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author | David Robillard <d@drobilla.net> | 2014-09-23 23:03:12 +0000 |
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committer | David Robillard <d@drobilla.net> | 2014-09-23 23:03:12 +0000 |
commit | 3fcde96f3361d0bc30b2b8f8e330a87cd51ef6d2 (patch) | |
tree | dc69564fd5b84d6b9cc9d88ac9c3753c4f98eae5 /src | |
parent | 21382932fd8df75884c3e21917d9dbd4527d78ac (diff) | |
download | sord-3fcde96f3361d0bc30b2b8f8e330a87cd51ef6d2.tar.gz sord-3fcde96f3361d0bc30b2b8f8e330a87cd51ef6d2.tar.bz2 sord-3fcde96f3361d0bc30b2b8f8e330a87cd51ef6d2.zip |
Fix B-tree on 32-bit systems.
git-svn-id: http://svn.drobilla.net/sord/trunk@308 3d64ff67-21c5-427c-a301-fe4f08042e5a
Diffstat (limited to 'src')
-rw-r--r-- | src/zix/btree.c | 61 |
1 files changed, 31 insertions, 30 deletions
diff --git a/src/zix/btree.c b/src/zix/btree.c index 26885e2..b03a6c5 100644 --- a/src/zix/btree.c +++ b/src/zix/btree.c @@ -25,8 +25,8 @@ // #define ZIX_BTREE_DEBUG 1 #define ZIX_BTREE_PAGE_SIZE 4096 -#define ZIX_BTREE_NODE_SPACE (ZIX_BTREE_PAGE_SIZE - 2 * sizeof(uint32_t)) -#define ZIX_BTREE_LEAF_VALS (ZIX_BTREE_NODE_SPACE / sizeof(void*)) +#define ZIX_BTREE_NODE_SPACE (ZIX_BTREE_PAGE_SIZE - 2 * sizeof(uint16_t)) +#define ZIX_BTREE_LEAF_VALS ((ZIX_BTREE_NODE_SPACE / sizeof(void*)) - 1) #define ZIX_BTREE_INODE_VALS (ZIX_BTREE_LEAF_VALS / 2) struct ZixBTreeImpl { @@ -39,8 +39,9 @@ struct ZixBTreeImpl { }; struct ZixBTreeNodeImpl { - uint32_t is_leaf; - uint32_t n_vals; + uint16_t is_leaf; + uint16_t n_vals; + // On 64-bit we rely on some padding here to get page-sized nodes void* vals[ZIX_BTREE_INODE_VALS]; // ZIX_BTREE_LEAF_VALS for leaves ZixBTreeNode* children[ZIX_BTREE_INODE_VALS + 1]; // Nonexistent for leaves }; @@ -51,7 +52,7 @@ typedef struct { } ZixBTreeIterFrame; struct ZixBTreeIterImpl { - unsigned level; ///< Current level in pos + unsigned level; ///< Current level in stack ZixBTreeIterFrame stack[]; ///< Position stack }; @@ -61,7 +62,7 @@ ZIX_PRIVATE void print_node(const ZixBTreeNode* n, const char* prefix) { printf("%s[", prefix); - for (unsigned v = 0; v < n->n_vals; ++v) { + for (uint16_t v = 0; v < n->n_vals; ++v) { printf(" %lu", (uintptr_t)n->vals[v]); } printf(" ]\n"); @@ -79,7 +80,7 @@ print_tree(const ZixBTreeNode* parent, const ZixBTreeNode* node, int level) } print_node(node, ""); if (!node->is_leaf) { - for (unsigned i = 0; i < node->n_vals + 1; ++i) { + for (uint16_t i = 0; i < node->n_vals + 1; ++i) { print_tree(node, node->children[i], level + 1); } } @@ -129,12 +130,12 @@ zix_btree_free_rec(ZixBTree* const t, ZixBTreeNode* const n) { if (n) { if (t->destroy) { - for (unsigned i = 0; i < n->n_vals; ++i) { + for (uint16_t i = 0; i < n->n_vals; ++i) { t->destroy(n->vals[i]); } } if (!n->is_leaf) { - for (unsigned i = 0; i < n->n_vals + 1; ++i) { + for (uint16_t i = 0; i < n->n_vals + 1; ++i) { zix_btree_free_rec(t, n->children[i]); } } @@ -157,13 +158,13 @@ zix_btree_size(const ZixBTree* const t) return t->size; } -ZIX_PRIVATE unsigned +ZIX_PRIVATE uint16_t zix_btree_max_vals(const ZixBTreeNode* const node) { return node->is_leaf ? ZIX_BTREE_LEAF_VALS : ZIX_BTREE_INODE_VALS; } -ZIX_PRIVATE unsigned +ZIX_PRIVATE uint16_t zix_btree_min_vals(const ZixBTreeNode* const node) { return ((zix_btree_max_vals(node) + 1) / 2) - 1; @@ -172,8 +173,8 @@ zix_btree_min_vals(const ZixBTreeNode* const node) /** Shift pointers in `array` of length `n` right starting at `i`. */ ZIX_PRIVATE void zix_btree_ainsert(void** const array, - const unsigned n, - const unsigned i, + const uint16_t n, + const uint16_t i, void* const e) { memmove(array + i + 1, array + i, (n - i) * sizeof(e)); @@ -182,7 +183,7 @@ zix_btree_ainsert(void** const array, /** Erase element `i` in `array` of length `n` and return erased element. */ ZIX_PRIVATE void* -zix_btree_aerase(void** const array, const unsigned n, const unsigned i) +zix_btree_aerase(void** const array, const uint16_t n, const uint16_t i) { void* const ret = array[i]; memmove(array + i, array + i + 1, (n - i) * sizeof(ret)); @@ -192,7 +193,7 @@ zix_btree_aerase(void** const array, const unsigned n, const unsigned i) /** Split lhs, the i'th child of `n`, into two nodes. */ ZIX_PRIVATE ZixBTreeNode* zix_btree_split_child(ZixBTreeNode* const n, - const uint32_t i, + const uint16_t i, ZixBTreeNode* const lhs) { assert(lhs->n_vals == zix_btree_max_vals(lhs)); @@ -200,7 +201,7 @@ zix_btree_split_child(ZixBTreeNode* const n, assert(i < n->n_vals + 1); assert(n->children[i] == lhs); - const unsigned max_n_vals = zix_btree_max_vals(lhs); + const uint16_t max_n_vals = zix_btree_max_vals(lhs); ZixBTreeNode* rhs = zix_btree_node_new(lhs->is_leaf); if (!rhs) { return NULL; @@ -232,23 +233,23 @@ zix_btree_split_child(ZixBTreeNode* const n, } /** Find the first value in `n` that is not less than `e` (lower bound). */ -ZIX_PRIVATE unsigned +ZIX_PRIVATE uint16_t zix_btree_node_find(const ZixBTree* const t, const ZixBTreeNode* const n, const void* const e, bool* const equal) { - unsigned first = 0; - unsigned len = n->n_vals; + uint16_t first = 0; + uint16_t len = n->n_vals; while (len > 0) { - const unsigned half = len >> 1; - const unsigned i = first + half; + const uint16_t half = len >> 1; + const uint16_t i = first + half; const int cmp = t->cmp(n->vals[i], e, t->cmp_data); if (cmp == 0) { *equal = true; len = half; // Keep searching for wildcard matches } else if (cmp < 0) { - const unsigned chop = half + 1; + const uint16_t chop = half + 1; first += chop; len -= chop; } else { @@ -264,7 +265,7 @@ zix_btree_insert(ZixBTree* const t, void* const e) { ZixBTreeNode* parent = NULL; // Parent of n ZixBTreeNode* n = t->root; // Current node - unsigned i = 0; // Index of n in parent + uint16_t i = 0; // Index of n in parent while (n) { if (n->n_vals == zix_btree_max_vals(n)) { // Node is full, split to ensure there is space for a leaf split @@ -325,7 +326,7 @@ zix_btree_node_is_minimal(ZixBTreeNode* const n) /** Enlarge left child by stealing a value from its right sibling. */ ZIX_PRIVATE ZixBTreeNode* -zix_btree_rotate_left(ZixBTreeNode* const parent, const unsigned i) +zix_btree_rotate_left(ZixBTreeNode* const parent, const uint16_t i) { ZixBTreeNode* const lhs = parent->children[i]; ZixBTreeNode* const rhs = parent->children[i + 1]; @@ -347,7 +348,7 @@ zix_btree_rotate_left(ZixBTreeNode* const parent, const unsigned i) /** Enlarge right child by stealing a value from its left sibling. */ ZIX_PRIVATE ZixBTreeNode* -zix_btree_rotate_right(ZixBTreeNode* const parent, const unsigned i) +zix_btree_rotate_right(ZixBTreeNode* const parent, const uint16_t i) { ZixBTreeNode* const lhs = parent->children[i - 1]; ZixBTreeNode* const rhs = parent->children[i]; @@ -371,7 +372,7 @@ zix_btree_rotate_right(ZixBTreeNode* const parent, const unsigned i) /** Move n[i] down, merge the left and right child, return the merged node. */ ZIX_PRIVATE ZixBTreeNode* -zix_btree_merge(ZixBTree* const t, ZixBTreeNode* const n, const unsigned i) +zix_btree_merge(ZixBTree* const t, ZixBTreeNode* const n, const uint16_t i) { ZixBTreeNode* const lhs = n->children[i]; ZixBTreeNode* const rhs = n->children[i + 1]; @@ -462,7 +463,7 @@ zix_btree_remove_rec(ZixBTree* const t, assert(n == t->root || !zix_btree_node_is_minimal(n)); bool equal = false; - const unsigned i = zix_btree_node_find(t, n, e, &equal); + const uint16_t i = zix_btree_node_find(t, n, e, &equal); if (n->is_leaf) { if (equal) { @@ -504,7 +505,7 @@ zix_btree_remove_rec(ZixBTree* const t, return zix_btree_remove_rec(t, lhs, e, removed); } else { // Both child's siblings are minimal, merge them - const unsigned m = (i < n->n_vals) ? i : i - 1; + const uint16_t m = (i < n->n_vals) ? i : i - 1; ZixBTreeNode* const merged = zix_btree_merge(t, n, m); return zix_btree_remove_rec(t, merged, e, removed); } @@ -550,7 +551,7 @@ zix_btree_find(const ZixBTree* const t, while (n) { bool equal = false; - const unsigned i = zix_btree_node_find(t, n, e, &equal); + const uint16_t i = zix_btree_node_find(t, n, e, &equal); // Update iterator stack (*ti)->stack[(*ti)->level].node = n; @@ -585,7 +586,7 @@ zix_btree_lower_bound(const ZixBTree* const t, while (n) { bool equal = false; - const unsigned i = zix_btree_node_find(t, n, e, &equal); + const uint16_t i = zix_btree_node_find(t, n, e, &equal); // Update iterator stack (*ti)->stack[(*ti)->level].node = n; |