sksp2024-mcu/libucw/ucw/sorter/array.c

/*
 *	UCW Library -- Optimized Array Sorter
 *
 *	(c) 2003--2007 Martin Mares <mj@ucw.cz>
 *
 *	This software may be freely distributed and used according to the terms
 *	of the GNU Lesser General Public License.
 */

#undef LOCAL_DEBUG

#include <ucw/lib.h>
#include <ucw/sorter/common.h>

#include <string.h>
#include <alloca.h>

#define ASORT_MIN_SHIFT 2

#define ASORT_TRACE(x...) ASORT_XTRACE(1, x)
#define ASORT_XTRACE(level, x...) do { if (sorter_trace_array >= level) msg(L_DEBUG, x); } while(0)

static void
asort_radix(struct asort_context *ctx, void *array, void *buffer, uint num_elts, uint hash_bits, uint swapped_output)
{
  // swap_output == 0 if result should be returned in `array', otherwise in `buffer'
  uint buckets = (1 << ctx->radix_bits);
  uint shift = (hash_bits > ctx->radix_bits) ? (hash_bits - ctx->radix_bits) : 0;
  uint cnt[buckets];

#if 0
  static int reported[64];
  if (!reported[hash_bits]++)
#endif
  DBG(">>> n=%u h=%d s=%d sw=%d", num_elts, hash_bits, shift, swapped_output);

  bzero(cnt, sizeof(cnt));
  ctx->radix_count(array, num_elts, cnt, shift);

  uint pos = 0;
  for (uint i=0; i<buckets; i++)
    {
      uint j = cnt[i];
      cnt[i] = pos;
      pos += j;
    }
  ASSERT(pos == num_elts);

  ctx->radix_split(array, buffer, num_elts, cnt, shift);
  pos = 0;
  for (uint i=0; i<buckets; i++)
    {
      uint n = cnt[i] - pos;
      if (n < ctx->radix_threshold || shift < ASORT_MIN_SHIFT)
	{
	  ctx->quicksort(buffer, n);
	  if (!swapped_output)
	    memcpy(array, buffer, n * ctx->elt_size);
	}
      else
	asort_radix(ctx, buffer, array, n, shift, !swapped_output);
      array += n * ctx->elt_size;
      buffer += n * ctx->elt_size;
      pos = cnt[i];
    }
}

#ifdef CONFIG_UCW_THREADS

#include <ucw/threads.h>
#include <ucw/workqueue.h>
#include <ucw/eltpool.h>

static uint asort_threads_use_count;
static uint asort_threads_ready;
static struct worker_pool asort_thread_pool;

static uint
rs_estimate_stack(void)
{
  // Stack space needed by the recursive radix-sorter
  uint ctrsize = sizeof(uint) * (1 << CONFIG_UCW_RADIX_SORTER_BITS);
  uint maxdepth = (64 / CONFIG_UCW_RADIX_SORTER_BITS) + 1;
  return ctrsize * maxdepth;
}

void
asort_start_threads(uint run)
{
  ucwlib_lock();
  asort_threads_use_count++;
  if (run && !asort_threads_ready)
    {
      // XXX: If somebody overrides the radix-sorter parameters to insane values,
      // he also should override the stack size to insane values.
      asort_thread_pool.stack_size = ucwlib_thread_stack_size + rs_estimate_stack();
      asort_thread_pool.num_threads = sorter_threads;
      ASORT_TRACE("Initializing thread pool (%d threads, %dK stack)", sorter_threads, asort_thread_pool.stack_size >> 10);
      worker_pool_init(&asort_thread_pool);
      asort_threads_ready = 1;
    }
  ucwlib_unlock();
}

void
asort_stop_threads(void)
{
  ucwlib_lock();
  if (!--asort_threads_use_count && asort_threads_ready)
    {
      ASORT_TRACE("Shutting down thread pool");
      worker_pool_cleanup(&asort_thread_pool);
      asort_threads_ready = 0;
    }
  ucwlib_unlock();
}

struct qs_work {
  struct work w;
  struct asort_context *ctx;
  void *array;
  uint num_elts;
  int left, right;
#define LR_UNDEF -100
};

static void
qs_handle_work(struct worker_thread *thr UNUSED, struct work *ww)
{
  struct qs_work *w = (struct qs_work *) ww;
  struct asort_context *ctx = w->ctx;

  DBG("Thread %d: got %u elts", thr->id, w->num_elts);
  if (w->num_elts < ctx->thread_threshold)
    {
      ctx->quicksort(w->array, w->num_elts);
      w->left = w->right = LR_UNDEF;
    }
  else
    ctx->quicksplit(w->array, w->num_elts, &w->left, &w->right);
  DBG("Thread %d: returning l=%u r=%u", thr->id, w->left, w->right);
}

static struct qs_work *
qs_alloc_work(struct asort_context *ctx)
{
  struct qs_work *w = ep_alloc(ctx->eltpool);
  w->w.priority = 0;
  w->w.go = qs_handle_work;
  w->ctx = ctx;
  return w;
}

static void
threaded_quicksort(struct asort_context *ctx)
{
  struct work_queue q;
  struct qs_work *v, *w;

  asort_start_threads(1);
  work_queue_init(&asort_thread_pool, &q);
  ctx->eltpool = ep_new(sizeof(struct qs_work), 1000);

  w = qs_alloc_work(ctx);
  w->array = ctx->array;
  w->num_elts = ctx->num_elts;
  work_submit(&q, &w->w);

  while (v = (struct qs_work *) work_wait(&q))
    {
      if (v->left != LR_UNDEF)
	{
	  if (v->right > 0)
	    {
	      w = qs_alloc_work(ctx);
	      w->array = v->array;
	      w->num_elts = v->right + 1;
	      w->w.priority = v->w.priority + 1;
	      work_submit(&q, &w->w);
	    }
	  if (v->left < (int)v->num_elts - 1)
	    {
	      w = qs_alloc_work(ctx);
	      w->array = v->array + v->left * ctx->elt_size;
	      w->num_elts = v->num_elts - v->left;
	      w->w.priority = v->w.priority + 1;
	      work_submit(&q, &w->w);
	    }
	}
      ep_free(ctx->eltpool, v);
    }

  ep_delete(ctx->eltpool);
  work_queue_cleanup(&q);
  asort_stop_threads();
}

struct rs_work {
  struct work w;
  struct asort_context *ctx;
  void *array, *buffer;		// Like asort_radix().
  uint num_elts;
  uint shift;
  uint swap_output;
  uint cnt[0];
};

static void
rs_count(struct worker_thread *thr UNUSED, struct work *ww)
{
  struct rs_work *w = (struct rs_work *) ww;

  DBG("Thread %d: Counting %u items, shift=%d", thr->id, w->num_elts, w->shift);
  w->ctx->radix_count(w->array, w->num_elts, w->cnt, w->shift);
  DBG("Thread %d: Counting done", thr->id);
}

static void
rs_split(struct worker_thread *thr UNUSED, struct work *ww)
{
  struct rs_work *w = (struct rs_work *) ww;

  DBG("Thread %d: Splitting %u items, shift=%d", thr->id, w->num_elts, w->shift);
  w->ctx->radix_split(w->array, w->buffer, w->num_elts, w->cnt, w->shift);
  DBG("Thread %d: Splitting done", thr->id);
}

static void
rs_finish(struct worker_thread *thr UNUSED, struct work *ww)
{
  struct rs_work *w = (struct rs_work *) ww;

  if (thr)
    DBG("Thread %d: Finishing %u items, shift=%d", thr->id, w->num_elts, w->shift);
  if (w->shift < ASORT_MIN_SHIFT || w->num_elts < w->ctx->radix_threshold)
    {
      w->ctx->quicksort(w->array, w->num_elts);
      if (w->swap_output)
	memcpy(w->buffer, w->array, w->num_elts * w->ctx->elt_size);
    }
  else
    asort_radix(w->ctx, w->array, w->buffer, w->num_elts, w->shift, w->swap_output);
  if (thr)
    DBG("Thread %d: Finishing done", thr->id);
}

static void
rs_wait_small(struct asort_context *ctx)
{
  struct rs_work *w;

  while (w = (struct rs_work *) work_wait(ctx->rs_work_queue))
    {
      DBG("Reaping small chunk of %u items", w->num_elts);
      ep_free(ctx->eltpool, w);
    }
}

static void
rs_radix(struct asort_context *ctx, void *array, void *buffer, uint num_elts, uint hash_bits, uint swapped_output)
{
  uint buckets = (1 << ctx->radix_bits);
  uint shift = (hash_bits > ctx->radix_bits) ? (hash_bits - ctx->radix_bits) : 0;
  uint cnt[buckets];
  uint blksize = num_elts / sorter_threads;
  DBG(">>> n=%u h=%d s=%d blk=%u sw=%d", num_elts, hash_bits, shift, blksize, swapped_output);

  // If there are any small chunks in progress, wait for them to finish
  rs_wait_small(ctx);

  // Start parallel counting
  void *iptr = array;
  for (uint i=0; i<sorter_threads; i++)
    {
      struct rs_work *w = ctx->rs_works[i];
      w->w.priority = 0;
      w->w.go = rs_count;
      w->ctx = ctx;
      w->array = iptr;
      w->buffer = buffer;
      w->num_elts = blksize;
      if (i == sorter_threads-1)
	w->num_elts += num_elts % sorter_threads;
      w->shift = shift;
      iptr += w->num_elts * ctx->elt_size;
      bzero(w->cnt, sizeof(uint) * buckets);
      work_submit(ctx->rs_work_queue, &w->w);
    }

  // Get bucket sizes from the counts
  bzero(cnt, sizeof(cnt));
  for (uint i=0; i<sorter_threads; i++)
    {
      struct rs_work *w = (struct rs_work *) work_wait(ctx->rs_work_queue);
      ASSERT(w);
      for (uint j=0; j<buckets; j++)
	cnt[j] += w->cnt[j];
    }

  // Calculate bucket starts
  uint pos = 0;
  for (uint i=0; i<buckets; i++)
    {
      uint j = cnt[i];
      cnt[i] = pos;
      pos += j;
    }
  ASSERT(pos == num_elts);

  // Start parallel splitting
  for (uint i=0; i<sorter_threads; i++)
    {
      struct rs_work *w = ctx->rs_works[i];
      w->w.go = rs_split;
      for (uint j=0; j<buckets; j++)
	{
	  uint k = w->cnt[j];
	  w->cnt[j] = cnt[j];
	  cnt[j] += k;
	}
      work_submit(ctx->rs_work_queue, &w->w);
    }
  ASSERT(cnt[buckets-1] == num_elts);

  // Wait for splits to finish
  while (work_wait(ctx->rs_work_queue))
    ;

  // Recurse on buckets
  pos = 0;
  for (uint i=0; i<buckets; i++)
    {
      uint n = cnt[i] - pos;
      if (!n)
	continue;
      if (n < ctx->thread_threshold || shift < ASORT_MIN_SHIFT)
	{
	  struct rs_work *w = ep_alloc(ctx->eltpool);
	  w->w.priority = 0;
	  w->w.go = rs_finish;
	  w->ctx = ctx;
	  w->array = buffer;
	  w->buffer = array;
	  w->num_elts = n;
	  w->shift = shift;
	  w->swap_output = !swapped_output;
	  if (n < ctx->thread_chunk)
	    {
	      DBG("Sorting block %u+%u inline", pos, n);
	      rs_finish(NULL, &w->w);
	      ep_free(ctx->eltpool, w);
	    }
	  else
	    {
	      DBG("Scheduling block %u+%u", pos, n);
	      work_submit(ctx->rs_work_queue, &w->w);
	    }
	}
      else
	rs_radix(ctx, buffer, array, n, shift, !swapped_output);
      pos = cnt[i];
      array += n * ctx->elt_size;
      buffer += n * ctx->elt_size;
    }
}

static void
threaded_radixsort(struct asort_context *ctx, uint swap)
{
  struct work_queue q;

  asort_start_threads(1);
  work_queue_init(&asort_thread_pool, &q);

  // Prepare work structures for counting and splitting.
  // We use big_alloc(), because we want to avoid cacheline aliasing between threads.
  ctx->rs_work_queue = &q;
  ctx->rs_works = alloca(sizeof(struct rs_work *) * sorter_threads);
  for (uint i=0; i<sorter_threads; i++)
    ctx->rs_works[i] = big_alloc(sizeof(struct rs_work) + sizeof(uint) * (1 << ctx->radix_bits));

  // Prepare a pool for all remaining small bits which will be sorted on background.
  ctx->eltpool = ep_new(sizeof(struct rs_work), 1000);

  // Do the big splitting
  rs_radix(ctx, ctx->array, ctx->buffer, ctx->num_elts, ctx->hash_bits, swap);
  for (uint i=0; i<sorter_threads; i++)
    big_free(ctx->rs_works[i], sizeof(struct rs_work) + sizeof(uint) * (1 << ctx->radix_bits));

  // Finish the small blocks
  rs_wait_small(ctx);

  ASSERT(!ctx->eltpool->num_allocated);
  ep_delete(ctx->eltpool);
  work_queue_cleanup(&q);
  asort_stop_threads();
}

#else

void asort_start_threads(uint run UNUSED) { }
void asort_stop_threads(void) { }

#endif

static uint
predict_swap(struct asort_context *ctx)
{
  uint bits = ctx->radix_bits;
  uint elts = ctx->num_elts;
  uint swap = 0;

  while (elts >= ctx->radix_threshold && bits >= ASORT_MIN_SHIFT)
    {
      DBG("Predicting pass: %u elts, %d bits", elts, bits);
      swap = !swap;
      elts >>= ctx->radix_bits;
      bits = MAX(bits, ctx->radix_bits) - ctx->radix_bits;
    }
  return swap;
}

void
asort_run(struct asort_context *ctx)
{
  ctx->thread_threshold = MIN(sorter_thread_threshold / ctx->elt_size, ~0U);
  ctx->thread_chunk = MIN(sorter_thread_chunk / ctx->elt_size, ~0U);
  ctx->radix_threshold = MIN(sorter_radix_threshold / ctx->elt_size, ~0U);

  ASORT_TRACE("Array-sorting %u items per %u bytes, hash_bits=%d", ctx->num_elts, ctx->elt_size, ctx->hash_bits);
  ASORT_XTRACE(2, "Limits: thread_threshold=%u, thread_chunk=%u, radix_threshold=%u",
	ctx->thread_threshold, ctx->thread_chunk, ctx->radix_threshold);
  uint allow_threads UNUSED = (sorter_threads > 1 &&
			      ctx->num_elts >= ctx->thread_threshold &&
			      !(sorter_debug & SORT_DEBUG_ASORT_NO_THREADS));

  if (ctx->num_elts < ctx->radix_threshold ||
      ctx->hash_bits <= ASORT_MIN_SHIFT ||
      !ctx->radix_split ||
      (sorter_debug & SORT_DEBUG_ASORT_NO_RADIX))
    {
#ifdef CONFIG_UCW_THREADS
      if (allow_threads)
	{
	  ASORT_XTRACE(2, "Decided to use parallel quicksort");
	  threaded_quicksort(ctx);
	}
      else
#endif
	{
	  ASORT_XTRACE(2, "Decided to use sequential quicksort");
	  ctx->quicksort(ctx->array, ctx->num_elts);
	}
    }
  else
    {
      uint swap = predict_swap(ctx);
#ifdef CONFIG_UCW_THREADS
      if (allow_threads)
	{
	  ASORT_XTRACE(2, "Decided to use parallel radix-sort (swap=%d)", swap);
	  threaded_radixsort(ctx, swap);
	}
      else
#endif
	{
	  ASORT_XTRACE(2, "Decided to use sequential radix-sort (swap=%d)", swap);
	  asort_radix(ctx, ctx->array, ctx->buffer, ctx->num_elts, ctx->hash_bits, swap);
	}
      if (swap)
	ctx->array = ctx->buffer;
    }

  ASORT_XTRACE(2, "Array-sort finished");
}
Imported libucw 2 months ago			`/*`
			`* UCW Library -- Optimized Array Sorter`
			`*`
			`* (c) 2003--2007 Martin Mares <mj@ucw.cz>`
			`*`
			`* This software may be freely distributed and used according to the terms`
			`* of the GNU Lesser General Public License.`
			`*/`

			`#undef LOCAL_DEBUG`

			`#include <ucw/lib.h>`
			`#include <ucw/sorter/common.h>`

			`#include <string.h>`
			`#include <alloca.h>`

			`#define ASORT_MIN_SHIFT 2`

			`#define ASORT_TRACE(x...) ASORT_XTRACE(1, x)`
			`#define ASORT_XTRACE(level, x...) do { if (sorter_trace_array >= level) msg(L_DEBUG, x); } while(0)`

			`static void`
			`asort_radix(struct asort_context ctx, void array, void *buffer, uint num_elts, uint hash_bits, uint swapped_output)`
			`{`
			// swap_output == 0 if result should be returned in `array', otherwise in `buffer'
			`uint buckets = (1 << ctx->radix_bits);`
			`uint shift = (hash_bits > ctx->radix_bits) ? (hash_bits - ctx->radix_bits) : 0;`
			`uint cnt[buckets];`

			`#if 0`
			`static int reported[64];`
			`if (!reported[hash_bits]++)`
			`#endif`
			`DBG(">>> n=%u h=%d s=%d sw=%d", num_elts, hash_bits, shift, swapped_output);`

			`bzero(cnt, sizeof(cnt));`
			`ctx->radix_count(array, num_elts, cnt, shift);`

			`uint pos = 0;`
			`for (uint i=0; i<buckets; i++)`
			`{`
			`uint j = cnt[i];`
			`cnt[i] = pos;`
			`pos += j;`
			`}`
			`ASSERT(pos == num_elts);`

			`ctx->radix_split(array, buffer, num_elts, cnt, shift);`
			`pos = 0;`
			`for (uint i=0; i<buckets; i++)`
			`{`
			`uint n = cnt[i] - pos;`
			`if (n < ctx->radix_threshold \|\| shift < ASORT_MIN_SHIFT)`
			`{`
			`ctx->quicksort(buffer, n);`
			`if (!swapped_output)`
			`memcpy(array, buffer, n * ctx->elt_size);`
			`}`
			`else`
			`asort_radix(ctx, buffer, array, n, shift, !swapped_output);`
			`array += n * ctx->elt_size;`
			`buffer += n * ctx->elt_size;`
			`pos = cnt[i];`
			`}`
			`}`

			`#ifdef CONFIG_UCW_THREADS`

			`#include <ucw/threads.h>`
			`#include <ucw/workqueue.h>`
			`#include <ucw/eltpool.h>`

			`static uint asort_threads_use_count;`
			`static uint asort_threads_ready;`
			`static struct worker_pool asort_thread_pool;`

			`static uint`
			`rs_estimate_stack(void)`
			`{`
			`// Stack space needed by the recursive radix-sorter`
			`uint ctrsize = sizeof(uint) * (1 << CONFIG_UCW_RADIX_SORTER_BITS);`
			`uint maxdepth = (64 / CONFIG_UCW_RADIX_SORTER_BITS) + 1;`
			`return ctrsize * maxdepth;`
			`}`

			`void`
			`asort_start_threads(uint run)`
			`{`
			`ucwlib_lock();`
			`asort_threads_use_count++;`
			`if (run && !asort_threads_ready)`
			`{`
			`// XXX: If somebody overrides the radix-sorter parameters to insane values,`
			`// he also should override the stack size to insane values.`
			`asort_thread_pool.stack_size = ucwlib_thread_stack_size + rs_estimate_stack();`
			`asort_thread_pool.num_threads = sorter_threads;`
			`ASORT_TRACE("Initializing thread pool (%d threads, %dK stack)", sorter_threads, asort_thread_pool.stack_size >> 10);`
			`worker_pool_init(&asort_thread_pool);`
			`asort_threads_ready = 1;`
			`}`
			`ucwlib_unlock();`
			`}`

			`void`
			`asort_stop_threads(void)`
			`{`
			`ucwlib_lock();`
			`if (!--asort_threads_use_count && asort_threads_ready)`
			`{`
			`ASORT_TRACE("Shutting down thread pool");`
			`worker_pool_cleanup(&asort_thread_pool);`
			`asort_threads_ready = 0;`
			`}`
			`ucwlib_unlock();`
			`}`

			`struct qs_work {`
			`struct work w;`
			`struct asort_context *ctx;`
			`void *array;`
			`uint num_elts;`
			`int left, right;`
			`#define LR_UNDEF -100`
			`};`

			`static void`
			`qs_handle_work(struct worker_thread thr UNUSED, struct work ww)`
			`{`
			`struct qs_work w = (struct qs_work ) ww;`
			`struct asort_context *ctx = w->ctx;`

			`DBG("Thread %d: got %u elts", thr->id, w->num_elts);`
			`if (w->num_elts < ctx->thread_threshold)`
			`{`
			`ctx->quicksort(w->array, w->num_elts);`
			`w->left = w->right = LR_UNDEF;`
			`}`
			`else`
			`ctx->quicksplit(w->array, w->num_elts, &w->left, &w->right);`
			`DBG("Thread %d: returning l=%u r=%u", thr->id, w->left, w->right);`
			`}`

			`static struct qs_work *`
			`qs_alloc_work(struct asort_context *ctx)`
			`{`
			`struct qs_work *w = ep_alloc(ctx->eltpool);`
			`w->w.priority = 0;`
			`w->w.go = qs_handle_work;`
			`w->ctx = ctx;`
			`return w;`
			`}`

			`static void`
			`threaded_quicksort(struct asort_context *ctx)`
			`{`
			`struct work_queue q;`
			`struct qs_work v, w;`

			`asort_start_threads(1);`
			`work_queue_init(&asort_thread_pool, &q);`
			`ctx->eltpool = ep_new(sizeof(struct qs_work), 1000);`

			`w = qs_alloc_work(ctx);`
			`w->array = ctx->array;`
			`w->num_elts = ctx->num_elts;`
			`work_submit(&q, &w->w);`

			`while (v = (struct qs_work *) work_wait(&q))`
			`{`
			`if (v->left != LR_UNDEF)`
			`{`
			`if (v->right > 0)`
			`{`
			`w = qs_alloc_work(ctx);`
			`w->array = v->array;`
			`w->num_elts = v->right + 1;`
			`w->w.priority = v->w.priority + 1;`
			`work_submit(&q, &w->w);`
			`}`
			`if (v->left < (int)v->num_elts - 1)`
			`{`
			`w = qs_alloc_work(ctx);`
			`w->array = v->array + v->left * ctx->elt_size;`
			`w->num_elts = v->num_elts - v->left;`
			`w->w.priority = v->w.priority + 1;`
			`work_submit(&q, &w->w);`
			`}`
			`}`
			`ep_free(ctx->eltpool, v);`
			`}`

			`ep_delete(ctx->eltpool);`
			`work_queue_cleanup(&q);`
			`asort_stop_threads();`
			`}`

			`struct rs_work {`
			`struct work w;`
			`struct asort_context *ctx;`
			`void array, buffer; // Like asort_radix().`
			`uint num_elts;`
			`uint shift;`
			`uint swap_output;`
			`uint cnt[0];`
			`};`

			`static void`
			`rs_count(struct worker_thread thr UNUSED, struct work ww)`
			`{`
			`struct rs_work w = (struct rs_work ) ww;`

			`DBG("Thread %d: Counting %u items, shift=%d", thr->id, w->num_elts, w->shift);`
			`w->ctx->radix_count(w->array, w->num_elts, w->cnt, w->shift);`
			`DBG("Thread %d: Counting done", thr->id);`
			`}`

			`static void`
			`rs_split(struct worker_thread thr UNUSED, struct work ww)`
			`{`
			`struct rs_work w = (struct rs_work ) ww;`

			`DBG("Thread %d: Splitting %u items, shift=%d", thr->id, w->num_elts, w->shift);`
			`w->ctx->radix_split(w->array, w->buffer, w->num_elts, w->cnt, w->shift);`
			`DBG("Thread %d: Splitting done", thr->id);`
			`}`

			`static void`
			`rs_finish(struct worker_thread thr UNUSED, struct work ww)`
			`{`
			`struct rs_work w = (struct rs_work ) ww;`

			`if (thr)`
			`DBG("Thread %d: Finishing %u items, shift=%d", thr->id, w->num_elts, w->shift);`
			`if (w->shift < ASORT_MIN_SHIFT \|\| w->num_elts < w->ctx->radix_threshold)`
			`{`
			`w->ctx->quicksort(w->array, w->num_elts);`
			`if (w->swap_output)`
			`memcpy(w->buffer, w->array, w->num_elts * w->ctx->elt_size);`
			`}`
			`else`
			`asort_radix(w->ctx, w->array, w->buffer, w->num_elts, w->shift, w->swap_output);`
			`if (thr)`
			`DBG("Thread %d: Finishing done", thr->id);`
			`}`

			`static void`
			`rs_wait_small(struct asort_context *ctx)`
			`{`
			`struct rs_work *w;`

			`while (w = (struct rs_work *) work_wait(ctx->rs_work_queue))`
			`{`
			`DBG("Reaping small chunk of %u items", w->num_elts);`
			`ep_free(ctx->eltpool, w);`
			`}`
			`}`

			`static void`
			`rs_radix(struct asort_context ctx, void array, void *buffer, uint num_elts, uint hash_bits, uint swapped_output)`
			`{`
			`uint buckets = (1 << ctx->radix_bits);`
			`uint shift = (hash_bits > ctx->radix_bits) ? (hash_bits - ctx->radix_bits) : 0;`
			`uint cnt[buckets];`
			`uint blksize = num_elts / sorter_threads;`
			`DBG(">>> n=%u h=%d s=%d blk=%u sw=%d", num_elts, hash_bits, shift, blksize, swapped_output);`

			`// If there are any small chunks in progress, wait for them to finish`
			`rs_wait_small(ctx);`

			`// Start parallel counting`
			`void *iptr = array;`
			`for (uint i=0; i<sorter_threads; i++)`
			`{`
			`struct rs_work *w = ctx->rs_works[i];`
			`w->w.priority = 0;`
			`w->w.go = rs_count;`
			`w->ctx = ctx;`
			`w->array = iptr;`
			`w->buffer = buffer;`
			`w->num_elts = blksize;`
			`if (i == sorter_threads-1)`
			`w->num_elts += num_elts % sorter_threads;`
			`w->shift = shift;`
			`iptr += w->num_elts * ctx->elt_size;`
			`bzero(w->cnt, sizeof(uint) * buckets);`
			`work_submit(ctx->rs_work_queue, &w->w);`
			`}`

			`// Get bucket sizes from the counts`
			`bzero(cnt, sizeof(cnt));`
			`for (uint i=0; i<sorter_threads; i++)`
			`{`
			`struct rs_work w = (struct rs_work ) work_wait(ctx->rs_work_queue);`
			`ASSERT(w);`
			`for (uint j=0; j<buckets; j++)`
			`cnt[j] += w->cnt[j];`
			`}`

			`// Calculate bucket starts`
			`uint pos = 0;`
			`for (uint i=0; i<buckets; i++)`
			`{`
			`uint j = cnt[i];`
			`cnt[i] = pos;`
			`pos += j;`
			`}`
			`ASSERT(pos == num_elts);`

			`// Start parallel splitting`
			`for (uint i=0; i<sorter_threads; i++)`
			`{`
			`struct rs_work *w = ctx->rs_works[i];`
			`w->w.go = rs_split;`
			`for (uint j=0; j<buckets; j++)`
			`{`
			`uint k = w->cnt[j];`
			`w->cnt[j] = cnt[j];`
			`cnt[j] += k;`
			`}`
			`work_submit(ctx->rs_work_queue, &w->w);`
			`}`
			`ASSERT(cnt[buckets-1] == num_elts);`

			`// Wait for splits to finish`
			`while (work_wait(ctx->rs_work_queue))`
			`;`

			`// Recurse on buckets`
			`pos = 0;`
			`for (uint i=0; i<buckets; i++)`
			`{`
			`uint n = cnt[i] - pos;`
			`if (!n)`
			`continue;`
			`if (n < ctx->thread_threshold \|\| shift < ASORT_MIN_SHIFT)`
			`{`
			`struct rs_work *w = ep_alloc(ctx->eltpool);`
			`w->w.priority = 0;`
			`w->w.go = rs_finish;`
			`w->ctx = ctx;`
			`w->array = buffer;`
			`w->buffer = array;`
			`w->num_elts = n;`
			`w->shift = shift;`
			`w->swap_output = !swapped_output;`
			`if (n < ctx->thread_chunk)`
			`{`
			`DBG("Sorting block %u+%u inline", pos, n);`
			`rs_finish(NULL, &w->w);`
			`ep_free(ctx->eltpool, w);`
			`}`
			`else`
			`{`
			`DBG("Scheduling block %u+%u", pos, n);`
			`work_submit(ctx->rs_work_queue, &w->w);`
			`}`
			`}`
			`else`
			`rs_radix(ctx, buffer, array, n, shift, !swapped_output);`
			`pos = cnt[i];`
			`array += n * ctx->elt_size;`
			`buffer += n * ctx->elt_size;`
			`}`
			`}`

			`static void`
			`threaded_radixsort(struct asort_context *ctx, uint swap)`
			`{`
			`struct work_queue q;`

			`asort_start_threads(1);`
			`work_queue_init(&asort_thread_pool, &q);`

			`// Prepare work structures for counting and splitting.`
			`// We use big_alloc(), because we want to avoid cacheline aliasing between threads.`
			`ctx->rs_work_queue = &q;`
			`ctx->rs_works = alloca(sizeof(struct rs_work ) sorter_threads);`
			`for (uint i=0; i<sorter_threads; i++)`
			`ctx->rs_works[i] = big_alloc(sizeof(struct rs_work) + sizeof(uint) * (1 << ctx->radix_bits));`

			`// Prepare a pool for all remaining small bits which will be sorted on background.`
			`ctx->eltpool = ep_new(sizeof(struct rs_work), 1000);`

			`// Do the big splitting`
			`rs_radix(ctx, ctx->array, ctx->buffer, ctx->num_elts, ctx->hash_bits, swap);`
			`for (uint i=0; i<sorter_threads; i++)`
			`big_free(ctx->rs_works[i], sizeof(struct rs_work) + sizeof(uint) * (1 << ctx->radix_bits));`

			`// Finish the small blocks`
			`rs_wait_small(ctx);`

			`ASSERT(!ctx->eltpool->num_allocated);`
			`ep_delete(ctx->eltpool);`
			`work_queue_cleanup(&q);`
			`asort_stop_threads();`
			`}`

			`#else`

			`void asort_start_threads(uint run UNUSED) { }`
			`void asort_stop_threads(void) { }`

			`#endif`

			`static uint`
			`predict_swap(struct asort_context *ctx)`
			`{`
			`uint bits = ctx->radix_bits;`
			`uint elts = ctx->num_elts;`
			`uint swap = 0;`

			`while (elts >= ctx->radix_threshold && bits >= ASORT_MIN_SHIFT)`
			`{`
			`DBG("Predicting pass: %u elts, %d bits", elts, bits);`
			`swap = !swap;`
			`elts >>= ctx->radix_bits;`
			`bits = MAX(bits, ctx->radix_bits) - ctx->radix_bits;`
			`}`
			`return swap;`
			`}`

			`void`
			`asort_run(struct asort_context *ctx)`
			`{`
			`ctx->thread_threshold = MIN(sorter_thread_threshold / ctx->elt_size, ~0U);`
			`ctx->thread_chunk = MIN(sorter_thread_chunk / ctx->elt_size, ~0U);`
			`ctx->radix_threshold = MIN(sorter_radix_threshold / ctx->elt_size, ~0U);`

			`ASORT_TRACE("Array-sorting %u items per %u bytes, hash_bits=%d", ctx->num_elts, ctx->elt_size, ctx->hash_bits);`
			`ASORT_XTRACE(2, "Limits: thread_threshold=%u, thread_chunk=%u, radix_threshold=%u",`
			`ctx->thread_threshold, ctx->thread_chunk, ctx->radix_threshold);`
			`uint allow_threads UNUSED = (sorter_threads > 1 &&`
			`ctx->num_elts >= ctx->thread_threshold &&`
			`!(sorter_debug & SORT_DEBUG_ASORT_NO_THREADS));`

			`if (ctx->num_elts < ctx->radix_threshold \|\|`
			`ctx->hash_bits <= ASORT_MIN_SHIFT \|\|`
			`!ctx->radix_split \|\|`
			`(sorter_debug & SORT_DEBUG_ASORT_NO_RADIX))`
			`{`
			`#ifdef CONFIG_UCW_THREADS`
			`if (allow_threads)`
			`{`
			`ASORT_XTRACE(2, "Decided to use parallel quicksort");`
			`threaded_quicksort(ctx);`
			`}`
			`else`
			`#endif`
			`{`
			`ASORT_XTRACE(2, "Decided to use sequential quicksort");`
			`ctx->quicksort(ctx->array, ctx->num_elts);`
			`}`
			`}`
			`else`
			`{`
			`uint swap = predict_swap(ctx);`
			`#ifdef CONFIG_UCW_THREADS`
			`if (allow_threads)`
			`{`
			`ASORT_XTRACE(2, "Decided to use parallel radix-sort (swap=%d)", swap);`
			`threaded_radixsort(ctx, swap);`
			`}`
			`else`
			`#endif`
			`{`
			`ASORT_XTRACE(2, "Decided to use sequential radix-sort (swap=%d)", swap);`
			`asort_radix(ctx, ctx->array, ctx->buffer, ctx->num_elts, ctx->hash_bits, swap);`
			`}`
			`if (swap)`
			`ctx->array = ctx->buffer;`
			`}`

			`ASORT_XTRACE(2, "Array-sort finished");`
			`}`