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btrie.c
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btrie.c
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/* Level-Compressed Tree Bitmap (LC-TBM) Trie implementation
*
* Contributed by Geoffrey T. Dairiki <[email protected]>
*
* This file is released under a "Three-clause BSD License".
*
* Copyright (c) 2013, Geoffrey T. Dairiki
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
*
* * Neither the name of Geoffrey T. Dairiki nor the names of other
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL GEOFFREY
* T. DAIRIKI BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE
* USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH
* DAMAGE.
*/
/*****************************************************************
*
* This code implements a routing table conceptually based on a binary
* trie structure. Internally, the trie is represented by two types
* of compound nodes: "multibit nodes", which contain the top few
* levels of an entire binary subtree; and "level compression" (LC)
* nodes which represent a (potentially long) chain of out-degree one
* (single child) binary nodes (possibly ending at a terminal node).
*
* The multibit nodes are represented using a "Tree Bitmap" structure
* (more on this below), which is very efficient --- both in terms of
* memory usage and lookup speed --- at representing densely branching
* parts of the trie. The LC nodes can efficiently represent long
* non-branching chains of binary trie nodes. Using both node types
* together results in efficient representation of both the sparse and
* dense parts of a binary trie.
*
* Graphically, here's the rough idea:
*
* ........
* .LC o .
* . / . LC nodes can
* . o . <= represent long chains
* . \ . of (non-branching) binary
* . o . trie nodes
* . / .
* . o .
* ......../.....
* .TBM o .
* . / \ . TBM nodes can represent
* . o * . <= several levels of densely
* . / \ . branching binary trie nodes
* . o o .
* ......./.....\.......
* .TBM o .. o LC.
* . / \ .. \ .
* . o o .. o .
* . / / \ .. \ .
* . * o *.. o .
* ...../....... / .
* . o LC. . o .
* . \ . .....\......
* . * . . o TBM.
* ........ . / \ .
* . o o .
* . / \ \ .
* .* * *.
* ...........
*
* Terminology
* -----------
*
* node
* Usually, in the comments below, "node" will be used to refer to
* a compound node: either a multibit (TBM) node or an LC node.
*
* "internal node" or "prefix"
* The terms "prefix" or "internal node" are used to refer to
* a node in the binary trie which is internal to a multibit (TBM)
* node.
*
* ----------------------------------------------------------------
*
* Internal Representation of the Nodes
* ====================================
*
* Multibit (TBM) Nodes
* ~~~~~~~~~~~~~~~~~~~~
*
* The multibit nodes are represented using a "Tree Bitmap" (TBM)
* structure as described by Eatherton, Dittia and Varghese[1]. See
* the paper referenced below for basic details.
*
* A multibit node, represents several levels of a binary trie.
* For example, here is a multibit node of stride 2 (which represent
* two levels of a binary trie.
*
* +------- | ------+
* | multi o |
* | bit / \ |
* | node / \ |
* | o * |
* +--- / \ - / \ --+
* O
*
* Note that, for a multibit node of stride S, there are 2^S - 1 internal
* nodes, each of which may have data (or not) associated with them, and
* 2^S "external paths" leading to other (possibly compound nodes).
* (In the diagram above, one of three internal node (the one denoted by "*")
* has data, and one of four extending paths leads to an external node
* (denoted by the 'O').)
*
* The TBM structure can represent these bitmaps in a very memory-efficient
* manner.
*
* Each TBM node consists of two bitmaps --- the "internal bitmap" and the
* "extending paths bitmap" --- and a pointer which points to an array
* which contains both the extending path ("child") nodes and any
* internal prefix data for the TBM node.
*
* +--------+--------+
* TBM | ext bm | int bm |
* Node +--------+--------+
* | pointer |----+
* +-----------------+ |
* |
* |
* +-----------------+ |
* | extending path | |
* | node[N-1] | |
* +-----------------+ |
* / ... / |
* / ... / |
* +-----------------+ |
* | extending path | |
* | node[0] | |
* +-----------------+<---+
* | int. data[M-1] |
* +-----------------+
* / ... /
* +-----------------+
* | int. data[0] |
* +-----------------+
*
* The extending paths bitmap (or "ext bitmap") has one bit for each
* possible "extending path" from the bottom of the multibit node. To
* check if a particular extending path is present, one checks to see if
* the corresponding bit is set in the ext bitmap. The index into the
* array of children for that path can be found by counting the number
* of set bits to the left of that bit.
*
* Similary, the internal bitmap has one bit for each binary node
* which is internal to the multibit node. To determine whether there
* is data stored for an internal prefix, one checks the corresponding
* bit in the internal bitmap. As for extending paths, the index into
* the array of internal data is found by counting the number of set
* bits to the left of that bit.
*
* To save space in the node structure, the node data array is stored
* contiguously with the node extending path array. The single
* ("children") pointer in the TBM structure points to the beginning
* of the array of extending path nodes and to (one past) the end of
* the the internal data array.
*
* The multibit stride is chosen so that the entire TBM node structure fits
* in the space of two pointers. On 32 bit machines this means the stride
* is four (each of the two bitmaps is 16 bits); on 32 bit machines the
* stride is five.
*
* Note that there are only 2^stride - 1 internal prefixes in a TBM
* node. That means there is one unused bit in the internal bitmap.
* We require that that bit must always be clear for a TBM node. (If
* set, it indicates that the structure represents, instead, an LC
* node. See below.)
*
* ----------------------------------------------------------------
*
* Level Compression (LC) Nodes
* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
*
* LC nodes are used to represent a chain of out-degree-one (single
* child) prefixes in the binary trie. The are represented by a bit
* string (the "relative prefix") along with its length and a pointer
* to the extending path (the next node past the LC node.)
*
*
* Non-Terminal LC Node:
*
* +------------------+-------+
* | relative prefix |1|0|len|
* +------------------+-------+
* | ptr.child |--+
* +--------------------------+ |
* |
* |
* +--------------------------+ |
* | Next node - | |
* | either LC or TBM | |
* | | |
* +--------------------------+<-+
*
* The Relative Prefix
* -------------------
*
* The maximum relative prefix per LC node is selected so that (again)
* the entire node structure fits in the space of two pointers. On 32 bit
* machines, the maximum relative prefix is 24 bits; on 62 bit machines
* the limit is 56 bits.
*
* In the LC node structure, the relative prefix is stored as an array
* of bytes. To avoid some bit-shifting during tree searches, these
* bytes are byte-aligned with the global prefix. In other words, in
* general there are (pos % 8) "pad" bits at the beginning of the
* relative prefix --- where pos "starting bit" (or depth in the
* binary tree) of the LC node --- which really belong to the parent
* node(s) of the LC node. For efficiency (so that we don't have to
* mask them out when matching) we require that these pad bits be
* correct --- they must match the path which leads to the LC node.
*
* The relative prefix length stored in the LC node structure does not
* count the pad bits.
*
* Terminal Node Compression
* -------------------------
*
* For memory efficiency, we also support "terminal LC" nodes. When
* the extension path from an LC node consists a single terminal node,
* we store that terminal nodes data directly in the parent LC node.
*
* Instead of this:
*
* +------------------+-------+
* | relative prefix |1|0|len|
* +------------------+-------+
* | ptr.child |--+
* +--------------------------+ |
* |
* +--------------------------+ |
* | Terminal Node (TBM node, | |
* | empty except for the | |
* +--| root internal node.) | |
* | +--------------------------+<-+
* |
* +->+--------------------------+
* | terminal node data |
* +--------------------------+
*
* We can do this:
*
* +------------------+-------+
* | relative prefix |1|1|len|
* +------------------+-------+
* | terminal node data |
* +--------------------------+
*
* Terminal LC nodes are differentiated from non-terminal LC nodes
* by the setting of the is_terminal flag.
*
* Node Structure Packing Details
* ------------------------------
*
* The LC and TBM node structures are carefully packed so that the
* "is_lc" flag (which indicates that a node is an LC node)
* corresponds to the one unused bit in the internal bitmap of the TBM
* node structure (which we require to be zero for TBM nodes).
*
* ----------------------------------------------------------------
*
* References
* ==========
*
* [1] Will Eatherton, George Varghese, and Zubin Dittia. 2004. Tree
* bitmap: hardware/software IP lookups with incremental
* updates. SIGCOMM Comput. Commun. Rev. 34, 2 (April 2004),
* 97-122. DOI=10.1145/997150.997160
* http://doi.acm.org/10.1145/997150.997160
* http://comnet.kaist.ac.kr/yhlee/CN_2008_Spring/readings/Eath-04-tree_bitmap.pdf
*
****************************************************************/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <setjmp.h>
#if defined(TEST) && defined(NDEBUG)
# warning undefining NDEBUG for TEST build
# undef NDEBUG
#endif
#include <assert.h>
#include "btrie.h"
#include "mempool.h"
#if __SIZEOF_POINTER__ == 4
# define TBM_STRIDE 4
#elif __SIZEOF_POINTER__ == 8
# define TBM_STRIDE 5
#else
# error "Unsupported word size"
#endif
#ifndef NO_STDINT_H
# if TBM_STRIDE == 4
typedef uint16_t tbm_bitmap_t;
# else
typedef uint32_t tbm_bitmap_t;
# endif
#else /* NO_STDINT_H */
# if TBM_STRIDE == 4
# if SIZEOF_SHORT == 2
typedef short unsigned tbm_bitmap_t;
# else
# error "can not determine type for 16 bit unsigned int"
# endif
# else /* TBM_STRIDE == 5 */
# if SIZEOF_INT == 4
typedef unsigned tbm_bitmap_t;
# elif SIZEOF_LONG == 4
typedef long unsigned tbm_bitmap_t;
# else
# error "can not determine type for 32 bit unsigned int"
# endif
# endif
#endif
#define TBM_FANOUT (1U << TBM_STRIDE)
#define LC_BYTES_PER_NODE (__SIZEOF_POINTER__ - 1)
typedef union node_u node_t;
/* The tbm_node and lc_node structs must be packed so that the the
* high bit (LC_FLAGS_IS_LC) of lc_flags in the the lc_node struct
* coincides with bit zero (the most significant bit) of tbm_node's
* int_bm. (This bit is how we differentiate between the two node
* types. It is always clear for a tbm_node and always set for an
* lc_node.)
*/
struct tbm_node {
#ifdef WORDS_BIGENDIAN
tbm_bitmap_t int_bm; /* the internal bitmap */
tbm_bitmap_t ext_bm; /* extending path ("external") bitmap */
#else
tbm_bitmap_t ext_bm; /* extending path ("external") bitmap */
tbm_bitmap_t int_bm; /* the internal bitmap */
#endif
union {
node_t *children; /* pointer to array of children */
const void **data_end; /* one past end of internal prefix data array */
} ptr;
};
struct lc_node {
/* lc_flags contains the LC prefix length and a couple of bit flags
* (apparently char-sized bit fields are a gcc extension)
*/
# define LC_FLAGS_IS_LC 0x80
# define LC_FLAGS_IS_TERMINAL 0x40
# define LC_FLAGS_LEN_MASK 0x3f
#ifdef WORDS_BIGENDIAN
btrie_oct_t lc_flags;
btrie_oct_t prefix[LC_BYTES_PER_NODE];
#else
btrie_oct_t prefix[LC_BYTES_PER_NODE];
btrie_oct_t lc_flags;
#endif
union {
node_t *child; /* pointer to child (if !is_terminal) */
const void *data; /* the prefix data (if is_terminal) */
} ptr;
};
union node_u {
struct tbm_node tbm_node;
struct lc_node lc_node;
};
struct free_hunk {
struct free_hunk *next;
};
#define MAX_CHILD_ARRAY_LEN (TBM_FANOUT + TBM_FANOUT / 2)
struct btrie {
node_t root;
struct mempool *mp;
struct free_hunk *free_list[MAX_CHILD_ARRAY_LEN];
jmp_buf exception;
/* mem mgmt stats */
size_t alloc_total; /* total bytes allocated from mempool */
size_t alloc_data; /* bytes allocated for TBM node int. prefix data */
size_t alloc_waste; /* bytes wasted by rounding of data array size */
#ifdef BTRIE_DEBUG_ALLOC
size_t alloc_hist[MAX_CHILD_ARRAY_LEN * 2]; /* histogram of alloc sizes */
#endif
/* trie stats */
size_t n_entries; /* number of entries */
size_t n_tbm_nodes; /* total number of TBM nodes in tree */
size_t n_lc_nodes; /* total number of LC nodes in tree */
};
/****************************************************************
*
* Memory management
*
* We will need to frequently resize child/data arrays. The current
* mempool implementation does not support resizing/freeing, so here
* we roll our own.
*/
static inline void
_free_hunk(struct btrie *btrie, void *buf, unsigned n_nodes)
{
struct free_hunk *hunk = buf;
hunk->next = btrie->free_list[n_nodes - 1];
btrie->free_list[n_nodes - 1] = hunk;
}
static inline void *
_get_hunk(struct btrie *btrie, unsigned n_nodes)
{
struct free_hunk *hunk = btrie->free_list[n_nodes - 1];
if (hunk != NULL)
btrie->free_list[n_nodes - 1] = hunk->next;
return hunk;
}
/* Get pointer to uninitialized child/data array.
*
* Allocates memory for an array of NDATA (void *)s followed by an
* array of NCHILDREN (node_t)s. The returned pointer points to to
* beginning of the children array (i.e. it points to (one past) the
* end of the data array.)
*/
static node_t *
alloc_nodes(struct btrie *btrie, unsigned nchildren, unsigned ndata)
{
size_t n_nodes = nchildren + (ndata + 1) / 2;
node_t *hunk;
assert(n_nodes > 0 && n_nodes <= MAX_CHILD_ARRAY_LEN);
hunk = _get_hunk(btrie, n_nodes);
if (hunk == NULL) {
/* Do not have free hunk of exactly the requested size, look for a
* larger hunk. (The funny order in which we scan the buckets is
* heuristically selected in an attempt to minimize unnecessary
* creation of small fragments)
*/
size_t n, skip = n_nodes > 4 ? 4 : n_nodes;
for (n = n_nodes + skip; n <= MAX_CHILD_ARRAY_LEN; n++) {
if ((hunk = _get_hunk(btrie, n)) != NULL) {
_free_hunk(btrie, hunk + n_nodes, n - n_nodes);
goto DONE;
}
}
for (n = n_nodes + 1; n < n_nodes + skip && n <= MAX_CHILD_ARRAY_LEN; n++) {
if ((hunk = _get_hunk(btrie, n)) != NULL) {
_free_hunk(btrie, hunk + n_nodes, n - n_nodes);
goto DONE;
}
}
/* failed to find free hunk, allocate a fresh one */
hunk = mp_alloc(btrie->mp, n_nodes * sizeof(node_t), 1);
if (hunk == NULL)
longjmp(btrie->exception, BTRIE_ALLOC_FAILED);
btrie->alloc_total += n_nodes * sizeof(node_t);
}
DONE:
btrie->alloc_data += ndata * sizeof(void *);
btrie->alloc_waste += (ndata % 2) * sizeof(void *);
#ifdef BTRIE_DEBUG_ALLOC
btrie->alloc_hist[2 * nchildren + ndata]++;
#endif
/* adjust pointer to allow room for data array before child array */
return hunk + (ndata + 1) / 2;
}
/* Free memory allocated by alloc_nodes */
static void
free_nodes(struct btrie *btrie, node_t *buf, unsigned nchildren, unsigned ndata)
{
size_t n_nodes = nchildren + (ndata + 1) / 2;
assert(n_nodes > 0 && n_nodes <= MAX_CHILD_ARRAY_LEN);
_free_hunk(btrie, buf - (ndata + 1) / 2, n_nodes);
btrie->alloc_data -= ndata * sizeof(void *);
btrie->alloc_waste -= (ndata % 2) * sizeof(void *);
#ifdef BTRIE_DEBUG_ALLOC
btrie->alloc_hist[2 * nchildren + ndata]--;
#endif
}
/* Debugging/development only: */
#ifdef BTRIE_DEBUG_ALLOC
static void
dump_alloc_hist(const struct btrie *btrie)
{
unsigned bin;
size_t total_alloc = 0;
size_t total_free = 0;
size_t total_bytes = 0;
size_t total_waste = 0;
size_t total_free_bytes = 0;
puts("hunk alloc free alloc wasted free");
puts("size hunks hunks bytes bytes bytes");
puts("==== ====== ====== ======== ======== ========");
for (bin = 1; bin < 2 * MAX_CHILD_ARRAY_LEN; bin++) {
size_t n_alloc = btrie->alloc_hist[bin];
size_t bytes = n_alloc * bin * sizeof(void *);
size_t waste_bytes = (bin % 2) * n_alloc * sizeof(void *);
size_t n_free = 0, free_bytes;
if (bin % 2 == 0) {
const struct free_hunk *hunk;
for (hunk = btrie->free_list[bin / 2 - 1]; hunk; hunk = hunk->next)
n_free++;
}
free_bytes = n_free * bin * sizeof(void *);
printf("%3zu: %6zu %6zu %8zu %8zu %8zu\n", bin * sizeof(void *),
n_alloc, n_free, bytes, waste_bytes, free_bytes);
total_alloc += n_alloc;
total_free += n_free;
total_bytes += bytes;
total_waste += waste_bytes;
total_free_bytes += free_bytes;
}
puts("---- ------ ------ -------- -------- --------");
printf("SUM: %6zu %6zu %8zu %8zu %8zu\n",
total_alloc, total_free, total_bytes, total_waste, total_free_bytes);
}
#endif
/****************************************************************
*
* Bit twiddling
*
*/
static inline tbm_bitmap_t
bit(unsigned b)
{
return 1U << ((1 << TBM_STRIDE) - 1 - b);
}
/* count the number of set bits in bitmap
*
* algorithm from
* http://graphics.stanford.edu/~seander/bithacks.html#CountBitsSetParallel
*/
static inline unsigned
count_bits(tbm_bitmap_t v)
{
/* Count set bits in parallel. */
/* v = (v & 0x5555...) + ((v >> 1) & 0x5555...); */
v -= (v >> 1) & (tbm_bitmap_t)~0UL/3;
/* v = (v & 0x3333...) + ((v >> 2) & 0x3333...); */
v = (v & (tbm_bitmap_t)~0UL/5) + ((v >> 2) & (tbm_bitmap_t)~0UL/5);
/* v = (v & 0x0f0f...) + ((v >> 4) & 0x0f0f...); */
v = (v + (v >> 4)) & (tbm_bitmap_t)~0UL/17;
/* v = v % 255; */
#if TBM_STRIDE == 4
/* tbm_bitmap_t is uint16_t, avoid the multiply */
return (v + (v >> 8)) & 0x0ff;
#else
return (v * (tbm_bitmap_t)(~0UL/255)) >> ((sizeof(tbm_bitmap_t) - 1) * 8);
#endif
}
static inline unsigned
count_bits_before(tbm_bitmap_t bm, int b)
{
return b ? count_bits(bm >> ((1 << TBM_STRIDE) - b)) : 0;
}
static inline unsigned
count_bits_from(tbm_bitmap_t bm, int b)
{
return count_bits(bm << b);
}
/* extracts a few bits from bitstring, returning them as an integer */
static inline btrie_oct_t
extract_bits(const btrie_oct_t *prefix, unsigned pos, unsigned nbits)
{
if (nbits == 0)
return 0;
else {
unsigned v = (prefix[pos / 8] << 8) + prefix[pos / 8 + 1];
return (v >> (16 - nbits - pos % 8)) & ((1U << nbits) - 1);
}
}
static inline unsigned
extract_bit(const btrie_oct_t *prefix, int pos)
{
return (prefix[pos / 8] >> (7 - pos % 8)) & 0x01;
}
/* get mask for high n bits of a byte */
static inline btrie_oct_t
high_bits(unsigned n)
{
return (btrie_oct_t) -(1U << (8 - n));
}
/* determine whether two prefixes are equal */
static inline int
prefixes_equal(const btrie_oct_t *pfx1, const btrie_oct_t *pfx2, unsigned len)
{
return (memcmp(pfx1, pfx2, len / 8) == 0
&& ((pfx1[len / 8] ^ pfx2[len / 8]) & high_bits(len % 8)) == 0);
}
/* determine length of longest common subprefix */
static inline unsigned
common_prefix(const btrie_oct_t *pfx1, const btrie_oct_t *pfx2, unsigned len)
{
/* algorithm adapted from
* http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogLookup
*/
static btrie_oct_t leading_zeros[] = {
8, 7, 6, 6, 5, 5, 5, 5, 4, 4, 4, 4, 4, 4, 4, 4,
3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3,
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
};
unsigned nb;
for (nb = 0; nb < len / 8; nb++) {
unsigned diff = *pfx1++ ^ *pfx2++;
if (diff != 0)
return 8 * nb + leading_zeros[diff];
}
if (len % 8) {
unsigned n = leading_zeros[*pfx1 ^ *pfx2];
if (n < len % 8)
return 8 * nb + n;
}
return len;
}
/****************************************************************
*/
static inline int
is_empty_node(const node_t *node)
{
return node->tbm_node.ext_bm == 0 && node->tbm_node.int_bm == 0;
}
static inline int
is_lc_node(const node_t *node)
{
return (node->lc_node.lc_flags & LC_FLAGS_IS_LC) != 0;
}
static inline int
is_tbm_node(const node_t *node)
{
return !is_lc_node(node);
}
/* is node a TBM node with internal data? */
static inline int
has_data(const node_t *node)
{
return is_tbm_node(node) && node->tbm_node.int_bm != 0;
}
static inline unsigned
base_index(unsigned pfx, unsigned plen)
{
assert(plen < TBM_STRIDE);
assert(pfx < (1U << plen));
return pfx | (1U << plen);
}
/* initialize node to an empty TBM node */
static inline void
init_empty_node(struct btrie *btrie, node_t *node)
{
memset(node, 0, sizeof(*node));
btrie->n_tbm_nodes++;
}
/* get pointer to TBM internal prefix data */
static inline const void **
tbm_data_p(const struct tbm_node *node, unsigned pfx, unsigned plen)
{
unsigned bi = base_index(pfx, plen);
if ((node->int_bm & bit(bi)) == 0)
return NULL; /* no data */
else {
return &node->ptr.data_end[ -(int)count_bits_from(node->int_bm, bi) ];
}
}
/* add an element to the internal data array */
static void
tbm_insert_data(struct btrie *btrie, struct tbm_node *node,
unsigned pfx, unsigned plen, const void *data)
{
/* XXX: don't realloc if already big enough? */
unsigned bi = base_index(pfx, plen);
unsigned nchildren = count_bits(node->ext_bm);
int ndata = count_bits(node->int_bm);
unsigned di = count_bits_before(node->int_bm, bi);
node_t *old_children = node->ptr.children;
const void **old_data_beg = node->ptr.data_end - ndata;
const void **data_beg;
assert((node->int_bm & bit(bi)) == 0);
node->ptr.children = alloc_nodes(btrie, nchildren, ndata + 1);
data_beg = node->ptr.data_end - (ndata + 1);
data_beg[di] = data;
node->int_bm |= bit(bi);
if (nchildren != 0 || ndata != 0) {
memcpy(data_beg, old_data_beg, di * sizeof(data_beg[0]));
memcpy(&data_beg[di + 1], &old_data_beg[di],
(ndata - di) * sizeof(data_beg[0]) + nchildren * sizeof(node_t));
free_nodes(btrie, old_children, nchildren, ndata);
}
}
/* determine whether TBM has internal prefix data for pfx/plen or ancestors */
static inline int
has_internal_data(const struct tbm_node *node, unsigned pfx, unsigned plen)
{
# define BIT(n) (1U << ((1 << TBM_STRIDE) - 1 - (n)))
# define B0() BIT(1) /* the bit for 0/0 */
# define B1(n) (BIT((n) + 2) | B0()) /* the bits for n/1 and its ancestors */
# define B2(n) (BIT((n) + 4) | B1(n >> 1)) /* the bits for n/2 and ancestors */
# define B3(n) (BIT((n) + 8) | B2(n >> 1)) /* the bits for n/3 and ancestors */
# define B4(n) (BIT((n) + 16) | B3(n >> 1)) /* the bits for n/4 and ancestors */
static tbm_bitmap_t ancestors[] = {
0, B0(),
B1(0), B1(1),
B2(0), B2(1), B2(2), B2(3),
B3(0), B3(1), B3(2), B3(3), B3(4), B3(5), B3(6), B3(7),
# if TBM_STRIDE == 5
B4(0), B4(1), B4(2), B4(3), B4(4), B4(5), B4(6), B4(7),
B4(8), B4(9), B4(10), B4(11), B4(12), B4(13), B4(14), B4(15),
# elif TBM_STRIDE != 4
# error "unsupported TBM_STRIDE"
# endif
};
# undef B4
# undef B3
# undef B2
# undef B1
# undef B0
# undef BIT
return (node->int_bm & ancestors[base_index(pfx, plen)]) != 0;
}
/* get pointer to TBM extending path */
static inline node_t *
tbm_ext_path(const struct tbm_node *node, unsigned pfx)
{
if ((node->ext_bm & bit(pfx)) == 0)
return NULL;
else
return &node->ptr.children[count_bits_before(node->ext_bm, pfx)];
}
/* resize TBM node child array to make space for new child node */
static node_t *
tbm_insert_ext_path(struct btrie *btrie, struct tbm_node *node, unsigned pfx)
{
unsigned nchildren = count_bits(node->ext_bm);
unsigned ci = count_bits_before(node->ext_bm, pfx);
int ndata = count_bits(node->int_bm);
node_t *old_children = node->ptr.children;
const void **old_data_beg = node->ptr.data_end - ndata;
assert ((node->ext_bm & bit(pfx)) == 0);
node->ptr.children = alloc_nodes(btrie, nchildren + 1, ndata);
init_empty_node(btrie, &node->ptr.children[ci]);
node->ext_bm |= bit(pfx);
if (nchildren != 0 || ndata != 0) {
const void **data_beg = node->ptr.data_end - ndata;
memcpy(data_beg, old_data_beg,
ndata * sizeof(data_beg[0]) + ci * sizeof(node_t));
memcpy(&node->ptr.children[ci + 1], &old_children[ci],
(nchildren - ci) * sizeof(old_children[0]));
free_nodes(btrie, old_children, nchildren, ndata);
}
return &node->ptr.children[ci];
}
static inline int
lc_is_terminal(const struct lc_node *node)
{
return (node->lc_flags & LC_FLAGS_IS_TERMINAL) != 0;
}
static inline unsigned
lc_len(const struct lc_node *node)
{
return node->lc_flags & LC_FLAGS_LEN_MASK;
}
static inline void
lc_init_flags(struct lc_node *node, int is_terminal, unsigned len)
{
assert((len & ~LC_FLAGS_LEN_MASK) == 0);
node->lc_flags = LC_FLAGS_IS_LC | len;
if (is_terminal)
node->lc_flags |= LC_FLAGS_IS_TERMINAL;
}
static inline void
lc_add_to_len(struct lc_node *node, int increment)
{
unsigned new_len = lc_len(node) + increment;
assert((new_len & ~LC_FLAGS_LEN_MASK) == 0);
node->lc_flags = (node->lc_flags & ~LC_FLAGS_LEN_MASK) | new_len;
}
static inline unsigned
lc_shift(unsigned pos)
{
return pos / 8;
}
static inline unsigned
lc_base(unsigned pos)
{
return 8 * lc_shift(pos);
}
static inline unsigned
lc_bits(const struct lc_node *node, unsigned pos)
{
return pos % 8 + lc_len(node);
}
static inline unsigned
lc_bytes(const struct lc_node *node, unsigned pos)
{
return (lc_bits(node, pos) + 7) / 8;
}
static inline unsigned
lc_leading_bits(const struct lc_node *node, unsigned pos, unsigned nbits)
{
return extract_bits(node->prefix, pos % 8, nbits);
}
/* Initialize a new terminal LC node
*
* If prefix is too long to fit in a single LC node, then a chain
* of LC nodes will be created.
*/
static void
init_terminal_node(struct btrie *btrie, node_t *dst, unsigned pos,
const btrie_oct_t *prefix, unsigned len, const void *data)
{
struct lc_node *node = &dst->lc_node;
unsigned nbytes = (len + 7) / 8;
while (nbytes - lc_shift(pos) > LC_BYTES_PER_NODE) {
memcpy(node->prefix, prefix + lc_shift(pos), LC_BYTES_PER_NODE);
lc_init_flags(node, 0, 8 * LC_BYTES_PER_NODE - pos % 8);
node->ptr.child = alloc_nodes(btrie, 1, 0);
pos += lc_len(node);
node = &node->ptr.child->lc_node;
btrie->n_lc_nodes++;
}
memcpy(node->prefix, prefix + lc_shift(pos), nbytes - lc_shift(pos));
lc_init_flags(node, 1, len - pos);
node->ptr.data = data;
btrie->n_lc_nodes++;
}
/* merge chains of multiple LC nodes into a single LC node, if possible.
*
* also ensure that the leading nodes in the LC chain have maximum length.
*/
static void
coalesce_lc_node(struct btrie *btrie, struct lc_node *node, unsigned pos)
{
while (! lc_is_terminal(node)
&& lc_bits(node, pos) < 8 * LC_BYTES_PER_NODE
&& is_lc_node(node->ptr.child)) {
struct lc_node *child = &node->ptr.child->lc_node;
unsigned spare_bits = 8 * LC_BYTES_PER_NODE - lc_bits(node, pos);
unsigned end = pos + lc_len(node);
unsigned shift = lc_shift(end) - lc_shift(pos);
if (lc_len(child) <= spare_bits) {
/* node plus child will fit in single node - merge */
memcpy(node->prefix + shift, child->prefix,
lc_bytes(child, end));
lc_init_flags(node, lc_is_terminal(child), lc_len(node) + lc_len(child));
node->ptr = child->ptr;
free_nodes(btrie, (node_t *)child, 1, 0);
btrie->n_lc_nodes--;
}
else {
/* can't merge, but can take some of childs bits */
unsigned cshift = lc_shift(end + spare_bits) - lc_shift(end);
memcpy(node->prefix + shift, child->prefix, LC_BYTES_PER_NODE - shift);
lc_add_to_len(node, spare_bits);
if (cshift)
memmove(child->prefix, child->prefix + cshift,
lc_bytes(child, end) - cshift);
assert(lc_len(child) > spare_bits);
lc_add_to_len(child, -spare_bits);
pos += lc_len(node);
node = child;
}
}
}
static void init_tbm_node(struct btrie *btrie, node_t *node, unsigned pos,
const btrie_oct_t pbyte,
const void **root_data_p,
node_t *left, node_t *right);
/* given an LC node at orig_pos, create a new (shorter) node at pos */
static void
shorten_lc_node(struct btrie *btrie, node_t *dst, unsigned pos,
struct lc_node *src, unsigned orig_pos)
{
assert(orig_pos < pos);
assert(lc_len(src) >= pos - orig_pos);
assert(dst != (node_t *)src);
if (lc_len(src) == pos - orig_pos && !lc_is_terminal(src)) {
/* just steal the child */
node_t *child = src->ptr.child;
*dst = *child;
free_nodes(btrie, child, 1, 0);
btrie->n_lc_nodes--;
}