cell.c 82.3 KB
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/*******************************************************************************
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 * This file is part of SWIFT.
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 * Copyright (c) 2012 Pedro Gonnet (pedro.gonnet@durham.ac.uk)
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 *                    Matthieu Schaller (matthieu.schaller@durham.ac.uk)
 *               2015 Peter W. Draper (p.w.draper@durham.ac.uk)
 *               2016 John A. Regan (john.a.regan@durham.ac.uk)
 *                    Tom Theuns (tom.theuns@durham.ac.uk)
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 *
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 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU Lesser General Public License as published
 * by the Free Software Foundation, either version 3 of the License, or
 * (at your option) any later version.
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 *
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 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
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 *
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 * You should have received a copy of the GNU Lesser General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
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 *
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 ******************************************************************************/

/* Config parameters. */
#include "../config.h"

/* Some standard headers. */
#include <float.h>
#include <limits.h>
#include <math.h>
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#include <pthread.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
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/* MPI headers. */
#ifdef WITH_MPI
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#include <mpi.h>
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#endif

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/* Switch off timers. */
#ifdef TIMER
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#undef TIMER
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#endif

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/* This object's header. */
#include "cell.h"

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/* Local headers. */
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#include "active.h"
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#include "atomic.h"
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#include "drift.h"
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#include "engine.h"
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#include "error.h"
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#include "gravity.h"
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#include "hydro.h"
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#include "hydro_properties.h"
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#include "memswap.h"
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#include "minmax.h"
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#include "scheduler.h"
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#include "space.h"
#include "timers.h"
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/* Global variables. */
int cell_next_tag = 0;

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/**
 * @brief Get the size of the cell subtree.
 *
 * @param c The #cell.
 */
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int cell_getsize(struct cell *c) {
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  /* Number of cells in this subtree. */
  int count = 1;
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  /* Sum up the progeny if split. */
  if (c->split)
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    for (int k = 0; k < 8; k++)
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      if (c->progeny[k] != NULL) count += cell_getsize(c->progeny[k]);

  /* Return the final count. */
  return count;
}

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/**
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 * @brief Link the cells recursively to the given #part array.
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 *
 * @param c The #cell.
 * @param parts The #part array.
 *
 * @return The number of particles linked.
 */
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int cell_link_parts(struct cell *c, struct part *parts) {
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  c->parts = parts;

  /* Fill the progeny recursively, depth-first. */
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  if (c->split) {
    int offset = 0;
    for (int k = 0; k < 8; k++) {
      if (c->progeny[k] != NULL)
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        offset += cell_link_parts(c->progeny[k], &parts[offset]);
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    }
  }
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  /* Return the total number of linked particles. */
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  return c->count;
}
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/**
 * @brief Link the cells recursively to the given #gpart array.
 *
 * @param c The #cell.
 * @param gparts The #gpart array.
 *
 * @return The number of particles linked.
 */
int cell_link_gparts(struct cell *c, struct gpart *gparts) {

  c->gparts = gparts;

  /* Fill the progeny recursively, depth-first. */
  if (c->split) {
    int offset = 0;
    for (int k = 0; k < 8; k++) {
      if (c->progeny[k] != NULL)
        offset += cell_link_gparts(c->progeny[k], &gparts[offset]);
    }
  }

  /* Return the total number of linked particles. */
  return c->gcount;
}

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/**
 * @brief Link the cells recursively to the given #spart array.
 *
 * @param c The #cell.
 * @param sparts The #spart array.
 *
 * @return The number of particles linked.
 */
int cell_link_sparts(struct cell *c, struct spart *sparts) {

  c->sparts = sparts;

  /* Fill the progeny recursively, depth-first. */
  if (c->split) {
    int offset = 0;
    for (int k = 0; k < 8; k++) {
      if (c->progeny[k] != NULL)
        offset += cell_link_sparts(c->progeny[k], &sparts[offset]);
    }
  }

  /* Return the total number of linked particles. */
  return c->scount;
}

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/**
 * @brief Pack the data of the given cell and all it's sub-cells.
 *
 * @param c The #cell.
 * @param pc Pointer to an array of packed cells in which the
 *      cells will be packed.
 *
 * @return The number of packed cells.
 */
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int cell_pack(struct cell *restrict c, struct pcell *restrict pc) {
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#ifdef WITH_MPI

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  /* Start by packing the data of the current cell. */
  pc->h_max = c->h_max;
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  pc->ti_hydro_end_min = c->ti_hydro_end_min;
  pc->ti_hydro_end_max = c->ti_hydro_end_max;
  pc->ti_gravity_end_min = c->ti_gravity_end_min;
  pc->ti_gravity_end_max = c->ti_gravity_end_max;
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  pc->ti_old_part = c->ti_old_part;
  pc->ti_old_gpart = c->ti_old_gpart;
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  pc->ti_old_multipole = c->ti_old_multipole;
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  pc->count = c->count;
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  pc->gcount = c->gcount;
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  pc->scount = c->scount;
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  c->tag = pc->tag = atomic_inc(&cell_next_tag) % cell_max_tag;
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#ifdef SWIFT_DEBUG_CHECKS
  pc->cellID = c->cellID;
#endif
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  /* Fill in the progeny, depth-first recursion. */
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  int count = 1;
  for (int k = 0; k < 8; k++)
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    if (c->progeny[k] != NULL) {
      pc->progeny[k] = count;
      count += cell_pack(c->progeny[k], &pc[count]);
    } else
      pc->progeny[k] = -1;

  /* Return the number of packed cells used. */
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  c->pcell_size = count;
  return count;
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#else
  error("SWIFT was not compiled with MPI support.");
  return 0;
#endif
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}

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/**
 * @brief Unpack the data of a given cell and its sub-cells.
 *
 * @param pc An array of packed #pcell.
 * @param c The #cell in which to unpack the #pcell.
 * @param s The #space in which the cells are created.
 *
 * @return The number of cells created.
 */
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int cell_unpack(struct pcell *restrict pc, struct cell *restrict c,
                struct space *restrict s) {
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#ifdef WITH_MPI

  /* Unpack the current pcell. */
  c->h_max = pc->h_max;
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  c->ti_hydro_end_min = pc->ti_hydro_end_min;
  c->ti_hydro_end_max = pc->ti_hydro_end_max;
  c->ti_gravity_end_min = pc->ti_gravity_end_min;
  c->ti_gravity_end_max = pc->ti_gravity_end_max;
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  c->ti_old_part = pc->ti_old_part;
  c->ti_old_gpart = pc->ti_old_gpart;
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  c->ti_old_multipole = pc->ti_old_multipole;
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  c->count = pc->count;
  c->gcount = pc->gcount;
  c->scount = pc->scount;
  c->tag = pc->tag;
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#ifdef SWIFT_DEBUG_CHECKS
  c->cellID = pc->cellID;
#endif
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  /* Number of new cells created. */
  int count = 1;

  /* Fill the progeny recursively, depth-first. */
  for (int k = 0; k < 8; k++)
    if (pc->progeny[k] >= 0) {
      struct cell *temp;
      space_getcells(s, 1, &temp);
      temp->count = 0;
      temp->gcount = 0;
      temp->scount = 0;
      temp->loc[0] = c->loc[0];
      temp->loc[1] = c->loc[1];
      temp->loc[2] = c->loc[2];
      temp->width[0] = c->width[0] / 2;
      temp->width[1] = c->width[1] / 2;
      temp->width[2] = c->width[2] / 2;
      temp->dmin = c->dmin / 2;
      if (k & 4) temp->loc[0] += temp->width[0];
      if (k & 2) temp->loc[1] += temp->width[1];
      if (k & 1) temp->loc[2] += temp->width[2];
      temp->depth = c->depth + 1;
      temp->split = 0;
      temp->dx_max_part = 0.f;
      temp->dx_max_gpart = 0.f;
      temp->dx_max_sort = 0.f;
      temp->nodeID = c->nodeID;
      temp->parent = c;
      c->progeny[k] = temp;
      c->split = 1;
      count += cell_unpack(&pc[pc->progeny[k]], temp, s);
    }

  /* Return the total number of unpacked cells. */
  c->pcell_size = count;
  return count;

#else
  error("SWIFT was not compiled with MPI support.");
  return 0;
#endif
}

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/**
 * @brief Pack the time information of the given cell and all it's sub-cells.
 *
 * @param c The #cell.
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 * @param pcells (output) The end-of-timestep information we pack into
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 *
 * @return The number of packed cells.
 */
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int cell_pack_end_step(struct cell *restrict c,
                       struct pcell_step *restrict pcells) {
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#ifdef WITH_MPI

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  /* Pack this cell's data. */
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  pcells[0].ti_hydro_end_min = c->ti_hydro_end_min;
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  pcells[0].ti_hydro_end_max = c->ti_hydro_end_max;
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  pcells[0].ti_gravity_end_min = c->ti_gravity_end_min;
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  pcells[0].ti_gravity_end_max = c->ti_gravity_end_max;
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  pcells[0].dx_max_part = c->dx_max_part;
  pcells[0].dx_max_gpart = c->dx_max_gpart;
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  /* Fill in the progeny, depth-first recursion. */
  int count = 1;
  for (int k = 0; k < 8; k++)
    if (c->progeny[k] != NULL) {
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      count += cell_pack_end_step(c->progeny[k], &pcells[count]);
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    }

  /* Return the number of packed values. */
  return count;
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#else
  error("SWIFT was not compiled with MPI support.");
  return 0;
#endif
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}

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/**
 * @brief Unpack the time information of a given cell and its sub-cells.
 *
 * @param c The #cell
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 * @param pcells The end-of-timestep information to unpack
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 *
 * @return The number of cells created.
 */
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int cell_unpack_end_step(struct cell *restrict c,
                         struct pcell_step *restrict pcells) {
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#ifdef WITH_MPI

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  /* Unpack this cell's data. */
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  c->ti_hydro_end_min = pcells[0].ti_hydro_end_min;
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  c->ti_hydro_end_max = pcells[0].ti_hydro_end_max;
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  c->ti_gravity_end_min = pcells[0].ti_gravity_end_min;
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  c->ti_gravity_end_max = pcells[0].ti_gravity_end_max;
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  c->dx_max_part = pcells[0].dx_max_part;
  c->dx_max_gpart = pcells[0].dx_max_gpart;
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  /* Fill in the progeny, depth-first recursion. */
  int count = 1;
  for (int k = 0; k < 8; k++)
    if (c->progeny[k] != NULL) {
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      count += cell_unpack_end_step(c->progeny[k], &pcells[count]);
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    }

  /* Return the number of packed values. */
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  return count;
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#else
  error("SWIFT was not compiled with MPI support.");
  return 0;
#endif
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}
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/**
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 * @brief Pack the multipole information of the given cell and all it's
 * sub-cells.
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 *
 * @param c The #cell.
 * @param pcells (output) The multipole information we pack into
 *
 * @return The number of packed cells.
 */
int cell_pack_multipoles(struct cell *restrict c,
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                         struct gravity_tensors *restrict pcells) {
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#ifdef WITH_MPI

  /* Pack this cell's data. */
  pcells[0] = *c->multipole;

  /* Fill in the progeny, depth-first recursion. */
  int count = 1;
  for (int k = 0; k < 8; k++)
    if (c->progeny[k] != NULL) {
      count += cell_pack_multipoles(c->progeny[k], &pcells[count]);
    }

  /* Return the number of packed values. */
  return count;

#else
  error("SWIFT was not compiled with MPI support.");
  return 0;
#endif
}

/**
 * @brief Unpack the multipole information of a given cell and its sub-cells.
 *
 * @param c The #cell
 * @param pcells The multipole information to unpack
 *
 * @return The number of cells created.
 */
int cell_unpack_multipoles(struct cell *restrict c,
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                           struct gravity_tensors *restrict pcells) {
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#ifdef WITH_MPI

  /* Unpack this cell's data. */
  *c->multipole = pcells[0];

  /* Fill in the progeny, depth-first recursion. */
  int count = 1;
  for (int k = 0; k < 8; k++)
    if (c->progeny[k] != NULL) {
      count += cell_unpack_multipoles(c->progeny[k], &pcells[count]);
    }

  /* Return the number of packed values. */
  return count;

#else
  error("SWIFT was not compiled with MPI support.");
  return 0;
#endif
}

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/**
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 * @brief Lock a cell for access to its array of #part and hold its parents.
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 *
 * @param c The #cell.
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 * @return 0 on success, 1 on failure
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 */
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int cell_locktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to lock this cell. */
  if (c->hold || lock_trylock(&c->lock) != 0) {
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Did somebody hold this cell in the meantime? */
  if (c->hold) {

    /* Unlock this cell. */
    if (lock_unlock(&c->lock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Climb up the tree and lock/hold/unlock. */
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  struct cell *finger;
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  for (finger = c->parent; finger != NULL; finger = finger->parent) {

    /* Lock this cell. */
    if (lock_trylock(&finger->lock) != 0) break;

    /* Increment the hold. */
    atomic_inc(&finger->hold);

    /* Unlock the cell. */
    if (lock_unlock(&finger->lock) != 0) error("Failed to unlock cell.");
  }

  /* If we reached the top of the tree, we're done. */
  if (finger == NULL) {
    TIMER_TOC(timer_locktree);
    return 0;
  }

  /* Otherwise, we hit a snag. */
  else {

    /* Undo the holds up to finger. */
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    for (struct cell *finger2 = c->parent; finger2 != finger;
         finger2 = finger2->parent)
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      atomic_dec(&finger2->hold);
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    /* Unlock this cell. */
    if (lock_unlock(&c->lock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }
}

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/**
 * @brief Lock a cell for access to its array of #gpart and hold its parents.
 *
 * @param c The #cell.
 * @return 0 on success, 1 on failure
 */
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int cell_glocktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to lock this cell. */
  if (c->ghold || lock_trylock(&c->glock) != 0) {
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Did somebody hold this cell in the meantime? */
  if (c->ghold) {

    /* Unlock this cell. */
    if (lock_unlock(&c->glock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Climb up the tree and lock/hold/unlock. */
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  struct cell *finger;
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  for (finger = c->parent; finger != NULL; finger = finger->parent) {

    /* Lock this cell. */
    if (lock_trylock(&finger->glock) != 0) break;

    /* Increment the hold. */
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    atomic_inc(&finger->ghold);
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    /* Unlock the cell. */
    if (lock_unlock(&finger->glock) != 0) error("Failed to unlock cell.");
  }

  /* If we reached the top of the tree, we're done. */
  if (finger == NULL) {
    TIMER_TOC(timer_locktree);
    return 0;
  }

  /* Otherwise, we hit a snag. */
  else {

    /* Undo the holds up to finger. */
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    for (struct cell *finger2 = c->parent; finger2 != finger;
         finger2 = finger2->parent)
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      atomic_dec(&finger2->ghold);
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    /* Unlock this cell. */
    if (lock_unlock(&c->glock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }
}
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/**
 * @brief Lock a cell for access to its #multipole and hold its parents.
 *
 * @param c The #cell.
 * @return 0 on success, 1 on failure
 */
int cell_mlocktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to lock this cell. */
  if (c->mhold || lock_trylock(&c->mlock) != 0) {
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Did somebody hold this cell in the meantime? */
  if (c->mhold) {

    /* Unlock this cell. */
    if (lock_unlock(&c->mlock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Climb up the tree and lock/hold/unlock. */
  struct cell *finger;
  for (finger = c->parent; finger != NULL; finger = finger->parent) {

    /* Lock this cell. */
    if (lock_trylock(&finger->mlock) != 0) break;

    /* Increment the hold. */
    atomic_inc(&finger->mhold);

    /* Unlock the cell. */
    if (lock_unlock(&finger->mlock) != 0) error("Failed to unlock cell.");
  }

  /* If we reached the top of the tree, we're done. */
  if (finger == NULL) {
    TIMER_TOC(timer_locktree);
    return 0;
  }

  /* Otherwise, we hit a snag. */
  else {

    /* Undo the holds up to finger. */
    for (struct cell *finger2 = c->parent; finger2 != finger;
         finger2 = finger2->parent)
      atomic_dec(&finger2->mhold);

    /* Unlock this cell. */
    if (lock_unlock(&c->mlock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }
}

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/**
 * @brief Lock a cell for access to its array of #spart and hold its parents.
 *
 * @param c The #cell.
 * @return 0 on success, 1 on failure
 */
int cell_slocktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to lock this cell. */
  if (c->shold || lock_trylock(&c->slock) != 0) {
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Did somebody hold this cell in the meantime? */
  if (c->shold) {

    /* Unlock this cell. */
    if (lock_unlock(&c->slock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }

  /* Climb up the tree and lock/hold/unlock. */
  struct cell *finger;
  for (finger = c->parent; finger != NULL; finger = finger->parent) {

    /* Lock this cell. */
    if (lock_trylock(&finger->slock) != 0) break;

    /* Increment the hold. */
    atomic_inc(&finger->shold);

    /* Unlock the cell. */
    if (lock_unlock(&finger->slock) != 0) error("Failed to unlock cell.");
  }

  /* If we reached the top of the tree, we're done. */
  if (finger == NULL) {
    TIMER_TOC(timer_locktree);
    return 0;
  }

  /* Otherwise, we hit a snag. */
  else {

    /* Undo the holds up to finger. */
    for (struct cell *finger2 = c->parent; finger2 != finger;
         finger2 = finger2->parent)
      atomic_dec(&finger2->shold);

    /* Unlock this cell. */
    if (lock_unlock(&c->slock) != 0) error("Failed to unlock cell.");

    /* Admit defeat. */
    TIMER_TOC(timer_locktree);
    return 1;
  }
}

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/**
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 * @brief Unlock a cell's parents for access to #part array.
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 *
 * @param c The #cell.
 */
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void cell_unlocktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to unlock this cell. */
  if (lock_unlock(&c->lock) != 0) error("Failed to unlock cell.");

  /* Climb up the tree and unhold the parents. */
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  for (struct cell *finger = c->parent; finger != NULL; finger = finger->parent)
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    atomic_dec(&finger->hold);
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  TIMER_TOC(timer_locktree);
}

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/**
 * @brief Unlock a cell's parents for access to #gpart array.
 *
 * @param c The #cell.
 */
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void cell_gunlocktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to unlock this cell. */
  if (lock_unlock(&c->glock) != 0) error("Failed to unlock cell.");

  /* Climb up the tree and unhold the parents. */
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  for (struct cell *finger = c->parent; finger != NULL; finger = finger->parent)
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    atomic_dec(&finger->ghold);
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  TIMER_TOC(timer_locktree);
}

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/**
 * @brief Unlock a cell's parents for access to its #multipole.
 *
 * @param c The #cell.
 */
void cell_munlocktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to unlock this cell. */
  if (lock_unlock(&c->mlock) != 0) error("Failed to unlock cell.");

  /* Climb up the tree and unhold the parents. */
  for (struct cell *finger = c->parent; finger != NULL; finger = finger->parent)
    atomic_dec(&finger->mhold);

  TIMER_TOC(timer_locktree);
}

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/**
 * @brief Unlock a cell's parents for access to #spart array.
 *
 * @param c The #cell.
 */
void cell_sunlocktree(struct cell *c) {

  TIMER_TIC

  /* First of all, try to unlock this cell. */
  if (lock_unlock(&c->slock) != 0) error("Failed to unlock cell.");

  /* Climb up the tree and unhold the parents. */
  for (struct cell *finger = c->parent; finger != NULL; finger = finger->parent)
    atomic_dec(&finger->shold);

  TIMER_TOC(timer_locktree);
}

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/**
 * @brief Sort the parts into eight bins along the given pivots.
 *
 * @param c The #cell array to be sorted.
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 * @param parts_offset Offset of the cell parts array relative to the
 *        space's parts array, i.e. c->parts - s->parts.
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 * @param sparts_offset Offset of the cell sparts array relative to the
 *        space's sparts array, i.e. c->sparts - s->sparts.
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 * @param buff A buffer with at least max(c->count, c->gcount) entries,
 *        used for sorting indices.
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 * @param sbuff A buffer with at least max(c->scount, c->gcount) entries,
 *        used for sorting indices for the sparts.
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 * @param gbuff A buffer with at least max(c->count, c->gcount) entries,
 *        used for sorting indices for the gparts.
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 */
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void cell_split(struct cell *c, ptrdiff_t parts_offset, ptrdiff_t sparts_offset,
                struct cell_buff *buff, struct cell_buff *sbuff,
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                struct cell_buff *gbuff) {
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  const int count = c->count, gcount = c->gcount, scount = c->scount;
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  struct part *parts = c->parts;
  struct xpart *xparts = c->xparts;
  struct gpart *gparts = c->gparts;
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  struct spart *sparts = c->sparts;
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  const double pivot[3] = {c->loc[0] + c->width[0] / 2,
                           c->loc[1] + c->width[1] / 2,
                           c->loc[2] + c->width[2] / 2};
  int bucket_count[8] = {0, 0, 0, 0, 0, 0, 0, 0};
  int bucket_offset[9];

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#ifdef SWIFT_DEBUG_CHECKS
  /* Check that the buffs are OK. */
  for (int k = 0; k < count; k++) {
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    if (buff[k].x[0] != parts[k].x[0] || buff[k].x[1] != parts[k].x[1] ||
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        buff[k].x[2] != parts[k].x[2])
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      error("Inconsistent buff contents.");
  }
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  for (int k = 0; k < gcount; k++) {
    if (gbuff[k].x[0] != gparts[k].x[0] || gbuff[k].x[1] != gparts[k].x[1] ||
        gbuff[k].x[2] != gparts[k].x[2])
      error("Inconsistent gbuff contents.");
  }
  for (int k = 0; k < scount; k++) {
    if (sbuff[k].x[0] != sparts[k].x[0] || sbuff[k].x[1] != sparts[k].x[1] ||
        sbuff[k].x[2] != sparts[k].x[2])
      error("Inconsistent sbuff contents.");
  }
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#endif /* SWIFT_DEBUG_CHECKS */
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  /* Fill the buffer with the indices. */
  for (int k = 0; k < count; k++) {
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    const int bid = (buff[k].x[0] > pivot[0]) * 4 +
                    (buff[k].x[1] > pivot[1]) * 2 + (buff[k].x[2] > pivot[2]);
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    bucket_count[bid]++;
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    buff[k].ind = bid;
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  }
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  /* Set the buffer offsets. */
  bucket_offset[0] = 0;
  for (int k = 1; k <= 8; k++) {
    bucket_offset[k] = bucket_offset[k - 1] + bucket_count[k - 1];
    bucket_count[k - 1] = 0;
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  }

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  /* Run through the buckets, and swap particles to their correct spot. */
  for (int bucket = 0; bucket < 8; bucket++) {
    for (int k = bucket_offset[bucket] + bucket_count[bucket];
         k < bucket_offset[bucket + 1]; k++) {
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      int bid = buff[k].ind;
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      if (bid != bucket) {
        struct part part = parts[k];
        struct xpart xpart = xparts[k];
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        struct cell_buff temp_buff = buff[k];
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        while (bid != bucket) {
          int j = bucket_offset[bid] + bucket_count[bid]++;
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          while (buff[j].ind == bid) {
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            j++;
            bucket_count[bid]++;
          }
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          memswap(&parts[j], &part, sizeof(struct part));
          memswap(&xparts[j], &xpart, sizeof(struct xpart));
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          memswap(&buff[j], &temp_buff, sizeof(struct cell_buff));
          bid = temp_buff.ind;
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        }
        parts[k] = part;
        xparts[k] = xpart;
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        buff[k] = temp_buff;
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      }
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      bucket_count[bid]++;
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    }
  }

  /* Store the counts and offsets. */
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  for (int k = 0; k < 8; k++) {
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    c->progeny[k]->count = bucket_count[k];
    c->progeny[k]->parts = &c->parts[bucket_offset[k]];
    c->progeny[k]->xparts = &c->xparts[bucket_offset[k]];
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  }

  /* Re-link the gparts. */
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  if (count > 0 && gcount > 0)
    part_relink_gparts_to_parts(parts, count, parts_offset);
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  /* Check that the buffs are OK. */
  for (int k = 1; k < count; k++) {
    if (buff[k].ind < buff[k - 1].ind) error("Buff not sorted.");
    if (buff[k].x[0] != parts[k].x[0] || buff[k].x[1] != parts[k].x[1] ||
        buff[k].x[2] != parts[k].x[2])
      error("Inconsistent buff contents (k=%i).", k);
  }

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  /* Verify that _all_ the parts have been assigned to a cell. */
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  for (int k = 1; k < 8; k++)
    if (&c->progeny[k - 1]->parts[c->progeny[k - 1]->count] !=
        c->progeny[k]->parts)
      error("Particle sorting failed (internal consistency).");
  if (c->progeny[0]->parts != c->parts)
    error("Particle sorting failed (left edge).");
  if (&c->progeny[7]->parts[c->progeny[7]->count] != &c->parts[count])
    error("Particle sorting failed (right edge).");
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  /* Verify a few sub-cells. */
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  for (int k = 0; k < c->progeny[0]->count; k++)
    if (c->progeny[0]->parts[k].x[0] > pivot[0] ||
        c->progeny[0]->parts[k].x[1] > pivot[1] ||
        c->progeny[0]->parts[k].x[2] > pivot[2])
      error("Sorting failed (progeny=0).");
  for (int k = 0; k < c->progeny[1]->count; k++)
    if (c->progeny[1]->parts[k].x[0] > pivot[0] ||
        c->progeny[1]->parts[k].x[1] > pivot[1] ||
        c->progeny[1]->parts[k].x[2] <= pivot[2])
      error("Sorting failed (progeny=1).");
  for (int k = 0; k < c->progeny[2]->count; k++)
    if (c->progeny[2]->parts[k].x[0] > pivot[0] ||
        c->progeny[2]->parts[k].x[1] <= pivot[1] ||
        c->progeny[2]->parts[k].x[2] > pivot[2])
      error("Sorting failed (progeny=2).");
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  for (int k = 0; k < c->progeny[3]->count; k++)
    if (c->progeny[3]->parts[k].x[0] > pivot[0] ||
        c->progeny[3]->parts[k].x[1] <= pivot[1] ||
        c->progeny[3]->parts[k].x[2] <= pivot[2])
      error("Sorting failed (progeny=3).");
  for (int k = 0; k < c->progeny[4]->count; k++)
    if (c->progeny[4]->parts[k].x[0] <= pivot[0] ||
        c->progeny[4]->parts[k].x[1] > pivot[1] ||
        c->progeny[4]->parts[k].x[2] > pivot[2])
      error("Sorting failed (progeny=4).");
  for (int k = 0; k < c->progeny[5]->count; k++)
    if (c->progeny[5]->parts[k].x[0] <= pivot[0] ||
        c->progeny[5]->parts[k].x[1] > pivot[1] ||
        c->progeny[5]->parts[k].x[2] <= pivot[2])
      error("Sorting failed (progeny=5).");
  for (int k = 0; k < c->progeny[6]->count; k++)
    if (c->progeny[6]->parts[k].x[0] <= pivot[0] ||
        c->progeny[6]->parts[k].x[1] <= pivot[1] ||
        c->progeny[6]->parts[k].x[2] > pivot[2])
      error("Sorting failed (progeny=6).");
  for (int k = 0; k < c->progeny[7]->count; k++)
    if (c->progeny[7]->parts[k].x[0] <= pivot[0] ||
        c->progeny[7]->parts[k].x[1] <= pivot[1] ||
        c->progeny[7]->parts[k].x[2] <= pivot[2])
      error("Sorting failed (progeny=7).");
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  /* Now do the same song and dance for the sparts. */
  for (int k = 0; k < 8; k++) bucket_count[k] = 0;

  /* Fill the buffer with the indices. */
  for (int k = 0; k < scount; k++) {
    const int bid = (sbuff[k].x[0] > pivot[0]) * 4 +
                    (sbuff[k].x[1] > pivot[1]) * 2 + (sbuff[k].x[2] > pivot[2]);
    bucket_count[bid]++;
    sbuff[k].ind = bid;
  }

  /* Set the buffer offsets. */
  bucket_offset[0] = 0;
  for (int k = 1; k <= 8; k++) {
    bucket_offset[k] = bucket_offset[k - 1] + bucket_count[k - 1];
    bucket_count[k - 1] = 0;
  }

  /* Run through the buckets, and swap particles to their correct spot. */
  for (int bucket = 0; bucket < 8; bucket++) {
    for (int k = bucket_offset[bucket] + bucket_count[bucket];
         k < bucket_offset[bucket + 1]; k++) {
      int bid = sbuff[k].ind;
      if (bid != bucket) {
        struct spart spart = sparts[k];
        struct cell_buff temp_buff = sbuff[k];
        while (bid != bucket) {
          int j = bucket_offset[bid] + bucket_count[bid]++;
          while (sbuff[j].ind == bid) {
            j++;
            bucket_count[bid]++;
          }
          memswap(&sparts[j], &spart, sizeof(struct spart));
          memswap(&sbuff[j], &temp_buff, sizeof(struct cell_buff));
          bid = temp_buff.ind;
        }
        sparts[k] = spart;
        sbuff[k] = temp_buff;
      }
      bucket_count[bid]++;
    }
  }

  /* Store the counts and offsets. */
  for (int k = 0; k < 8; k++) {
    c->progeny[k]->scount = bucket_count[k];
    c->progeny[k]->sparts = &c->sparts[bucket_offset[k]];
  }

  /* Re-link the gparts. */
  if (scount > 0 && gcount > 0)
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    part_relink_gparts_to_sparts(sparts, scount, sparts_offset);
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  /* Finally, do the same song and dance for the gparts. */
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  for (int k = 0; k < 8; k++) bucket_count[k] = 0;

  /* Fill the buffer with the indices. */
  for (int k = 0; k < gcount; k++) {
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    const int bid = (gbuff[k].x[0] > pivot[0]) * 4 +
                    (gbuff[k].x[1] > pivot[1]) * 2 + (gbuff[k].x[2] > pivot[2]);
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    bucket_count[bid]++;
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    gbuff[k].ind = bid;
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  }
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  /* Set the buffer offsets. */
  bucket_offset[0] = 0;
  for (int k = 1; k <= 8; k++) {
    bucket_offset[k] = bucket_offset[k - 1] + bucket_count[k - 1];
    bucket_count[k - 1] = 0;
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  }

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  /* Run through the buckets, and swap particles to their correct spot. */
  for (int bucket = 0; bucket < 8; bucket++) {
    for (int k = bucket_offset[bucket] + bucket_count[bucket];
         k < bucket_offset[bucket + 1]; k++) {
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      int bid = gbuff[k].ind;
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      if (bid != bucket) {
        struct gpart gpart = gparts[k];
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        struct cell_buff temp_buff = gbuff[k];
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        while (bid != bucket) {
          int j = bucket_offset[bid] + bucket_count[bid]++;
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          while (gbuff[j].ind == bid) {
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            j++;
            bucket_count[bid]++;
          }
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          memswap(&gparts[j], &gpart, sizeof(struct gpart));
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          memswap(&gbuff[j], &temp_buff, sizeof(struct cell_buff));
          bid = temp_buff.ind;
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        }
        gparts[k] = gpart;
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        gbuff[k] = temp_buff;
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      }
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      bucket_count[bid]++;
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    }
  }

  /* Store the counts and offsets. */
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  for (int k = 0; k < 8; k++) {
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    c->progeny[k]->gcount = bucket_count[k];
    c->progeny[k]->gparts = &c->gparts[bucket_offset[k]];
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  }

  /* Re-link the parts. */
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  if (count > 0 && gcount > 0)
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    part_relink_parts_to_gparts(gparts, gcount, parts - parts_offset);
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  /* Re-link the sparts. */
  if (scount > 0 && gcount > 0)
    part_relink_sparts_to_gparts(gparts, gcount, sparts - sparts_offset);
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}
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/**
 * @brief Sanitizes the smoothing length values of cells by setting large
 * outliers to more sensible values.
 *
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 * Each cell with <1000 part will be processed. We limit h to be the size of
 * the cell and replace 0s with a good estimate.
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 *
 * @param c The cell.
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void cell_sanitize(struct cell *c, int treated) {
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  const int count = c->count;
  struct part *parts = c->parts;
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  float h_max = 0.f;
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  /* Treat cells will <1000 particles */
  if (count < 1000 && !treated) {
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    /* Get an upper bound on h */
    const float upper_h_max = c->dmin / (1.2f * kernel_gamma);
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    /* Apply it */
    for (int i = 0; i < count; ++i) {
      if (parts[i].h == 0.f || parts[i].h > upper_h_max)
        parts[i].h = upper_h_max;
    }
  }
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  /* Recurse and gather the new h_max values */
  if (c->split) {
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    for (int k = 0; k < 8; ++k) {
      if (c->progeny[k] != NULL) {
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        /* Recurse */
        cell_sanitize(c->progeny[k], (count < 1000));
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        /* And collect */
        h_max = max(h_max, c->progeny[k]->h_max);
      }
    }
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  } else {

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    /* Get the new value of h_max */
    for (int i = 0; i < count; ++i) h_max = max(h_max, parts[i].h);
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  }
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  /* Record the change */
  c->h_max = h_max;
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}

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/**
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 * @brief Converts hydro quantities to a valid state after the initial density
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 * calculation
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 *
 * @param c Cell to act upon
 * @param data Unused parameter
 */
void cell_convert_hydro(struct cell *c, void *data) {

  struct part *p = c->parts;
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  struct xpart *xp = c->xparts;
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  for (int i = 0; i < c->count; ++i) {
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    hydro_convert_quantities(&p[i], &xp[i]);
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  }
}

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/**
 * @brief Cleans the links in a given cell.
 *
 * @param c Cell to act upon
 * @param data Unused parameter
 */
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void cell_clean_links(struct cell *c, void *data) {
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  c->density = NULL;
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  c->gradient = NULL;
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  c->force = NULL;
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  c->grav = NULL;
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}
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/**
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 * @brief Checks that the #part in a cell are at the
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 * current point in time
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 *
 * Calls error() if the cell is not at the current time.
 *
 * @param c Cell to act upon
 * @param data The current time on the integer time-line
 */
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void cell_check_part_drift_point(struct cell *c, void *data) {
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#ifdef SWIFT_DEBUG_CHECKS

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  const integertime_t ti_drift = *(integertime_t *)data;
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  /* Only check local cells */
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  if (c->nodeID != engine_rank) return;
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  if (c->ti_old_part != ti_drift)
    error("Cell in an incorrect time-zone! c->ti_old_part=%lld ti_drift=%lld",
          c->ti_old_part, ti_drift);
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  for (int i = 0; i < c->count; ++i)
    if (c->parts[i].ti_drift != ti_drift)
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      error("part in an incorrect time-zone! p->ti_drift=%lld ti_drift=%lld",
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            c->parts[i].ti_drift, ti_drift);
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#else
  error("Calling debugging code without debugging flag activated.");
#endif
}

/**
 * @brief Checks that the #gpart and #spart in a cell are at the
 * current point in time
 *
 * Calls error() if the cell is not at the current time.
 *
 * @param c Cell to act upon
 * @param data The current time on the integer time-line
 */
void cell_check_gpart_drift_point(struct cell *c, void *data) {

#ifdef SWIFT_DEBUG_CHECKS

  const integertime_t ti_drift = *(integertime_t *)data;

  /* Only check local cells */
  if (c->nodeID != engine_rank) return;

  if (c->ti_old_gpart != ti_drift)
    error("Cell in an incorrect time-zone! c->ti_old_gpart=%lld ti_drift=%lld",
          c->ti_old_gpart, ti_drift);
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  for (int i = 0; i < c->gcount; ++i)
    if (c->gparts[i].ti_drift != ti_drift)
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      error("g-part in an incorrect time-zone! gp->ti_drift=%lld ti_drift=%lld",
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            c->gparts[i].ti_drift, ti_drift);
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  for (int i = 0; i < c->scount; ++i)
    if (c->sparts[i].ti_drift != ti_drift)
      error("s-part in an incorrect time-zone! sp->ti_drift=%lld ti_drift=%lld",
            c->sparts[i].ti_drift, ti_drift);
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#else
  error("Calling debugging code without debugging flag activated.");
#endif
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}

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/**
 * @brief Checks that the multipole of a cell is at the current point in time
 *
 * Calls error() if the cell is not at the current time.
 *
 * @param c Cell to act upon
 * @param data The current time on the integer time-line
 */
void cell_check_multipole_drift_point(struct cell *c, void *data) {

#ifdef SWIFT_DEBUG_CHECKS

  const integertime_t ti_drift = *(integertime_t *)data;

  if (c->ti_old_multipole != ti_drift)
    error(
        "Cell multipole in an incorrect time-zone! c->ti_old_multipole=%lld "
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        "ti_drift=%lld (depth=%d)",
        c->ti_old_multipole, ti_drift, c->depth);
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#else
  error("Calling debugging code without debugging flag activated.");
#endif
}

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/**
 * @brief Resets all the individual cell task counters to 0.
 *
 * Should only be used for debugging purposes.
 *
 * @param c The #cell to reset.
 */
void cell_reset_task_counters(struct cell *c) {

#ifdef SWIFT_DEBUG_CHECKS
  for (int t = 0; t < task_type_count; ++t) c->tasks_executed[t] = 0;
  for (int t = 0; t < task_subtype_count; ++t) c->subtasks_executed[t] = 0;
#else
  error("Calling debugging code without debugging flag activated.");
#endif
}

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/**
 * @brief Recursively construct all the multipoles in a cell hierarchy.
 *
 * @param c The #cell.
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 * @param ti_current The current integer time.
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 */
void cell_make_multipoles(struct cell *c, integertime_t ti_current) {

  /* Reset everything */
  gravity_reset(c->multipole);

  if (c->split) {

    /* Compute CoM of all progenies */
    double CoM[3] = {0., 0., 0.};
    double mass = 0.;

    for (int k = 0; k < 8; ++k) {
      if (c->progeny[k] != NULL) {
        const struct gravity_tensors *m = c->progeny[k]->multipole;
        CoM[0] += m->CoM[0] * m->m_pole.M_000;
        CoM[1] += m->CoM[1] * m->m_pole.M_000;
        CoM[2] += m->CoM[2] * m->m_pole.M_000;
        mass += m->m_pole.M_000;
      }
    }
    c->multipole->CoM[0] = CoM[0] / mass;
    c->multipole->CoM[1] = CoM[1] / mass;
    c->multipole->CoM[2] = CoM[2] / mass;

    /* Now shift progeny multipoles and add them up */
    struct multipole temp;
    double r_max = 0.;
    for (int k = 0; k < 8; ++k) {
      if (c->progeny[k] != NULL) {
        const struct cell *cp = c->progeny[k];
        const struct multipole *m = &cp->multipole->m_pole;

        /* Contribution to multipole */
        gravity_M2M(&temp, m, c->multipole->CoM, cp->multipole->CoM);
        gravity_multipole_add(&c->multipole->m_pole, &temp);

        /* Upper limit of max CoM<->gpart distance */
        const double dx = c->multipole->CoM[0] - cp->multipole->CoM[0];
        const double dy = c->multipole->CoM[1] - cp->multipole->CoM[1];
        const double dz = c->multipole->CoM[2] - cp->multipole->CoM[2];
        const double r2 = dx * dx + dy * dy + dz * dz;
        r_max = max(r_max, cp->multipole->r_max + sqrt(r2));
      }
    }
    /* Alternative upper limit of max CoM<->gpart distance */
    const double dx = c->multipole->CoM[0] > c->loc[0] + c->width[0] / 2.
                          ? c->multipole->CoM[0] - c->loc[0]
                          : c->loc[0] + c->width[0] - c->multipole->CoM[0];
    const double dy = c->multipole->CoM[1] > c->loc[1] + c->width[1] / 2.
                          ? c->multipole->CoM[1] - c->loc[1]
                          : c->loc[1] + c->width[1] - c->multipole->CoM[1];
    const double dz = c->multipole->CoM[2] > c->loc[2] + c->width[2] / 2.
                          ? c->multipole->CoM[2] - c->loc[2]
                          : c->loc[2] + c->width[2] - c->multipole->CoM[2];

    /* Take minimum of both limits */
    c->multipole->r_max = min(r_max, sqrt(dx * dx + dy * dy + dz * dz));

  } else {

    if (c->gcount > 0) {
      gravity_P2M(c->multipole, c->gparts, c->gcount);
      const double dx = c->multipole->CoM[0] > c->loc[0] + c->width[0] / 2.
                            ? c->multipole->CoM[0] - c->loc[0]
                            : c->loc[0] + c->width[0] - c->multipole->CoM[0];
      const double dy = c->multipole->CoM[1] > c->loc[1] + c->width[1] / 2.
                            ? c->multipole->CoM[1] - c->loc[1]
                            : c->loc[1] + c->width[1] - c->multipole->CoM[1];
      const double dz = c->multipole->CoM[2] > c->loc[2] + c->width[2] / 2.
                            ? c->multipole->CoM[2] - c->loc[2]
                            : c->loc[2] + c->width[2] - c->multipole->CoM[2];
      c->multipole->r_max = sqrt(dx * dx + dy * dy + dz * dz);
    } else {
      gravity_multipole_init(&c->multipole->m_pole);
      c->multipole->CoM[0] = c->loc[0] + c->width[0] / 2.;
      c->multipole->CoM[1] = c->loc[1] + c->width[1] / 2.;
      c->multipole->CoM[2] = c->loc[2] + c->width[2] / 2.;
      c->multipole->r_max = 0.;
    }
  }

  c->ti_old_multipole = ti_current;
}

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/**
 * @brief Computes the multi-pole brutally and compare to the
 * recursively computed one.
 *
 * @param c Cell to act upon
 * @param data Unused parameter
 */
void cell_check_multipole(struct cell *c, void *data) {

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#ifdef SWIFT_DEBUG_CHECKS
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  struct gravity_tensors ma;
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  const double tolerance = 1e-3; /* Relative */
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  return;

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  /* First recurse */
  if (c->split)
    for (int k = 0; k < 8; k++)
      if (c->progeny[k] != NULL) cell_check_multipole(c->progeny[k], NULL);
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  if (c->gcount > 0) {

    /* Brute-force calculation */
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    gravity_P2M(&ma, c->gparts, c->gcount);
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    /* Now  compare the multipole expansion */
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    if (!gravity_multipole_equal(&ma, c->multipole, tolerance)) {
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      message("Multipoles are not equal at depth=%d! tol=%f", c->depth,
              tolerance);
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