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bird/filter/tree.c
Maria Jan Matejka f93315c417 Config: Make the parser and lexer reentrant.
This is part of the multithreading journey. The parser and lexer were
using loads of global variables and all of these are now packed into
struct cf_context and others.

Note that the config API has changed:

* cfg_alloc[zu]?(size) is now cf_alloc[zu]?(ctx, size)
* cf_error(msg, ...) is now cf_error(ctx, msg, ...)
* config_parse() and cli_parse() are now called differently
* there is a brand new CF_CTX section in *.Y files which participates
  in struct cf_context construction
2018-09-14 14:44:45 +02:00

178 lines
3.6 KiB
C

/*
* Filters: utility functions
*
* Copyright 1998 Pavel Machek <pavel@ucw.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
#include "lib/alloca.h"
#include "nest/bird.h"
#include "conf/conf.h"
#include "conf/parser.h"
#include "filter/filter.h"
/**
* find_tree
* @t: tree to search in
* @val: value to find
*
* Search for given value in the tree. I relies on fact that sorted tree is populated
* by &f_val structures (that can be compared by val_compare()). In each node of tree,
* either single value (then t->from==t->to) or range is present.
*
* Both set matching and |switch() { }| construction is implemented using this function,
* thus both are as fast as they can be.
*/
struct f_tree *
find_tree(struct f_tree *t, struct f_val val)
{
if (!t)
return NULL;
if ((val_compare(t->from, val) != 1) &&
(val_compare(t->to, val) != -1))
return t;
if (val_compare(t->from, val) == -1)
return find_tree(t->right, val);
else
return find_tree(t->left, val);
}
static struct f_tree *
build_tree_rec(struct f_tree **buf, int l, int h)
{
struct f_tree *n;
int pos;
if (l >= h)
return NULL;
pos = (l+h)/2;
n = buf[pos];
n->left = build_tree_rec(buf, l, pos);
n->right = build_tree_rec(buf, pos+1, h);
return n;
}
static int
tree_compare(const void *p1, const void *p2)
{
return val_compare((* (struct f_tree **) p1)->from, (* (struct f_tree **) p2)->from);
}
/**
* build_tree
* @from: degenerated tree (linked by @tree->left) to be transformed into form suitable for find_tree()
*
* Transforms degenerated tree into balanced tree.
*/
struct f_tree *
build_tree(struct f_tree *from)
{
struct f_tree *tmp, *root;
struct f_tree **buf;
int len, i;
if (from == NULL)
return NULL;
len = 0;
for (tmp = from; tmp != NULL; tmp = tmp->left)
len++;
if (len <= 1024)
buf = alloca(len * sizeof(struct f_tree *));
else
buf = xmalloc(len * sizeof(struct f_tree *));
/* Convert a degenerated tree into an sorted array */
i = 0;
for (tmp = from; tmp != NULL; tmp = tmp->left)
buf[i++] = tmp;
qsort(buf, len, sizeof(struct f_tree *), tree_compare);
root = build_tree_rec(buf, 0, len);
if (len > 1024)
xfree(buf);
return root;
}
struct f_tree *
f_new_tree(struct cf_context *ctx)
{
struct f_tree * ret;
ret = cfg_alloc(sizeof(struct f_tree));
ret->left = ret->right = NULL;
ret->from.type = ret->to.type = T_VOID;
ret->from.val.i = ret->to.val.i = 0;
ret->data = NULL;
return ret;
}
/**
* same_tree
* @t1: first tree to be compared
* @t2: second one
*
* Compares two trees and returns 1 if they are same
*/
int
same_tree(struct f_tree *t1, struct f_tree *t2)
{
if ((!!t1) != (!!t2))
return 0;
if (!t1)
return 1;
if (val_compare(t1->from, t2->from))
return 0;
if (val_compare(t1->to, t2->to))
return 0;
if (!same_tree(t1->left, t2->left))
return 0;
if (!same_tree(t1->right, t2->right))
return 0;
if (!i_same(t1->data, t2->data))
return 0;
return 1;
}
static void
tree_node_format(struct f_tree *t, buffer *buf)
{
if (t == NULL)
return;
tree_node_format(t->left, buf);
val_format(t->from, buf);
if (val_compare(t->from, t->to) != 0)
{
buffer_puts(buf, "..");
val_format(t->to, buf);
}
buffer_puts(buf, ", ");
tree_node_format(t->right, buf);
}
void
tree_format(struct f_tree *t, buffer *buf)
{
buffer_puts(buf, "[");
tree_node_format(t, buf);
if (buf->pos == buf->end)
return;
/* Undo last separator */
if (buf->pos[-1] != '[')
buf->pos -= 2;
buffer_puts(buf, "]");
}