305       p = (void *)b->ql.flink;
306 
307       brel(th, buf);
308     }
309   }
310 }
311 
312 /* Chain together the free buffers by using the thread owner field */
313 static void __kmp_bget_enqueue(kmp_info_t *th, void *buf
314 #ifdef USE_QUEUING_LOCK_FOR_BGET
315                                ,
316                                kmp_int32 rel_gtid
317 #endif
318 ) {
319   bfhead_t *b = BFH(((char *)buf) - sizeof(bhead_t));
320 
321   KMP_DEBUG_ASSERT(b->bh.bb.bsize != 0);
322   KMP_DEBUG_ASSERT(((kmp_uintptr_t)TCR_PTR(b->bh.bb.bthr) & ~1) ==
323                    (kmp_uintptr_t)th); // clear possible mark
324 
325   b->ql.blink = 0;
326 
327   KC_TRACE(10, ("__kmp_bget_enqueue: moving buffer to T#%d list\n",
328                 __kmp_gtid_from_thread(th)));
329 
330 #if USE_CMP_XCHG_FOR_BGET
331   {
332     volatile void *old_value = TCR_PTR(th->th.th_local.bget_list);
333     /* the next pointer must be set before setting bget_list to buf to avoid
334        exposing a broken list to other threads, even for an instant. */
335     b->ql.flink = BFH(CCAST(void *, old_value));
336 
337     while (!KMP_COMPARE_AND_STORE_PTR(&th->th.th_local.bget_list,
338                                       CCAST(void *, old_value), buf)) {
339       KMP_CPU_PAUSE();
340       old_value = TCR_PTR(th->th.th_local.bget_list);
341       /* the next pointer must be set before setting bget_list to buf to avoid
342          exposing a broken list to other threads, even for an instant. */
343       b->ql.flink = BFH(CCAST(void *, old_value));
344     }
345   }
346 #else /* ! USE_CMP_XCHG_FOR_BGET */
347 #ifdef USE_QUEUING_LOCK_FOR_BGET
348   __kmp_acquire_lock(&th->th.th_local.bget_lock, rel_gtid);
349 #else
350   __kmp_acquire_bootstrap_lock(&th->th.th_local.bget_lock);
351 #endif
352 
353   b->ql.flink = BFH(th->th.th_local.bget_list);
354   th->th.th_local.bget_list = (void *)buf;
355 
356 #ifdef USE_QUEUING_LOCK_FOR_BGET
357   __kmp_release_lock(&th->th.th_local.bget_lock, rel_gtid);
358 #else
359   __kmp_release_bootstrap_lock(&th->th.th_local.bget_lock);
360 #endif
361 #endif /* USE_CMP_XCHG_FOR_BGET */
362 }
363 
364 /* insert buffer back onto a new freelist */
365 static void __kmp_bget_insert_into_freelist(thr_data_t *thr, bfhead_t *b) {
366   int bin;
367 
368   KMP_DEBUG_ASSERT(((size_t)b) % SizeQuant == 0);
369   KMP_DEBUG_ASSERT(b->bh.bb.bsize % SizeQuant == 0);
370 
371   bin = bget_get_bin(b->bh.bb.bsize);
372 
373   KMP_DEBUG_ASSERT(thr->freelist[bin].ql.blink->ql.flink ==
374                    &thr->freelist[bin]);
375   KMP_DEBUG_ASSERT(thr->freelist[bin].ql.flink->ql.blink ==
376                    &thr->freelist[bin]);
377 
378   b->ql.flink = &thr->freelist[bin];
379   b->ql.blink = thr->freelist[bin].ql.blink;
380 
381   thr->freelist[bin].ql.blink = b;
382   b->ql.blink->ql.flink = b;
383 }
384 
385 /* unlink the buffer from the old freelist */
386 static void __kmp_bget_remove_from_freelist(bfhead_t *b) {
387   KMP_DEBUG_ASSERT(b->ql.blink->ql.flink == b);
388   KMP_DEBUG_ASSERT(b->ql.flink->ql.blink == b);
389 
390   b->ql.blink->ql.flink = b->ql.flink;
391   b->ql.flink->ql.blink = b->ql.blink;
392 }
393 
394 /*  GET STATS -- check info on free list */
395 static void bcheck(kmp_info_t *th, bufsize *max_free, bufsize *total_free) {
396   thr_data_t *thr = get_thr_data(th);
397   int bin;
398 
399   *total_free = *max_free = 0;
400 
401   for (bin = 0; bin < MAX_BGET_BINS; ++bin) {
402     bfhead_t *b, *best;
403 
404     best = &thr->freelist[bin];
405     b = best->ql.flink;
406 
407     while (b != &thr->freelist[bin]) {
408       *total_free += (b->bh.bb.bsize - sizeof(bhead_t));
409       if ((best == &thr->freelist[bin]) || (b->bh.bb.bsize < best->bh.bb.bsize))
410         best = b;
411 
412       /* Link to next buffer */
413       b = b->ql.flink;
414     }
415 
416     if (*max_free < best->bh.bb.bsize)
417       *max_free = best->bh.bb.bsize;
418   }
419 
420   if (*max_free > (bufsize)sizeof(bhead_t))
421     *max_free -= sizeof(bhead_t);
422 }
423 
424 /*  BGET  --  Allocate a buffer.  */
425 static void *bget(kmp_info_t *th, bufsize requested_size) {
426   thr_data_t *thr = get_thr_data(th);
427   bufsize size = requested_size;
428   bfhead_t *b;
429   void *buf;
430   int compactseq = 0;
431   int use_blink = 0;
432   /* For BestFit */
433   bfhead_t *best;
434 
435   if (size < 0 || size + sizeof(bhead_t) > MaxSize) {
436     return NULL;
437   }
438 
439   __kmp_bget_dequeue(th); /* Release any queued buffers */
440 
441   if (size < (bufsize)SizeQ) { // Need at least room for the queue links.
442     size = SizeQ;
443   }
444 #if defined(SizeQuant) && (SizeQuant > 1)
445   size = (size + (SizeQuant - 1)) & (~(SizeQuant - 1));
446 #endif
447 
448   size += sizeof(bhead_t); // Add overhead in allocated buffer to size required.
449   KMP_DEBUG_ASSERT(size >= 0);
450   KMP_DEBUG_ASSERT(size % SizeQuant == 0);
451 
452   use_blink = (thr->mode == bget_mode_lifo);
453 
454   /* If a compact function was provided in the call to bectl(), wrap
455      a loop around the allocation process  to  allow  compaction  to
456      intervene in case we don't find a suitable buffer in the chain. */
457 
458   for (;;) {
459     int bin;
460 
461     for (bin = bget_get_bin(size); bin < MAX_BGET_BINS; ++bin) {
462       /* Link to next buffer */
463       b = (use_blink ? thr->freelist[bin].ql.blink
464                      : thr->freelist[bin].ql.flink);
465 
466       if (thr->mode == bget_mode_best) {
467         best = &thr->freelist[bin];
468 
469         /* Scan the free list searching for the first buffer big enough
470            to hold the requested size buffer. */
471         while (b != &thr->freelist[bin]) {
472           if (b->bh.bb.bsize >= (bufsize)size) {
473             if ((best == &thr->freelist[bin]) ||
474                 (b->bh.bb.bsize < best->bh.bb.bsize)) {
475               best = b;
476             }
477           }
478 
479           /* Link to next buffer */
480           b = (use_blink ? b->ql.blink : b->ql.flink);
481         }
482         b = best;
483       }
484 
485       while (b != &thr->freelist[bin]) {
486         if ((bufsize)b->bh.bb.bsize >= (bufsize)size) {
487 
488           // Buffer is big enough to satisfy the request. Allocate it to the
489           // caller. We must decide whether the buffer is large enough to split
490           // into the part given to the caller and a free buffer that remains
491           // on the free list, or whether the entire buffer should be removed
492           // from the free list and given to the caller in its entirety. We
493           // only split the buffer if enough room remains for a header plus the
494           // minimum quantum of allocation.
495           if ((b->bh.bb.bsize - (bufsize)size) >
496               (bufsize)(SizeQ + (sizeof(bhead_t)))) {
497             bhead_t *ba, *bn;
498 
499             ba = BH(((char *)b) + (b->bh.bb.bsize - (bufsize)size));
500             bn = BH(((char *)ba) + size);
501 
502             KMP_DEBUG_ASSERT(bn->bb.prevfree == b->bh.bb.bsize);
503 
504             /* Subtract size from length of free block. */
505             b->bh.bb.bsize -= (bufsize)size;
506 
507             /* Link allocated buffer to the previous free buffer. */
508             ba->bb.prevfree = b->bh.bb.bsize;
509 
510             /* Plug negative size into user buffer. */
511             ba->bb.bsize = -size;
512 
513             /* Mark this buffer as owned by this thread. */
514             TCW_PTR(ba->bb.bthr,
515                     th); // not an allocated address (do not mark it)
516             /* Mark buffer after this one not preceded by free block. */
517             bn->bb.prevfree = 0;
518 
519             // unlink buffer from old freelist, and reinsert into new freelist
520             __kmp_bget_remove_from_freelist(b);
521             __kmp_bget_insert_into_freelist(thr, b);
522 #if BufStats
523             thr->totalloc += (size_t)size;
524             thr->numget++; /* Increment number of bget() calls */
525 #endif
526             buf = (void *)((((char *)ba) + sizeof(bhead_t)));
527             KMP_DEBUG_ASSERT(((size_t)buf) % SizeQuant == 0);
528             return buf;
529           } else {
530             bhead_t *ba;
531 
532             ba = BH(((char *)b) + b->bh.bb.bsize);
533 
534             KMP_DEBUG_ASSERT(ba->bb.prevfree == b->bh.bb.bsize);
535 
536             /* The buffer isn't big enough to split.  Give  the  whole
537                shebang to the caller and remove it from the free list. */
538 
539             __kmp_bget_remove_from_freelist(b);
540 #if BufStats
541             thr->totalloc += (size_t)b->bh.bb.bsize;
542             thr->numget++; /* Increment number of bget() calls */
543 #endif
544             /* Negate size to mark buffer allocated. */
545             b->bh.bb.bsize = -(b->bh.bb.bsize);
546 
547             /* Mark this buffer as owned by this thread. */
548             TCW_PTR(ba->bb.bthr, th); // not an allocated address (do not mark)
549             /* Zero the back pointer in the next buffer in memory
550                to indicate that this buffer is allocated. */
551             ba->bb.prevfree = 0;
552 
553             /* Give user buffer starting at queue links. */
554             buf = (void *)&(b->ql);
555             KMP_DEBUG_ASSERT(((size_t)buf) % SizeQuant == 0);
556             return buf;
557           }
558         }
559 
560         /* Link to next buffer */
561         b = (use_blink ? b->ql.blink : b->ql.flink);
562       }
563     }
564 
565     /* We failed to find a buffer. If there's a compact function defined,
566        notify it of the size requested. If it returns TRUE, try the allocation
567        again. */
568 
569     if ((thr->compfcn == 0) || (!(*thr->compfcn)(size, ++compactseq))) {
570       break;
571     }
572   }
573 
574   /* No buffer available with requested size free. */
575 
576   /* Don't give up yet -- look in the reserve supply. */
577   if (thr->acqfcn != 0) {
578     if (size > (bufsize)(thr->exp_incr - sizeof(bhead_t))) {
579       /* Request is too large to fit in a single expansion block.
580          Try to satisfy it by a direct buffer acquisition. */
581       bdhead_t *bdh;
582 
583       size += sizeof(bdhead_t) - sizeof(bhead_t);
584 
585       KE_TRACE(10, ("%%%%%% MALLOC( %d )\n", (int)size));
586 
587       /* richryan */
588       bdh = BDH((*thr->acqfcn)((bufsize)size));
589       if (bdh != NULL) {
590 
591         // Mark the buffer special by setting size field of its header to zero.
592         bdh->bh.bb.bsize = 0;
593 
594         /* Mark this buffer as owned by this thread. */
595         TCW_PTR(bdh->bh.bb.bthr, th); // don't mark buffer as allocated,
596         // because direct buffer never goes to free list
597         bdh->bh.bb.prevfree = 0;
598         bdh->tsize = size;
599 #if BufStats
600         thr->totalloc += (size_t)size;
601         thr->numget++; /* Increment number of bget() calls */
602         thr->numdget++; /* Direct bget() call count */
603 #endif
604         buf = (void *)(bdh + 1);
605         KMP_DEBUG_ASSERT(((size_t)buf) % SizeQuant == 0);
606         return buf;
607       }
608 
609     } else {
610 
611       /*  Try to obtain a new expansion block */
612       void *newpool;
613 
614       KE_TRACE(10, ("%%%%%% MALLOCB( %d )\n", (int)thr->exp_incr));
615 
616       /* richryan */
617       newpool = (*thr->acqfcn)((bufsize)thr->exp_incr);
618       KMP_DEBUG_ASSERT(((size_t)newpool) % SizeQuant == 0);
619       if (newpool != NULL) {
620         bpool(th, newpool, thr->exp_incr);
621         buf = bget(
622             th, requested_size); /* This can't, I say, can't get into a loop. */
623         return buf;
624       }
625     }
626   }
627 
628   /*  Still no buffer available */
629 
630   return NULL;
631 }
632 
633 /*  BGETZ  --  Allocate a buffer and clear its contents to zero.  We clear
634                the  entire  contents  of  the buffer to zero, not just the
635                region requested by the caller. */
636 
637 static void *bgetz(kmp_info_t *th, bufsize size) {
638   char *buf = (char *)bget(th, size);
639 
640   if (buf != NULL) {
641     bhead_t *b;
642     bufsize rsize;
643 
644     b = BH(buf - sizeof(bhead_t));
645     rsize = -(b->bb.bsize);
646     if (rsize == 0) {
647       bdhead_t *bd;
648 
649       bd = BDH(buf - sizeof(bdhead_t));
650       rsize = bd->tsize - (bufsize)sizeof(bdhead_t);
651     } else {
652       rsize -= sizeof(bhead_t);
653     }
654 
655     KMP_DEBUG_ASSERT(rsize >= size);
656 
657     (void)memset(buf, 0, (bufsize)rsize);
658   }
659   return ((void *)buf);
660 }
661 
662 /*  BGETR  --  Reallocate a buffer.  This is a minimal implementation,
663                simply in terms of brel()  and  bget().   It  could  be
664                enhanced to allow the buffer to grow into adjacent free
665                blocks and to avoid moving data unnecessarily.  */
666 
667 static void *bgetr(kmp_info_t *th, void *buf, bufsize size) {
668   void *nbuf;
669   bufsize osize; /* Old size of buffer */
670   bhead_t *b;
671 
672   nbuf = bget(th, size);
673   if (nbuf == NULL) { /* Acquire new buffer */
674     return NULL;
675   }
676   if (buf == NULL) {
677     return nbuf;
678   }
679   b = BH(((char *)buf) - sizeof(bhead_t));
680   osize = -b->bb.bsize;
681   if (osize == 0) {
682     /*  Buffer acquired directly through acqfcn. */
683     bdhead_t *bd;
684 
685     bd = BDH(((char *)buf) - sizeof(bdhead_t));
686     osize = bd->tsize - (bufsize)sizeof(bdhead_t);
687   } else {
688     osize -= sizeof(bhead_t);
689   }
690 
691   KMP_DEBUG_ASSERT(osize > 0);
692 
693   (void)KMP_MEMCPY((char *)nbuf, (char *)buf, /* Copy the data */
694                    (size_t)((size < osize) ? size : osize));
695   brel(th, buf);
696 
697   return nbuf;
698 }
699 
700 /*  BREL  --  Release a buffer.  */
701 static void brel(kmp_info_t *th, void *buf) {
702   thr_data_t *thr = get_thr_data(th);
703   bfhead_t *b, *bn;
704   kmp_info_t *bth;
705 
706   KMP_DEBUG_ASSERT(buf != NULL);
707   KMP_DEBUG_ASSERT(((size_t)buf) % SizeQuant == 0);
708 
709   b = BFH(((char *)buf) - sizeof(bhead_t));
710 
711   if (b->bh.bb.bsize == 0) { /* Directly-acquired buffer? */
712     bdhead_t *bdh;
713 
714     bdh = BDH(((char *)buf) - sizeof(bdhead_t));
715     KMP_DEBUG_ASSERT(b->bh.bb.prevfree == 0);
716 #if BufStats
717     thr->totalloc -= (size_t)bdh->tsize;
718     thr->numdrel++; /* Number of direct releases */
719     thr->numrel++; /* Increment number of brel() calls */
720 #endif /* BufStats */
721 #ifdef FreeWipe
722     (void)memset((char *)buf, 0x55, (size_t)(bdh->tsize - sizeof(bdhead_t)));
723 #endif /* FreeWipe */
724 
725     KE_TRACE(10, ("%%%%%% FREE( %p )\n", (void *)bdh));
726 
727     KMP_DEBUG_ASSERT(thr->relfcn != 0);
728     (*thr->relfcn)((void *)bdh); /* Release it directly. */
729     return;
730   }
731 
732   bth = (kmp_info_t *)((kmp_uintptr_t)TCR_PTR(b->bh.bb.bthr) &
733                        ~1); // clear possible mark before comparison
734   if (bth != th) {
735     /* Add this buffer to be released by the owning thread later */
736     __kmp_bget_enqueue(bth, buf
737 #ifdef USE_QUEUING_LOCK_FOR_BGET
738                        ,
739                        __kmp_gtid_from_thread(th)
740 #endif
741     );
742     return;
743   }
744 
745   /* Buffer size must be negative, indicating that the buffer is allocated. */
746   if (b->bh.bb.bsize >= 0) {
747     bn = NULL;
748   }
749   KMP_DEBUG_ASSERT(b->bh.bb.bsize < 0);
750 
751   /*  Back pointer in next buffer must be zero, indicating the same thing: */
752 
753   KMP_DEBUG_ASSERT(BH((char *)b - b->bh.bb.bsize)->bb.prevfree == 0);
754 
755 #if BufStats
756   thr->numrel++; /* Increment number of brel() calls */
757   thr->totalloc += (size_t)b->bh.bb.bsize;
758 #endif
759 
760   /* If the back link is nonzero, the previous buffer is free.  */
761 
762   if (b->bh.bb.prevfree != 0) {
763     /* The previous buffer is free. Consolidate this buffer with it by adding
764        the length of this buffer to the previous free buffer. Note that we
765        subtract the size in the buffer being released, since it's negative to
766        indicate that the buffer is allocated. */
767     bufsize size = b->bh.bb.bsize;
768 
769     /* Make the previous buffer the one we're working on. */
770     KMP_DEBUG_ASSERT(BH((char *)b - b->bh.bb.prevfree)->bb.bsize ==
771                      b->bh.bb.prevfree);
772     b = BFH(((char *)b) - b->bh.bb.prevfree);
773     b->bh.bb.bsize -= size;
774 
775     /* unlink the buffer from the old freelist */
776     __kmp_bget_remove_from_freelist(b);
777   } else {
778     /* The previous buffer isn't allocated. Mark this buffer size as positive
779        (i.e. free) and fall through to place the buffer on the free list as an
780        isolated free block. */
781     b->bh.bb.bsize = -b->bh.bb.bsize;
782   }
783 
784   /* insert buffer back onto a new freelist */
785   __kmp_bget_insert_into_freelist(thr, b);
786 
787   /* Now we look at the next buffer in memory, located by advancing from
788      the  start  of  this  buffer  by its size, to see if that buffer is
789      free.  If it is, we combine  this  buffer  with  the  next  one  in
790      memory, dechaining the second buffer from the free list. */
791   bn = BFH(((char *)b) + b->bh.bb.bsize);
792   if (bn->bh.bb.bsize > 0) {
793 
794     /* The buffer is free.  Remove it from the free list and add
795        its size to that of our buffer. */
796     KMP_DEBUG_ASSERT(BH((char *)bn + bn->bh.bb.bsize)->bb.prevfree ==
797                      bn->bh.bb.bsize);
798 
799     __kmp_bget_remove_from_freelist(bn);
800 
801     b->bh.bb.bsize += bn->bh.bb.bsize;
802 
803     /* unlink the buffer from the old freelist, and reinsert it into the new
804      * freelist */
805     __kmp_bget_remove_from_freelist(b);
806     __kmp_bget_insert_into_freelist(thr, b);
807 
808     /* Finally,  advance  to   the  buffer  that   follows  the  newly
809        consolidated free block.  We must set its  backpointer  to  the
810        head  of  the  consolidated free block.  We know the next block
811        must be an allocated block because the process of recombination
812        guarantees  that  two  free  blocks will never be contiguous in
813        memory.  */
814     bn = BFH(((char *)b) + b->bh.bb.bsize);
815   }
816 #ifdef FreeWipe
817   (void)memset(((char *)b) + sizeof(bfhead_t), 0x55,
818                (size_t)(b->bh.bb.bsize - sizeof(bfhead_t)));
819 #endif
820   KMP_DEBUG_ASSERT(bn->bh.bb.bsize < 0);
821 
822   /* The next buffer is allocated.  Set the backpointer in it  to  point
823      to this buffer; the previous free buffer in memory. */
824 
825   bn->bh.bb.prevfree = b->bh.bb.bsize;
826 
827   /*  If  a  block-release function is defined, and this free buffer
828       constitutes the entire block, release it.  Note that  pool_len
829       is  defined  in  such a way that the test will fail unless all
830       pool blocks are the same size.  */
831   if (thr->relfcn != 0 &&
832       b->bh.bb.bsize == (bufsize)(thr->pool_len - sizeof(bhead_t))) {
833 #if BufStats
834     if (thr->numpblk !=
835         1) { /* Do not release the last buffer until finalization time */
836 #endif
837 
838       KMP_DEBUG_ASSERT(b->bh.bb.prevfree == 0);
839       KMP_DEBUG_ASSERT(BH((char *)b + b->bh.bb.bsize)->bb.bsize == ESent);
840       KMP_DEBUG_ASSERT(BH((char *)b + b->bh.bb.bsize)->bb.prevfree ==
841                        b->bh.bb.bsize);
842 
843       /*  Unlink the buffer from the free list  */
844       __kmp_bget_remove_from_freelist(b);
845 
846       KE_TRACE(10, ("%%%%%% FREE( %p )\n", (void *)b));
847 
848       (*thr->relfcn)(b);
849 #if BufStats
850       thr->numprel++; /* Nr of expansion block releases */
851       thr->numpblk--; /* Total number of blocks */
852       KMP_DEBUG_ASSERT(thr->numpblk == thr->numpget - thr->numprel);
853 
854       // avoid leaving stale last_pool pointer around if it is being dealloced
855       if (thr->last_pool == b)
856         thr->last_pool = 0;
857     } else {
858       thr->last_pool = b;
859     }
860 #endif /* BufStats */
861   }
862 }
863 
864 /*  BECTL  --  Establish automatic pool expansion control  */
865 static void bectl(kmp_info_t *th, bget_compact_t compact,
866                   bget_acquire_t acquire, bget_release_t release,
867                   bufsize pool_incr) {
868   thr_data_t *thr = get_thr_data(th);
869 
870   thr->compfcn = compact;
871   thr->acqfcn = acquire;
872   thr->relfcn = release;
873   thr->exp_incr = pool_incr;
874 }
875 
876 /*  BPOOL  --  Add a region of memory to the buffer pool.  */
877 static void bpool(kmp_info_t *th, void *buf, bufsize len) {
878   /*    int bin = 0; */
879   thr_data_t *thr = get_thr_data(th);
880   bfhead_t *b = BFH(buf);
881   bhead_t *bn;
882 
883   __kmp_bget_dequeue(th); /* Release any queued buffers */
884 
885 #ifdef SizeQuant
886   len &= ~((bufsize)(SizeQuant - 1));
887 #endif
888   if (thr->pool_len == 0) {
889     thr->pool_len = len;
890   } else if (len != thr->pool_len) {
891     thr->pool_len = -1;
892   }
893 #if BufStats
894   thr->numpget++; /* Number of block acquisitions */
895   thr->numpblk++; /* Number of blocks total */
896   KMP_DEBUG_ASSERT(thr->numpblk == thr->numpget - thr->numprel);
897 #endif /* BufStats */
898 
899   /* Since the block is initially occupied by a single free  buffer,
900      it  had  better  not  be  (much) larger than the largest buffer
901      whose size we can store in bhead.bb.bsize. */
902   KMP_DEBUG_ASSERT(len - sizeof(bhead_t) <= -((bufsize)ESent + 1));
903 
904   /* Clear  the  backpointer at  the start of the block to indicate that
905      there  is  no  free  block  prior  to  this   one.    That   blocks
906      recombination when the first block in memory is released. */
907   b->bh.bb.prevfree = 0;
908 
909   /* Create a dummy allocated buffer at the end of the pool.  This dummy
910      buffer is seen when a buffer at the end of the pool is released and
911      blocks  recombination  of  the last buffer with the dummy buffer at
912      the end.  The length in the dummy buffer  is  set  to  the  largest
913      negative  number  to  denote  the  end  of  the pool for diagnostic
914      routines (this specific value is  not  counted  on  by  the  actual
915      allocation and release functions). */
916   len -= sizeof(bhead_t);
917   b->bh.bb.bsize = (bufsize)len;
918   /* Set the owner of this buffer */
919   TCW_PTR(b->bh.bb.bthr,
920           (kmp_info_t *)((kmp_uintptr_t)th |
921                          1)); // mark the buffer as allocated address
922 
923   /* Chain the new block to the free list. */
924   __kmp_bget_insert_into_freelist(thr, b);
925 
926 #ifdef FreeWipe
927   (void)memset(((char *)b) + sizeof(bfhead_t), 0x55,
928                (size_t)(len - sizeof(bfhead_t)));
929 #endif
930   bn = BH(((char *)b) + len);
931   bn->bb.prevfree = (bufsize)len;
932   /* Definition of ESent assumes two's complement! */
933   KMP_DEBUG_ASSERT((~0) == -1 && (bn != 0));
934 
935   bn->bb.bsize = ESent;
936 }
937 
938 /*  BFREED  --  Dump the free lists for this thread. */
939 static void bfreed(kmp_info_t *th) {
940   int bin = 0, count = 0;
941   int gtid = __kmp_gtid_from_thread(th);
942   thr_data_t *thr = get_thr_data(th);
943 
944 #if BufStats
945   __kmp_printf_no_lock("__kmp_printpool: T#%d total=%" KMP_UINT64_SPEC
946                        " get=%" KMP_INT64_SPEC " rel=%" KMP_INT64_SPEC
947                        " pblk=%" KMP_INT64_SPEC " pget=%" KMP_INT64_SPEC
948                        " prel=%" KMP_INT64_SPEC " dget=%" KMP_INT64_SPEC
949                        " drel=%" KMP_INT64_SPEC "\n",
950                        gtid, (kmp_uint64)thr->totalloc, (kmp_int64)thr->numget,
951                        (kmp_int64)thr->numrel, (kmp_int64)thr->numpblk,
952                        (kmp_int64)thr->numpget, (kmp_int64)thr->numprel,
953                        (kmp_int64)thr->numdget, (kmp_int64)thr->numdrel);
954 #endif
955 
956   for (bin = 0; bin < MAX_BGET_BINS; ++bin) {
957     bfhead_t *b;
958 
959     for (b = thr->freelist[bin].ql.flink; b != &thr->freelist[bin];
960          b = b->ql.flink) {
961       bufsize bs = b->bh.bb.bsize;
962 
963       KMP_DEBUG_ASSERT(b->ql.blink->ql.flink == b);
964       KMP_DEBUG_ASSERT(b->ql.flink->ql.blink == b);
965       KMP_DEBUG_ASSERT(bs > 0);
966 
967       count += 1;
968 
969       __kmp_printf_no_lock(
970           "__kmp_printpool: T#%d Free block: 0x%p size %6ld bytes.\n", gtid, b,
971           (long)bs);
972 #ifdef FreeWipe
973       {
974         char *lerr = ((char *)b) + sizeof(bfhead_t);
975         if ((bs > sizeof(bfhead_t)) &&
976             ((*lerr != 0x55) ||
977              (memcmp(lerr, lerr + 1, (size_t)(bs - (sizeof(bfhead_t) + 1))) !=
978               0))) {
979           __kmp_printf_no_lock("__kmp_printpool: T#%d     (Contents of above "
980                                "free block have been overstored.)\n",
981                                gtid);
982         }
983       }
984 #endif
985     }
986   }
987 
988   if (count == 0)
989     __kmp_printf_no_lock("__kmp_printpool: T#%d No free blocks\n", gtid);
990 }
991 
992 void __kmp_initialize_bget(kmp_info_t *th) {
993   KMP_DEBUG_ASSERT(SizeQuant >= sizeof(void *) && (th != 0));
994 
995   set_thr_data(th);
996 
997   bectl(th, (bget_compact_t)0, (bget_acquire_t)malloc, (bget_release_t)free,
998         (bufsize)__kmp_malloc_pool_incr);
999 }
1000 
1001 void __kmp_finalize_bget(kmp_info_t *th) {
1002   thr_data_t *thr;
1003   bfhead_t *b;
1004 
1005   KMP_DEBUG_ASSERT(th != 0);
1006 
1007 #if BufStats
1008   thr = (thr_data_t *)th->th.th_local.bget_data;
1009   KMP_DEBUG_ASSERT(thr != NULL);
1010   b = thr->last_pool;
1011 
1012   /*  If a block-release function is defined, and this free buffer constitutes
1013       the entire block, release it. Note that pool_len is defined in such a way
1014       that the test will fail unless all pool blocks are the same size.  */
1015 
1016   // Deallocate the last pool if one exists because we no longer do it in brel()
1017   if (thr->relfcn != 0 && b != 0 && thr->numpblk != 0 &&
1018       b->bh.bb.bsize == (bufsize)(thr->pool_len - sizeof(bhead_t))) {
1019     KMP_DEBUG_ASSERT(b->bh.bb.prevfree == 0);
1020     KMP_DEBUG_ASSERT(BH((char *)b + b->bh.bb.bsize)->bb.bsize == ESent);
1021     KMP_DEBUG_ASSERT(BH((char *)b + b->bh.bb.bsize)->bb.prevfree ==
1022                      b->bh.bb.bsize);
1023 
1024     /*  Unlink the buffer from the free list  */
1025     __kmp_bget_remove_from_freelist(b);
1026 
1027     KE_TRACE(10, ("%%%%%% FREE( %p )\n", (void *)b));
1028 
1029     (*thr->relfcn)(b);
1030     thr->numprel++; /* Nr of expansion block releases */
1031     thr->numpblk--; /* Total number of blocks */
1032     KMP_DEBUG_ASSERT(thr->numpblk == thr->numpget - thr->numprel);
1033   }
1034 #endif /* BufStats */
1035 
1036   /* Deallocate bget_data */
1037   if (th->th.th_local.bget_data != NULL) {
1038     __kmp_free(th->th.th_local.bget_data);
1039     th->th.th_local.bget_data = NULL;
1040   }
1041 }
1042 
1043 void kmpc_set_poolsize(size_t size) {
1044   bectl(__kmp_get_thread(), (bget_compact_t)0, (bget_acquire_t)malloc,
1045         (bget_release_t)free, (bufsize)size);
1046 }
1047 
1048 size_t kmpc_get_poolsize(void) {
1049   thr_data_t *p;
1050 
1051   p = get_thr_data(__kmp_get_thread());
1052 
1053   return p->exp_incr;
1054 }
1055 
1056 void kmpc_set_poolmode(int mode) {
1057   thr_data_t *p;
1058 
1059   if (mode == bget_mode_fifo || mode == bget_mode_lifo ||
1060       mode == bget_mode_best) {
1061     p = get_thr_data(__kmp_get_thread());
1062     p->mode = (bget_mode_t)mode;
1063   }
1064 }
1065 
1066 int kmpc_get_poolmode(void) {
1067   thr_data_t *p;
1068 
1069   p = get_thr_data(__kmp_get_thread());
1070 
1071   return p->mode;
1072 }
1073 
1074 void kmpc_get_poolstat(size_t *maxmem, size_t *allmem) {
1075   kmp_info_t *th = __kmp_get_thread();
1076   bufsize a, b;
1077 
1078   __kmp_bget_dequeue(th); /* Release any queued buffers */
1079 
1080   bcheck(th, &a, &b);
1081 
1082   *maxmem = a;
1083   *allmem = b;
1084 }
1085 
1086 void kmpc_poolprint(void) {
1087   kmp_info_t *th = __kmp_get_thread();
1088 
1089   __kmp_bget_dequeue(th); /* Release any queued buffers */
1090 
1091   bfreed(th);
1092 }
1093 
1094 #endif // #if KMP_USE_BGET
1095 
1096 void *kmpc_malloc(size_t size) {
1097   void *ptr;
1098   ptr = bget(__kmp_entry_thread(), (bufsize)(size + sizeof(ptr)));
1099   if (ptr != NULL) {
1100     // save allocated pointer just before one returned to user
1101     *(void **)ptr = ptr;
1102     ptr = (void **)ptr + 1;
1103   }
1104   return ptr;
1105 }
1106 
1107 #define IS_POWER_OF_TWO(n) (((n) & ((n)-1)) == 0)
1108 
1109 void *kmpc_aligned_malloc(size_t size, size_t alignment) {
1110   void *ptr;
1111   void *ptr_allocated;
1112   KMP_DEBUG_ASSERT(alignment < 32 * 1024); // Alignment should not be too big
1113   if (!IS_POWER_OF_TWO(alignment)) {
1114     // AC: do we need to issue a warning here?
1115     errno = EINVAL;
1116     return NULL;
1117   }
1118   size = size + sizeof(void *) + alignment;
1119   ptr_allocated = bget(__kmp_entry_thread(), (bufsize)size);
1120   if (ptr_allocated != NULL) {
1121     // save allocated pointer just before one returned to user
1122     ptr = (void *)(((kmp_uintptr_t)ptr_allocated + sizeof(void *) + alignment) &
1123                    ~(alignment - 1));
1124     *((void **)ptr - 1) = ptr_allocated;
1125   } else {
1126     ptr = NULL;
1127   }
1128   return ptr;
1129 }
1130 
1131 void *kmpc_calloc(size_t nelem, size_t elsize) {
1132   void *ptr;
1133   ptr = bgetz(__kmp_entry_thread(), (bufsize)(nelem * elsize + sizeof(ptr)));
1134   if (ptr != NULL) {
1135     // save allocated pointer just before one returned to user
1136     *(void **)ptr = ptr;
1137     ptr = (void **)ptr + 1;
1138   }
1139   return ptr;
1140 }
1141 
1142 void *kmpc_realloc(void *ptr, size_t size) {
1143   void *result = NULL;
1144   if (ptr == NULL) {
1145     // If pointer is NULL, realloc behaves like malloc.
1146     result = bget(__kmp_entry_thread(), (bufsize)(size + sizeof(ptr)));
1147     // save allocated pointer just before one returned to user
1148     if (result != NULL) {
1149       *(void **)result = result;
1150       result = (void **)result + 1;
1151     }
1152   } else if (size == 0) {
1153     // If size is 0, realloc behaves like free.
1154     // The thread must be registered by the call to kmpc_malloc() or
1155     // kmpc_calloc() before.
1156     // So it should be safe to call __kmp_get_thread(), not
1157     // __kmp_entry_thread().
1158     KMP_ASSERT(*((void **)ptr - 1));
1159     brel(__kmp_get_thread(), *((void **)ptr - 1));
1160   } else {
1161     result = bgetr(__kmp_entry_thread(), *((void **)ptr - 1),
1162                    (bufsize)(size + sizeof(ptr)));
1163     if (result != NULL) {
1164       *(void **)result = result;
1165       result = (void **)result + 1;
1166     }
1167   }
1168   return result;
1169 }
1170 
1171 // NOTE: the library must have already been initialized by a previous allocate
1172 void kmpc_free(void *ptr) {
1173   if (!__kmp_init_serial) {
1174     return;
1175   }
1176   if (ptr != NULL) {
1177     kmp_info_t *th = __kmp_get_thread();
1178     __kmp_bget_dequeue(th); /* Release any queued buffers */
1179     // extract allocated pointer and free it
1180     KMP_ASSERT(*((void **)ptr - 1));
1181     brel(th, *((void **)ptr - 1));
1182   }
1183 }
1184 
1185 void *___kmp_thread_malloc(kmp_info_t *th, size_t size KMP_SRC_LOC_DECL) {
1186   void *ptr;
1187   KE_TRACE(30, ("-> __kmp_thread_malloc( %p, %d ) called from %s:%d\n", th,
1188                 (int)size KMP_SRC_LOC_PARM));
1189   ptr = bget(th, (bufsize)size);
1190   KE_TRACE(30, ("<- __kmp_thread_malloc() returns %p\n", ptr));
1191   return ptr;
1192 }
1193 
1194 void *___kmp_thread_calloc(kmp_info_t *th, size_t nelem,
1195                            size_t elsize KMP_SRC_LOC_DECL) {
1196   void *ptr;
1197   KE_TRACE(30, ("-> __kmp_thread_calloc( %p, %d, %d ) called from %s:%d\n", th,
1198                 (int)nelem, (int)elsize KMP_SRC_LOC_PARM));
1199   ptr = bgetz(th, (bufsize)(nelem * elsize));
1200   KE_TRACE(30, ("<- __kmp_thread_calloc() returns %p\n", ptr));
1201   return ptr;
1202 }
1203 
1204 void *___kmp_thread_realloc(kmp_info_t *th, void *ptr,
1205                             size_t size KMP_SRC_LOC_DECL) {
1206   KE_TRACE(30, ("-> __kmp_thread_realloc( %p, %p, %d ) called from %s:%d\n", th,
1207                 ptr, (int)size KMP_SRC_LOC_PARM));
1208   ptr = bgetr(th, ptr, (bufsize)size);
1209   KE_TRACE(30, ("<- __kmp_thread_realloc() returns %p\n", ptr));
1210   return ptr;
1211 }
1212 
1213 void ___kmp_thread_free(kmp_info_t *th, void *ptr KMP_SRC_LOC_DECL) {
1214   KE_TRACE(30, ("-> __kmp_thread_free( %p, %p ) called from %s:%d\n", th,
1215                 ptr KMP_SRC_LOC_PARM));
1216   if (ptr != NULL) {
1217     __kmp_bget_dequeue(th); /* Release any queued buffers */
1218     brel(th, ptr);
1219   }
1220   KE_TRACE(30, ("<- __kmp_thread_free()\n"));
1221 }
1222 
1223 /* OMP 5.0 Memory Management support */
1224 static const char *kmp_mk_lib_name;
1225 static void *h_memkind;
1226 /* memkind experimental API: */
1227 // memkind_alloc
1228 static void *(*kmp_mk_alloc)(void *k, size_t sz);
1229 // memkind_free
1230 static void (*kmp_mk_free)(void *kind, void *ptr);
1231 // memkind_check_available
1232 static int (*kmp_mk_check)(void *kind);
1233 // kinds we are going to use
1234 static void **mk_default;
1235 static void **mk_interleave;
1236 static void **mk_hbw;
1237 static void **mk_hbw_interleave;
1238 static void **mk_hbw_preferred;
1239 static void **mk_hugetlb;
1240 static void **mk_hbw_hugetlb;
1241 static void **mk_hbw_preferred_hugetlb;
1242 static void **mk_dax_kmem;
1243 static void **mk_dax_kmem_all;
1244 static void **mk_dax_kmem_preferred;
1245 static void *(*kmp_target_alloc_host)(size_t size, int device);
1246 static void *(*kmp_target_alloc_shared)(size_t size, int device);
1247 static void *(*kmp_target_alloc_device)(size_t size, int device);
1248 static void *(*kmp_target_free)(void *ptr, int device);
1249 static bool __kmp_target_mem_available;
1250 #define KMP_IS_TARGET_MEM_SPACE(MS)                                            \
1251   (MS == llvm_omp_target_host_mem_space ||                                     \
1252    MS == llvm_omp_target_shared_mem_space ||                                   \
1253    MS == llvm_omp_target_device_mem_space)
1254 #define KMP_IS_TARGET_MEM_ALLOC(MA)                                            \
1255   (MA == llvm_omp_target_host_mem_alloc ||                                     \
1256    MA == llvm_omp_target_shared_mem_alloc ||                                   \
1257    MA == llvm_omp_target_device_mem_alloc)
1258 
1259 #if KMP_OS_UNIX && KMP_DYNAMIC_LIB && !KMP_OS_DARWIN
1260 static inline void chk_kind(void ***pkind) {
1261   KMP_DEBUG_ASSERT(pkind);
1262   if (*pkind) // symbol found
1263     if (kmp_mk_check(**pkind)) // kind not available or error
1264       *pkind = NULL;
1265 }
1266 #endif
1267 
1268 void __kmp_init_memkind() {
1269 // as of 2018-07-31 memkind does not support Windows*, exclude it for now
1270 #if KMP_OS_UNIX && KMP_DYNAMIC_LIB && !KMP_OS_DARWIN
1271   // use of statically linked memkind is problematic, as it depends on libnuma
1272   kmp_mk_lib_name = "libmemkind.so";
1273   h_memkind = dlopen(kmp_mk_lib_name, RTLD_LAZY);
1274   if (h_memkind) {
1275     kmp_mk_check = (int (*)(void *))dlsym(h_memkind, "memkind_check_available");
1276     kmp_mk_alloc =
1277         (void *(*)(void *, size_t))dlsym(h_memkind, "memkind_malloc");
1278     kmp_mk_free = (void (*)(void *, void *))dlsym(h_memkind, "memkind_free");
1279     mk_default = (void **)dlsym(h_memkind, "MEMKIND_DEFAULT");
1280     if (kmp_mk_check && kmp_mk_alloc && kmp_mk_free && mk_default &&
1281         !kmp_mk_check(*mk_default)) {
1282       __kmp_memkind_available = 1;
1283       mk_interleave = (void **)dlsym(h_memkind, "MEMKIND_INTERLEAVE");
1284       chk_kind(&mk_interleave);
1285       mk_hbw = (void **)dlsym(h_memkind, "MEMKIND_HBW");
1286       chk_kind(&mk_hbw);
1287       mk_hbw_interleave = (void **)dlsym(h_memkind, "MEMKIND_HBW_INTERLEAVE");
1288       chk_kind(&mk_hbw_interleave);
1289       mk_hbw_preferred = (void **)dlsym(h_memkind, "MEMKIND_HBW_PREFERRED");
1290       chk_kind(&mk_hbw_preferred);
1291       mk_hugetlb = (void **)dlsym(h_memkind, "MEMKIND_HUGETLB");
1292       chk_kind(&mk_hugetlb);
1293       mk_hbw_hugetlb = (void **)dlsym(h_memkind, "MEMKIND_HBW_HUGETLB");
1294       chk_kind(&mk_hbw_hugetlb);
1295       mk_hbw_preferred_hugetlb =
1296           (void **)dlsym(h_memkind, "MEMKIND_HBW_PREFERRED_HUGETLB");
1297       chk_kind(&mk_hbw_preferred_hugetlb);
1298       mk_dax_kmem = (void **)dlsym(h_memkind, "MEMKIND_DAX_KMEM");
1299       chk_kind(&mk_dax_kmem);
1300       mk_dax_kmem_all = (void **)dlsym(h_memkind, "MEMKIND_DAX_KMEM_ALL");
1301       chk_kind(&mk_dax_kmem_all);
1302       mk_dax_kmem_preferred =
1303           (void **)dlsym(h_memkind, "MEMKIND_DAX_KMEM_PREFERRED");
1304       chk_kind(&mk_dax_kmem_preferred);
1305       KE_TRACE(25, ("__kmp_init_memkind: memkind library initialized\n"));
1306       return; // success
1307     }
1308     dlclose(h_memkind); // failure
1309   }
1310 #else // !(KMP_OS_UNIX && KMP_DYNAMIC_LIB)
1311   kmp_mk_lib_name = "";
1312 #endif // !(KMP_OS_UNIX && KMP_DYNAMIC_LIB)
1313   h_memkind = NULL;
1314   kmp_mk_check = NULL;
1315   kmp_mk_alloc = NULL;
1316   kmp_mk_free = NULL;
1317   mk_default = NULL;
1318   mk_interleave = NULL;
1319   mk_hbw = NULL;
1320   mk_hbw_interleave = NULL;
1321   mk_hbw_preferred = NULL;
1322   mk_hugetlb = NULL;
1323   mk_hbw_hugetlb = NULL;
1324   mk_hbw_preferred_hugetlb = NULL;
1325   mk_dax_kmem = NULL;
1326   mk_dax_kmem_all = NULL;
1327   mk_dax_kmem_preferred = NULL;
1328 }
1329 
1330 void __kmp_fini_memkind() {
1331 #if KMP_OS_UNIX && KMP_DYNAMIC_LIB
1332   if (__kmp_memkind_available)
1333     KE_TRACE(25, ("__kmp_fini_memkind: finalize memkind library\n"));
1334   if (h_memkind) {
1335     dlclose(h_memkind);
1336     h_memkind = NULL;
1337   }
1338   kmp_mk_check = NULL;
1339   kmp_mk_alloc = NULL;
1340   kmp_mk_free = NULL;
1341   mk_default = NULL;
1342   mk_interleave = NULL;
1343   mk_hbw = NULL;
1344   mk_hbw_interleave = NULL;
1345   mk_hbw_preferred = NULL;
1346   mk_hugetlb = NULL;
1347   mk_hbw_hugetlb = NULL;
1348   mk_hbw_preferred_hugetlb = NULL;
1349   mk_dax_kmem = NULL;
1350   mk_dax_kmem_all = NULL;
1351   mk_dax_kmem_preferred = NULL;
1352 #endif
1353 }
1354 
1355 void __kmp_init_target_mem() {
1356   *(void **)(&kmp_target_alloc_host) = KMP_DLSYM("llvm_omp_target_alloc_host");
1357   *(void **)(&kmp_target_alloc_shared) =
1358       KMP_DLSYM("llvm_omp_target_alloc_shared");
1359   *(void **)(&kmp_target_alloc_device) =
1360       KMP_DLSYM("llvm_omp_target_alloc_device");
1361   *(void **)(&kmp_target_free) = KMP_DLSYM("omp_target_free");
1362   __kmp_target_mem_available = kmp_target_alloc_host &&
1363                                kmp_target_alloc_shared &&
1364                                kmp_target_alloc_device && kmp_target_free;
1365 }
1366 
1367 omp_allocator_handle_t __kmpc_init_allocator(int gtid, omp_memspace_handle_t ms,
1368                                              int ntraits,
1369                                              omp_alloctrait_t traits[]) {
1370   // OpenMP 5.0 only allows predefined memspaces
1371   KMP_DEBUG_ASSERT(ms == omp_default_mem_space || ms == omp_low_lat_mem_space ||
1372                    ms == omp_large_cap_mem_space || ms == omp_const_mem_space ||
1373                    ms == omp_high_bw_mem_space || KMP_IS_TARGET_MEM_SPACE(ms));
1374   kmp_allocator_t *al;
1375   int i;
1376   al = (kmp_allocator_t *)__kmp_allocate(sizeof(kmp_allocator_t)); // zeroed
1377   al->memspace = ms; // not used currently
1378   for (i = 0; i < ntraits; ++i) {
1379     switch (traits[i].key) {
1380     case omp_atk_sync_hint:
1381     case omp_atk_access:
1382     case omp_atk_pinned:
1383       break;
1384     case omp_atk_alignment:
1385       __kmp_type_convert(traits[i].value, &(al->alignment));
1386       KMP_ASSERT(IS_POWER_OF_TWO(al->alignment));
1387       break;
1388     case omp_atk_pool_size:
1389       al->pool_size = traits[i].value;
1390       break;
1391     case omp_atk_fallback:
1392       al->fb = (omp_alloctrait_value_t)traits[i].value;
1393       KMP_DEBUG_ASSERT(
1394           al->fb == omp_atv_default_mem_fb || al->fb == omp_atv_null_fb ||
1395           al->fb == omp_atv_abort_fb || al->fb == omp_atv_allocator_fb);
1396       break;
1397     case omp_atk_fb_data:
1398       al->fb_data = RCAST(kmp_allocator_t *, traits[i].value);
1399       break;
1400     case omp_atk_partition:
1401       al->memkind = RCAST(void **, traits[i].value);
1402       break;
1403     default:
1404       KMP_ASSERT2(0, "Unexpected allocator trait");
1405     }
1406   }
1407   if (al->fb == 0) {
1408     // set default allocator
1409     al->fb = omp_atv_default_mem_fb;
1410     al->fb_data = (kmp_allocator_t *)omp_default_mem_alloc;
1411   } else if (al->fb == omp_atv_allocator_fb) {
1412     KMP_ASSERT(al->fb_data != NULL);
1413   } else if (al->fb == omp_atv_default_mem_fb) {
1414     al->fb_data = (kmp_allocator_t *)omp_default_mem_alloc;
1415   }
1416   if (__kmp_memkind_available) {
1417     // Let's use memkind library if available
1418     if (ms == omp_high_bw_mem_space) {
1419       if (al->memkind == (void *)omp_atv_interleaved && mk_hbw_interleave) {
1420         al->memkind = mk_hbw_interleave;
1421       } else if (mk_hbw_preferred) {
1422         // AC: do not try to use MEMKIND_HBW for now, because memkind library
1423         // cannot reliably detect exhaustion of HBW memory.
1424         // It could be possible using hbw_verify_memory_region() but memkind
1425         // manual says: "Using this function in production code may result in
1426         // serious performance penalty".
1427         al->memkind = mk_hbw_preferred;
1428       } else {
1429         // HBW is requested but not available --> return NULL allocator
1430         __kmp_free(al);
1431         return omp_null_allocator;
1432       }
1433     } else if (ms == omp_large_cap_mem_space) {
1434       if (mk_dax_kmem_all) {
1435         // All pmem nodes are visited
1436         al->memkind = mk_dax_kmem_all;
1437       } else if (mk_dax_kmem) {
1438         // Only closest pmem node is visited
1439         al->memkind = mk_dax_kmem;
1440       } else {
1441         __kmp_free(al);
1442         return omp_null_allocator;
1443       }
1444     } else {
1445       if (al->memkind == (void *)omp_atv_interleaved && mk_interleave) {
1446         al->memkind = mk_interleave;
1447       } else {
1448         al->memkind = mk_default;
1449       }
1450     }
1451   } else if (KMP_IS_TARGET_MEM_SPACE(ms) && !__kmp_target_mem_available) {
1452     __kmp_free(al);
1453     return omp_null_allocator;
1454   } else {
1455     if (ms == omp_high_bw_mem_space) {
1456       // cannot detect HBW memory presence without memkind library
1457       __kmp_free(al);
1458       return omp_null_allocator;
1459     }
1460   }
1461   return (omp_allocator_handle_t)al;
1462 }
1463 
1464 void __kmpc_destroy_allocator(int gtid, omp_allocator_handle_t allocator) {
1465   if (allocator > kmp_max_mem_alloc)
1466     __kmp_free(allocator);
1467 }
1468 
1469 void __kmpc_set_default_allocator(int gtid, omp_allocator_handle_t allocator) {
1470   if (allocator == omp_null_allocator)
1471     allocator = omp_default_mem_alloc;
1472   __kmp_threads[gtid]->th.th_def_allocator = allocator;
1473 }
1474 
1475 omp_allocator_handle_t __kmpc_get_default_allocator(int gtid) {
1476   return __kmp_threads[gtid]->th.th_def_allocator;
1477 }
1478 
1479 typedef struct kmp_mem_desc { // Memory block descriptor
1480   void *ptr_alloc; // Pointer returned by allocator
1481   size_t size_a; // Size of allocated memory block (initial+descriptor+align)
1482   size_t size_orig; // Original size requested
1483   void *ptr_align; // Pointer to aligned memory, returned
1484   kmp_allocator_t *allocator; // allocator
1485 } kmp_mem_desc_t;
1486 static int alignment = sizeof(void *); // align to pointer size by default
1487 
1488 // external interfaces are wrappers over internal implementation
1489 void *__kmpc_alloc(int gtid, size_t size, omp_allocator_handle_t allocator) {
1490   KE_TRACE(25, ("__kmpc_alloc: T#%d (%d, %p)\n", gtid, (int)size, allocator));
1491   void *ptr = __kmp_alloc(gtid, 0, size, allocator);
1492   KE_TRACE(25, ("__kmpc_alloc returns %p, T#%d\n", ptr, gtid));
1493   return ptr;
1494 }
1495 
1496 void *__kmpc_aligned_alloc(int gtid, size_t algn, size_t size,
1497                            omp_allocator_handle_t allocator) {
1498   KE_TRACE(25, ("__kmpc_aligned_alloc: T#%d (%d, %d, %p)\n", gtid, (int)algn,
1499                 (int)size, allocator));
1500   void *ptr = __kmp_alloc(gtid, algn, size, allocator);
1501   KE_TRACE(25, ("__kmpc_aligned_alloc returns %p, T#%d\n", ptr, gtid));
1502   return ptr;
1503 }
1504 
1505 void *__kmpc_calloc(int gtid, size_t nmemb, size_t size,
1506                     omp_allocator_handle_t allocator) {
1507   KE_TRACE(25, ("__kmpc_calloc: T#%d (%d, %d, %p)\n", gtid, (int)nmemb,
1508                 (int)size, allocator));
1509   void *ptr = __kmp_calloc(gtid, 0, nmemb, size, allocator);
1510   KE_TRACE(25, ("__kmpc_calloc returns %p, T#%d\n", ptr, gtid));
1511   return ptr;
1512 }
1513 
1514 void *__kmpc_realloc(int gtid, void *ptr, size_t size,
1515                      omp_allocator_handle_t allocator,
1516                      omp_allocator_handle_t free_allocator) {
1517   KE_TRACE(25, ("__kmpc_realloc: T#%d (%p, %d, %p, %p)\n", gtid, ptr, (int)size,
1518                 allocator, free_allocator));
1519   void *nptr = __kmp_realloc(gtid, ptr, size, allocator, free_allocator);
1520   KE_TRACE(25, ("__kmpc_realloc returns %p, T#%d\n", nptr, gtid));
1521   return nptr;
1522 }
1523 
1524 void __kmpc_free(int gtid, void *ptr, omp_allocator_handle_t allocator) {
1525   KE_TRACE(25, ("__kmpc_free: T#%d free(%p,%p)\n", gtid, ptr, allocator));
1526   ___kmpc_free(gtid, ptr, allocator);
1527   KE_TRACE(10, ("__kmpc_free: T#%d freed %p (%p)\n", gtid, ptr, allocator));
1528   return;
1529 }
1530 
1531 // internal implementation, called from inside the library
1532 void *__kmp_alloc(int gtid, size_t algn, size_t size,
1533                   omp_allocator_handle_t allocator) {
1534   void *ptr = NULL;
1535   kmp_allocator_t *al;
1536   KMP_DEBUG_ASSERT(__kmp_init_serial);
1537   if (size == 0)
1538     return NULL;
1539   if (allocator == omp_null_allocator)
1540     allocator = __kmp_threads[gtid]->th.th_def_allocator;
1541 
1542   al = RCAST(kmp_allocator_t *, allocator);
1543 
1544   int sz_desc = sizeof(kmp_mem_desc_t);
1545   kmp_mem_desc_t desc;
1546   kmp_uintptr_t addr; // address returned by allocator
1547   kmp_uintptr_t addr_align; // address to return to caller
1548   kmp_uintptr_t addr_descr; // address of memory block descriptor
1549   size_t align = alignment; // default alignment
1550   if (allocator > kmp_max_mem_alloc && al->alignment > align)
1551     align = al->alignment; // alignment required by allocator trait
1552   if (align < algn)
1553     align = algn; // max of allocator trait, parameter and sizeof(void*)
1554   desc.size_orig = size;
1555   desc.size_a = size + sz_desc + align;
1556 
1557   if (__kmp_memkind_available) {
1558     if (allocator < kmp_max_mem_alloc) {
1559       // pre-defined allocator
1560       if (allocator == omp_high_bw_mem_alloc && mk_hbw_preferred) {
1561         ptr = kmp_mk_alloc(*mk_hbw_preferred, desc.size_a);
1562       } else if (allocator == omp_large_cap_mem_alloc && mk_dax_kmem_all) {
1563         ptr = kmp_mk_alloc(*mk_dax_kmem_all, desc.size_a);
1564       } else {
1565         ptr = kmp_mk_alloc(*mk_default, desc.size_a);
1566       }
1567     } else if (al->pool_size > 0) {
1568       // custom allocator with pool size requested
1569       kmp_uint64 used =
1570           KMP_TEST_THEN_ADD64((kmp_int64 *)&al->pool_used, desc.size_a);
1571       if (used + desc.size_a > al->pool_size) {
1572         // not enough space, need to go fallback path
1573         KMP_TEST_THEN_ADD64((kmp_int64 *)&al->pool_used, -desc.size_a);
1574         if (al->fb == omp_atv_default_mem_fb) {
1575           al = (kmp_allocator_t *)omp_default_mem_alloc;
1576           ptr = kmp_mk_alloc(*mk_default, desc.size_a);
1577         } else if (al->fb == omp_atv_abort_fb) {
1578           KMP_ASSERT(0); // abort fallback requested
1579         } else if (al->fb == omp_atv_allocator_fb) {
1580           KMP_ASSERT(al != al->fb_data);
1581           al = al->fb_data;
1582           return __kmp_alloc(gtid, algn, size, (omp_allocator_handle_t)al);
1583         } // else ptr == NULL;
1584       } else {
1585         // pool has enough space
1586         ptr = kmp_mk_alloc(*al->memkind, desc.size_a);
1587         if (ptr == NULL) {
1588           if (al->fb == omp_atv_default_mem_fb) {
1589             al = (kmp_allocator_t *)omp_default_mem_alloc;
1590             ptr = kmp_mk_alloc(*mk_default, desc.size_a);
1591           } else if (al->fb == omp_atv_abort_fb) {
1592             KMP_ASSERT(0); // abort fallback requested
1593           } else if (al->fb == omp_atv_allocator_fb) {
1594             KMP_ASSERT(al != al->fb_data);
1595             al = al->fb_data;
1596             return __kmp_alloc(gtid, algn, size, (omp_allocator_handle_t)al);
1597           }
1598         }
1599       }
1600     } else {
1601       // custom allocator, pool size not requested
1602       ptr = kmp_mk_alloc(*al->memkind, desc.size_a);
1603       if (ptr == NULL) {
1604         if (al->fb == omp_atv_default_mem_fb) {
1605           al = (kmp_allocator_t *)omp_default_mem_alloc;
1606           ptr = kmp_mk_alloc(*mk_default, desc.size_a);
1607         } else if (al->fb == omp_atv_abort_fb) {
1608           KMP_ASSERT(0); // abort fallback requested
1609         } else if (al->fb == omp_atv_allocator_fb) {
1610           KMP_ASSERT(al != al->fb_data);
1611           al = al->fb_data;
1612           return __kmp_alloc(gtid, algn, size, (omp_allocator_handle_t)al);
1613         }
1614       }
1615     }
1616   } else if (allocator < kmp_max_mem_alloc) {
1617     if (KMP_IS_TARGET_MEM_ALLOC(allocator)) {
1618       // Use size input directly as the memory may not be accessible on host.
1619       // Use default device for now.
1620       if (__kmp_target_mem_available) {
1621         kmp_int32 device =
1622             __kmp_threads[gtid]->th.th_current_task->td_icvs.default_device;
1623         if (allocator == llvm_omp_target_host_mem_alloc)
1624           ptr = kmp_target_alloc_host(size, device);
1625         else if (allocator == llvm_omp_target_shared_mem_alloc)
1626           ptr = kmp_target_alloc_shared(size, device);
1627         else // allocator == llvm_omp_target_device_mem_alloc
1628           ptr = kmp_target_alloc_device(size, device);
1629       }
1630       return ptr;
1631     }
1632 
1633     // pre-defined allocator
1634     if (allocator == omp_high_bw_mem_alloc) {
1635       // ptr = NULL;
1636     } else if (allocator == omp_large_cap_mem_alloc) {
1637       // warnings?
1638     } else {
1639       ptr = __kmp_thread_malloc(__kmp_thread_from_gtid(gtid), desc.size_a);
1640     }
1641   } else if (KMP_IS_TARGET_MEM_SPACE(al->memspace)) {
1642     if (__kmp_target_mem_available) {
1643       kmp_int32 device =
1644           __kmp_threads[gtid]->th.th_current_task->td_icvs.default_device;
1645       if (al->memspace == llvm_omp_target_host_mem_space)
1646         ptr = kmp_target_alloc_host(size, device);
1647       else if (al->memspace == llvm_omp_target_shared_mem_space)
1648         ptr = kmp_target_alloc_shared(size, device);
1649       else // al->memspace == llvm_omp_target_device_mem_space
1650         ptr = kmp_target_alloc_device(size, device);
1651     }
1652     return ptr;
1653   } else if (al->pool_size > 0) {
1654     // custom allocator with pool size requested
1655     kmp_uint64 used =
1656         KMP_TEST_THEN_ADD64((kmp_int64 *)&al->pool_used, desc.size_a);
1657     if (used + desc.size_a > al->pool_size) {
1658       // not enough space, need to go fallback path
1659       KMP_TEST_THEN_ADD64((kmp_int64 *)&al->pool_used, -desc.size_a);
1660       if (al->fb == omp_atv_default_mem_fb) {
1661         al = (kmp_allocator_t *)omp_default_mem_alloc;
1662         ptr = __kmp_thread_malloc(__kmp_thread_from_gtid(gtid), desc.size_a);
1663       } else if (al->fb == omp_atv_abort_fb) {
1664         KMP_ASSERT(0); // abort fallback requested
1665       } else if (al->fb == omp_atv_allocator_fb) {
1666         KMP_ASSERT(al != al->fb_data);
1667         al = al->fb_data;
1668         return __kmp_alloc(gtid, algn, size, (omp_allocator_handle_t)al);
1669       } // else ptr == NULL;
1670     } else {
1671       // pool has enough space
1672       ptr = __kmp_thread_malloc(__kmp_thread_from_gtid(gtid), desc.size_a);
1673       if (ptr == NULL && al->fb == omp_atv_abort_fb) {
1674         KMP_ASSERT(0); // abort fallback requested
1675       } // no sense to look for another fallback because of same internal alloc
1676     }
1677   } else {
1678     // custom allocator, pool size not requested
1679     ptr = __kmp_thread_malloc(__kmp_thread_from_gtid(gtid), desc.size_a);
1680     if (ptr == NULL && al->fb == omp_atv_abort_fb) {
1681       KMP_ASSERT(0); // abort fallback requested
1682     } // no sense to look for another fallback because of same internal alloc
1683   }
1684   KE_TRACE(10, ("__kmp_alloc: T#%d %p=alloc(%d)\n", gtid, ptr, desc.size_a));
1685   if (ptr == NULL)
1686     return NULL;
1687 
1688   addr = (kmp_uintptr_t)ptr;
1689   addr_align = (addr + sz_desc + align - 1) & ~(align - 1);
1690   addr_descr = addr_align - sz_desc;
1691 
1692   desc.ptr_alloc = ptr;
1693   desc.ptr_align = (void *)addr_align;
1694   desc.allocator = al;
1695   *((kmp_mem_desc_t *)addr_descr) = desc; // save descriptor contents
1696   KMP_MB();
1697 
1698   return desc.ptr_align;
1699 }
1700 
1701 void *__kmp_calloc(int gtid, size_t algn, size_t nmemb, size_t size,
1702                    omp_allocator_handle_t allocator) {
1703   void *ptr = NULL;
1704   kmp_allocator_t *al;
1705   KMP_DEBUG_ASSERT(__kmp_init_serial);
1706 
1707   if (allocator == omp_null_allocator)
1708     allocator = __kmp_threads[gtid]->th.th_def_allocator;
1709 
1710   al = RCAST(kmp_allocator_t *, allocator);
1711 
1712   if (nmemb == 0 || size == 0)
1713     return ptr;
1714 
1715   if ((SIZE_MAX - sizeof(kmp_mem_desc_t)) / size < nmemb) {
1716     if (al->fb == omp_atv_abort_fb) {
1717       KMP_ASSERT(0);
1718     }
1719     return ptr;
1720   }
1721 
1722   ptr = __kmp_alloc(gtid, algn, nmemb * size, allocator);
1723 
1724   if (ptr) {
1725     memset(ptr, 0x00, nmemb * size);
1726   }
1727   return ptr;
1728 }
1729 
1730 void *__kmp_realloc(int gtid, void *ptr, size_t size,
1731                     omp_allocator_handle_t allocator,
1732                     omp_allocator_handle_t free_allocator) {
1733   void *nptr = NULL;
1734   KMP_DEBUG_ASSERT(__kmp_init_serial);
1735 
1736   if (size == 0) {
1737     if (ptr != NULL)
1738       ___kmpc_free(gtid, ptr, free_allocator);
1739     return nptr;
1740   }
1741 
1742   nptr = __kmp_alloc(gtid, 0, size, allocator);
1743 
1744   if (nptr != NULL && ptr != NULL) {
1745     kmp_mem_desc_t desc;
1746     kmp_uintptr_t addr_align; // address to return to caller
1747     kmp_uintptr_t addr_descr; // address of memory block descriptor
1748 
1749     addr_align = (kmp_uintptr_t)ptr;
1750     addr_descr = addr_align - sizeof(kmp_mem_desc_t);
1751     desc = *((kmp_mem_desc_t *)addr_descr); // read descriptor
1752 
1753     KMP_DEBUG_ASSERT(desc.ptr_align == ptr);
1754     KMP_DEBUG_ASSERT(desc.size_orig > 0);
1755     KMP_DEBUG_ASSERT(desc.size_orig < desc.size_a);
1756     KMP_MEMCPY((char *)nptr, (char *)ptr,
1757                (size_t)((size < desc.size_orig) ? size : desc.size_orig));
1758   }
1759 
1760   if (nptr != NULL) {
1761     ___kmpc_free(gtid, ptr, free_allocator);
1762   }
1763 
1764   return nptr;
1765 }
1766 
1767 void ___kmpc_free(int gtid, void *ptr, omp_allocator_handle_t allocator) {
1768   if (ptr == NULL)
1769     return;
1770 
1771   kmp_allocator_t *al;
1772   omp_allocator_handle_t oal;
1773   al = RCAST(kmp_allocator_t *, CCAST(omp_allocator_handle_t, allocator));
1774   kmp_mem_desc_t desc;
1775   kmp_uintptr_t addr_align; // address to return to caller
1776   kmp_uintptr_t addr_descr; // address of memory block descriptor
1777   if (KMP_IS_TARGET_MEM_ALLOC(allocator) ||
1778       (allocator > kmp_max_mem_alloc &&
1779        KMP_IS_TARGET_MEM_SPACE(al->memspace))) {
1780     KMP_DEBUG_ASSERT(kmp_target_free);
1781     kmp_int32 device =
1782         __kmp_threads[gtid]->th.th_current_task->td_icvs.default_device;
1783     kmp_target_free(ptr, device);
1784     return;
1785   }
1786 
1787   addr_align = (kmp_uintptr_t)ptr;
1788   addr_descr = addr_align - sizeof(kmp_mem_desc_t);
1789   desc = *((kmp_mem_desc_t *)addr_descr); // read descriptor
1790 
1791   KMP_DEBUG_ASSERT(desc.ptr_align == ptr);
1792   if (allocator) {
1793     KMP_DEBUG_ASSERT(desc.allocator == al || desc.allocator == al->fb_data);
1794   }
1795   al = desc.allocator;
1796   oal = (omp_allocator_handle_t)al; // cast to void* for comparisons
1797   KMP_DEBUG_ASSERT(al);
1798 
1799   if (__kmp_memkind_available) {
1800     if (oal < kmp_max_mem_alloc) {
1801       // pre-defined allocator
1802       if (oal == omp_high_bw_mem_alloc && mk_hbw_preferred) {
1803         kmp_mk_free(*mk_hbw_preferred, desc.ptr_alloc);
1804       } else if (oal == omp_large_cap_mem_alloc && mk_dax_kmem_all) {
1805         kmp_mk_free(*mk_dax_kmem_all, desc.ptr_alloc);
1806       } else {
1807         kmp_mk_free(*mk_default, desc.ptr_alloc);
1808       }
1809     } else {
1810       if (al->pool_size > 0) { // custom allocator with pool size requested
1811         kmp_uint64 used =
1812             KMP_TEST_THEN_ADD64((kmp_int64 *)&al->pool_used, -desc.size_a);
1813         (void)used; // to suppress compiler warning
1814         KMP_DEBUG_ASSERT(used >= desc.size_a);
1815       }
1816       kmp_mk_free(*al->memkind, desc.ptr_alloc);
1817     }
1818   } else {
1819     if (oal > kmp_max_mem_alloc && al->pool_size > 0) {
1820       kmp_uint64 used =
1821           KMP_TEST_THEN_ADD64((kmp_int64 *)&al->pool_used, -desc.size_a);
1822       (void)used; // to suppress compiler warning
1823       KMP_DEBUG_ASSERT(used >= desc.size_a);
1824     }
1825     __kmp_thread_free(__kmp_thread_from_gtid(gtid), desc.ptr_alloc);
1826   }
1827 }
1828 
1829 /* If LEAK_MEMORY is defined, __kmp_free() will *not* free memory. It causes
1830    memory leaks, but it may be useful for debugging memory corruptions, used
1831    freed pointers, etc. */
1832 /* #define LEAK_MEMORY */
1833 struct kmp_mem_descr { // Memory block descriptor.
1834   void *ptr_allocated; // Pointer returned by malloc(), subject for free().
1835   size_t size_allocated; // Size of allocated memory block.
1836   void *ptr_aligned; // Pointer to aligned memory, to be used by client code.
1837   size_t size_aligned; // Size of aligned memory block.
1838 };
1839 typedef struct kmp_mem_descr kmp_mem_descr_t;
1840 
1841 /* Allocate memory on requested boundary, fill allocated memory with 0x00.
1842    NULL is NEVER returned, __kmp_abort() is called in case of memory allocation
1843    error. Must use __kmp_free when freeing memory allocated by this routine! */
1844 static void *___kmp_allocate_align(size_t size,
1845                                    size_t alignment KMP_SRC_LOC_DECL) {
1846   /* __kmp_allocate() allocates (by call to malloc()) bigger memory block than
1847      requested to return properly aligned pointer. Original pointer returned
1848      by malloc() and size of allocated block is saved in descriptor just
1849      before the aligned pointer. This information used by __kmp_free() -- it
1850      has to pass to free() original pointer, not aligned one.
1851 
1852           +---------+------------+-----------------------------------+---------+
1853           | padding | descriptor |           aligned block           | padding |
1854           +---------+------------+-----------------------------------+---------+
1855           ^                      ^
1856           |                      |
1857           |                      +- Aligned pointer returned to caller
1858           +- Pointer returned by malloc()
1859 
1860       Aligned block is filled with zeros, paddings are filled with 0xEF. */
1861 
1862   kmp_mem_descr_t descr;
1863   kmp_uintptr_t addr_allocated; // Address returned by malloc().
1864   kmp_uintptr_t addr_aligned; // Aligned address to return to caller.
1865   kmp_uintptr_t addr_descr; // Address of memory block descriptor.
1866 
1867   KE_TRACE(25, ("-> ___kmp_allocate_align( %d, %d ) called from %s:%d\n",
1868                 (int)size, (int)alignment KMP_SRC_LOC_PARM));
1869 
1870   KMP_DEBUG_ASSERT(alignment < 32 * 1024); // Alignment should not be too
1871   KMP_DEBUG_ASSERT(sizeof(void *) <= sizeof(kmp_uintptr_t));
1872   // Make sure kmp_uintptr_t is enough to store addresses.
1873 
1874   descr.size_aligned = size;
1875   descr.size_allocated =
1876       descr.size_aligned + sizeof(kmp_mem_descr_t) + alignment;
1877 
1878 #if KMP_DEBUG
1879   descr.ptr_allocated = _malloc_src_loc(descr.size_allocated, _file_, _line_);
1880 #else
1881   descr.ptr_allocated = malloc_src_loc(descr.size_allocated KMP_SRC_LOC_PARM);
1882 #endif
1883   KE_TRACE(10, ("   malloc( %d ) returned %p\n", (int)descr.size_allocated,
1884                 descr.ptr_allocated));
1885   if (descr.ptr_allocated == NULL) {
1886     KMP_FATAL(OutOfHeapMemory);
1887   }
1888 
1889   addr_allocated = (kmp_uintptr_t)descr.ptr_allocated;
1890   addr_aligned =
1891       (addr_allocated + sizeof(kmp_mem_descr_t) + alignment) & ~(alignment - 1);
1892   addr_descr = addr_aligned - sizeof(kmp_mem_descr_t);
1893 
1894   descr.ptr_aligned = (void *)addr_aligned;
1895 
1896   KE_TRACE(26, ("   ___kmp_allocate_align: "
1897                 "ptr_allocated=%p, size_allocated=%d, "
1898                 "ptr_aligned=%p, size_aligned=%d\n",
1899                 descr.ptr_allocated, (int)descr.size_allocated,
1900                 descr.ptr_aligned, (int)descr.size_aligned));
1901 
1902   KMP_DEBUG_ASSERT(addr_allocated <= addr_descr);
1903   KMP_DEBUG_ASSERT(addr_descr + sizeof(kmp_mem_descr_t) == addr_aligned);
1904   KMP_DEBUG_ASSERT(addr_aligned + descr.size_aligned <=
1905                    addr_allocated + descr.size_allocated);
1906   KMP_DEBUG_ASSERT(addr_aligned % alignment == 0);
1907 #ifdef KMP_DEBUG
1908   memset(descr.ptr_allocated, 0xEF, descr.size_allocated);
1909 // Fill allocated memory block with 0xEF.
1910 #endif
1911   memset(descr.ptr_aligned, 0x00, descr.size_aligned);
1912   // Fill the aligned memory block (which is intended for using by caller) with
1913   // 0x00. Do not
1914   // put this filling under KMP_DEBUG condition! Many callers expect zeroed
1915   // memory. (Padding
1916   // bytes remain filled with 0xEF in debugging library.)
1917   *((kmp_mem_descr_t *)addr_descr) = descr;
1918 
1919   KMP_MB();
1920 
1921   KE_TRACE(25, ("<- ___kmp_allocate_align() returns %p\n", descr.ptr_aligned));
1922   return descr.ptr_aligned;
1923 } // func ___kmp_allocate_align
1924 
1925 /* Allocate memory on cache line boundary, fill allocated memory with 0x00.
1926    Do not call this func directly! Use __kmp_allocate macro instead.
1927    NULL is NEVER returned, __kmp_abort() is called in case of memory allocation
1928    error. Must use __kmp_free when freeing memory allocated by this routine! */
1929 void *___kmp_allocate(size_t size KMP_SRC_LOC_DECL) {
1930   void *ptr;
1931   KE_TRACE(25, ("-> __kmp_allocate( %d ) called from %s:%d\n",
1932                 (int)size KMP_SRC_LOC_PARM));
1933   ptr = ___kmp_allocate_align(size, __kmp_align_alloc KMP_SRC_LOC_PARM);
1934   KE_TRACE(25, ("<- __kmp_allocate() returns %p\n", ptr));
1935   return ptr;
1936 } // func ___kmp_allocate
1937 
1938 /* Allocate memory on page boundary, fill allocated memory with 0x00.
1939    Does not call this func directly! Use __kmp_page_allocate macro instead.
1940    NULL is NEVER returned, __kmp_abort() is called in case of memory allocation
1941    error. Must use __kmp_free when freeing memory allocated by this routine! */
1942 void *___kmp_page_allocate(size_t size KMP_SRC_LOC_DECL) {
1943   int page_size = 8 * 1024;
1944   void *ptr;
1945 
1946   KE_TRACE(25, ("-> __kmp_page_allocate( %d ) called from %s:%d\n",
1947                 (int)size KMP_SRC_LOC_PARM));
1948   ptr = ___kmp_allocate_align(size, page_size KMP_SRC_LOC_PARM);
1949   KE_TRACE(25, ("<- __kmp_page_allocate( %d ) returns %p\n", (int)size, ptr));
1950   return ptr;
1951 } // ___kmp_page_allocate
1952 
1953 /* Free memory allocated by __kmp_allocate() and __kmp_page_allocate().
1954    In debug mode, fill the memory block with 0xEF before call to free(). */
1955 void ___kmp_free(void *ptr KMP_SRC_LOC_DECL) {
1956   kmp_mem_descr_t descr;
1957 #if KMP_DEBUG
1958   kmp_uintptr_t addr_allocated; // Address returned by malloc().
1959   kmp_uintptr_t addr_aligned; // Aligned address passed by caller.
1960 #endif
1961   KE_TRACE(25,
1962            ("-> __kmp_free( %p ) called from %s:%d\n", ptr KMP_SRC_LOC_PARM));
1963   KMP_ASSERT(ptr != NULL);
1964 
1965   descr = *(kmp_mem_descr_t *)((kmp_uintptr_t)ptr - sizeof(kmp_mem_descr_t));
1966 
1967   KE_TRACE(26, ("   __kmp_free:     "
1968                 "ptr_allocated=%p, size_allocated=%d, "
1969                 "ptr_aligned=%p, size_aligned=%d\n",
1970                 descr.ptr_allocated, (int)descr.size_allocated,
1971                 descr.ptr_aligned, (int)descr.size_aligned));
1972 #if KMP_DEBUG
1973   addr_allocated = (kmp_uintptr_t)descr.ptr_allocated;
1974   addr_aligned = (kmp_uintptr_t)descr.ptr_aligned;
1975   KMP_DEBUG_ASSERT(addr_aligned % CACHE_LINE == 0);
1976   KMP_DEBUG_ASSERT(descr.ptr_aligned == ptr);
1977   KMP_DEBUG_ASSERT(addr_allocated + sizeof(kmp_mem_descr_t) <= addr_aligned);
1978   KMP_DEBUG_ASSERT(descr.size_aligned < descr.size_allocated);
1979   KMP_DEBUG_ASSERT(addr_aligned + descr.size_aligned <=
1980                    addr_allocated + descr.size_allocated);
1981   memset(descr.ptr_allocated, 0xEF, descr.size_allocated);
1982 // Fill memory block with 0xEF, it helps catch using freed memory.
1983 #endif
1984 
1985 #ifndef LEAK_MEMORY
1986   KE_TRACE(10, ("   free( %p )\n", descr.ptr_allocated));
1987 #ifdef KMP_DEBUG
1988   _free_src_loc(descr.ptr_allocated, _file_, _line_);
1989 #else
1990   free_src_loc(descr.ptr_allocated KMP_SRC_LOC_PARM);
1991 #endif
1992 #endif
1993   KMP_MB();
1994   KE_TRACE(25, ("<- __kmp_free() returns\n"));
1995 } // func ___kmp_free
1996 
1997 #if USE_FAST_MEMORY == 3
1998 // Allocate fast memory by first scanning the thread's free lists
1999 // If a chunk the right size exists, grab it off the free list.
2000 // Otherwise allocate normally using kmp_thread_malloc.
2001 
2002 // AC: How to choose the limit? Just get 16 for now...
2003 #define KMP_FREE_LIST_LIMIT 16
2004 
2005 // Always use 128 bytes for determining buckets for caching memory blocks
2006 #define DCACHE_LINE 128
2007 
2008 void *___kmp_fast_allocate(kmp_info_t *this_thr, size_t size KMP_SRC_LOC_DECL) {
2009   void *ptr;
2010   size_t num_lines, idx;
2011   int index;
2012   void *alloc_ptr;
2013   size_t alloc_size;
2014   kmp_mem_descr_t *descr;
2015 
2016   KE_TRACE(25, ("-> __kmp_fast_allocate( T#%d, %d ) called from %s:%d\n",
2017                 __kmp_gtid_from_thread(this_thr), (int)size KMP_SRC_LOC_PARM));
2018 
2019   num_lines = (size + DCACHE_LINE - 1) / DCACHE_LINE;
2020   idx = num_lines - 1;
2021   KMP_DEBUG_ASSERT(idx >= 0);
2022   if (idx < 2) {
2023     index = 0; // idx is [ 0, 1 ], use first free list
2024     num_lines = 2; // 1, 2 cache lines or less than cache line
2025   } else if ((idx >>= 2) == 0) {
2026     index = 1; // idx is [ 2, 3 ], use second free list
2027     num_lines = 4; // 3, 4 cache lines
2028   } else if ((idx >>= 2) == 0) {
2029     index = 2; // idx is [ 4, 15 ], use third free list
2030     num_lines = 16; // 5, 6, ..., 16 cache lines
2031   } else if ((idx >>= 2) == 0) {
2032     index = 3; // idx is [ 16, 63 ], use fourth free list
2033     num_lines = 64; // 17, 18, ..., 64 cache lines
2034   } else {
2035     goto alloc_call; // 65 or more cache lines ( > 8KB ), don't use free lists
2036   }
2037 
2038   ptr = this_thr->th.th_free_lists[index].th_free_list_self;
2039   if (ptr != NULL) {
2040     // pop the head of no-sync free list
2041     this_thr->th.th_free_lists[index].th_free_list_self = *((void **)ptr);
2042     KMP_DEBUG_ASSERT(this_thr == ((kmp_mem_descr_t *)((kmp_uintptr_t)ptr -
2043                                                       sizeof(kmp_mem_descr_t)))
2044                                      ->ptr_aligned);
2045     goto end;
2046   }
2047   ptr = TCR_SYNC_PTR(this_thr->th.th_free_lists[index].th_free_list_sync);
2048   if (ptr != NULL) {
2049     // no-sync free list is empty, use sync free list (filled in by other
2050     // threads only)
2051     // pop the head of the sync free list, push NULL instead
2052     while (!KMP_COMPARE_AND_STORE_PTR(
2053         &this_thr->th.th_free_lists[index].th_free_list_sync, ptr, nullptr)) {
2054       KMP_CPU_PAUSE();
2055       ptr = TCR_SYNC_PTR(this_thr->th.th_free_lists[index].th_free_list_sync);
2056     }
2057     // push the rest of chain into no-sync free list (can be NULL if there was
2058     // the only block)
2059     this_thr->th.th_free_lists[index].th_free_list_self = *((void **)ptr);
2060     KMP_DEBUG_ASSERT(this_thr == ((kmp_mem_descr_t *)((kmp_uintptr_t)ptr -
2061                                                       sizeof(kmp_mem_descr_t)))
2062                                      ->ptr_aligned);
2063     goto end;
2064   }
2065 
2066 alloc_call:
2067   // haven't found block in the free lists, thus allocate it
2068   size = num_lines * DCACHE_LINE;
2069 
2070   alloc_size = size + sizeof(kmp_mem_descr_t) + DCACHE_LINE;
2071   KE_TRACE(25, ("__kmp_fast_allocate: T#%d Calling __kmp_thread_malloc with "
2072                 "alloc_size %d\n",
2073                 __kmp_gtid_from_thread(this_thr), alloc_size));
2074   alloc_ptr = bget(this_thr, (bufsize)alloc_size);
2075 
2076   // align ptr to DCACHE_LINE
2077   ptr = (void *)((((kmp_uintptr_t)alloc_ptr) + sizeof(kmp_mem_descr_t) +
2078                   DCACHE_LINE) &
2079                  ~(DCACHE_LINE - 1));
2080   descr = (kmp_mem_descr_t *)(((kmp_uintptr_t)ptr) - sizeof(kmp_mem_descr_t));
2081 
2082   descr->ptr_allocated = alloc_ptr; // remember allocated pointer
2083   // we don't need size_allocated
2084   descr->ptr_aligned = (void *)this_thr; // remember allocating thread
2085   // (it is already saved in bget buffer,
2086   // but we may want to use another allocator in future)
2087   descr->size_aligned = size;
2088 
2089 end:
2090   KE_TRACE(25, ("<- __kmp_fast_allocate( T#%d ) returns %p\n",
2091                 __kmp_gtid_from_thread(this_thr), ptr));
2092   return ptr;
2093 } // func __kmp_fast_allocate
2094 
2095 // Free fast memory and place it on the thread's free list if it is of
2096 // the correct size.
2097 void ___kmp_fast_free(kmp_info_t *this_thr, void *ptr KMP_SRC_LOC_DECL) {
2098   kmp_mem_descr_t *descr;
2099   kmp_info_t *alloc_thr;
2100   size_t size;
2101   size_t idx;
2102   int index;
2103 
2104   KE_TRACE(25, ("-> __kmp_fast_free( T#%d, %p ) called from %s:%d\n",
2105                 __kmp_gtid_from_thread(this_thr), ptr KMP_SRC_LOC_PARM));
2106   KMP_ASSERT(ptr != NULL);
2107 
2108   descr = (kmp_mem_descr_t *)(((kmp_uintptr_t)ptr) - sizeof(kmp_mem_descr_t));
2109 
2110   KE_TRACE(26, ("   __kmp_fast_free:     size_aligned=%d\n",
2111                 (int)descr->size_aligned));
2112 
2113   size = descr->size_aligned; // 2, 4, 16, 64, 65, 66, ... cache lines
2114 
2115   idx = DCACHE_LINE * 2; // 2 cache lines is minimal size of block
2116   if (idx == size) {
2117     index = 0; // 2 cache lines
2118   } else if ((idx <<= 1) == size) {
2119     index = 1; // 4 cache lines
2120   } else if ((idx <<= 2) == size) {
2121     index = 2; // 16 cache lines
2122   } else if ((idx <<= 2) == size) {
2123     index = 3; // 64 cache lines
2124   } else {
2125     KMP_DEBUG_ASSERT(size > DCACHE_LINE * 64);
2126     goto free_call; // 65 or more cache lines ( > 8KB )
2127   }
2128 
2129   alloc_thr = (kmp_info_t *)descr->ptr_aligned; // get thread owning the block
2130   if (alloc_thr == this_thr) {
2131     // push block to self no-sync free list, linking previous head (LIFO)
2132     *((void **)ptr) = this_thr->th.th_free_lists[index].th_free_list_self;
2133     this_thr->th.th_free_lists[index].th_free_list_self = ptr;
2134   } else {
2135     void *head = this_thr->th.th_free_lists[index].th_free_list_other;
2136     if (head == NULL) {
2137       // Create new free list
2138       this_thr->th.th_free_lists[index].th_free_list_other = ptr;
2139       *((void **)ptr) = NULL; // mark the tail of the list
2140       descr->size_allocated = (size_t)1; // head of the list keeps its length
2141     } else {
2142       // need to check existed "other" list's owner thread and size of queue
2143       kmp_mem_descr_t *dsc =
2144           (kmp_mem_descr_t *)((char *)head - sizeof(kmp_mem_descr_t));
2145       // allocating thread, same for all queue nodes
2146       kmp_info_t *q_th = (kmp_info_t *)(dsc->ptr_aligned);
2147       size_t q_sz =
2148           dsc->size_allocated + 1; // new size in case we add current task
2149       if (q_th == alloc_thr && q_sz <= KMP_FREE_LIST_LIMIT) {
2150         // we can add current task to "other" list, no sync needed
2151         *((void **)ptr) = head;
2152         descr->size_allocated = q_sz;
2153         this_thr->th.th_free_lists[index].th_free_list_other = ptr;
2154       } else {
2155         // either queue blocks owner is changing or size limit exceeded
2156         // return old queue to allocating thread (q_th) synchronously,
2157         // and start new list for alloc_thr's tasks
2158         void *old_ptr;
2159         void *tail = head;
2160         void *next = *((void **)head);
2161         while (next != NULL) {
2162           KMP_DEBUG_ASSERT(
2163               // queue size should decrease by 1 each step through the list
2164               ((kmp_mem_descr_t *)((char *)next - sizeof(kmp_mem_descr_t)))
2165                       ->size_allocated +
2166                   1 ==
2167               ((kmp_mem_descr_t *)((char *)tail - sizeof(kmp_mem_descr_t)))
2168                   ->size_allocated);
2169           tail = next; // remember tail node
2170           next = *((void **)next);
2171         }
2172         KMP_DEBUG_ASSERT(q_th != NULL);
2173         // push block to owner's sync free list
2174         old_ptr = TCR_PTR(q_th->th.th_free_lists[index].th_free_list_sync);
2175         /* the next pointer must be set before setting free_list to ptr to avoid
2176            exposing a broken list to other threads, even for an instant. */
2177         *((void **)tail) = old_ptr;
2178 
2179         while (!KMP_COMPARE_AND_STORE_PTR(
2180             &q_th->th.th_free_lists[index].th_free_list_sync, old_ptr, head)) {
2181           KMP_CPU_PAUSE();
2182           old_ptr = TCR_PTR(q_th->th.th_free_lists[index].th_free_list_sync);
2183           *((void **)tail) = old_ptr;
2184         }
2185 
2186         // start new list of not-selt tasks
2187         this_thr->th.th_free_lists[index].th_free_list_other = ptr;
2188         *((void **)ptr) = NULL;
2189         descr->size_allocated = (size_t)1; // head of queue keeps its length
2190       }
2191     }
2192   }
2193   goto end;
2194 
2195 free_call:
2196   KE_TRACE(25, ("__kmp_fast_free: T#%d Calling __kmp_thread_free for size %d\n",
2197                 __kmp_gtid_from_thread(this_thr), size));
2198   __kmp_bget_dequeue(this_thr); /* Release any queued buffers */
2199   brel(this_thr, descr->ptr_allocated);
2200 
2201 end:
2202   KE_TRACE(25, ("<- __kmp_fast_free() returns\n"));
2203 
2204 } // func __kmp_fast_free
2205 
2206 // Initialize the thread free lists related to fast memory
2207 // Only do this when a thread is initially created.
2208 void __kmp_initialize_fast_memory(kmp_info_t *this_thr) {
2209   KE_TRACE(10, ("__kmp_initialize_fast_memory: Called from th %p\n", this_thr));
2210 
2211   memset(this_thr->th.th_free_lists, 0, NUM_LISTS * sizeof(kmp_free_list_t));
2212 }
2213 
2214 // Free the memory in the thread free lists related to fast memory
2215 // Only do this when a thread is being reaped (destroyed).
2216 void __kmp_free_fast_memory(kmp_info_t *th) {
2217   // Suppose we use BGET underlying allocator, walk through its structures...
2218   int bin;
2219   thr_data_t *thr = get_thr_data(th);
2220   void **lst = NULL;
2221 
2222   KE_TRACE(
2223       5, ("__kmp_free_fast_memory: Called T#%d\n", __kmp_gtid_from_thread(th)));
2224 
2225   __kmp_bget_dequeue(th); // Release any queued buffers
2226 
2227   // Dig through free lists and extract all allocated blocks
2228   for (bin = 0; bin < MAX_BGET_BINS; ++bin) {
2229     bfhead_t *b = thr->freelist[bin].ql.flink;
2230     while (b != &thr->freelist[bin]) {
2231       if ((kmp_uintptr_t)b->bh.bb.bthr & 1) { // the buffer is allocated address
2232         *((void **)b) =
2233             lst; // link the list (override bthr, but keep flink yet)
2234         lst = (void **)b; // push b into lst
2235       }
2236       b = b->ql.flink; // get next buffer
2237     }
2238   }
2239   while (lst != NULL) {
2240     void *next = *lst;
2241     KE_TRACE(10, ("__kmp_free_fast_memory: freeing %p, next=%p th %p (%d)\n",
2242                   lst, next, th, __kmp_gtid_from_thread(th)));
2243     (*thr->relfcn)(lst);
2244 #if BufStats
2245     // count blocks to prevent problems in __kmp_finalize_bget()
2246     thr->numprel++; /* Nr of expansion block releases */
2247     thr->numpblk--; /* Total number of blocks */
2248 #endif
2249     lst = (void **)next;
2250   }
2251 
2252   KE_TRACE(
2253       5, ("__kmp_free_fast_memory: Freed T#%d\n", __kmp_gtid_from_thread(th)));
2254 }
2255 
2256 #endif // USE_FAST_MEMORY
2257