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1 /*
2  * Copyright 2011 Christoph Bumiller
3  *
4  * Permission is hereby granted, free of charge, to any person obtaining a
5  * copy of this software and associated documentation files (the "Software"),
6  * to deal in the Software without restriction, including without limitation
7  * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8  * and/or sell copies of the Software, and to permit persons to whom the
9  * Software is furnished to do so, subject to the following conditions:
10  *
11  * The above copyright notice and this permission notice shall be included in
12  * all copies or substantial portions of the Software.
13  *
14  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
15  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
16  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
17  * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR
18  * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
19  * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
20  * OTHER DEALINGS IN THE SOFTWARE.
21  */
22 
23 #include "codegen/nv50_ir_graph.h"
24 #include <limits>
25 #include <list>
26 #include <stack>
27 #include "codegen/nv50_ir.h"
28 
29 namespace nv50_ir {
30 
Graph()31 Graph::Graph()
32 {
33    root = NULL;
34    size = 0;
35    sequence = 0;
36 }
37 
~Graph()38 Graph::~Graph()
39 {
40    for (IteratorRef it = safeIteratorDFS(); !it->end(); it->next())
41       reinterpret_cast<Node *>(it->get())->cut();
42 }
43 
insert(Node * node)44 void Graph::insert(Node *node)
45 {
46    if (!root)
47       root = node;
48 
49    node->graph = this;
50    size++;
51 }
52 
unlink()53 void Graph::Edge::unlink()
54 {
55    if (origin) {
56       prev[0]->next[0] = next[0];
57       next[0]->prev[0] = prev[0];
58       if (origin->out == this)
59          origin->out = (next[0] == this) ? NULL : next[0];
60 
61       --origin->outCount;
62    }
63    if (target) {
64       prev[1]->next[1] = next[1];
65       next[1]->prev[1] = prev[1];
66       if (target->in == this)
67          target->in = (next[1] == this) ? NULL : next[1];
68 
69       --target->inCount;
70    }
71 }
72 
typeStr() const73 const char *Graph::Edge::typeStr() const
74 {
75    switch (type) {
76    case TREE:    return "tree";
77    case FORWARD: return "forward";
78    case BACK:    return "back";
79    case CROSS:   return "cross";
80    case UNKNOWN:
81    default:
82       return "unk";
83    }
84 }
85 
Node(void * priv)86 Graph::Node::Node(void *priv) : data(priv),
87                                 in(0), out(0), graph(0),
88                                 visited(0),
89                                 inCount(0), outCount(0)
90 {
91    // nothing to do
92 }
93 
attach(Node * node,Edge::Type kind)94 void Graph::Node::attach(Node *node, Edge::Type kind)
95 {
96    Edge *edge = new Edge(this, node, kind);
97 
98    // insert head
99    if (this->out) {
100       edge->next[0] = this->out;
101       edge->prev[0] = this->out->prev[0];
102       edge->prev[0]->next[0] = edge;
103       this->out->prev[0] = edge;
104    }
105    this->out = edge;
106 
107    if (node->in) {
108       edge->next[1] = node->in;
109       edge->prev[1] = node->in->prev[1];
110       edge->prev[1]->next[1] = edge;
111       node->in->prev[1] = edge;
112    }
113    node->in = edge;
114 
115    ++this->outCount;
116    ++node->inCount;
117 
118    assert(graph || node->graph);
119    if (!node->graph)
120       graph->insert(node);
121    if (!graph)
122       node->graph->insert(this);
123 
124    if (kind == Edge::UNKNOWN)
125       graph->classifyEdges();
126 }
127 
detach(Graph::Node * node)128 bool Graph::Node::detach(Graph::Node *node)
129 {
130    EdgeIterator ei = this->outgoing();
131    for (; !ei.end(); ei.next())
132       if (ei.getNode() == node)
133          break;
134    if (ei.end()) {
135       ERROR("no such node attached\n");
136       return false;
137    }
138    delete ei.getEdge();
139    return true;
140 }
141 
142 // Cut a node from the graph, deleting all attached edges.
cut()143 void Graph::Node::cut()
144 {
145    while (out)
146       delete out;
147    while (in)
148       delete in;
149 
150    if (graph) {
151       if (graph->root == this)
152          graph->root = NULL;
153       graph = NULL;
154    }
155 }
156 
Edge(Node * org,Node * tgt,Type kind)157 Graph::Edge::Edge(Node *org, Node *tgt, Type kind)
158 {
159    target = tgt;
160    origin = org;
161    type = kind;
162 
163    next[0] = next[1] = this;
164    prev[0] = prev[1] = this;
165 }
166 
167 bool
reachableBy(const Node * node,const Node * term) const168 Graph::Node::reachableBy(const Node *node, const Node *term) const
169 {
170    std::stack<const Node *> stack;
171    const Node *pos = NULL;
172    const int seq = graph->nextSequence();
173 
174    stack.push(node);
175 
176    while (!stack.empty()) {
177       pos = stack.top();
178       stack.pop();
179 
180       if (pos == this)
181          return true;
182       if (pos == term)
183          continue;
184 
185       for (EdgeIterator ei = pos->outgoing(); !ei.end(); ei.next()) {
186          if (ei.getType() == Edge::BACK)
187             continue;
188          if (ei.getNode()->visit(seq))
189             stack.push(ei.getNode());
190       }
191    }
192    return pos == this;
193 }
194 
195 class DFSIterator : public Iterator
196 {
197 public:
DFSIterator(Graph * graph,const bool preorder)198    DFSIterator(Graph *graph, const bool preorder)
199    {
200       unsigned int seq = graph->nextSequence();
201 
202       nodes = new Graph::Node * [graph->getSize() + 1];
203       count = 0;
204       pos = 0;
205       nodes[graph->getSize()] = 0;
206 
207       if (graph->getRoot()) {
208          graph->getRoot()->visit(seq);
209          search(graph->getRoot(), preorder, seq);
210       }
211    }
212 
~DFSIterator()213    ~DFSIterator()
214    {
215       if (nodes)
216          delete[] nodes;
217    }
218 
search(Graph::Node * node,const bool preorder,const int sequence)219    void search(Graph::Node *node, const bool preorder, const int sequence)
220    {
221       if (preorder)
222          nodes[count++] = node;
223 
224       for (Graph::EdgeIterator ei = node->outgoing(); !ei.end(); ei.next())
225          if (ei.getNode()->visit(sequence))
226             search(ei.getNode(), preorder, sequence);
227 
228       if (!preorder)
229          nodes[count++] = node;
230    }
231 
end() const232    virtual bool end() const { return pos >= count; }
next()233    virtual void next() { if (pos < count) ++pos; }
get() const234    virtual void *get() const { return nodes[pos]; }
reset()235    virtual void reset() { pos = 0; }
236 
237 protected:
238    Graph::Node **nodes;
239    int count;
240    int pos;
241 };
242 
iteratorDFS(bool preorder)243 IteratorRef Graph::iteratorDFS(bool preorder)
244 {
245    return IteratorRef(new DFSIterator(this, preorder));
246 }
247 
safeIteratorDFS(bool preorder)248 IteratorRef Graph::safeIteratorDFS(bool preorder)
249 {
250    return this->iteratorDFS(preorder);
251 }
252 
253 class CFGIterator : public Iterator
254 {
255 public:
CFGIterator(Graph * graph)256    CFGIterator(Graph *graph)
257    {
258       nodes = new Graph::Node * [graph->getSize() + 1];
259       count = 0;
260       pos = 0;
261       nodes[graph->getSize()] = 0;
262 
263       // TODO: argh, use graph->sequence instead of tag and just raise it by > 1
264       for (IteratorRef it = graph->iteratorDFS(); !it->end(); it->next())
265          reinterpret_cast<Graph::Node *>(it->get())->tag = 0;
266 
267       if (graph->getRoot())
268          search(graph->getRoot(), graph->nextSequence());
269    }
270 
~CFGIterator()271    ~CFGIterator()
272    {
273       if (nodes)
274          delete[] nodes;
275    }
276 
get() const277    virtual void *get() const { return nodes[pos]; }
end() const278    virtual bool end() const { return pos >= count; }
next()279    virtual void next() { if (pos < count) ++pos; }
reset()280    virtual void reset() { pos = 0; }
281 
282 private:
search(Graph::Node * node,const int sequence)283    void search(Graph::Node *node, const int sequence)
284    {
285       Stack bb, cross;
286 
287       bb.push(node);
288 
289       while (bb.getSize() || cross.getSize()) {
290          if (bb.getSize() == 0)
291             cross.moveTo(bb);
292 
293          node = reinterpret_cast<Graph::Node *>(bb.pop().u.p);
294          assert(node);
295          if (!node->visit(sequence))
296             continue;
297          node->tag = 0;
298 
299          for (Graph::EdgeIterator ei = node->outgoing(); !ei.end(); ei.next()) {
300             switch (ei.getType()) {
301             case Graph::Edge::TREE:
302             case Graph::Edge::FORWARD:
303                if (++(ei.getNode()->tag) == ei.getNode()->incidentCountFwd())
304                   bb.push(ei.getNode());
305                break;
306             case Graph::Edge::BACK:
307                continue;
308             case Graph::Edge::CROSS:
309                if (++(ei.getNode()->tag) == 1)
310                   cross.push(ei.getNode());
311                break;
312             default:
313                assert(!"unknown edge kind in CFG");
314                break;
315             }
316          }
317          nodes[count++] = node;
318       }
319    }
320 
321 private:
322    Graph::Node **nodes;
323    int count;
324    int pos;
325 };
326 
iteratorCFG()327 IteratorRef Graph::iteratorCFG()
328 {
329    return IteratorRef(new CFGIterator(this));
330 }
331 
safeIteratorCFG()332 IteratorRef Graph::safeIteratorCFG()
333 {
334    return this->iteratorCFG();
335 }
336 
337 /**
338  * Edge classification:
339  *
340  * We have a graph and want to classify the edges into one of four types:
341  * - TREE:    edges that belong to a spanning tree of the graph
342  * - FORWARD: edges from a node to a descendent in the spanning tree
343  * - BACK:    edges from a node to a parent (or itself) in the spanning tree
344  * - CROSS:   all other edges (because they cross between branches in the
345  *            spanning tree)
346  */
classifyEdges()347 void Graph::classifyEdges()
348 {
349    int seq;
350 
351    for (IteratorRef it = iteratorDFS(true); !it->end(); it->next()) {
352       Node *node = reinterpret_cast<Node *>(it->get());
353       node->visit(0);
354       node->tag = 0;
355    }
356 
357    classifyDFS(root, (seq = 0));
358 
359    sequence = seq;
360 }
361 
classifyDFS(Node * curr,int & seq)362 void Graph::classifyDFS(Node *curr, int& seq)
363 {
364    Graph::Edge *edge;
365    Graph::Node *node;
366 
367    curr->visit(++seq);
368    curr->tag = 1;
369 
370    for (edge = curr->out; edge; edge = edge->next[0]) {
371       node = edge->target;
372 
373       if (node->getSequence() == 0) {
374          edge->type = Edge::TREE;
375          classifyDFS(node, seq);
376       } else
377       if (node->getSequence() > curr->getSequence()) {
378          edge->type = Edge::FORWARD;
379       } else {
380          edge->type = node->tag ? Edge::BACK : Edge::CROSS;
381       }
382    }
383 
384    for (edge = curr->in; edge; edge = edge->next[1]) {
385       node = edge->origin;
386 
387       if (node->getSequence() == 0) {
388          edge->type = Edge::TREE;
389          classifyDFS(node, seq);
390       } else
391       if (node->getSequence() > curr->getSequence()) {
392          edge->type = Edge::FORWARD;
393       } else {
394          edge->type = node->tag ? Edge::BACK : Edge::CROSS;
395       }
396    }
397 
398    curr->tag = 0;
399 }
400 
401 // @dist is indexed by Node::tag, returns -1 if no path found
402 int
findLightestPathWeight(Node * a,Node * b,const std::vector<int> & weight)403 Graph::findLightestPathWeight(Node *a, Node *b, const std::vector<int> &weight)
404 {
405    std::vector<int> path(weight.size(), std::numeric_limits<int>::max());
406    std::list<Node *> nodeList;
407    const int seq = nextSequence();
408 
409    path[a->tag] = 0;
410    for (Node *c = a; c && c != b;) {
411       const int p = path[c->tag] + weight[c->tag];
412       for (EdgeIterator ei = c->outgoing(); !ei.end(); ei.next()) {
413          Node *t = ei.getNode();
414          if (t->getSequence() < seq) {
415             if (path[t->tag] == std::numeric_limits<int>::max())
416                nodeList.push_front(t);
417             if (p < path[t->tag])
418                path[t->tag] = p;
419          }
420       }
421       c->visit(seq);
422       Node *next = NULL;
423       for (std::list<Node *>::iterator n = nodeList.begin();
424            n != nodeList.end(); ++n) {
425          if (!next || path[(*n)->tag] < path[next->tag])
426             next = *n;
427          if ((*n) == c) {
428             // erase visited
429             n = nodeList.erase(n);
430             --n;
431          }
432       }
433       c = next;
434    }
435    if (path[b->tag] == std::numeric_limits<int>::max())
436       return -1;
437    return path[b->tag];
438 }
439 
440 } // namespace nv50_ir
441