mirror of
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315 lines
7.6 KiB
C
315 lines
7.6 KiB
C
/* radare - LGPL - Copyright 2007-2020 - pancake, ret2libc */
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#include <r_util.h>
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enum {
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WHITE_COLOR = 0,
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GRAY_COLOR,
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BLACK_COLOR
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};
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static RGraphNode *r_graph_node_new(void *data) {
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RGraphNode *p = R_NEW0 (RGraphNode);
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if (p) {
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p->data = data;
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p->free = NULL;
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p->out_nodes = r_list_new ();
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p->in_nodes = r_list_new ();
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p->all_neighbours = r_list_new ();
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}
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return p;
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}
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static void r_graph_node_free(RGraphNode *n) {
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if (!n) {
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return;
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}
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if (n->free) {
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n->free (n->data);
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}
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r_list_free (n->out_nodes);
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r_list_free (n->in_nodes);
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r_list_free (n->all_neighbours);
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free (n);
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}
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static int node_cmp(unsigned int idx, RGraphNode *b) {
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return idx == b->idx ? 0 : -1;
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}
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// direction == true => forwards
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static void dfs_node(RGraph *g, RGraphNode *n, RGraphVisitor *vis, int color[], const bool direction) {
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if (!n) {
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return;
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}
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RStack *s = r_stack_new (2 * g->n_edges + 1);
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if (!s) {
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return;
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}
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RGraphEdge *edg = R_NEW0 (RGraphEdge);
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if (!edg) {
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r_stack_free (s);
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return;
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}
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edg->from = NULL;
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edg->to = n;
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r_stack_push (s, edg);
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while (!r_stack_is_empty (s)) {
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RGraphEdge *cur_edge = (RGraphEdge *)r_stack_pop (s);
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RGraphNode *v, *cur = cur_edge->to, *from = cur_edge->from;
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RListIter *it;
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int i;
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if (from && cur) {
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if (color[cur->idx] == WHITE_COLOR && vis->tree_edge) {
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vis->tree_edge (cur_edge, vis);
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} else if (color[cur->idx] == GRAY_COLOR && vis->back_edge) {
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vis->back_edge (cur_edge, vis);
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} else if (color[cur->idx] == BLACK_COLOR && vis->fcross_edge) {
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vis->fcross_edge (cur_edge, vis);
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}
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} else if (!cur && from) {
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if (color[from->idx] != BLACK_COLOR && vis->finish_node) {
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vis->finish_node (from, vis);
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}
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color[from->idx] = BLACK_COLOR;
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}
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free (cur_edge);
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if (!cur || color[cur->idx] != WHITE_COLOR) {
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continue;
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}
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if (color[cur->idx] == WHITE_COLOR && vis->discover_node) {
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vis->discover_node (cur, vis);
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}
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color[cur->idx] = GRAY_COLOR;
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edg = R_NEW0 (RGraphEdge);
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if (!edg) {
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break;
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}
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edg->from = cur;
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r_stack_push (s, edg);
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i = 0;
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const RList *neighbours = direction ? cur->out_nodes : cur->in_nodes;
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r_list_foreach (neighbours, it, v) {
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edg = R_NEW (RGraphEdge);
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edg->from = cur;
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edg->to = v;
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edg->nth = i++;
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r_stack_push (s, edg);
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}
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}
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r_stack_free (s);
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}
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R_API RGraph *r_graph_new(void) {
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RGraph *t = R_NEW0 (RGraph);
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if (!t) {
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return NULL;
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}
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t->nodes = r_list_new ();
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if (!t->nodes) {
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r_graph_free (t);
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return NULL;
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}
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t->nodes->free = (RListFree)r_graph_node_free;
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t->n_nodes = 0;
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t->last_index = 0;
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return t;
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}
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R_API void r_graph_free(RGraph* t) {
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if (!t) {
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return;
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}
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r_list_free (t->nodes);
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free (t);
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}
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R_API RGraphNode *r_graph_get_node(const RGraph *t, unsigned int idx) {
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RListIter *it = r_list_find (t->nodes, (void *)(size_t)idx, (RListComparator)node_cmp);
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if (!it) {
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return NULL;
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}
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return (RGraphNode *)it->data;
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}
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R_API RListIter *r_graph_node_iter(const RGraph *t, unsigned int idx) {
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return r_list_find (t->nodes, (void *)(size_t)idx, (RListComparator)node_cmp);
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}
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R_API void r_graph_reset(RGraph *t) {
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r_list_free (t->nodes);
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t->nodes = r_list_new ();
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if (!t->nodes) {
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return;
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}
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t->nodes->free = (RListFree)r_graph_node_free;
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t->n_nodes = 0;
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t->n_edges = 0;
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t->last_index = 0;
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}
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R_API RGraphNode *r_graph_add_node(RGraph *t, void *data) {
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if (!t) {
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return NULL;
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}
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RGraphNode *n = r_graph_node_new (data);
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if (!n) {
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return NULL;
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}
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n->idx = t->last_index++;
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r_list_append (t->nodes, n);
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t->n_nodes++;
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return n;
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}
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R_API RGraphNode *r_graph_add_nodef(RGraph *graph, void *data, RListFree user_free) {
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RGraphNode *node = r_graph_add_node (graph, data);
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if (node) {
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node->free = user_free;
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}
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return node;
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}
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/* remove the node from the graph and free the node */
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/* users of this function should be aware they can't access n anymore */
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R_API void r_graph_del_node(RGraph *t, RGraphNode *n) {
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RGraphNode *gn;
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RListIter *it;
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if (!n) {
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return;
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}
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r_list_foreach (n->in_nodes, it, gn) {
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r_list_delete_data (gn->out_nodes, n);
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r_list_delete_data (gn->all_neighbours, n);
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t->n_edges--;
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}
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r_list_foreach (n->out_nodes, it, gn) {
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r_list_delete_data (gn->in_nodes, n);
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r_list_delete_data (gn->all_neighbours, n);
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t->n_edges--;
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}
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r_list_delete_data (t->nodes, n);
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t->n_nodes--;
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}
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R_API void r_graph_add_edge(RGraph *t, RGraphNode *from, RGraphNode *to) {
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r_graph_add_edge_at (t, from, to, -1);
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}
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R_API void r_graph_add_edge_at(RGraph *t, RGraphNode *from, RGraphNode *to, int nth) {
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if (from && to) {
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r_list_insert (from->out_nodes, nth, to);
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r_list_append (from->all_neighbours, to);
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r_list_append (to->in_nodes, from);
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r_list_append (to->all_neighbours, from);
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t->n_edges++;
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}
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}
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// splits the "split_me", so that new node has it's outnodes
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R_API RGraphNode *r_graph_node_split_forward(RGraph *g, RGraphNode *split_me, void *data) {
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RGraphNode *front = r_graph_add_node(g, data);
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RList *tmp = front->out_nodes;
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front->out_nodes = split_me->out_nodes;
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split_me->out_nodes = tmp;
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RListIter *iter;
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RGraphNode *n;
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r_list_foreach (front->out_nodes, iter, n) {
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r_list_delete_data (n->in_nodes, split_me); // optimize me
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r_list_delete_data (n->all_neighbours, split_me); // boy this all_neighbours is so retarding perf here
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r_list_delete_data (split_me->all_neighbours, n);
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r_list_append (n->all_neighbours, front);
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r_list_append (n->in_nodes, front);
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r_list_append (front->all_neighbours, n);
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}
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return front;
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}
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R_API void r_graph_del_edge(RGraph *t, RGraphNode *from, RGraphNode *to) {
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if (!from || !to || !r_graph_adjacent (t, from, to)) {
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return;
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}
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r_list_delete_data (from->out_nodes, to);
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r_list_delete_data (from->all_neighbours, to);
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r_list_delete_data (to->in_nodes, from);
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r_list_delete_data (to->all_neighbours, from);
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t->n_edges--;
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}
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// XXX remove comments and static inline all this crap
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/* returns the list of nodes reachable from `n` */
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R_API const RList *r_graph_get_neighbours(const RGraph *g, const RGraphNode *n) {
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return n? n->out_nodes: NULL;
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}
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/* returns the n-th nodes reachable from the give node `n`.
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* This, of course, depends on the order of the nodes. */
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R_API RGraphNode *r_graph_nth_neighbour(const RGraph *g, const RGraphNode *n, int nth) {
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return n? (RGraphNode *)r_list_get_n (n->out_nodes, nth): NULL;
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}
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/* returns the list of nodes that can reach `n` */
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R_API const RList *r_graph_innodes(const RGraph *g, const RGraphNode *n) {
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return n? n->in_nodes: NULL;
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}
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/* returns the list of nodes reachable from `n` and that can reach `n`. */
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R_API const RList *r_graph_all_neighbours(const RGraph *g, const RGraphNode *n) {
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return n? n->all_neighbours: NULL;
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}
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R_API const RList *r_graph_get_nodes(const RGraph *g) {
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return g? g->nodes: NULL;
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}
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/* true if there is an edge from the node `from` to the node `to` */
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R_API bool r_graph_adjacent(const RGraph *g, const RGraphNode *from, const RGraphNode *to) {
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if (!g || !from) {
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return false;
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}
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return r_list_contains (from->out_nodes, to);
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}
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R_API void r_graph_dfs_node(RGraph *g, RGraphNode *n, RGraphVisitor *vis) {
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if (!g || !n || !vis) {
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return;
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}
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int *color = R_NEWS0 (int, g->last_index);
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if (color) {
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dfs_node (g, n, vis, color, true);
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free (color);
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}
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}
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R_API void r_graph_dfs_node_reverse(RGraph *g, RGraphNode *n, RGraphVisitor *vis) {
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if (!g || !n || !vis) {
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return;
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}
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int *color = R_NEWS0 (int, g->last_index);
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if (color) {
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dfs_node (g, n, vis, color, false);
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free (color);
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}
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}
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R_API void r_graph_dfs(RGraph *g, RGraphVisitor *vis) {
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r_return_if_fail (g && vis);
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RGraphNode *n;
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RListIter *it;
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int *color = R_NEWS0 (int, g->last_index);
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if (color) {
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r_list_foreach (g->nodes, it, n) {
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if (color[n->idx] == WHITE_COLOR) {
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dfs_node (g, n, vis, color, true);
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}
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}
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free (color);
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}
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}
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