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[libucw.git] / ucw / trie.h

/*
 *      UCW Library -- Byte-based trie
 *
 *      (c) 2008 Pavel Charvat <pchar@ucw.cz>
 *
 *      This software may be freely distributed and used according to the terms
 *      of the GNU Lesser General Public License.
 */

/*
 *      This is not a normal header file, it's a generator of tries.
 *      Each time you include it with parameters set in the corresponding
 *      preprocessor macros, it generates a trie with the parameters given.
 *
 *      You need to specify:
 *
 *      [*] TRIE_PREFIX(x)              macro to add a name prefix (used on all global names
 *                                      defined by the trie generator).
 *
 *      [*] TRIE_NODE_TYPE              data type where a node dwells (usually a struct).
 *          TRIE_NODE_KEY(node)         macro to return the pointer to the key (default=&x)
 *          TRIE_NODE_LEN(node)         macro to return the length of the key (default=str_len(TRIE_NODE_KEY(node)))
 *          TRIE_LEN_TYPE               integer type large enough to hold length of any inserted string (default=u32).
 *          TRIE_REV                    work with reversed strings.
 *          TRIE_DYNAMIC
 *
 *          TRIE_WANT_CLEANUP           cleanup()
 *
 *          TRIE_WANT_FIND              node *find(char *str)
 *          TRIE_WANT_FIND_BUF          node *find_buf(byte *ptr, uint len)
 *          TRIE_WANT_ADD               add(*node)
 *          TRIE_WANT_REPLACE           node *replace(*node)
 *          TRIE_WANT_DELETE            delete(char *str)
 *          TRIE_WANT_DELETE_BUF        delete_buf(byte *ptr, uint len)
 *          TRIE_WANT_REMOVE            remove(*node)
 *
 *          TRIE_WANT_AUDIT             audit()
 *          TRIE_WANT_STATS
 *
 *      Be warned that the implementation uses alloca() in several macros,
 *      so if you use automatic variable-length arrays in the same function,
 *      all the hell may be unleashed.
 */

/*** Define once ***/

#ifndef _SHERLOCK_UCW_TRIE_H
#define _SHERLOCK_UCW_TRIE_H

#include <ucw/eltpool.h>
#include <ucw/hashfunc.h>

#include <string.h>

#define TRIE_FLAG_DEG           0x01ff  // mask for edge degree (0-256)
#define TRIE_FLAG_HASH          0x0200  // sons are stored in a hash table
#define TRIE_FLAG_NODE          0x0400  // edge contains inserted data

#endif

/*** Defaults ***/

#ifndef TRIE_PREFIX
#error Undefined mandatory macro TRIE_PREFIX
#endif
#define P(x) TRIE_PREFIX(x)

#ifndef TRIE_NODE_TYPE
#error Undefined mandatory macro TRIE_NODE_TYPE
#endif
typedef TRIE_NODE_TYPE P(node_t);

#ifndef TRIE_NODE_KEY
#define TRIE_NODE_KEY(node) ((char *)&(node))
#endif

#ifndef TRIE_NODE_LEN
#define TRIE_NODE_LEN(node) (str_len(TRIE_NODE_KEY(node)))
#endif

#ifndef TRIE_LEN_TYPE
#define TRIE_LEN_TYPE u32
#endif
typedef TRIE_LEN_TYPE P(len_t);

#ifndef TRIE_ELTPOOL_SIZE
#define TRIE_ELTPOOL_SIZE 1024
#endif

#ifndef TRIE_HASH_THRESHOLD
#define TRIE_HASH_THRESHOLD (6 - sizeof(P(len_t)))
#endif

#ifndef TRIE_BUCKET_RANK
#define TRIE_BUCKET_RANK (2U + (sizeof(void *) > 4))
#endif
#define TRIE_BUCKET_SIZE (1U << TRIE_BUCKET_RANK)
#define TRIE_BUCKET_MASK (TRIE_BUCKET_SIZE - 1)
enum { P(bucket_rank) = TRIE_BUCKET_RANK };

#define TRIE_COMPILE_ASSERT(x, y) typedef char TRIE_PREFIX(x##_compile_assert)[!!(y)-1]
TRIE_COMPILE_ASSERT(len_type, sizeof(P(len_t)) <= sizeof(uint));
TRIE_COMPILE_ASSERT(hash_threshold, TRIE_HASH_THRESHOLD >= 2);
TRIE_COMPILE_ASSERT(bucket_size, TRIE_BUCKET_RANK >= 1 && TRIE_BUCKET_MASK < sizeof(void *));

#ifdef TRIE_TRACE
#define TRIE_DBG(x...) msg(L_DEBUG, "TRIE: " x)
#else
#define TRIE_DBG(x...) do{}while(0)
#endif

/*** Solve dependencies ***/

#if !defined(TRIE_WANT_DO_FIND) && (defined(TRIE_WANT_FIND) || defined(TRIE_WANT_FIND_BUF))
#define TRIE_WANT_DO_FIND
#endif

#if !defined(TRIE_WANT_DO_LOOKUP) && (defined(TRIE_WANT_ADD) || defined(TRIE_WANT_REPLACE))
#define TRIE_WANT_DO_LOOKUP
#endif

#if !defined(TRIE_WANT_DO_DELETE) && (defined(TRIE_WANT_DELETE) || defined(TRIE_WANT_DELETE_BUF) || defined(TRIE_WANT_REMOVE))
#define TRIE_WANT_DO_DELETE
#endif

#if !defined(TRIE_WANT_DO_LOOKUP)
#error You must request at least one method for inserting nodes
#endif

/*** Data structures ***/

struct P(trie) {
  struct P(edge) *root;                         // root edge or NULL
  struct eltpool *epool[TRIE_HASH_THRESHOLD + 1]; // eltpools for edges with array of sons
  struct eltpool *hpool[9];                     // eltpools for edges with hash table
};

struct P(edge) {
  u16 flags;                                    // TRIE_FLAG_x
  union {
    byte trans[TRIE_HASH_THRESHOLD];            // transition characters (!TRIE_FLAG_HASH)
    struct {
      byte hash_rank;                           // logarithmic hash size (TRIE_FLAG_HASH)
      byte hash_deleted;                        // number of deleted items
    };
  };
  P(len_t) len;                                 // sum of all ancestor edges with their trasition
                                                //   characters plus the length of the current edge
  union {
    P(node_t) *node;                            // inserted data (TRIE_FLAG_NODE)
    struct P(edge) *leaf;                       // reference to a descendant with data (!TRIE_FLAG_NODE)
  };
  struct P(edge) *son[0];                       // array of sons (!TRIE_FLAG_HASH)
                                                //   or hash table (TRIE_FLAG_HASH)
};

#ifdef TRIE_DYNAMIC
#define T (*trie)
#define TA struct P(trie) *trie
#define TAC TA,
#define TT trie
#define TTC trie,
#else
static struct P(trie) P(trie);
#define T P(trie)
#define TA void
#define TAC
#define TT
#define TTC
#endif

/*** Memory management ***/

static void
P(init)(TA)
{
  TRIE_DBG("Initializing");
  bzero(&T, sizeof(T));
  for (uint i = 0; i < ARRAY_SIZE(T.epool); i++)
    {
      uint size = sizeof(struct P(edge)) + i * sizeof(void *);
      T.epool[i] = ep_new(size, MAX(TRIE_ELTPOOL_SIZE / size, 1));
    }
  for (uint i = 0; i < ARRAY_SIZE(T.hpool); i++)
    {
      uint size = sizeof(struct P(edge)) + ((sizeof(void *) << TRIE_BUCKET_RANK) << i);
      T.hpool[i] = ep_new(size, MAX(TRIE_ELTPOOL_SIZE / size, 1));
    }
}

#ifdef TRIE_WANT_CLEANUP
static void
P(cleanup)(TA)
{
  TRIE_DBG("Cleaning up");
  for (uint i = 0; i < ARRAY_SIZE(T.epool); i++)
    ep_delete(T.epool[i]);
  for (uint i = 0; i < ARRAY_SIZE(T.hpool); i++)
    ep_delete(T.hpool[i]);
}
#endif

static struct P(edge) *
P(edge_alloc)(TAC uint flags)
{
  struct P(edge) *edge;
  if (flags & TRIE_FLAG_HASH)
    {
      uint rank = 0, deg = flags & TRIE_FLAG_DEG;
      while ((TRIE_BUCKET_MASK << rank) < deg * 2) // 25-50% density
        rank++;
      ASSERT(rank < ARRAY_SIZE(T.hpool));
      edge = ep_alloc(T.hpool[rank]);
      edge->hash_rank = rank;
      edge->hash_deleted = 0;
      bzero(edge->son, (sizeof(void *) << TRIE_BUCKET_RANK) << rank);
    }
  else
    edge = ep_alloc(T.epool[flags & TRIE_FLAG_DEG]);
  edge->flags = flags;
  TRIE_DBG("Allocated edge %p, flags=0x%x", edge, flags);
  return edge;
}

static void
P(edge_free)(TAC struct P(edge) *edge)
{
  TRIE_DBG("Freeing edge %p, flags=0x%x", edge, edge->flags);
  if (edge->flags & TRIE_FLAG_HASH)
    ep_free(T.hpool[edge->hash_rank], edge);
  else
    ep_free(T.epool[edge->flags & TRIE_FLAG_DEG], edge);
}

/*** Manipulation with strings ***/

static inline byte *
P(str_get)(P(node_t) *node)
{
  return TRIE_NODE_KEY((*node));
}

static inline uint
P(str_len)(P(node_t) *node)
{
  return TRIE_NODE_LEN((*node));
}

static inline uint
P(str_char)(byte *ptr, uint len UNUSED, uint pos)
{
#ifndef TRIE_REV
  return ptr[pos];
#else
  return ptr[len - pos - 1];
#endif
}

static inline byte *
P(str_prefix)(byte *ptr, uint len UNUSED, uint prefix UNUSED)
{
#ifndef TRIE_REV
  return ptr;
#else
  return ptr + len - prefix;
#endif
}

static inline byte *
P(str_suffix)(byte *ptr, uint len UNUSED, uint suffix UNUSED)
{
#ifndef TRIE_REV
  return ptr + len - suffix;
#else
  return ptr;
#endif
}

static inline uint
P(common_prefix)(byte *ptr1, uint len1, byte *ptr2, uint len2)
{
  uint l = MIN(len1, len2), i;
  for (i = 0; i < l; i++)
    if (P(str_char)(ptr1, len1, i) != P(str_char)(ptr2, len2, i))
      break;
  return i;
}

/*** Sons ***/

static inline uint
P(hash_func)(uint c)
{
  return hash_u32(c) >> 16;
}

static inline struct P(edge) **
P(hash_find)(struct P(edge) *edge, uint c)
{
  uint mask = (TRIE_BUCKET_SIZE << edge->hash_rank) - 1;
  for (uint i = P(hash_func)(c); ; i++)
    if (((i &= mask) & TRIE_BUCKET_MASK) && (uintptr_t)edge->son[i] != 1)
      if (!edge->son[i])
        return NULL;
      else if (((byte *)&edge->son[i & ~TRIE_BUCKET_MASK])[i & TRIE_BUCKET_MASK] == c)
        return &edge->son[i];
}

static inline struct P(edge) **
P(hash_insert)(struct P(edge) *edge, uint c)
{
  uint mask = (TRIE_BUCKET_SIZE << edge->hash_rank) - 1;
  for (uint i = P(hash_func)(c); ; i++)
    if (((i &= mask) & TRIE_BUCKET_MASK) && (uintptr_t)edge->son[i] <= 1)
      {
        edge->hash_deleted -= (uintptr_t)edge->son[i];
        edge->son[i] = NULL;
        ((byte *)&edge->son[i & ~TRIE_BUCKET_MASK])[i & TRIE_BUCKET_MASK] = c;
        return &edge->son[i];
      }
}

#ifdef TRIE_WANT_DO_DELETE
static inline void
P(hash_delete)(struct P(edge) *edge, uint c)
{
  uint mask = (TRIE_BUCKET_SIZE << edge->hash_rank) - 1;
  for (uint i = P(hash_func)(c); ; i++)
    if (((i &= mask) & TRIE_BUCKET_MASK) && (uintptr_t)edge->son[i] > 1 &&
      ((byte *)&edge->son[i & ~TRIE_BUCKET_MASK])[i & TRIE_BUCKET_MASK] == c)
      {
        edge->hash_deleted++;
        edge->son[i] = (void *)1;
        return;
      }
}
#endif

#define TRIE_HASH_FOR_ALL(xedge, xtrans, xson) do { \
  struct P(edge) *_edge = (xedge); \
  for (uint _i = (TRIE_BUCKET_SIZE << _edge->hash_rank); _i--; ) \
    if ((_i & TRIE_BUCKET_MASK) && (uintptr_t)_edge->son[_i] > 1) { \
      UNUSED uint xtrans = ((byte *)&_edge->son[_i & ~TRIE_BUCKET_MASK])[_i & TRIE_BUCKET_MASK]; \
      UNUSED struct P(edge) *xson = _edge->son[_i]; \
      do {
#define TRIE_HASH_END_FOR }while(0);}}while(0)

static void
P(hash_realloc)(TAC struct P(edge) **ref)
{
  struct P(edge) *old = *ref, *edge = *ref = P(edge_alloc)(TTC old->flags);
  TRIE_DBG("Reallocating hash table");
  edge->node = old->node;
  edge->len = old->len;
  TRIE_HASH_FOR_ALL(old, trans, son)
    *P(hash_insert)(edge, trans) = son;
  TRIE_HASH_END_FOR;
  P(edge_free)(TTC old);
}

/*** Finding/inserting/deleting sons ***/

static struct P(edge) **
P(son_find)(struct P(edge) *edge, uint c)
{
  if (edge->flags & TRIE_FLAG_HASH)
    return P(hash_find)(edge, c);
  else
    for (uint i = edge->flags & TRIE_FLAG_DEG; i--; )
      if (edge->trans[i] == c)
        return &edge->son[i];
  return NULL;
}

static struct P(edge) **
P(son_insert)(TAC struct P(edge) **ref, uint c)
{
  struct P(edge) *old = *ref, *edge;
  uint deg = old->flags & TRIE_FLAG_DEG;
  if (old->flags & TRIE_FLAG_HASH)
    {
      old->flags++;
      if ((deg + 1 + old->hash_deleted) * 4 > (TRIE_BUCKET_MASK << old->hash_rank) * 3) // >75% density
        {
          P(hash_realloc)(TTC ref);
          edge = *ref;
        }
      else
        edge = old;
    }
  else
    {
      if (deg < TRIE_HASH_THRESHOLD)
        {
          TRIE_DBG("Growing array");
          edge = P(edge_alloc)(TTC old->flags + 1);
          memcpy((byte *)edge + sizeof(edge->flags), (byte *)old + sizeof(edge->flags),
            sizeof(*old) - sizeof(edge->flags) + deg * sizeof(*old->son));
          edge->trans[deg] = c;
          edge->son[deg] = NULL;
          P(edge_free)(TTC old);
          *ref = edge;
          return &edge->son[deg];
        }
      else
        {
          TRIE_DBG("Growing array to hash table");
          edge = P(edge_alloc)(TTC (old->flags + 1) | TRIE_FLAG_HASH);
          edge->node = old->node;
          edge->len = old->len;
          for (uint i = 0; i < deg; i++)
            *P(hash_insert)(edge, old->trans[i]) = old->son[i];
          P(edge_free)(TTC old);
        }
    }
  *ref = edge;
  return P(hash_insert)(edge, c);
}

#ifdef TRIE_WANT_DO_DELETE
static void
P(son_delete)(TAC struct P(edge) **ref, uint c)
{
  struct P(edge) *old = *ref, *edge;
  uint deg = old->flags & TRIE_FLAG_DEG;
  ASSERT(deg);
  if (old->flags & TRIE_FLAG_HASH)
    {
      P(hash_delete)(old, c);
      old->flags--;
      deg--;
      if (deg <= TRIE_HASH_THRESHOLD / 2)
        {
          TRIE_DBG("Reducing hash table to array");
          edge = P(edge_alloc)(TTC old->flags & ~TRIE_FLAG_HASH);
          uint k = 0;
          TRIE_HASH_FOR_ALL(old, trans, son)
            edge->trans[k] = trans;
            edge->son[k] = son;
            k++;
          TRIE_HASH_END_FOR;
          ASSERT(k == deg);
        }
      else if (deg * 6 >= (TRIE_BUCKET_MASK << old->hash_rank)) // >= 16%
        return;
      else
        {
          P(hash_realloc)(TTC ref);
          edge = *ref;
          return;
        }
    }
  else
    {
      TRIE_DBG("Reducing array");
      edge = P(edge_alloc)(TTC old->flags - 1);
      uint j = 0;
      for (uint i = 0; i < deg; i++)
        if (old->trans[i] != c)
          {
            edge->trans[j] = old->trans[i];
            edge->son[j] = old->son[i];
            j++;
          }
      ASSERT(j == deg - 1);
    }
  edge->node = old->node;
  edge->len = old->len;
  P(edge_free)(TTC old);
  *ref = edge;
}
#endif

#ifdef TRIE_WANT_DO_DELETE
static struct P(edge) *
P(son_any)(struct P(edge) *edge)
{
  ASSERT(edge->flags & TRIE_FLAG_DEG);
  if (!(edge->flags & TRIE_FLAG_HASH))
    return edge->son[0];
  else
    for (uint i = 0; ; i++)
      if ((i & TRIE_BUCKET_MASK) && (uintptr_t)edge->son[i] > 1)
        return edge->son[i];
}
#endif

/*** Find/insert/delete ***/

#ifdef TRIE_WANT_DO_FIND
static struct P(edge) *
P(do_find)(TAC byte *ptr, uint len)
{
  TRIE_DBG("do_find('%.*s')", len, ptr);
  struct P(edge) **ref = &T.root, *edge;
  do
    {
      if (!(edge = *ref) || edge->len > len)
        return NULL;
      else if (edge->len == len)
        return ((edge->flags & TRIE_FLAG_NODE) && !memcmp(ptr, P(str_get)(edge->node), len)) ? edge : NULL;
    }
  while (ref = P(son_find)(edge, P(str_char)(ptr, len, edge->len)));
  return NULL;
}
#endif

static struct P(edge) *
P(do_lookup)(TAC byte *ptr, uint len)
{
  TRIE_DBG("do_lookup('%.*s')", len, ptr);
  struct P(edge) **ref, *edge, *leaf, *newleaf;
  uint prefix, elen, trans, pos;
  byte *eptr;

  if (!(edge = T.root))
    {
      TRIE_DBG("Creating first edge");
      edge = T.root = P(edge_alloc)(TTC TRIE_FLAG_NODE);
      edge->node = NULL;
      edge->len = len;
      return edge;
    }
  else
    {
      while (edge->len < len && (ref = P(son_find)(edge, P(str_char)(ptr, len, edge->len))))
        edge = *ref;
      if (!(edge->flags & TRIE_FLAG_NODE))
        edge = edge->leaf;
      ASSERT(edge->flags & TRIE_FLAG_NODE);
      eptr = P(str_get)(edge->node);
      elen = edge->len;
      prefix = P(common_prefix)(ptr, len, eptr, elen);
      if (prefix == len && prefix == elen)
        return edge;
      TRIE_DBG("The longest common prefix is '%.*s'", prefix, P(str_prefix)(ptr, len, prefix));

      if (prefix < len)
        {
          TRIE_DBG("Creating a new leaf");
          newleaf = P(edge_alloc)(TTC TRIE_FLAG_NODE);
          newleaf->node = NULL;
          newleaf->len = len;
        }
      else
        newleaf = NULL;

      ref = &T.root;
      while (edge = *ref)
        {
          pos = edge->len;
          if (prefix < pos)
            {
              leaf = (edge->flags & TRIE_FLAG_NODE) ? edge : edge->leaf;
              TRIE_DBG("Splitting edge '%.*s'", leaf->len, P(str_get)(leaf->node));
              trans = P(str_char)(P(str_get)(leaf->node), leaf->len, prefix);
              if (len == prefix)
                {
                  edge = P(edge_alloc)(TTC 1 | TRIE_FLAG_NODE);
                  edge->len = prefix;
                  edge->node = NULL;
                  edge->trans[0] = trans;
                  edge->son[0] = *ref;
                  return *ref = edge;
                }
              else
                {
                  edge = P(edge_alloc)(TTC 2);
                  edge->len = prefix;
                  edge->leaf = leaf;
                  edge->trans[0] = trans;
                  edge->son[0] = *ref;
                  edge->trans[1] = P(str_char)(ptr, len, prefix);
                  *ref = edge;
                  return edge->son[1] = newleaf;
                }
            }
          if (pos == len)
            {
              TRIE_DBG("Adding the node to an already existing edge");
              edge->flags |= TRIE_FLAG_NODE;
              edge->node = NULL;
              return edge;
            }
          if (!(edge->flags & TRIE_FLAG_NODE) && newleaf)
            edge->leaf = newleaf;
          trans = P(str_char)(ptr, len, pos);
          if (pos < prefix)
            ref = P(son_find)(edge, trans);
          else
            ref = P(son_insert)(TTC ref, trans);
        }
    }
  return *ref = newleaf;
}

#ifdef TRIE_WANT_DO_DELETE
static P(node_t) *
P(do_delete)(TAC byte *ptr, uint len)
{
  TRIE_DBG("do_delete('%.*s')", len, ptr);
  struct P(edge) **ref = &T.root, **pref = NULL, *edge, *parent, *leaf, *pold = NULL;
  while (1)
    {
      if (!(edge = *ref) || edge->len > len)
        return NULL;
      else if (edge->len == len)
        if ((edge->flags & TRIE_FLAG_NODE) && !memcmp(ptr, P(str_get)(edge->node), len))
          break;
        else
          return NULL;
      pref = ref;
      if (!(ref = P(son_find)(edge, P(str_char)(ptr, len, edge->len))))
        return NULL;
    }

  P(node_t) *node = edge->node;
  uint deg = edge->flags & TRIE_FLAG_DEG;

  if (!deg)
    {
      if (!pref)
        {
          TRIE_DBG("Deleting last edge");
          T.root = NULL;
          P(edge_free)(TTC edge);
          return node;
        }
      else
        {
          TRIE_DBG("Deleting a leaf");
          pold = *pref;
          P(son_delete)(TTC pref, P(str_char)(ptr, len, pold->len));
          parent = *pref;
          if ((parent->flags & (TRIE_FLAG_DEG | TRIE_FLAG_NODE)) <= 1)
            {
              ASSERT((parent->flags & (TRIE_FLAG_DEG | TRIE_FLAG_HASH)) == 1);
              TRIE_DBG("... and its parent");
              leaf = *pref = parent->son[0];
              P(edge_free)(TTC parent);
            }
          else if (parent->flags & TRIE_FLAG_NODE)
            leaf = parent;
          else
            leaf = P(son_any)(parent);
        }
      P(edge_free)(TTC edge);
    }
  else if (deg == 1)
    {
      TRIE_DBG("Deleting internal edge");
      ASSERT(!(edge->flags & TRIE_FLAG_HASH));
      leaf = *ref = edge->son[0];
      P(edge_free)(TTC edge);
    }
  else
    {
      TRIE_DBG("Deleting node, but leaving edge");
      leaf = P(son_any)(edge);
      if (!(leaf->flags & TRIE_FLAG_NODE))
        leaf = leaf->leaf;
      edge->leaf = leaf;
      edge->flags &= ~TRIE_FLAG_NODE;
    }

  TRIE_DBG("Updating leaf pointers");
  if (!(leaf->flags & TRIE_FLAG_NODE))
    leaf = leaf->leaf;
  ASSERT(leaf->flags & TRIE_FLAG_NODE);
  for (ref = &T.root; ref && (*ref)->len < len; ref = P(son_find)(*ref, P(str_char)(ptr, len, (*ref)->len)))
    if ((*ref)->leaf == edge || (*ref)->leaf == pold)
      (*ref)->leaf = leaf;
  return node;
}
#endif

#ifdef TRIE_WANT_FIND
static inline P(node_t) *
P(find)(TAC char *str)
{
  struct P(edge) *edge = P(do_find)(TTC str, str_len(str));
  return edge ? edge->node : NULL;
}
#endif

#ifdef TRIE_WANT_FIND_BUF
static inline P(node_t) *
P(find_buf)(TAC byte *ptr, uint len)
{
  struct P(edge) *edge = P(do_find)(TTC ptr, len);
  return edge ? edge->node : NULL;
}
#endif

#ifdef TRIE_WANT_ADD
static inline void
P(add)(TAC P(node_t) *node)
{
  struct P(edge) *edge = P(do_lookup)(TTC P(str_get)(node), P(str_len)(node));
  ASSERT(!edge->node);
  edge->node = node;
}
#endif

#ifdef TRIE_WANT_REPLACE
static inline P(node_t) *
P(replace)(TAC P(node_t) *node)
{
  struct P(edge) *edge = P(do_lookup)(TTC P(str_get)(node), P(str_len)(node));
  P(node_t) *over = edge->node;
  edge->node = node;
  return over;
}
#endif

#ifdef TRIE_WANT_DELETE
static inline P(node_t) *
P(delete)(TAC char *str)
{
  return P(do_delete)(TTC str, str_len(str));
}
#endif

#ifdef TRIE_WANT_DELETE_BUF
static inline P(node_t) *
P(delete_buf)(TAC byte *ptr, uint len)
{
  return P(do_delete)(TTC ptr, len);
}
#endif

#ifdef TRIE_WANT_REMOVE
static inline void
P(remove)(TAC P(node_t) *node)
{
  if (unlikely(P(do_delete)(TTC P(str_get)(node), P(str_len)(node)) != node))
    ASSERT(0);
}
#endif

/*** Traversing prefixes and subtrees ***/

#ifndef TRIE_FOR_ALL

// for all matched edges until the first >=xlen (including)
#define TRIE_FOR_PREFIX_EDGES(px, xtrie, xptr, xlen, xedge)             \
  do                                                                    \
    {                                                                   \
      byte *_ptr = (xptr);                                              \
      uint _len = (xlen);                                               \
      struct px##trie *_trie = (xtrie);                                 \
      struct px##edge *xedge, **_ref;                                   \
      if (!(xedge = _trie->root))                                       \
        break;                                                          \
      while (xedge->len < _len && (_ref = px##son_find(xedge, px##str_char(_ptr, _len, xedge->len))))           \
        xedge = *_ref;                                                  \
      if (!(xedge->flags & TRIE_FLAG_NODE))                             \
        xedge = xedge->leaf;                                            \
      uint _prefix = px##common_prefix(_ptr, _len, px##str_get(xedge->node), xedge->len);                       \
      for (_ref = &_trie->root; _ref && ((xedge = *_ref)->len <= _prefix || _prefix == _len);                   \
        _ref = (xedge->len < _prefix) ? px##son_find(xedge, px##str_char(_ptr, _len, xedge->len)) : NULL)       \
        {
#define TRIE_END_PREFIX_EDGES                                           \
        }                                                               \
    }                                                                   \
  while (0)

// for entire subtree starting in the xstart edge
#define TRIE_FOR_SUBTREE_EDGES(px, xstart, xedge)                       \
  do                                                                    \
    {                                                                   \
      struct { struct px##edge *edge; uint pos; }                       \
        *_sbuf = alloca(sizeof(*_sbuf) * 16),                           \
        *_sptr = _sbuf, *_send = _sbuf + 16;                            \
      struct px##edge *_next = (xstart), *xedge;                        \
      while (xedge = _next)                                             \
        {                                                               \
          if (xedge->flags & TRIE_FLAG_DEG)                             \
            {                                                           \
              if (_sptr == _send)                                       \
                {                                                       \
                  uint stack_size = _sptr - _sbuf;                      \
                  _sptr = alloca(sizeof(*_sptr) * (stack_size * 2));    \
                  memcpy(_sptr, _sbuf, sizeof(*_sptr) * stack_size);    \
                  _sbuf = _sptr;                                        \
                  _send = _sptr + stack_size * 2;                       \
                }                                                       \
              _sptr->edge = xedge;                                      \
              _sptr->pos = (xedge->flags & TRIE_FLAG_HASH) ?            \
                (1U << px##bucket_rank) << xedge->hash_rank :           \
                (xedge->flags & TRIE_FLAG_DEG);                         \
              _sptr++;                                                  \
            }                                                           \
          while (1)                                                     \
            {                                                           \
              if (_sptr == _sbuf)                                       \
                {                                                       \
                  _next = NULL;                                         \
                  break;                                                \
                }                                                       \
              _next = (--_sptr)->edge;                                  \
              uint pos = --(_sptr->pos);                                \
              uint flags = _next->flags;                                \
              _next = _next->son[pos];                                  \
              if (pos)                                                  \
                _sptr++;                                                \
              if (!(flags & TRIE_FLAG_HASH) ||                          \
                ((pos & ((1U << px##bucket_rank) - 1)) &&               \
                 (uintptr_t)_next > 1))                                 \
                break;                                                  \
            }
#define TRIE_END_SUBTREE_EDGES                                          \
        }                                                               \
    }                                                                   \
  while (0)

#define TRIE_FOR_SUBTREE(px, xstart, xnode)                             \
  TRIE_FOR_SUBTREE_EDGES(px, xstart, _edge)                             \
    if (_edge->flags & TRIE_FLAG_NODE)                                  \
      {                                                                 \
        px##node_t *xnode = _edge->node;
#define TRIE_END_SUBTREE                                                \
      }                                                                 \
  TRIE_END_SUBTREE_EDGES;

#define TRIE_FOR_ALL_EDGES(px, xtrie, xedge) TRIE_FOR_SUBTREE_EDGES(px, (xtrie)->root, xedge)
#define TRIE_END_ALL_EDGES TRIE_END_SUBTREE_EDGES

#define TRIE_FOR_ALL(px, xtrie, xnode) TRIE_FOR_SUBTREE(px, (xtrie)->root, xnode)
#define TRIE_END_ALL TRIE_END_SUBTREE

#endif

/*** Check consistency ***/

#ifdef TRIE_WANT_AUDIT

static void
P(audit)(TA)
{
  uint count = 0;
  TRIE_FOR_ALL_EDGES(TRIE_PREFIX(), &T, edge)
    {
      ASSERT(edge);
      uint deg = edge->flags & TRIE_FLAG_DEG;
      ASSERT(edge->node);
      struct P(edge) * leaf = (edge->flags & TRIE_FLAG_NODE) ? edge : edge->leaf;
      if (leaf != edge)
        {
          ASSERT(leaf->flags & TRIE_FLAG_NODE);
          ASSERT(leaf->len > edge->len);
          ASSERT(leaf->node);
        }
      TRIE_DBG("Checking edge %p, %s=%p, flags=0x%x, key='%.*s'",
          edge, (edge->flags & TRIE_FLAG_NODE) ? "node" : "leaf", edge->node, edge->flags,
          edge->len, P(str_prefix)(P(str_get)(leaf->node), leaf->len, edge->len));
      ASSERT(deg >= 2 || (edge->flags & TRIE_FLAG_NODE));
      if (edge->flags & TRIE_FLAG_HASH)
        {
          ASSERT(deg > 1 && deg <= 256);
          uint count = 0, deleted = 0;
          for (uint i = TRIE_BUCKET_SIZE << edge->hash_rank; i--; )
            if (i & TRIE_BUCKET_MASK)
              if ((uintptr_t)edge->son[i] == 1)
                deleted++;
              else if (edge->son[i])
                {
                  ASSERT(edge->son[i]->len > edge->len);
                  count++;
                }
          ASSERT(count == deg);
          ASSERT(deleted == edge->hash_deleted);
        }
      else
        {
          ASSERT(deg <= TRIE_HASH_THRESHOLD);
          for (uint i = 0; i < deg; i++)
            ASSERT(edge->son[i]->len > edge->len);
        }
      count++;
    }
  TRIE_END_ALL_EDGES;
  TRIE_DBG("Found %u edges", count);
}

#endif

/*** Statistics ***/

#ifdef TRIE_WANT_STATS

struct P(stats) {
  u64 total_size;
  u64 small_size;
  u64 hash_size;
};

static void
P(stats)(TAC struct P(stats) *stats)
{
  bzero(stats, sizeof(*stats));
  for (uint i = 0; i < ARRAY_SIZE(T.epool); i++)
    stats->small_size += ep_total_size(T.epool[i]);
  for (uint i = 0; i < ARRAY_SIZE(T.hpool); i++)
    stats->hash_size += ep_total_size(T.hpool[i]);
  stats->total_size = stats->small_size + stats->hash_size + sizeof(T);
}

static inline u64
P(total_size)(TA)
{
  struct P(stats) stats;
  P(stats)(TTC &stats);
  return stats.total_size;
}

#endif

/*** Clean up local macros ***/

#undef P
#undef T
#undef TA
#undef TAC
#undef TT
#undef TTC

#undef TRIE_PREFIX
#undef TRIE_NODE_TYPE
#undef TRIE_NODE_KEY
#undef TRIE_NODE_LEN
#undef TRIE_LEN_TYPE
#undef TRIE_REV
#undef TRIE_DYNAMIC
#undef TRIE_ELTPOOL_SIZE
#undef TRIE_HASH_THRESHOLD
#undef TRIE_BUCKET_RANK
#undef TRIE_BUCKET_SIZE
#undef TRIE_BUCKET_MASK
#undef TRIE_TRACE
#undef TRIE_DBG
#undef TRIE_HASH_FOR_ALL
#undef TRIE_HASH_END_FOR

#undef TRIE_WANT_CLEANUP

#undef TRIE_WANT_DO_FIND
#undef TRIE_WANT_DO_LOOKUP
#undef TRIE_WANT_DO_DELETE

#undef TRIE_WANT_FIND
#undef TRIE_WANT_FIND_BUF
#undef TRIE_WANT_ADD
#undef TRIE_WANT_ADD_OVER
#undef TRIE_WANT_DELETE
#undef TRIE_WANT_DELETE_BUF
#undef TRIE_WANT_REMOVE

#undef TRIE_WANT_AUDIT