r3/src/node.c

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#include "config.h"
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#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
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#include <ctype.h>
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// PCRE
#include <pcre.h>
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#include "r3.h"
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#include "r3_str.h"
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#include "slug.h"
#include "zmalloc.h"
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#define CHECK_PTR(ptr) if (ptr == NULL) return NULL;
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// String value as the index http://judy.sourceforge.net/doc/JudySL_3x.htm
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static int strndiff(char * d1, char * d2, unsigned int n) {
char * o = d1;
while ( *d1 == *d2 && n-- > 0 ) {
d1++;
d2++;
}
return d1 - o;
}
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/*
static int strdiff(char * d1, char * d2) {
char * o = d1;
while( *d1 == *d2 ) {
d1++;
d2++;
}
return d1 - o;
}
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*/
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/**
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* Create a node object
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*/
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node * r3_tree_create(int cap) {
node * n = (node*) zmalloc( sizeof(node) );
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CHECK_PTR(n);
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n->edges = (edge**) zmalloc( sizeof(edge*) * cap );
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CHECK_PTR(n->edges);
n->edge_len = 0;
n->edge_cap = cap;
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n->routes = NULL;
n->route_len = 0;
n->route_cap = 0;
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n->endpoint = 0;
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n->combined_pattern = NULL;
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n->pcre_pattern = NULL;
n->pcre_extra = NULL;
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n->data = NULL;
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return n;
}
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void r3_tree_free(node * tree) {
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for (int i = 0 ; i < tree->edge_len ; i++ ) {
if (tree->edges[i]) {
r3_edge_free(tree->edges[ i ]);
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}
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}
zfree(tree->edges);
zfree(tree->routes);
if (tree->pcre_pattern) {
pcre_free(tree->pcre_pattern);
}
#ifdef PCRE_STUDY_JIT_COMPILE
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if (tree->pcre_extra) {
pcre_free_study(tree->pcre_extra);
}
#endif
zfree(tree->combined_pattern);
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zfree(tree);
tree = NULL;
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}
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/**
* Connect two node objects, and create an edge object between them.
*/
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edge * r3_node_connectl(node * n, const char * pat, int len, int dupl, node *child) {
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// find the same sub-pattern, if it does not exist, create one
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edge * e;
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e = r3_node_find_edge(n, pat, len);
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if (e) {
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return e;
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}
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if (dupl) {
pat = zstrndup(pat, len);
}
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e = r3_edge_createl(pat, len, child);
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CHECK_PTR(e);
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r3_node_append_edge(n, e);
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return e;
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}
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void r3_node_append_edge(node *n, edge *e) {
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if (n->edges == NULL) {
n->edge_cap = 3;
n->edges = zmalloc(sizeof(edge) * n->edge_cap);
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}
if (n->edge_len >= n->edge_cap) {
n->edge_cap *= 2;
edge ** p = zrealloc(n->edges, sizeof(edge) * n->edge_cap);
if(p) {
n->edges = p;
}
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}
n->edges[ n->edge_len++ ] = e;
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}
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/**
* Find the existing edge with specified pattern (include slug)
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*
* if "pat" is a slug, we should compare with the specified pattern.
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*/
edge * r3_node_find_edge(const node * n, const char * pat, int pat_len) {
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edge * e;
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int i;
for (i = 0 ; i < n->edge_len ; i++ ) {
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e = n->edges[i];
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// there is a case: "{foo}" vs "{foo:xxx}",
// we should return the match result: full-match or partial-match
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if ( strcmp(e->pattern, pat) == 0 ) {
return e;
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}
}
return NULL;
}
int r3_tree_compile(node *n, char **errstr)
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{
int ret = 0;
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bool use_slug = r3_node_has_slug_edges(n);
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if ( use_slug ) {
if ( (ret = r3_tree_compile_patterns(n, errstr)) ) {
return ret;
}
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} else {
// use normal text matching...
n->combined_pattern = NULL;
}
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for (int i = 0 ; i < n->edge_len ; i++ ) {
if ( (ret = r3_tree_compile(n->edges[i]->child, errstr)) ) {
return ret; // stop here if error occurs
}
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}
return 0;
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}
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/**
* This function combines ['/foo', '/bar', '/{slug}'] into (/foo)|(/bar)|/([^/]+)}
*
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* Return -1 if error occurs
* Return 0 if success
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*/
int r3_tree_compile_patterns(node * n, char **errstr) {
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char * cpat;
char * p;
cpat = zcalloc(sizeof(char) * 220); // XXX
if (!cpat) {
asprintf(errstr, "Can not allocate memory");
return -1;
}
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p = cpat;
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edge *e = NULL;
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int opcode_cnt = 0;
for ( int i = 0 ; i < n->edge_len ; i++ ) {
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e = n->edges[i];
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if ( e->opcode )
opcode_cnt++;
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if ( e->has_slug ) {
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// compile "foo/{slug}" to "foo/[^/]+"
char * slug_pat = r3_slug_compile(e->pattern, e->pattern_len);
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strcat(p, slug_pat);
} else {
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strncat(p,"^(", 2);
p += 2;
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strncat(p, e->pattern, e->pattern_len);
p += e->pattern_len;
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strncat(p++,")", 1);
}
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if ( i + 1 < n->edge_len && n->edge_len > 1 ) {
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strncat(p++,"|",1);
}
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}
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info("pattern: %s\n",cpat);
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// if all edges use opcode, we should skip the combined_pattern.
if ( opcode_cnt == n->edge_len ) {
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// zfree(cpat);
n->compare_type = NODE_COMPARE_OPCODE;
} else {
n->compare_type = NODE_COMPARE_PCRE;
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}
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n->combined_pattern = cpat;
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const char *pcre_error;
int pcre_erroffset;
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unsigned int option_bits = 0;
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n->ov_cnt = (1 + n->edge_len) * 3;
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if (n->pcre_pattern) {
pcre_free(n->pcre_pattern);
}
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n->pcre_pattern = pcre_compile(
n->combined_pattern, /* the pattern */
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option_bits, /* default options */
&pcre_error, /* for error message */
&pcre_erroffset, /* for error offset */
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NULL); /* use default character tables */
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if (n->pcre_pattern == NULL) {
if (errstr) {
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asprintf(errstr, "PCRE compilation failed at offset %d: %s, pattern: %s", pcre_erroffset, pcre_error, n->combined_pattern);
}
return -1;
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}
#ifdef PCRE_STUDY_JIT_COMPILE
if (n->pcre_extra) {
pcre_free_study(n->pcre_extra);
}
n->pcre_extra = pcre_study(n->pcre_pattern, 0, &pcre_error);
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if (n->pcre_extra == NULL) {
if (errstr) {
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asprintf(errstr, "PCRE study failed at offset %s, pattern: %s", pcre_error, n->combined_pattern);
}
return -1;
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}
#endif
return 0;
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}
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/**
* This function matches the URL path and return the left node
*
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* r3_tree_matchl returns NULL when the path does not match. returns *node when the path matches.
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*
* @param node n the root of the tree
* @param char* path the URL path to dispatch
* @param int path_len the length of the URL path.
* @param match_entry* entry match_entry is used for saving the captured dynamic strings from pcre result.
*/
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node * r3_tree_matchl(const node * n, const char * path, int path_len, match_entry * entry) {
info("try matching: %s\n", path);
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edge *e;
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unsigned short i;
unsigned short restlen;
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const char *pp;
const char *pp_end;
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if (n->compare_type == NODE_COMPARE_OPCODE) {
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pp_end = path + path_len;
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for (i = n->edge_len; i--; ) {
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pp = path;
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e = n->edges[i];
switch(e->opcode) {
case OP_EXPECT_NOSLASH:
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while (*pp != '/' && pp < pp_end) pp++;
break;
case OP_EXPECT_MORE_ALPHA:
while ( isalpha(*pp) && pp < pp_end) pp++;
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break;
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case OP_EXPECT_MORE_DIGITS:
while ( isdigit(*pp) && pp < pp_end) pp++;
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break;
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case OP_EXPECT_MORE_WORDS:
while ( (isdigit(*pp) || isalpha(*pp)) && pp < pp_end) pp++;
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break;
case OP_EXPECT_NODASH:
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while (*pp != '-' && pp < pp_end) pp++;
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break;
}
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// check match
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if ( (pp - path) > 0) {
restlen = pp_end - pp;
if (entry) {
str_array_append(entry->vars , zstrndup(path, pp - path));
}
if (restlen == 0) {
return e->child && e->child->endpoint > 0 ? e->child : NULL;
}
return r3_tree_matchl(e->child, pp, pp_end - pp, entry);
}
}
}
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// if the pcre_pattern is found, and the pointer is not NULL, then it's
// pcre pattern node, we use pcre_exec to match the nodes
if (n->pcre_pattern) {
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const char *substring_start = NULL;
int substring_length = 0;
int ov[ n->ov_cnt ];
int rc;
info("pcre matching %s on %s\n", n->combined_pattern, path);
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rc = pcre_exec(
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n->pcre_pattern, /* the compiled pattern */
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n->pcre_extra,
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path, /* the subject string */
path_len, /* the length of the subject */
0, /* start at offset 0 in the subject */
0, /* default options */
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ov, /* output vector for substring information */
n->ov_cnt); /* number of elements in the output vector */
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// does not match all edges, return NULL;
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if (rc < 0) {
#ifdef DEBUG
printf("pcre rc: %d\n", rc );
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switch(rc)
{
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case PCRE_ERROR_NOMATCH:
printf("pcre: no match '%s' on pattern '%s'\n", path, n->combined_pattern);
break;
// Handle other special cases if you like
default:
printf("pcre matching error '%d' '%s' on pattern '%s'\n", rc, path, n->combined_pattern);
break;
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}
#endif
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return NULL;
}
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restlen = path_len - ov[1]; // if it's fully matched to the end (rest string length)
if (restlen == 0 ) {
// Check the substring to decide we should go deeper on which edge
for (i = 1; i < rc; i++)
{
substring_length = ov[2*i+1] - ov[2*i];
// if it's not matched for this edge, just skip them quickly
if (substring_length == 0)
continue;
substring_start = path + ov[2*i];
e = n->edges[i - 1];
if (entry && e->has_slug) {
// append captured token to entry
str_array_append(entry->vars , zstrndup(substring_start, substring_length));
}
// since restlen == 0 return the edge quickly.
return e->child && e->child->endpoint > 0 ? e->child : NULL;
}
}
// Check the substring to decide we should go deeper on which edge
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for (i = 1; i < rc; i++)
{
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substring_length = ov[2*i+1] - ov[2*i];
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// if it's not matched for this edge, just skip them quickly
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if ( substring_length == 0) {
continue;
}
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substring_start = path + ov[2*i];
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e = n->edges[i - 1];
if (entry && e->has_slug) {
// append captured token to entry
str_array_append(entry->vars , zstrndup(substring_start, substring_length));
}
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// get the length of orginal string: $0
return r3_tree_matchl( e->child, path + (ov[1] - ov[0]), restlen, entry);
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}
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// does not match
return NULL;
}
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if ( (e = r3_node_find_edge_str(n, path, path_len)) != NULL ) {
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restlen = path_len - e->pattern_len;
if (restlen == 0) {
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return e->child && e->child->endpoint > 0 ? e->child : NULL;
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}
return r3_tree_matchl(e->child, path + e->pattern_len, restlen, entry);
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}
return NULL;
}
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route * r3_tree_match_route(const node *tree, match_entry * entry) {
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node *n;
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int i;
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n = r3_tree_match_entry(tree, entry);
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if (n && n->routes && n->route_len > 0) {
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for (i = n->route_len; i--; ) {
if ( r3_route_cmp(n->routes[i], entry) == 0 ) {
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return n->routes[i];
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}
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}
}
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return NULL;
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}
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inline edge * r3_node_find_edge_str(const node * n, const char * str, int str_len) {
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char firstbyte = *str;
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unsigned int i;
for (i = n->edge_len; i--; ) {
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if ( firstbyte == *(n->edges[i]->pattern) ) {
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info("matching '%s' with '%s'\n", str, r3_node_edge_pattern(n,i) );
if ( strncmp( r3_node_edge_pattern(n,i), str, r3_node_edge_pattern_len(n,i) ) == 0 ) {
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return n->edges[i];
}
return NULL;
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}
}
return NULL;
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}
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node * r3_node_create() {
node * n = (node*) zmalloc( sizeof(node) );
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CHECK_PTR(n);
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n->edges = NULL;
n->edge_len = 0;
n->edge_cap = 0;
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n->routes = NULL;
n->route_len = 0;
n->route_cap = 0;
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n->endpoint = 0;
n->combined_pattern = NULL;
n->pcre_pattern = NULL;
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n->pcre_extra = NULL;
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n->data = NULL;
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return n;
}
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void r3_route_free(route * route) {
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zfree(route);
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}
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route * r3_route_createl(const char * path, int path_len) {
route * info = zmalloc(sizeof(route));
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CHECK_PTR(info);
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info->path = (char*) path;
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info->path_len = path_len;
info->request_method = 0; // can be (GET || POST)
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info->data = NULL;
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info->host = NULL; // required host name
info->host_len = 0;
info->remote_addr_pattern = NULL;
info->remote_addr_pattern_len = 0;
return info;
}
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/**
* Helper function for creating routes from request URI path and request method
*
* method (int): METHOD_GET, METHOD_POST, METHOD_PUT, METHOD_DELETE ...
*/
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route * r3_tree_insert_routel_ex(node *tree, int method, const char *path, int path_len, void *data, char **errstr) {
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route *r = r3_route_createl(path, path_len);
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CHECK_PTR(r);
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r->request_method = method; // ALLOW GET OR POST METHOD
node * ret = r3_tree_insert_pathl_ex(tree, path, path_len, r, data, errstr);
if (!ret) {
// failed insert
r3_route_free(r);
return NULL;
}
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return r;
}
/**
* Find common prefix from the edges of the node.
*
* Some cases of the common prefix:
*
* 1. "/foo/{slug}" vs "/foo/bar" => common prefix = "/foo/"
* 2. "{slug}/hate" vs "{slug}/bar" => common prefix = "{slug}/"
* 2. "/z/{slug}/hate" vs "/z/{slog}/bar" => common prefix = "/z/"
* 3. "{slug:xxx}/hate" vs "{slug:yyy}/bar" => common prefix = ""
* 4. "aaa{slug:xxx}/hate" vs "aab{slug:yyy}/bar" => common prefix = "aa"
* 5. "/foo/{slug}/hate" vs "/fo{slug}/bar" => common prefix = "/fo"
*/
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edge * r3_node_find_common_prefix(node *n, const char *path, int path_len, int *prefix_len, char **errstr) {
int i = 0;
int prefix = 0;
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*prefix_len = 0;
edge *e = NULL;
for(i = 0 ; i < n->edge_len ; i++ ) {
// ignore all edges with slug
prefix = strndiff( (char*) path, n->edges[i]->pattern, n->edges[i]->pattern_len);
// no common, consider insert a new edge
if ( prefix > 0 ) {
e = n->edges[i];
break;
}
}
// found common prefix edge
if (prefix > 0) {
r3_slug_t *slug;
int ret = 0;
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const char *offset = path;
const char *p = path + prefix;
slug = r3_slug_new(path, path_len);
do {
ret = r3_slug_parse(slug, path, path_len, offset, errstr);
// found slug
if (ret == 1) {
// inside slug, backtrace to the begin of the slug
if ( p >= slug->begin && p <= slug->end ) {
prefix = slug->begin - path - 1;
break;
} else if ( p < slug->begin ) {
break;
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} else if ( p >= slug->end && p < (path + path_len) ) {
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offset = slug->end + 1;
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prefix = p - path;
continue;
} else {
break;
}
} else if (ret == -1) {
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return NULL;
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} else {
break;
}
} while(ret == 1);
}
*prefix_len = prefix;
return e;
}
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/**
* Return the last inserted node.
*/
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node * r3_tree_insert_pathl_ex(node *tree, const char *path, int path_len, route * route, void * data, char **errstr)
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{
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node * n = tree;
// common edge
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edge * e = NULL;
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/* length of common prefix */
int prefix_len = 0;
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char *err = NULL;
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e = r3_node_find_common_prefix(tree, path, path_len, &prefix_len, &err);
if (err) {
// copy the error message pointer
if (errstr) *errstr = err;
return NULL;
}
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const char * subpath = path + prefix_len;
const int subpath_len = path_len - prefix_len;
// common prefix not found, insert a new edge for this pattern
if ( prefix_len == 0 ) {
// there are two more slugs, we should break them into several parts
int slug_cnt = slug_count(path, path_len, errstr);
if (slug_cnt == -1) {
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return NULL;
}
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if ( slug_cnt > 1 ) {
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int slug_len;
char *p = r3_slug_find_placeholder(path, &slug_len);
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#ifdef DEBUG
assert(p);
#endif
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// find the next one '{', then break there
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if(p) {
p = r3_slug_find_placeholder(p + slug_len + 1, NULL);
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}
#ifdef DEBUG
assert(p);
#endif
// insert the first one edge, and break at "p"
node * child = r3_tree_create(3);
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CHECK_PTR(child);
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r3_node_connect(n, zstrndup(path, (int)(p - path)), child);
// and insert the rest part to the child
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return r3_tree_insert_pathl_ex(child, p, path_len - (int)(p - path), route, data, errstr);
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} else {
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if (slug_cnt == 1) {
// there is one slug, let's see if it's optimiz-able by opcode
int slug_len = 0;
char *slug_p = r3_slug_find_placeholder(path, &slug_len);
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int slug_pattern_len = 0;
char *slug_pattern = r3_slug_find_pattern(slug_p, &slug_pattern_len);
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int opcode = 0;
// if there is a pattern defined.
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if (slug_pattern_len) {
char *cpattern = r3_slug_compile(slug_pattern, slug_pattern_len);
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opcode = r3_pattern_to_opcode(cpattern, strlen(cpattern));
zfree(cpattern);
} else {
opcode = OP_EXPECT_NOSLASH;
}
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// if the slug starts after one+ charactor, for example foo{slug}
node *c1;
if (slug_p > path) {
c1 = r3_tree_create(3);
CHECK_PTR(c1);
r3_node_connectl(n, path, slug_p - path, 1, c1); // duplicate
} else {
c1 = n;
}
node * c2 = r3_tree_create(3);
CHECK_PTR(c2);
edge * op_edge = r3_node_connectl(c1, slug_p, slug_len , 1, c2);
if(opcode) {
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op_edge->opcode = opcode;
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}
int restlen = path_len - ((slug_p - path) + slug_len);
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if (restlen) {
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return r3_tree_insert_pathl_ex(c2, slug_p + slug_len, restlen, route, data, errstr);
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}
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c2->data = data;
c2->endpoint++;
if (route) {
route->data = data;
r3_node_append_route(c2, route);
}
return c2;
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}
// only one slug
node * child = r3_tree_create(3);
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CHECK_PTR(child);
child->endpoint++;
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if (data)
child->data = data;
r3_node_connectl(n, path, path_len, 1, child);
if (route) {
route->data = data;
r3_node_append_route(child, route);
}
return child;
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}
} else if ( prefix_len == e->pattern_len ) { // fully-equal to the pattern of the edge
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// there are something more we can insert
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if ( subpath_len > 0 ) {
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return r3_tree_insert_pathl_ex(e->child, subpath, subpath_len, route, data, errstr);
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} else {
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// there are no more path to insert
// see if there is an endpoint already, we should n't overwrite the data on child.
// but we still need to append the route.
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if (route) {
route->data = data;
r3_node_append_route(e->child, route);
e->child->endpoint++; // make it as an endpoint
return e->child;
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}
// insertion without route
if (e->child->endpoint > 0) {
// TODO: return an error code instead of NULL
return NULL;
}
e->child->endpoint++; // make it as an endpoint
e->child->data = data; // set data
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return e->child;
}
} else if ( prefix_len < e->pattern_len ) {
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/* it's partially matched with the pattern,
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* we should split the end point and make a branch here...
*/
r3_edge_branch(e, prefix_len);
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return r3_tree_insert_pathl_ex(e->child, subpath, subpath_len, route , data, errstr);
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} else {
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fprintf(stderr, "unexpected route.");
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return NULL;
}
return n;
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}
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bool r3_node_has_slug_edges(const node *n) {
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bool found = FALSE;
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edge *e;
for ( int i = 0 ; i < n->edge_len ; i++ ) {
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e = n->edges[i];
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e->has_slug = r3_path_contains_slug_char(e->pattern);
if (e->has_slug)
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found = TRUE;
}
return found;
}
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void r3_tree_dump(const node * n, int level) {
print_indent(level);
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printf("(o)");
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if ( n->combined_pattern ) {
printf(" regexp:%s", n->combined_pattern);
}
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printf(" endpoint:%d", n->endpoint);
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if (n->data) {
printf(" data:%p", n->data);
}
printf("\n");
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for ( int i = 0 ; i < n->edge_len ; i++ ) {
edge * e = n->edges[i];
print_indent(level + 1);
printf("|-\"%s\"", e->pattern);
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if (e->opcode ) {
printf(" opcode:%d", e->opcode);
}
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if ( e->child ) {
printf("\n");
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r3_tree_dump( e->child, level + 1);
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}
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printf("\n");
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}
}
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/**
* return 0 == equal
*
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* -1 == different route
*/
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inline int r3_route_cmp(const route *r1, const match_entry *r2) {
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if (r1->request_method != 0) {
if (0 == (r1->request_method & r2->request_method) ) {
return -1;
}
}
if ( r1->host && r2->host ) {
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if (strcmp(r1->host, r2->host) != 0 ) {
return -1;
}
}
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if (r1->remote_addr_pattern) {
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/*
* XXX: consider "netinet/in.h"
if (r2->remote_addr) {
inet_addr(r2->remote_addr);
}
*/
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if ( strcmp(r1->remote_addr_pattern, r2->remote_addr) != 0 ) {
return -1;
}
}
return 0;
}
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/**
*
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*/
void r3_node_append_route(node * n, route * r) {
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if (n->routes == NULL) {
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n->route_cap = 3;
n->routes = zmalloc(sizeof(route) * n->route_cap);
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}
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if (n->route_len >= n->route_cap) {
n->route_cap *= 2;
n->routes = zrealloc(n->routes, sizeof(route) * n->route_cap);
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}
n->routes[ n->route_len++ ] = r;
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}