983 lines
36 KiB
C
983 lines
36 KiB
C
/*-
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*******************************************************************************
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*
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* cpp macro implementation of left-leaning 2-3 red-black trees. Parent
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* pointers are not used, and color bits are stored in the least significant
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* bit of right-child pointers (if RB_COMPACT is defined), thus making node
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* linkage as compact as is possible for red-black trees.
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*
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* Usage:
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*
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* #include <stdint.h>
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* #include <stdbool.h>
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* #define NDEBUG // (Optional, see assert(3).)
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* #include <assert.h>
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* #define RB_COMPACT // (Optional, embed color bits in right-child pointers.)
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* #include <rb.h>
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* ...
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*
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*******************************************************************************
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*/
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#ifndef RB_H_
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#define RB_H_
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#ifdef RB_COMPACT
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/* Node structure. */
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#define rb_node(a_type) \
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struct { \
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a_type *rbn_left; \
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a_type *rbn_right_red; \
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}
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#else
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#define rb_node(a_type) \
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struct { \
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a_type *rbn_left; \
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a_type *rbn_right; \
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bool rbn_red; \
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}
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#endif
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/* Root structure. */
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#define rb_tree(a_type) \
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struct { \
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a_type *rbt_root; \
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a_type rbt_nil; \
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}
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/* Left accessors. */
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#define rbtn_left_get(a_type, a_field, a_node) \
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((a_node)->a_field.rbn_left)
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#define rbtn_left_set(a_type, a_field, a_node, a_left) do { \
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(a_node)->a_field.rbn_left = a_left; \
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} while (0)
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#ifdef RB_COMPACT
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/* Right accessors. */
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#define rbtn_right_get(a_type, a_field, a_node) \
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((a_type *) (((intptr_t) (a_node)->a_field.rbn_right_red) \
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& ((ssize_t)-2)))
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#define rbtn_right_set(a_type, a_field, a_node, a_right) do { \
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(a_node)->a_field.rbn_right_red = (a_type *) (((uintptr_t) a_right) \
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| (((uintptr_t) (a_node)->a_field.rbn_right_red) & ((size_t)1))); \
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} while (0)
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/* Color accessors. */
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#define rbtn_red_get(a_type, a_field, a_node) \
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((bool) (((uintptr_t) (a_node)->a_field.rbn_right_red) \
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& ((size_t)1)))
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#define rbtn_color_set(a_type, a_field, a_node, a_red) do { \
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(a_node)->a_field.rbn_right_red = (a_type *) ((((intptr_t) \
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(a_node)->a_field.rbn_right_red) & ((ssize_t)-2)) \
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| ((ssize_t)a_red)); \
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} while (0)
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#define rbtn_red_set(a_type, a_field, a_node) do { \
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(a_node)->a_field.rbn_right_red = (a_type *) (((uintptr_t) \
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(a_node)->a_field.rbn_right_red) | ((size_t)1)); \
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} while (0)
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#define rbtn_black_set(a_type, a_field, a_node) do { \
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(a_node)->a_field.rbn_right_red = (a_type *) (((intptr_t) \
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(a_node)->a_field.rbn_right_red) & ((ssize_t)-2)); \
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} while (0)
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#else
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/* Right accessors. */
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#define rbtn_right_get(a_type, a_field, a_node) \
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((a_node)->a_field.rbn_right)
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#define rbtn_right_set(a_type, a_field, a_node, a_right) do { \
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(a_node)->a_field.rbn_right = a_right; \
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} while (0)
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/* Color accessors. */
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#define rbtn_red_get(a_type, a_field, a_node) \
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((a_node)->a_field.rbn_red)
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#define rbtn_color_set(a_type, a_field, a_node, a_red) do { \
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(a_node)->a_field.rbn_red = (a_red); \
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} while (0)
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#define rbtn_red_set(a_type, a_field, a_node) do { \
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(a_node)->a_field.rbn_red = true; \
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} while (0)
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#define rbtn_black_set(a_type, a_field, a_node) do { \
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(a_node)->a_field.rbn_red = false; \
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} while (0)
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#endif
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/* Node initializer. */
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#define rbt_node_new(a_type, a_field, a_rbt, a_node) do { \
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rbtn_left_set(a_type, a_field, (a_node), &(a_rbt)->rbt_nil); \
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rbtn_right_set(a_type, a_field, (a_node), &(a_rbt)->rbt_nil); \
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rbtn_red_set(a_type, a_field, (a_node)); \
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} while (0)
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/* Tree initializer. */
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#define rb_new(a_type, a_field, a_rbt) do { \
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(a_rbt)->rbt_root = &(a_rbt)->rbt_nil; \
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rbt_node_new(a_type, a_field, a_rbt, &(a_rbt)->rbt_nil); \
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rbtn_black_set(a_type, a_field, &(a_rbt)->rbt_nil); \
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} while (0)
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/* Internal utility macros. */
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#define rbtn_first(a_type, a_field, a_rbt, a_root, r_node) do { \
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(r_node) = (a_root); \
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if ((r_node) != &(a_rbt)->rbt_nil) { \
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for (; \
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rbtn_left_get(a_type, a_field, (r_node)) != &(a_rbt)->rbt_nil;\
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(r_node) = rbtn_left_get(a_type, a_field, (r_node))) { \
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} \
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} \
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} while (0)
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#define rbtn_last(a_type, a_field, a_rbt, a_root, r_node) do { \
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(r_node) = (a_root); \
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if ((r_node) != &(a_rbt)->rbt_nil) { \
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for (; rbtn_right_get(a_type, a_field, (r_node)) != \
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&(a_rbt)->rbt_nil; (r_node) = rbtn_right_get(a_type, a_field, \
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(r_node))) { \
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} \
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} \
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} while (0)
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#define rbtn_rotate_left(a_type, a_field, a_node, r_node) do { \
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(r_node) = rbtn_right_get(a_type, a_field, (a_node)); \
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rbtn_right_set(a_type, a_field, (a_node), \
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rbtn_left_get(a_type, a_field, (r_node))); \
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rbtn_left_set(a_type, a_field, (r_node), (a_node)); \
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} while (0)
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#define rbtn_rotate_right(a_type, a_field, a_node, r_node) do { \
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(r_node) = rbtn_left_get(a_type, a_field, (a_node)); \
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rbtn_left_set(a_type, a_field, (a_node), \
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rbtn_right_get(a_type, a_field, (r_node))); \
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rbtn_right_set(a_type, a_field, (r_node), (a_node)); \
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} while (0)
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/*
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* The rb_proto() macro generates function prototypes that correspond to the
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* functions generated by an equivalently parameterized call to rb_gen().
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*/
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#define rb_proto(a_attr, a_prefix, a_rbt_type, a_type) \
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a_attr void \
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a_prefix##new(a_rbt_type *rbtree); \
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a_attr bool \
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a_prefix##empty(a_rbt_type *rbtree); \
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a_attr a_type * \
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a_prefix##first(a_rbt_type *rbtree); \
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a_attr a_type * \
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a_prefix##last(a_rbt_type *rbtree); \
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a_attr a_type * \
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a_prefix##next(a_rbt_type *rbtree, a_type *node); \
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a_attr a_type * \
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a_prefix##prev(a_rbt_type *rbtree, a_type *node); \
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a_attr a_type * \
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a_prefix##search(a_rbt_type *rbtree, a_type *key); \
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a_attr a_type * \
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a_prefix##nsearch(a_rbt_type *rbtree, a_type *key); \
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a_attr a_type * \
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a_prefix##psearch(a_rbt_type *rbtree, a_type *key); \
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a_attr void \
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a_prefix##insert(a_rbt_type *rbtree, a_type *node); \
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a_attr void \
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a_prefix##remove(a_rbt_type *rbtree, a_type *node); \
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a_attr a_type * \
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a_prefix##iter(a_rbt_type *rbtree, a_type *start, a_type *(*cb)( \
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a_rbt_type *, a_type *, void *), void *arg); \
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a_attr a_type * \
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a_prefix##reverse_iter(a_rbt_type *rbtree, a_type *start, \
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a_type *(*cb)(a_rbt_type *, a_type *, void *), void *arg);
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/*
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* The rb_gen() macro generates a type-specific red-black tree implementation,
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* based on the above cpp macros.
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*
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* Arguments:
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*
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* a_attr : Function attribute for generated functions (ex: static).
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* a_prefix : Prefix for generated functions (ex: ex_).
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* a_rb_type : Type for red-black tree data structure (ex: ex_t).
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* a_type : Type for red-black tree node data structure (ex: ex_node_t).
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* a_field : Name of red-black tree node linkage (ex: ex_link).
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* a_cmp : Node comparison function name, with the following prototype:
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* int (a_cmp *)(a_type *a_node, a_type *a_other);
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* ^^^^^^
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* or a_key
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* Interpretation of comparision function return values:
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* -1 : a_node < a_other
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* 0 : a_node == a_other
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* 1 : a_node > a_other
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* In all cases, the a_node or a_key macro argument is the first
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* argument to the comparison function, which makes it possible
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* to write comparison functions that treat the first argument
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* specially.
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*
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* Assuming the following setup:
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*
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* typedef struct ex_node_s ex_node_t;
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* struct ex_node_s {
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* rb_node(ex_node_t) ex_link;
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* };
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* typedef rb_tree(ex_node_t) ex_t;
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* rb_gen(static, ex_, ex_t, ex_node_t, ex_link, ex_cmp)
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*
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* The following API is generated:
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*
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* static void
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* ex_new(ex_t *tree);
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* Description: Initialize a red-black tree structure.
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* Args:
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* tree: Pointer to an uninitialized red-black tree object.
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*
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* static bool
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* ex_empty(ex_t *tree);
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* Description: Determine whether tree is empty.
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* Args:
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* tree: Pointer to an initialized red-black tree object.
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* Ret: True if tree is empty, false otherwise.
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*
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* static ex_node_t *
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* ex_first(ex_t *tree);
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* static ex_node_t *
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* ex_last(ex_t *tree);
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* Description: Get the first/last node in tree.
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* Args:
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* tree: Pointer to an initialized red-black tree object.
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* Ret: First/last node in tree, or NULL if tree is empty.
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*
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* static ex_node_t *
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* ex_next(ex_t *tree, ex_node_t *node);
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* static ex_node_t *
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* ex_prev(ex_t *tree, ex_node_t *node);
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* Description: Get node's successor/predecessor.
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* Args:
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* tree: Pointer to an initialized red-black tree object.
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* node: A node in tree.
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* Ret: node's successor/predecessor in tree, or NULL if node is
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* last/first.
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*
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* static ex_node_t *
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* ex_search(ex_t *tree, ex_node_t *key);
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* Description: Search for node that matches key.
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* Args:
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* tree: Pointer to an initialized red-black tree object.
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* key : Search key.
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* Ret: Node in tree that matches key, or NULL if no match.
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*
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* static ex_node_t *
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* ex_nsearch(ex_t *tree, ex_node_t *key);
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* static ex_node_t *
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* ex_psearch(ex_t *tree, ex_node_t *key);
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* Description: Search for node that matches key. If no match is found,
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* return what would be key's successor/predecessor, were
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* key in tree.
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* Args:
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* tree: Pointer to an initialized red-black tree object.
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* key : Search key.
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* Ret: Node in tree that matches key, or if no match, hypothetical node's
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* successor/predecessor (NULL if no successor/predecessor).
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*
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* static void
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* ex_insert(ex_t *tree, ex_node_t *node);
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* Description: Insert node into tree.
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* Args:
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* tree: Pointer to an initialized red-black tree object.
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* node: Node to be inserted into tree.
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*
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* static void
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* ex_remove(ex_t *tree, ex_node_t *node);
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* Description: Remove node from tree.
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* Args:
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* tree: Pointer to an initialized red-black tree object.
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* node: Node in tree to be removed.
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*
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* static ex_node_t *
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* ex_iter(ex_t *tree, ex_node_t *start, ex_node_t *(*cb)(ex_t *,
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* ex_node_t *, void *), void *arg);
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* static ex_node_t *
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* ex_reverse_iter(ex_t *tree, ex_node_t *start, ex_node *(*cb)(ex_t *,
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* ex_node_t *, void *), void *arg);
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* Description: Iterate forward/backward over tree, starting at node. If
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* tree is modified, iteration must be immediately
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* terminated by the callback function that causes the
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* modification.
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* Args:
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* tree : Pointer to an initialized red-black tree object.
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* start: Node at which to start iteration, or NULL to start at
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* first/last node.
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* cb : Callback function, which is called for each node during
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* iteration. Under normal circumstances the callback function
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* should return NULL, which causes iteration to continue. If a
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* callback function returns non-NULL, iteration is immediately
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* terminated and the non-NULL return value is returned by the
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* iterator. This is useful for re-starting iteration after
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* modifying tree.
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* arg : Opaque pointer passed to cb().
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* Ret: NULL if iteration completed, or the non-NULL callback return value
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* that caused termination of the iteration.
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*/
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#define rb_gen(a_attr, a_prefix, a_rbt_type, a_type, a_field, a_cmp) \
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a_attr void \
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a_prefix##new(a_rbt_type *rbtree) { \
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rb_new(a_type, a_field, rbtree); \
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} \
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a_attr bool \
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a_prefix##empty(a_rbt_type *rbtree) { \
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return (rbtree->rbt_root == &rbtree->rbt_nil); \
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} \
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a_attr a_type * \
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a_prefix##first(a_rbt_type *rbtree) { \
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a_type *ret; \
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rbtn_first(a_type, a_field, rbtree, rbtree->rbt_root, ret); \
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if (ret == &rbtree->rbt_nil) { \
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ret = NULL; \
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} \
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return (ret); \
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} \
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a_attr a_type * \
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a_prefix##last(a_rbt_type *rbtree) { \
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a_type *ret; \
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rbtn_last(a_type, a_field, rbtree, rbtree->rbt_root, ret); \
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if (ret == &rbtree->rbt_nil) { \
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ret = NULL; \
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} \
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return (ret); \
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} \
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a_attr a_type * \
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a_prefix##next(a_rbt_type *rbtree, a_type *node) { \
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a_type *ret; \
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if (rbtn_right_get(a_type, a_field, node) != &rbtree->rbt_nil) { \
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rbtn_first(a_type, a_field, rbtree, rbtn_right_get(a_type, \
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a_field, node), ret); \
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} else { \
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a_type *tnode = rbtree->rbt_root; \
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assert(tnode != &rbtree->rbt_nil); \
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ret = &rbtree->rbt_nil; \
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while (true) { \
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int cmp = (a_cmp)(node, tnode); \
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if (cmp < 0) { \
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ret = tnode; \
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tnode = rbtn_left_get(a_type, a_field, tnode); \
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} else if (cmp > 0) { \
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tnode = rbtn_right_get(a_type, a_field, tnode); \
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} else { \
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break; \
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} \
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assert(tnode != &rbtree->rbt_nil); \
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} \
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} \
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if (ret == &rbtree->rbt_nil) { \
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ret = (NULL); \
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} \
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return (ret); \
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} \
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a_attr a_type * \
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a_prefix##prev(a_rbt_type *rbtree, a_type *node) { \
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a_type *ret; \
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if (rbtn_left_get(a_type, a_field, node) != &rbtree->rbt_nil) { \
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rbtn_last(a_type, a_field, rbtree, rbtn_left_get(a_type, \
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a_field, node), ret); \
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} else { \
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a_type *tnode = rbtree->rbt_root; \
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assert(tnode != &rbtree->rbt_nil); \
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ret = &rbtree->rbt_nil; \
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while (true) { \
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int cmp = (a_cmp)(node, tnode); \
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if (cmp < 0) { \
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tnode = rbtn_left_get(a_type, a_field, tnode); \
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} else if (cmp > 0) { \
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ret = tnode; \
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tnode = rbtn_right_get(a_type, a_field, tnode); \
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} else { \
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break; \
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} \
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assert(tnode != &rbtree->rbt_nil); \
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} \
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} \
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if (ret == &rbtree->rbt_nil) { \
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ret = (NULL); \
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} \
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return (ret); \
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} \
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a_attr a_type * \
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a_prefix##search(a_rbt_type *rbtree, a_type *key) { \
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a_type *ret; \
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int cmp; \
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ret = rbtree->rbt_root; \
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while (ret != &rbtree->rbt_nil \
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&& (cmp = (a_cmp)(key, ret)) != 0) { \
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if (cmp < 0) { \
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ret = rbtn_left_get(a_type, a_field, ret); \
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} else { \
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ret = rbtn_right_get(a_type, a_field, ret); \
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} \
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} \
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if (ret == &rbtree->rbt_nil) { \
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ret = (NULL); \
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} \
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return (ret); \
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} \
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a_attr a_type * \
|
|
a_prefix##nsearch(a_rbt_type *rbtree, a_type *key) { \
|
|
a_type *ret; \
|
|
a_type *tnode = rbtree->rbt_root; \
|
|
ret = &rbtree->rbt_nil; \
|
|
while (tnode != &rbtree->rbt_nil) { \
|
|
int cmp = (a_cmp)(key, tnode); \
|
|
if (cmp < 0) { \
|
|
ret = tnode; \
|
|
tnode = rbtn_left_get(a_type, a_field, tnode); \
|
|
} else if (cmp > 0) { \
|
|
tnode = rbtn_right_get(a_type, a_field, tnode); \
|
|
} else { \
|
|
ret = tnode; \
|
|
break; \
|
|
} \
|
|
} \
|
|
if (ret == &rbtree->rbt_nil) { \
|
|
ret = (NULL); \
|
|
} \
|
|
return (ret); \
|
|
} \
|
|
a_attr a_type * \
|
|
a_prefix##psearch(a_rbt_type *rbtree, a_type *key) { \
|
|
a_type *ret; \
|
|
a_type *tnode = rbtree->rbt_root; \
|
|
ret = &rbtree->rbt_nil; \
|
|
while (tnode != &rbtree->rbt_nil) { \
|
|
int cmp = (a_cmp)(key, tnode); \
|
|
if (cmp < 0) { \
|
|
tnode = rbtn_left_get(a_type, a_field, tnode); \
|
|
} else if (cmp > 0) { \
|
|
ret = tnode; \
|
|
tnode = rbtn_right_get(a_type, a_field, tnode); \
|
|
} else { \
|
|
ret = tnode; \
|
|
break; \
|
|
} \
|
|
} \
|
|
if (ret == &rbtree->rbt_nil) { \
|
|
ret = (NULL); \
|
|
} \
|
|
return (ret); \
|
|
} \
|
|
a_attr void \
|
|
a_prefix##insert(a_rbt_type *rbtree, a_type *node) { \
|
|
struct { \
|
|
a_type *node; \
|
|
int cmp; \
|
|
} path[sizeof(void *) << 4], *pathp; \
|
|
rbt_node_new(a_type, a_field, rbtree, node); \
|
|
/* Wind. */ \
|
|
path->node = rbtree->rbt_root; \
|
|
for (pathp = path; pathp->node != &rbtree->rbt_nil; pathp++) { \
|
|
int cmp = pathp->cmp = a_cmp(node, pathp->node); \
|
|
assert(cmp != 0); \
|
|
if (cmp < 0) { \
|
|
pathp[1].node = rbtn_left_get(a_type, a_field, \
|
|
pathp->node); \
|
|
} else { \
|
|
pathp[1].node = rbtn_right_get(a_type, a_field, \
|
|
pathp->node); \
|
|
} \
|
|
} \
|
|
pathp->node = node; \
|
|
/* Unwind. */ \
|
|
for (pathp--; (uintptr_t)pathp >= (uintptr_t)path; pathp--) { \
|
|
a_type *cnode = pathp->node; \
|
|
if (pathp->cmp < 0) { \
|
|
a_type *left = pathp[1].node; \
|
|
rbtn_left_set(a_type, a_field, cnode, left); \
|
|
if (rbtn_red_get(a_type, a_field, left)) { \
|
|
a_type *leftleft = rbtn_left_get(a_type, a_field, left);\
|
|
if (rbtn_red_get(a_type, a_field, leftleft)) { \
|
|
/* Fix up 4-node. */ \
|
|
a_type *tnode; \
|
|
rbtn_black_set(a_type, a_field, leftleft); \
|
|
rbtn_rotate_right(a_type, a_field, cnode, tnode); \
|
|
cnode = tnode; \
|
|
} \
|
|
} else { \
|
|
return; \
|
|
} \
|
|
} else { \
|
|
a_type *right = pathp[1].node; \
|
|
rbtn_right_set(a_type, a_field, cnode, right); \
|
|
if (rbtn_red_get(a_type, a_field, right)) { \
|
|
a_type *left = rbtn_left_get(a_type, a_field, cnode); \
|
|
if (rbtn_red_get(a_type, a_field, left)) { \
|
|
/* Split 4-node. */ \
|
|
rbtn_black_set(a_type, a_field, left); \
|
|
rbtn_black_set(a_type, a_field, right); \
|
|
rbtn_red_set(a_type, a_field, cnode); \
|
|
} else { \
|
|
/* Lean left. */ \
|
|
a_type *tnode; \
|
|
bool tred = rbtn_red_get(a_type, a_field, cnode); \
|
|
rbtn_rotate_left(a_type, a_field, cnode, tnode); \
|
|
rbtn_color_set(a_type, a_field, tnode, tred); \
|
|
rbtn_red_set(a_type, a_field, cnode); \
|
|
cnode = tnode; \
|
|
} \
|
|
} else { \
|
|
return; \
|
|
} \
|
|
} \
|
|
pathp->node = cnode; \
|
|
} \
|
|
/* Set root, and make it black. */ \
|
|
rbtree->rbt_root = path->node; \
|
|
rbtn_black_set(a_type, a_field, rbtree->rbt_root); \
|
|
} \
|
|
a_attr void \
|
|
a_prefix##remove(a_rbt_type *rbtree, a_type *node) { \
|
|
struct { \
|
|
a_type *node; \
|
|
int cmp; \
|
|
} *pathp, *nodep, path[sizeof(void *) << 4]; \
|
|
/* Wind. */ \
|
|
nodep = NULL; /* Silence compiler warning. */ \
|
|
path->node = rbtree->rbt_root; \
|
|
for (pathp = path; pathp->node != &rbtree->rbt_nil; pathp++) { \
|
|
int cmp = pathp->cmp = a_cmp(node, pathp->node); \
|
|
if (cmp < 0) { \
|
|
pathp[1].node = rbtn_left_get(a_type, a_field, \
|
|
pathp->node); \
|
|
} else { \
|
|
pathp[1].node = rbtn_right_get(a_type, a_field, \
|
|
pathp->node); \
|
|
if (cmp == 0) { \
|
|
/* Find node's successor, in preparation for swap. */ \
|
|
pathp->cmp = 1; \
|
|
nodep = pathp; \
|
|
for (pathp++; pathp->node != &rbtree->rbt_nil; \
|
|
pathp++) { \
|
|
pathp->cmp = -1; \
|
|
pathp[1].node = rbtn_left_get(a_type, a_field, \
|
|
pathp->node); \
|
|
} \
|
|
break; \
|
|
} \
|
|
} \
|
|
} \
|
|
assert(nodep->node == node); \
|
|
pathp--; \
|
|
if (pathp->node != node) { \
|
|
/* Swap node with its successor. */ \
|
|
bool tred = rbtn_red_get(a_type, a_field, pathp->node); \
|
|
rbtn_color_set(a_type, a_field, pathp->node, \
|
|
rbtn_red_get(a_type, a_field, node)); \
|
|
rbtn_left_set(a_type, a_field, pathp->node, \
|
|
rbtn_left_get(a_type, a_field, node)); \
|
|
/* If node's successor is its right child, the following code */\
|
|
/* will do the wrong thing for the right child pointer. */\
|
|
/* However, it doesn't matter, because the pointer will be */\
|
|
/* properly set when the successor is pruned. */\
|
|
rbtn_right_set(a_type, a_field, pathp->node, \
|
|
rbtn_right_get(a_type, a_field, node)); \
|
|
rbtn_color_set(a_type, a_field, node, tred); \
|
|
/* The pruned leaf node's child pointers are never accessed */\
|
|
/* again, so don't bother setting them to nil. */\
|
|
nodep->node = pathp->node; \
|
|
pathp->node = node; \
|
|
if (nodep == path) { \
|
|
rbtree->rbt_root = nodep->node; \
|
|
} else { \
|
|
if (nodep[-1].cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, nodep[-1].node, \
|
|
nodep->node); \
|
|
} else { \
|
|
rbtn_right_set(a_type, a_field, nodep[-1].node, \
|
|
nodep->node); \
|
|
} \
|
|
} \
|
|
} else { \
|
|
a_type *left = rbtn_left_get(a_type, a_field, node); \
|
|
if (left != &rbtree->rbt_nil) { \
|
|
/* node has no successor, but it has a left child. */\
|
|
/* Splice node out, without losing the left child. */\
|
|
assert(rbtn_red_get(a_type, a_field, node) == false); \
|
|
assert(rbtn_red_get(a_type, a_field, left)); \
|
|
rbtn_black_set(a_type, a_field, left); \
|
|
if (pathp == path) { \
|
|
rbtree->rbt_root = left; \
|
|
} else { \
|
|
if (pathp[-1].cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, pathp[-1].node, \
|
|
left); \
|
|
} else { \
|
|
rbtn_right_set(a_type, a_field, pathp[-1].node, \
|
|
left); \
|
|
} \
|
|
} \
|
|
return; \
|
|
} else if (pathp == path) { \
|
|
/* The tree only contained one node. */ \
|
|
rbtree->rbt_root = &rbtree->rbt_nil; \
|
|
return; \
|
|
} \
|
|
} \
|
|
if (rbtn_red_get(a_type, a_field, pathp->node)) { \
|
|
/* Prune red node, which requires no fixup. */ \
|
|
assert(pathp[-1].cmp < 0); \
|
|
rbtn_left_set(a_type, a_field, pathp[-1].node, \
|
|
&rbtree->rbt_nil); \
|
|
return; \
|
|
} \
|
|
/* The node to be pruned is black, so unwind until balance is */\
|
|
/* restored. */\
|
|
pathp->node = &rbtree->rbt_nil; \
|
|
for (pathp--; (uintptr_t)pathp >= (uintptr_t)path; pathp--) { \
|
|
assert(pathp->cmp != 0); \
|
|
if (pathp->cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, pathp->node, \
|
|
pathp[1].node); \
|
|
assert(rbtn_red_get(a_type, a_field, pathp[1].node) \
|
|
== false); \
|
|
if (rbtn_red_get(a_type, a_field, pathp->node)) { \
|
|
a_type *right = rbtn_right_get(a_type, a_field, \
|
|
pathp->node); \
|
|
a_type *rightleft = rbtn_left_get(a_type, a_field, \
|
|
right); \
|
|
a_type *tnode; \
|
|
if (rbtn_red_get(a_type, a_field, rightleft)) { \
|
|
/* In the following diagrams, ||, //, and \\ */\
|
|
/* indicate the path to the removed node. */\
|
|
/* */\
|
|
/* || */\
|
|
/* pathp(r) */\
|
|
/* // \ */\
|
|
/* (b) (b) */\
|
|
/* / */\
|
|
/* (r) */\
|
|
/* */\
|
|
rbtn_black_set(a_type, a_field, pathp->node); \
|
|
rbtn_rotate_right(a_type, a_field, right, tnode); \
|
|
rbtn_right_set(a_type, a_field, pathp->node, tnode);\
|
|
rbtn_rotate_left(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
} else { \
|
|
/* || */\
|
|
/* pathp(r) */\
|
|
/* // \ */\
|
|
/* (b) (b) */\
|
|
/* / */\
|
|
/* (b) */\
|
|
/* */\
|
|
rbtn_rotate_left(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
} \
|
|
/* Balance restored, but rotation modified subtree */\
|
|
/* root. */\
|
|
assert((uintptr_t)pathp > (uintptr_t)path); \
|
|
if (pathp[-1].cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, pathp[-1].node, \
|
|
tnode); \
|
|
} else { \
|
|
rbtn_right_set(a_type, a_field, pathp[-1].node, \
|
|
tnode); \
|
|
} \
|
|
return; \
|
|
} else { \
|
|
a_type *right = rbtn_right_get(a_type, a_field, \
|
|
pathp->node); \
|
|
a_type *rightleft = rbtn_left_get(a_type, a_field, \
|
|
right); \
|
|
if (rbtn_red_get(a_type, a_field, rightleft)) { \
|
|
/* || */\
|
|
/* pathp(b) */\
|
|
/* // \ */\
|
|
/* (b) (b) */\
|
|
/* / */\
|
|
/* (r) */\
|
|
a_type *tnode; \
|
|
rbtn_black_set(a_type, a_field, rightleft); \
|
|
rbtn_rotate_right(a_type, a_field, right, tnode); \
|
|
rbtn_right_set(a_type, a_field, pathp->node, tnode);\
|
|
rbtn_rotate_left(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
/* Balance restored, but rotation modified */\
|
|
/* subree root, which may actually be the tree */\
|
|
/* root. */\
|
|
if (pathp == path) { \
|
|
/* Set root. */ \
|
|
rbtree->rbt_root = tnode; \
|
|
} else { \
|
|
if (pathp[-1].cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, \
|
|
pathp[-1].node, tnode); \
|
|
} else { \
|
|
rbtn_right_set(a_type, a_field, \
|
|
pathp[-1].node, tnode); \
|
|
} \
|
|
} \
|
|
return; \
|
|
} else { \
|
|
/* || */\
|
|
/* pathp(b) */\
|
|
/* // \ */\
|
|
/* (b) (b) */\
|
|
/* / */\
|
|
/* (b) */\
|
|
a_type *tnode; \
|
|
rbtn_red_set(a_type, a_field, pathp->node); \
|
|
rbtn_rotate_left(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
pathp->node = tnode; \
|
|
} \
|
|
} \
|
|
} else { \
|
|
a_type *left; \
|
|
rbtn_right_set(a_type, a_field, pathp->node, \
|
|
pathp[1].node); \
|
|
left = rbtn_left_get(a_type, a_field, pathp->node); \
|
|
if (rbtn_red_get(a_type, a_field, left)) { \
|
|
a_type *tnode; \
|
|
a_type *leftright = rbtn_right_get(a_type, a_field, \
|
|
left); \
|
|
a_type *leftrightleft = rbtn_left_get(a_type, a_field, \
|
|
leftright); \
|
|
if (rbtn_red_get(a_type, a_field, leftrightleft)) { \
|
|
/* || */\
|
|
/* pathp(b) */\
|
|
/* / \\ */\
|
|
/* (r) (b) */\
|
|
/* \ */\
|
|
/* (b) */\
|
|
/* / */\
|
|
/* (r) */\
|
|
a_type *unode; \
|
|
rbtn_black_set(a_type, a_field, leftrightleft); \
|
|
rbtn_rotate_right(a_type, a_field, pathp->node, \
|
|
unode); \
|
|
rbtn_rotate_right(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
rbtn_right_set(a_type, a_field, unode, tnode); \
|
|
rbtn_rotate_left(a_type, a_field, unode, tnode); \
|
|
} else { \
|
|
/* || */\
|
|
/* pathp(b) */\
|
|
/* / \\ */\
|
|
/* (r) (b) */\
|
|
/* \ */\
|
|
/* (b) */\
|
|
/* / */\
|
|
/* (b) */\
|
|
assert(leftright != &rbtree->rbt_nil); \
|
|
rbtn_red_set(a_type, a_field, leftright); \
|
|
rbtn_rotate_right(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
rbtn_black_set(a_type, a_field, tnode); \
|
|
} \
|
|
/* Balance restored, but rotation modified subtree */\
|
|
/* root, which may actually be the tree root. */\
|
|
if (pathp == path) { \
|
|
/* Set root. */ \
|
|
rbtree->rbt_root = tnode; \
|
|
} else { \
|
|
if (pathp[-1].cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, pathp[-1].node, \
|
|
tnode); \
|
|
} else { \
|
|
rbtn_right_set(a_type, a_field, pathp[-1].node, \
|
|
tnode); \
|
|
} \
|
|
} \
|
|
return; \
|
|
} else if (rbtn_red_get(a_type, a_field, pathp->node)) { \
|
|
a_type *leftleft = rbtn_left_get(a_type, a_field, left);\
|
|
if (rbtn_red_get(a_type, a_field, leftleft)) { \
|
|
/* || */\
|
|
/* pathp(r) */\
|
|
/* / \\ */\
|
|
/* (b) (b) */\
|
|
/* / */\
|
|
/* (r) */\
|
|
a_type *tnode; \
|
|
rbtn_black_set(a_type, a_field, pathp->node); \
|
|
rbtn_red_set(a_type, a_field, left); \
|
|
rbtn_black_set(a_type, a_field, leftleft); \
|
|
rbtn_rotate_right(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
/* Balance restored, but rotation modified */\
|
|
/* subtree root. */\
|
|
assert((uintptr_t)pathp > (uintptr_t)path); \
|
|
if (pathp[-1].cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, pathp[-1].node, \
|
|
tnode); \
|
|
} else { \
|
|
rbtn_right_set(a_type, a_field, pathp[-1].node, \
|
|
tnode); \
|
|
} \
|
|
return; \
|
|
} else { \
|
|
/* || */\
|
|
/* pathp(r) */\
|
|
/* / \\ */\
|
|
/* (b) (b) */\
|
|
/* / */\
|
|
/* (b) */\
|
|
rbtn_red_set(a_type, a_field, left); \
|
|
rbtn_black_set(a_type, a_field, pathp->node); \
|
|
/* Balance restored. */ \
|
|
return; \
|
|
} \
|
|
} else { \
|
|
a_type *leftleft = rbtn_left_get(a_type, a_field, left);\
|
|
if (rbtn_red_get(a_type, a_field, leftleft)) { \
|
|
/* || */\
|
|
/* pathp(b) */\
|
|
/* / \\ */\
|
|
/* (b) (b) */\
|
|
/* / */\
|
|
/* (r) */\
|
|
a_type *tnode; \
|
|
rbtn_black_set(a_type, a_field, leftleft); \
|
|
rbtn_rotate_right(a_type, a_field, pathp->node, \
|
|
tnode); \
|
|
/* Balance restored, but rotation modified */\
|
|
/* subtree root, which may actually be the tree */\
|
|
/* root. */\
|
|
if (pathp == path) { \
|
|
/* Set root. */ \
|
|
rbtree->rbt_root = tnode; \
|
|
} else { \
|
|
if (pathp[-1].cmp < 0) { \
|
|
rbtn_left_set(a_type, a_field, \
|
|
pathp[-1].node, tnode); \
|
|
} else { \
|
|
rbtn_right_set(a_type, a_field, \
|
|
pathp[-1].node, tnode); \
|
|
} \
|
|
} \
|
|
return; \
|
|
} else { \
|
|
/* || */\
|
|
/* pathp(b) */\
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/* / \\ */\
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/* (b) (b) */\
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/* / */\
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/* (b) */\
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rbtn_red_set(a_type, a_field, left); \
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} \
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} \
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} \
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} \
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/* Set root. */ \
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rbtree->rbt_root = path->node; \
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assert(rbtn_red_get(a_type, a_field, rbtree->rbt_root) == false); \
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|
} \
|
|
a_attr a_type * \
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a_prefix##iter_recurse(a_rbt_type *rbtree, a_type *node, \
|
|
a_type *(*cb)(a_rbt_type *, a_type *, void *), void *arg) { \
|
|
if (node == &rbtree->rbt_nil) { \
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|
return (&rbtree->rbt_nil); \
|
|
} else { \
|
|
a_type *ret; \
|
|
if ((ret = a_prefix##iter_recurse(rbtree, rbtn_left_get(a_type, \
|
|
a_field, node), cb, arg)) != &rbtree->rbt_nil \
|
|
|| (ret = cb(rbtree, node, arg)) != NULL) { \
|
|
return (ret); \
|
|
} \
|
|
return (a_prefix##iter_recurse(rbtree, rbtn_right_get(a_type, \
|
|
a_field, node), cb, arg)); \
|
|
} \
|
|
} \
|
|
a_attr a_type * \
|
|
a_prefix##iter_start(a_rbt_type *rbtree, a_type *start, a_type *node, \
|
|
a_type *(*cb)(a_rbt_type *, a_type *, void *), void *arg) { \
|
|
int cmp = a_cmp(start, node); \
|
|
if (cmp < 0) { \
|
|
a_type *ret; \
|
|
if ((ret = a_prefix##iter_start(rbtree, start, \
|
|
rbtn_left_get(a_type, a_field, node), cb, arg)) != \
|
|
&rbtree->rbt_nil || (ret = cb(rbtree, node, arg)) != NULL) { \
|
|
return (ret); \
|
|
} \
|
|
return (a_prefix##iter_recurse(rbtree, rbtn_right_get(a_type, \
|
|
a_field, node), cb, arg)); \
|
|
} else if (cmp > 0) { \
|
|
return (a_prefix##iter_start(rbtree, start, \
|
|
rbtn_right_get(a_type, a_field, node), cb, arg)); \
|
|
} else { \
|
|
a_type *ret; \
|
|
if ((ret = cb(rbtree, node, arg)) != NULL) { \
|
|
return (ret); \
|
|
} \
|
|
return (a_prefix##iter_recurse(rbtree, rbtn_right_get(a_type, \
|
|
a_field, node), cb, arg)); \
|
|
} \
|
|
} \
|
|
a_attr a_type * \
|
|
a_prefix##iter(a_rbt_type *rbtree, a_type *start, a_type *(*cb)( \
|
|
a_rbt_type *, a_type *, void *), void *arg) { \
|
|
a_type *ret; \
|
|
if (start != NULL) { \
|
|
ret = a_prefix##iter_start(rbtree, start, rbtree->rbt_root, \
|
|
cb, arg); \
|
|
} else { \
|
|
ret = a_prefix##iter_recurse(rbtree, rbtree->rbt_root, cb, arg);\
|
|
} \
|
|
if (ret == &rbtree->rbt_nil) { \
|
|
ret = NULL; \
|
|
} \
|
|
return (ret); \
|
|
} \
|
|
a_attr a_type * \
|
|
a_prefix##reverse_iter_recurse(a_rbt_type *rbtree, a_type *node, \
|
|
a_type *(*cb)(a_rbt_type *, a_type *, void *), void *arg) { \
|
|
if (node == &rbtree->rbt_nil) { \
|
|
return (&rbtree->rbt_nil); \
|
|
} else { \
|
|
a_type *ret; \
|
|
if ((ret = a_prefix##reverse_iter_recurse(rbtree, \
|
|
rbtn_right_get(a_type, a_field, node), cb, arg)) != \
|
|
&rbtree->rbt_nil || (ret = cb(rbtree, node, arg)) != NULL) { \
|
|
return (ret); \
|
|
} \
|
|
return (a_prefix##reverse_iter_recurse(rbtree, \
|
|
rbtn_left_get(a_type, a_field, node), cb, arg)); \
|
|
} \
|
|
} \
|
|
a_attr a_type * \
|
|
a_prefix##reverse_iter_start(a_rbt_type *rbtree, a_type *start, \
|
|
a_type *node, a_type *(*cb)(a_rbt_type *, a_type *, void *), \
|
|
void *arg) { \
|
|
int cmp = a_cmp(start, node); \
|
|
if (cmp > 0) { \
|
|
a_type *ret; \
|
|
if ((ret = a_prefix##reverse_iter_start(rbtree, start, \
|
|
rbtn_right_get(a_type, a_field, node), cb, arg)) != \
|
|
&rbtree->rbt_nil || (ret = cb(rbtree, node, arg)) != NULL) { \
|
|
return (ret); \
|
|
} \
|
|
return (a_prefix##reverse_iter_recurse(rbtree, \
|
|
rbtn_left_get(a_type, a_field, node), cb, arg)); \
|
|
} else if (cmp < 0) { \
|
|
return (a_prefix##reverse_iter_start(rbtree, start, \
|
|
rbtn_left_get(a_type, a_field, node), cb, arg)); \
|
|
} else { \
|
|
a_type *ret; \
|
|
if ((ret = cb(rbtree, node, arg)) != NULL) { \
|
|
return (ret); \
|
|
} \
|
|
return (a_prefix##reverse_iter_recurse(rbtree, \
|
|
rbtn_left_get(a_type, a_field, node), cb, arg)); \
|
|
} \
|
|
} \
|
|
a_attr a_type * \
|
|
a_prefix##reverse_iter(a_rbt_type *rbtree, a_type *start, \
|
|
a_type *(*cb)(a_rbt_type *, a_type *, void *), void *arg) { \
|
|
a_type *ret; \
|
|
if (start != NULL) { \
|
|
ret = a_prefix##reverse_iter_start(rbtree, start, \
|
|
rbtree->rbt_root, cb, arg); \
|
|
} else { \
|
|
ret = a_prefix##reverse_iter_recurse(rbtree, rbtree->rbt_root, \
|
|
cb, arg); \
|
|
} \
|
|
if (ret == &rbtree->rbt_nil) { \
|
|
ret = NULL; \
|
|
} \
|
|
return (ret); \
|
|
}
|
|
|
|
#endif /* RB_H_ */
|