/* * Copyright 2011 Christoph Bumiller * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ #include "nv50_ir.h" namespace nv50_ir { Function::Function(Program *p, const char *fnName, uint32_t label) : call(this), label(label), name(fnName), prog(p) { cfgExit = NULL; domTree = NULL; bbArray = NULL; bbCount = 0; loopNestingBound = 0; regClobberMax = 0; binPos = 0; binSize = 0; stackPtr = NULL; tlsBase = 0; tlsSize = 0; prog->add(this, id); } Function::~Function() { prog->del(this, id); if (domTree) delete domTree; if (bbArray) delete[] bbArray; // clear value refs and defs ins.clear(); outs.clear(); for (ArrayList::Iterator it = allInsns.iterator(); !it.end(); it.next()) delete_Instruction(prog, reinterpret_cast(it.get())); for (ArrayList::Iterator it = allLValues.iterator(); !it.end(); it.next()) delete_Value(prog, reinterpret_cast(it.get())); for (ArrayList::Iterator BBs = allBBlocks.iterator(); !BBs.end(); BBs.next()) delete reinterpret_cast(BBs.get()); } BasicBlock::BasicBlock(Function *fn) : cfg(this), dom(this), func(fn) { program = func->getProgram(); joinAt = phi = entry = exit = NULL; numInsns = 0; binPos = 0; binSize = 0; explicitCont = false; func->add(this, this->id); } BasicBlock::~BasicBlock() { // nothing yet } BasicBlock * BasicBlock::clone(ClonePolicy& pol) const { BasicBlock *bb = new BasicBlock(pol.context()); pol.set(this, bb); for (Instruction *i = getFirst(); i; i = i->next) bb->insertTail(i->clone(pol)); pol.context()->cfg.insert(&bb->cfg); for (Graph::EdgeIterator it = cfg.outgoing(); !it.end(); it.next()) { BasicBlock *obb = BasicBlock::get(it.getNode()); bb->cfg.attach(&pol.get(obb)->cfg, it.getType()); } return bb; } BasicBlock * BasicBlock::idom() const { Graph::Node *dn = dom.parent(); return dn ? BasicBlock::get(dn) : NULL; } void BasicBlock::insertHead(Instruction *inst) { assert(inst->next == 0 && inst->prev == 0); if (inst->op == OP_PHI) { if (phi) { insertBefore(phi, inst); } else { if (entry) { insertBefore(entry, inst); } else { assert(!exit); phi = exit = inst; inst->bb = this; ++numInsns; } } } else { if (entry) { insertBefore(entry, inst); } else { if (phi) { insertAfter(exit, inst); // after last phi } else { assert(!exit); entry = exit = inst; inst->bb = this; ++numInsns; } } } } void BasicBlock::insertTail(Instruction *inst) { assert(inst->next == 0 && inst->prev == 0); if (inst->op == OP_PHI) { if (entry) { insertBefore(entry, inst); } else if (exit) { assert(phi); insertAfter(exit, inst); } else { assert(!phi); phi = exit = inst; inst->bb = this; ++numInsns; } } else { if (exit) { insertAfter(exit, inst); } else { assert(!phi); entry = exit = inst; inst->bb = this; ++numInsns; } } } void BasicBlock::insertBefore(Instruction *q, Instruction *p) { assert(p && q); assert(p->next == 0 && p->prev == 0); if (q == entry) { if (p->op == OP_PHI) { if (!phi) phi = p; } else { entry = p; } } else if (q == phi) { assert(p->op == OP_PHI); phi = p; } p->next = q; p->prev = q->prev; if (p->prev) p->prev->next = p; q->prev = p; p->bb = this; ++numInsns; } void BasicBlock::insertAfter(Instruction *p, Instruction *q) { assert(p && q); assert(q->op != OP_PHI || p->op == OP_PHI); assert(q->next == 0 && q->prev == 0); if (p == exit) exit = q; if (p->op == OP_PHI && q->op != OP_PHI) entry = q; q->prev = p; q->next = p->next; if (q->next) q->next->prev = q; p->next = q; q->bb = this; ++numInsns; } void BasicBlock::remove(Instruction *insn) { assert(insn->bb == this); if (insn->prev) insn->prev->next = insn->next; if (insn->next) insn->next->prev = insn->prev; else exit = insn->prev; if (insn == entry) { if (insn->next) entry = insn->next; else if (insn->prev && insn->prev->op != OP_PHI) entry = insn->prev; else entry = NULL; } if (insn == phi) phi = (insn->next && insn->next->op == OP_PHI) ? insn->next : 0; --numInsns; insn->bb = NULL; insn->next = insn->prev = NULL; } void BasicBlock::permuteAdjacent(Instruction *a, Instruction *b) { assert(a->bb == b->bb); if (a->next != b) { Instruction *i = a; a = b; b = i; } assert(a->next == b); assert(a->op != OP_PHI && b->op != OP_PHI); if (b == exit) exit = a; if (a == entry) entry = b; b->prev = a->prev; a->next = b->next; b->next = a; a->prev = b; if (b->prev) b->prev->next = b; if (a->prev) a->next->prev = a; } void BasicBlock::splitCommon(Instruction *insn, BasicBlock *bb, bool attach) { bb->entry = insn; if (insn) { exit = insn->prev; insn->prev = NULL; } if (exit) exit->next = NULL; else entry = NULL; while (!cfg.outgoing(true).end()) { Graph::Edge *e = cfg.outgoing(true).getEdge(); bb->cfg.attach(e->getTarget(), e->getType()); this->cfg.detach(e->getTarget()); } for (; insn; insn = insn->next) { this->numInsns--; bb->numInsns++; insn->bb = bb; bb->exit = insn; } if (attach) this->cfg.attach(&bb->cfg, Graph::Edge::TREE); } BasicBlock * BasicBlock::splitBefore(Instruction *insn, bool attach) { BasicBlock *bb = new BasicBlock(func); assert(!insn || insn->op != OP_PHI); splitCommon(insn, bb, attach); return bb; } BasicBlock * BasicBlock::splitAfter(Instruction *insn, bool attach) { BasicBlock *bb = new BasicBlock(func); assert(!insn || insn->op != OP_PHI); bb->joinAt = joinAt; joinAt = NULL; splitCommon(insn ? insn->next : NULL, bb, attach); return bb; } bool BasicBlock::dominatedBy(BasicBlock *that) { Graph::Node *bn = &that->dom; Graph::Node *dn = &this->dom; while (dn && dn != bn) dn = dn->parent(); return dn != NULL; } unsigned int BasicBlock::initiatesSimpleConditional() const { Graph::Node *out[2]; int n; Graph::Edge::Type eR; if (cfg.outgoingCount() != 2) // -> if and -> else/endif return false; n = 0; for (Graph::EdgeIterator ei = cfg.outgoing(); !ei.end(); ei.next()) out[n++] = ei.getNode(); eR = out[1]->outgoing().getType(); // IF block is out edge to the right if (eR == Graph::Edge::CROSS || eR == Graph::Edge::BACK) return 0x2; if (out[1]->outgoingCount() != 1) // 0 is IF { RET; }, >1 is more divergence return 0x0; // do they reconverge immediately ? if (out[1]->outgoing().getNode() == out[0]) return 0x1; if (out[0]->outgoingCount() == 1) if (out[0]->outgoing().getNode() == out[1]->outgoing().getNode()) return 0x3; return 0x0; } bool Function::setEntry(BasicBlock *bb) { if (cfg.getRoot()) return false; cfg.insert(&bb->cfg); return true; } bool Function::setExit(BasicBlock *bb) { if (cfgExit) return false; cfgExit = &bb->cfg; return true; } unsigned int Function::orderInstructions(ArrayList &result) { result.clear(); for (IteratorRef it = cfg.iteratorCFG(); !it->end(); it->next()) { BasicBlock *bb = BasicBlock::get(reinterpret_cast(it->get())); for (Instruction *insn = bb->getFirst(); insn; insn = insn->next) result.insert(insn, insn->serial); } return result.getSize(); } void Function::buildLiveSets() { for (unsigned i = 0; i <= loopNestingBound; ++i) buildLiveSetsPreSSA(BasicBlock::get(cfg.getRoot()), cfg.nextSequence()); for (ArrayList::Iterator bi = allBBlocks.iterator(); !bi.end(); bi.next()) BasicBlock::get(bi)->liveSet.marker = false; } void Function::buildDefSets() { for (unsigned i = 0; i <= loopNestingBound; ++i) buildDefSetsPreSSA(BasicBlock::get(cfgExit), cfg.nextSequence()); for (ArrayList::Iterator bi = allBBlocks.iterator(); !bi.end(); bi.next()) BasicBlock::get(bi)->liveSet.marker = false; } bool Pass::run(Program *prog, bool ordered, bool skipPhi) { this->prog = prog; err = false; return doRun(prog, ordered, skipPhi); } bool Pass::doRun(Program *prog, bool ordered, bool skipPhi) { for (IteratorRef it = prog->calls.iteratorDFS(false); !it->end(); it->next()) { Graph::Node *n = reinterpret_cast(it->get()); if (!doRun(Function::get(n), ordered, skipPhi)) return false; } return !err; } bool Pass::run(Function *func, bool ordered, bool skipPhi) { prog = func->getProgram(); err = false; return doRun(func, ordered, skipPhi); } bool Pass::doRun(Function *func, bool ordered, bool skipPhi) { IteratorRef bbIter; BasicBlock *bb; Instruction *insn, *next; this->func = func; if (!visit(func)) return false; bbIter = ordered ? func->cfg.iteratorCFG() : func->cfg.iteratorDFS(); for (; !bbIter->end(); bbIter->next()) { bb = BasicBlock::get(reinterpret_cast(bbIter->get())); if (!visit(bb)) break; for (insn = skipPhi ? bb->getEntry() : bb->getFirst(); insn != NULL; insn = next) { next = insn->next; if (!visit(insn)) break; } } return !err; } void Function::printCFGraph(const char *filePath) { FILE *out = fopen(filePath, "a"); if (!out) { ERROR("failed to open file: %s\n", filePath); return; } INFO("printing control flow graph to: %s\n", filePath); fprintf(out, "digraph G {\n"); for (IteratorRef it = cfg.iteratorDFS(); !it->end(); it->next()) { BasicBlock *bb = BasicBlock::get( reinterpret_cast(it->get())); int idA = bb->getId(); for (Graph::EdgeIterator ei = bb->cfg.outgoing(); !ei.end(); ei.next()) { int idB = BasicBlock::get(ei.getNode())->getId(); switch (ei.getType()) { case Graph::Edge::TREE: fprintf(out, "\t%i -> %i;\n", idA, idB); break; case Graph::Edge::FORWARD: fprintf(out, "\t%i -> %i [color=green];\n", idA, idB); break; case Graph::Edge::CROSS: fprintf(out, "\t%i -> %i [color=red];\n", idA, idB); break; case Graph::Edge::BACK: fprintf(out, "\t%i -> %i;\n", idA, idB); break; case Graph::Edge::DUMMY: fprintf(out, "\t%i -> %i [style=dotted];\n", idA, idB); break; default: assert(0); break; } } } fprintf(out, "}\n"); fclose(out); } } // namespace nv50_ir