/* * 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 "codegen/nv50_ir.h" #include "codegen/nv50_ir_target.h" #include <algorithm> #include <stack> #include <limits> #if __cplusplus >= 201103L #include <unordered_map> #else #include <tr1/unordered_map> #endif namespace nv50_ir { #if __cplusplus >= 201103L using std::hash; using std::unordered_map; #else using std::tr1::hash; using std::tr1::unordered_map; #endif #define MAX_REGISTER_FILE_SIZE 256 class RegisterSet { public: RegisterSet(const Target *); void init(const Target *); void reset(DataFile, bool resetMax = false); void periodicMask(DataFile f, uint32_t lock, uint32_t unlock); void intersect(DataFile f, const RegisterSet *); bool assign(int32_t& reg, DataFile f, unsigned int size); void release(DataFile f, int32_t reg, unsigned int size); void occupy(DataFile f, int32_t reg, unsigned int size); void occupy(const Value *); void occupyMask(DataFile f, int32_t reg, uint8_t mask); bool isOccupied(DataFile f, int32_t reg, unsigned int size) const; bool testOccupy(const Value *); bool testOccupy(DataFile f, int32_t reg, unsigned int size); inline int getMaxAssigned(DataFile f) const { return fill[f]; } inline unsigned int getFileSize(DataFile f, uint8_t regSize) const { if (restrictedGPR16Range && f == FILE_GPR && regSize == 2) return (last[f] + 1) / 2; return last[f] + 1; } inline unsigned int units(DataFile f, unsigned int size) const { return size >> unit[f]; } // for regs of size >= 4, id is counted in 4-byte words (like nv50/c0 binary) inline unsigned int idToBytes(const Value *v) const { return v->reg.data.id * MIN2(v->reg.size, 4); } inline unsigned int idToUnits(const Value *v) const { return units(v->reg.file, idToBytes(v)); } inline int bytesToId(Value *v, unsigned int bytes) const { if (v->reg.size < 4) return units(v->reg.file, bytes); return bytes / 4; } inline int unitsToId(DataFile f, int u, uint8_t size) const { if (u < 0) return -1; return (size < 4) ? u : ((u << unit[f]) / 4); } void print(DataFile f) const; const bool restrictedGPR16Range; private: BitSet bits[LAST_REGISTER_FILE + 1]; int unit[LAST_REGISTER_FILE + 1]; // log2 of allocation granularity int last[LAST_REGISTER_FILE + 1]; int fill[LAST_REGISTER_FILE + 1]; }; void RegisterSet::reset(DataFile f, bool resetMax) { bits[f].fill(0); if (resetMax) fill[f] = -1; } void RegisterSet::init(const Target *targ) { for (unsigned int rf = 0; rf <= FILE_ADDRESS; ++rf) { DataFile f = static_cast<DataFile>(rf); last[rf] = targ->getFileSize(f) - 1; unit[rf] = targ->getFileUnit(f); fill[rf] = -1; assert(last[rf] < MAX_REGISTER_FILE_SIZE); bits[rf].allocate(last[rf] + 1, true); } } RegisterSet::RegisterSet(const Target *targ) : restrictedGPR16Range(targ->getChipset() < 0xc0) { init(targ); for (unsigned int i = 0; i <= LAST_REGISTER_FILE; ++i) reset(static_cast<DataFile>(i)); } void RegisterSet::periodicMask(DataFile f, uint32_t lock, uint32_t unlock) { bits[f].periodicMask32(lock, unlock); } void RegisterSet::intersect(DataFile f, const RegisterSet *set) { bits[f] |= set->bits[f]; } void RegisterSet::print(DataFile f) const { INFO("GPR:"); bits[f].print(); INFO("\n"); } bool RegisterSet::assign(int32_t& reg, DataFile f, unsigned int size) { reg = bits[f].findFreeRange(size); if (reg < 0) return false; fill[f] = MAX2(fill[f], (int32_t)(reg + size - 1)); return true; } bool RegisterSet::isOccupied(DataFile f, int32_t reg, unsigned int size) const { return bits[f].testRange(reg, size); } void RegisterSet::occupy(const Value *v) { occupy(v->reg.file, idToUnits(v), v->reg.size >> unit[v->reg.file]); } void RegisterSet::occupyMask(DataFile f, int32_t reg, uint8_t mask) { bits[f].setMask(reg & ~31, static_cast<uint32_t>(mask) << (reg % 32)); } void RegisterSet::occupy(DataFile f, int32_t reg, unsigned int size) { bits[f].setRange(reg, size); INFO_DBG(0, REG_ALLOC, "reg occupy: %u[%i] %u\n", f, reg, size); fill[f] = MAX2(fill[f], (int32_t)(reg + size - 1)); } bool RegisterSet::testOccupy(const Value *v) { return testOccupy(v->reg.file, idToUnits(v), v->reg.size >> unit[v->reg.file]); } bool RegisterSet::testOccupy(DataFile f, int32_t reg, unsigned int size) { if (isOccupied(f, reg, size)) return false; occupy(f, reg, size); return true; } void RegisterSet::release(DataFile f, int32_t reg, unsigned int size) { bits[f].clrRange(reg, size); INFO_DBG(0, REG_ALLOC, "reg release: %u[%i] %u\n", f, reg, size); } class RegAlloc { public: RegAlloc(Program *program) : prog(program), sequence(0) { } bool exec(); bool execFunc(); private: class PhiMovesPass : public Pass { private: virtual bool visit(BasicBlock *); inline bool needNewElseBlock(BasicBlock *b, BasicBlock *p); inline void splitEdges(BasicBlock *b); }; class ArgumentMovesPass : public Pass { private: virtual bool visit(BasicBlock *); }; class BuildIntervalsPass : public Pass { private: virtual bool visit(BasicBlock *); void collectLiveValues(BasicBlock *); void addLiveRange(Value *, const BasicBlock *, int end); }; class InsertConstraintsPass : public Pass { public: bool exec(Function *func); private: virtual bool visit(BasicBlock *); bool insertConstraintMoves(); void condenseDefs(Instruction *); void condenseSrcs(Instruction *, const int first, const int last); void addHazard(Instruction *i, const ValueRef *src); void textureMask(TexInstruction *); void addConstraint(Instruction *, int s, int n); bool detectConflict(Instruction *, int s); // target specific functions, TODO: put in subclass or Target void texConstraintNV50(TexInstruction *); void texConstraintNVC0(TexInstruction *); void texConstraintNVE0(TexInstruction *); void texConstraintGM107(TexInstruction *); std::list<Instruction *> constrList; const Target *targ; }; bool buildLiveSets(BasicBlock *); private: Program *prog; Function *func; // instructions in control flow / chronological order ArrayList insns; int sequence; // for manual passes through CFG }; typedef std::pair<Value *, Value *> ValuePair; class SpillCodeInserter { public: SpillCodeInserter(Function *fn) : func(fn), stackSize(0), stackBase(0) { } bool run(const std::list<ValuePair>&); Symbol *assignSlot(const Interval&, const unsigned int size); Value *offsetSlot(Value *, const LValue *); inline int32_t getStackSize() const { return stackSize; } private: Function *func; struct SpillSlot { Interval occup; std::list<Value *> residents; // needed to recalculate occup Symbol *sym; int32_t offset; inline uint8_t size() const { return sym->reg.size; } }; std::list<SpillSlot> slots; int32_t stackSize; int32_t stackBase; LValue *unspill(Instruction *usei, LValue *, Value *slot); void spill(Instruction *defi, Value *slot, LValue *); }; void RegAlloc::BuildIntervalsPass::addLiveRange(Value *val, const BasicBlock *bb, int end) { Instruction *insn = val->getUniqueInsn(); if (!insn) insn = bb->getFirst(); assert(bb->getFirst()->serial <= bb->getExit()->serial); assert(bb->getExit()->serial + 1 >= end); int begin = insn->serial; if (begin < bb->getEntry()->serial || begin > bb->getExit()->serial) begin = bb->getEntry()->serial; INFO_DBG(prog->dbgFlags, REG_ALLOC, "%%%i <- live range [%i(%i), %i)\n", val->id, begin, insn->serial, end); if (begin != end) // empty ranges are only added as hazards for fixed regs val->livei.extend(begin, end); } bool RegAlloc::PhiMovesPass::needNewElseBlock(BasicBlock *b, BasicBlock *p) { if (b->cfg.incidentCount() <= 1) return false; int n = 0; for (Graph::EdgeIterator ei = p->cfg.outgoing(); !ei.end(); ei.next()) if (ei.getType() == Graph::Edge::TREE || ei.getType() == Graph::Edge::FORWARD) ++n; return (n == 2); } struct PhiMapHash { size_t operator()(const std::pair<Instruction *, BasicBlock *>& val) const { return hash<Instruction*>()(val.first) * 31 + hash<BasicBlock*>()(val.second); } }; typedef unordered_map< std::pair<Instruction *, BasicBlock *>, Value *, PhiMapHash> PhiMap; // Critical edges need to be split up so that work can be inserted along // specific edge transitions. Unfortunately manipulating incident edges into a // BB invalidates all the PHI nodes since their sources are implicitly ordered // by incident edge order. // // TODO: Make it so that that is not the case, and PHI nodes store pointers to // the original BBs. void RegAlloc::PhiMovesPass::splitEdges(BasicBlock *bb) { BasicBlock *pb, *pn; Instruction *phi; Graph::EdgeIterator ei; std::stack<BasicBlock *> stack; int j = 0; for (ei = bb->cfg.incident(); !ei.end(); ei.next()) { pb = BasicBlock::get(ei.getNode()); assert(pb); if (needNewElseBlock(bb, pb)) stack.push(pb); } // No critical edges were found, no need to perform any work. if (stack.empty()) return; // We're about to, potentially, reorder the inbound edges. This means that // we need to hold on to the (phi, bb) -> src mapping, and fix up the phi // nodes after the graph has been modified. PhiMap phis; j = 0; for (ei = bb->cfg.incident(); !ei.end(); ei.next(), j++) { pb = BasicBlock::get(ei.getNode()); for (phi = bb->getPhi(); phi && phi->op == OP_PHI; phi = phi->next) phis.insert(std::make_pair(std::make_pair(phi, pb), phi->getSrc(j))); } while (!stack.empty()) { pb = stack.top(); pn = new BasicBlock(func); stack.pop(); pb->cfg.detach(&bb->cfg); pb->cfg.attach(&pn->cfg, Graph::Edge::TREE); pn->cfg.attach(&bb->cfg, Graph::Edge::FORWARD); assert(pb->getExit()->op != OP_CALL); if (pb->getExit()->asFlow()->target.bb == bb) pb->getExit()->asFlow()->target.bb = pn; for (phi = bb->getPhi(); phi && phi->op == OP_PHI; phi = phi->next) { PhiMap::iterator it = phis.find(std::make_pair(phi, pb)); assert(it != phis.end()); phis.insert(std::make_pair(std::make_pair(phi, pn), it->second)); phis.erase(it); } } // Now go through and fix up all of the phi node sources. j = 0; for (ei = bb->cfg.incident(); !ei.end(); ei.next(), j++) { pb = BasicBlock::get(ei.getNode()); for (phi = bb->getPhi(); phi && phi->op == OP_PHI; phi = phi->next) { PhiMap::const_iterator it = phis.find(std::make_pair(phi, pb)); assert(it != phis.end()); phi->setSrc(j, it->second); } } } // For each operand of each PHI in b, generate a new value by inserting a MOV // at the end of the block it is coming from and replace the operand with its // result. This eliminates liveness conflicts and enables us to let values be // copied to the right register if such a conflict exists nonetheless. // // These MOVs are also crucial in making sure the live intervals of phi srces // are extended until the end of the loop, since they are not included in the // live-in sets. bool RegAlloc::PhiMovesPass::visit(BasicBlock *bb) { Instruction *phi, *mov; splitEdges(bb); // insert MOVs (phi->src(j) should stem from j-th in-BB) int j = 0; for (Graph::EdgeIterator ei = bb->cfg.incident(); !ei.end(); ei.next()) { BasicBlock *pb = BasicBlock::get(ei.getNode()); if (!pb->isTerminated()) pb->insertTail(new_FlowInstruction(func, OP_BRA, bb)); for (phi = bb->getPhi(); phi && phi->op == OP_PHI; phi = phi->next) { LValue *tmp = new_LValue(func, phi->getDef(0)->asLValue()); mov = new_Instruction(func, OP_MOV, typeOfSize(tmp->reg.size)); mov->setSrc(0, phi->getSrc(j)); mov->setDef(0, tmp); phi->setSrc(j, tmp); pb->insertBefore(pb->getExit(), mov); } ++j; } return true; } bool RegAlloc::ArgumentMovesPass::visit(BasicBlock *bb) { // Bind function call inputs/outputs to the same physical register // the callee uses, inserting moves as appropriate for the case a // conflict arises. for (Instruction *i = bb->getEntry(); i; i = i->next) { FlowInstruction *cal = i->asFlow(); // TODO: Handle indirect calls. // Right now they should only be generated for builtins. if (!cal || cal->op != OP_CALL || cal->builtin || cal->indirect) continue; RegisterSet clobberSet(prog->getTarget()); // Bind input values. for (int s = cal->indirect ? 1 : 0; cal->srcExists(s); ++s) { const int t = cal->indirect ? (s - 1) : s; LValue *tmp = new_LValue(func, cal->getSrc(s)->asLValue()); tmp->reg.data.id = cal->target.fn->ins[t].rep()->reg.data.id; Instruction *mov = new_Instruction(func, OP_MOV, typeOfSize(tmp->reg.size)); mov->setDef(0, tmp); mov->setSrc(0, cal->getSrc(s)); cal->setSrc(s, tmp); bb->insertBefore(cal, mov); } // Bind output values. for (int d = 0; cal->defExists(d); ++d) { LValue *tmp = new_LValue(func, cal->getDef(d)->asLValue()); tmp->reg.data.id = cal->target.fn->outs[d].rep()->reg.data.id; Instruction *mov = new_Instruction(func, OP_MOV, typeOfSize(tmp->reg.size)); mov->setSrc(0, tmp); mov->setDef(0, cal->getDef(d)); cal->setDef(d, tmp); bb->insertAfter(cal, mov); clobberSet.occupy(tmp); } // Bind clobbered values. for (std::deque<Value *>::iterator it = cal->target.fn->clobbers.begin(); it != cal->target.fn->clobbers.end(); ++it) { if (clobberSet.testOccupy(*it)) { Value *tmp = new_LValue(func, (*it)->asLValue()); tmp->reg.data.id = (*it)->reg.data.id; cal->setDef(cal->defCount(), tmp); } } } // Update the clobber set of the function. if (BasicBlock::get(func->cfgExit) == bb) { func->buildDefSets(); for (unsigned int i = 0; i < bb->defSet.getSize(); ++i) if (bb->defSet.test(i)) func->clobbers.push_back(func->getLValue(i)); } return true; } // Build the set of live-in variables of bb. bool RegAlloc::buildLiveSets(BasicBlock *bb) { Function *f = bb->getFunction(); BasicBlock *bn; Instruction *i; unsigned int s, d; INFO_DBG(prog->dbgFlags, REG_ALLOC, "buildLiveSets(BB:%i)\n", bb->getId()); bb->liveSet.allocate(func->allLValues.getSize(), false); int n = 0; for (Graph::EdgeIterator ei = bb->cfg.outgoing(); !ei.end(); ei.next()) { bn = BasicBlock::get(ei.getNode()); if (bn == bb) continue; if (bn->cfg.visit(sequence)) if (!buildLiveSets(bn)) return false; if (n++ || bb->liveSet.marker) bb->liveSet |= bn->liveSet; else bb->liveSet = bn->liveSet; } if (!n && !bb->liveSet.marker) bb->liveSet.fill(0); bb->liveSet.marker = true; if (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) { INFO("BB:%i live set of out blocks:\n", bb->getId()); bb->liveSet.print(); } // if (!bb->getEntry()) // return true; if (bb == BasicBlock::get(f->cfgExit)) { for (std::deque<ValueRef>::iterator it = f->outs.begin(); it != f->outs.end(); ++it) { assert(it->get()->asLValue()); bb->liveSet.set(it->get()->id); } } for (i = bb->getExit(); i && i != bb->getEntry()->prev; i = i->prev) { for (d = 0; i->defExists(d); ++d) bb->liveSet.clr(i->getDef(d)->id); for (s = 0; i->srcExists(s); ++s) if (i->getSrc(s)->asLValue()) bb->liveSet.set(i->getSrc(s)->id); } for (i = bb->getPhi(); i && i->op == OP_PHI; i = i->next) bb->liveSet.clr(i->getDef(0)->id); if (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) { INFO("BB:%i live set after propagation:\n", bb->getId()); bb->liveSet.print(); } return true; } void RegAlloc::BuildIntervalsPass::collectLiveValues(BasicBlock *bb) { BasicBlock *bbA = NULL, *bbB = NULL; if (bb->cfg.outgoingCount()) { // trickery to save a loop of OR'ing liveSets // aliasing works fine with BitSet::setOr for (Graph::EdgeIterator ei = bb->cfg.outgoing(); !ei.end(); ei.next()) { if (ei.getType() == Graph::Edge::DUMMY) continue; if (bbA) { bb->liveSet.setOr(&bbA->liveSet, &bbB->liveSet); bbA = bb; } else { bbA = bbB; } bbB = BasicBlock::get(ei.getNode()); } bb->liveSet.setOr(&bbB->liveSet, bbA ? &bbA->liveSet : NULL); } else if (bb->cfg.incidentCount()) { bb->liveSet.fill(0); } } bool RegAlloc::BuildIntervalsPass::visit(BasicBlock *bb) { collectLiveValues(bb); INFO_DBG(prog->dbgFlags, REG_ALLOC, "BuildIntervals(BB:%i)\n", bb->getId()); // go through out blocks and delete phi sources that do not originate from // the current block from the live set for (Graph::EdgeIterator ei = bb->cfg.outgoing(); !ei.end(); ei.next()) { BasicBlock *out = BasicBlock::get(ei.getNode()); for (Instruction *i = out->getPhi(); i && i->op == OP_PHI; i = i->next) { bb->liveSet.clr(i->getDef(0)->id); for (int s = 0; i->srcExists(s); ++s) { assert(i->src(s).getInsn()); if (i->getSrc(s)->getUniqueInsn()->bb == bb) // XXX: reachableBy ? bb->liveSet.set(i->getSrc(s)->id); else bb->liveSet.clr(i->getSrc(s)->id); } } } // remaining live-outs are live until end if (bb->getExit()) { for (unsigned int j = 0; j < bb->liveSet.getSize(); ++j) if (bb->liveSet.test(j)) addLiveRange(func->getLValue(j), bb, bb->getExit()->serial + 1); } for (Instruction *i = bb->getExit(); i && i->op != OP_PHI; i = i->prev) { for (int d = 0; i->defExists(d); ++d) { bb->liveSet.clr(i->getDef(d)->id); if (i->getDef(d)->reg.data.id >= 0) // add hazard for fixed regs i->getDef(d)->livei.extend(i->serial, i->serial); } for (int s = 0; i->srcExists(s); ++s) { if (!i->getSrc(s)->asLValue()) continue; if (!bb->liveSet.test(i->getSrc(s)->id)) { bb->liveSet.set(i->getSrc(s)->id); addLiveRange(i->getSrc(s), bb, i->serial); } } } if (bb == BasicBlock::get(func->cfg.getRoot())) { for (std::deque<ValueDef>::iterator it = func->ins.begin(); it != func->ins.end(); ++it) { if (it->get()->reg.data.id >= 0) // add hazard for fixed regs it->get()->livei.extend(0, 1); } } return true; } #define JOIN_MASK_PHI (1 << 0) #define JOIN_MASK_UNION (1 << 1) #define JOIN_MASK_MOV (1 << 2) #define JOIN_MASK_TEX (1 << 3) class GCRA { public: GCRA(Function *, SpillCodeInserter&); ~GCRA(); bool allocateRegisters(ArrayList& insns); void printNodeInfo() const; private: class RIG_Node : public Graph::Node { public: RIG_Node(); void init(const RegisterSet&, LValue *); void addInterference(RIG_Node *); void addRegPreference(RIG_Node *); inline LValue *getValue() const { return reinterpret_cast<LValue *>(data); } inline void setValue(LValue *lval) { data = lval; } inline uint8_t getCompMask() const { return ((1 << colors) - 1) << (reg & 7); } static inline RIG_Node *get(const Graph::EdgeIterator& ei) { return static_cast<RIG_Node *>(ei.getNode()); } public: uint32_t degree; uint16_t degreeLimit; // if deg < degLimit, node is trivially colourable uint16_t colors; DataFile f; int32_t reg; float weight; // list pointers for simplify() phase RIG_Node *next; RIG_Node *prev; // union of the live intervals of all coalesced values (we want to retain // the separate intervals for testing interference of compound values) Interval livei; std::list<RIG_Node *> prefRegs; }; private: inline RIG_Node *getNode(const LValue *v) const { return &nodes[v->id]; } void buildRIG(ArrayList&); bool coalesce(ArrayList&); bool doCoalesce(ArrayList&, unsigned int mask); void calculateSpillWeights(); bool simplify(); bool selectRegisters(); void cleanup(const bool success); void simplifyEdge(RIG_Node *, RIG_Node *); void simplifyNode(RIG_Node *); bool coalesceValues(Value *, Value *, bool force); void resolveSplitsAndMerges(); void makeCompound(Instruction *, bool isSplit); inline void checkInterference(const RIG_Node *, Graph::EdgeIterator&); inline void insertOrderedTail(std::list<RIG_Node *>&, RIG_Node *); void checkList(std::list<RIG_Node *>&); private: std::stack<uint32_t> stack; // list headers for simplify() phase RIG_Node lo[2]; RIG_Node hi; Graph RIG; RIG_Node *nodes; unsigned int nodeCount; Function *func; Program *prog; static uint8_t relDegree[17][17]; RegisterSet regs; // need to fixup register id for participants of OP_MERGE/SPLIT std::list<Instruction *> merges; std::list<Instruction *> splits; SpillCodeInserter& spill; std::list<ValuePair> mustSpill; }; uint8_t GCRA::relDegree[17][17]; GCRA::RIG_Node::RIG_Node() : Node(NULL), next(this), prev(this) { colors = 0; } void GCRA::printNodeInfo() const { for (unsigned int i = 0; i < nodeCount; ++i) { if (!nodes[i].colors) continue; INFO("RIG_Node[%%%i]($[%u]%i): %u colors, weight %f, deg %u/%u\n X", i, nodes[i].f,nodes[i].reg,nodes[i].colors, nodes[i].weight, nodes[i].degree, nodes[i].degreeLimit); for (Graph::EdgeIterator ei = nodes[i].outgoing(); !ei.end(); ei.next()) INFO(" %%%i", RIG_Node::get(ei)->getValue()->id); for (Graph::EdgeIterator ei = nodes[i].incident(); !ei.end(); ei.next()) INFO(" %%%i", RIG_Node::get(ei)->getValue()->id); INFO("\n"); } } static bool isShortRegOp(Instruction *insn) { // Immediates are always in src1. Every other situation can be resolved by // using a long encoding. return insn->srcExists(1) && insn->src(1).getFile() == FILE_IMMEDIATE; } // Check if this LValue is ever used in an instruction that can't be encoded // with long registers (i.e. > r63) static bool isShortRegVal(LValue *lval) { if (lval->getInsn() == NULL) return false; for (Value::DefCIterator def = lval->defs.begin(); def != lval->defs.end(); ++def) if (isShortRegOp((*def)->getInsn())) return true; for (Value::UseCIterator use = lval->uses.begin(); use != lval->uses.end(); ++use) if (isShortRegOp((*use)->getInsn())) return true; return false; } void GCRA::RIG_Node::init(const RegisterSet& regs, LValue *lval) { setValue(lval); if (lval->reg.data.id >= 0) lval->noSpill = lval->fixedReg = 1; colors = regs.units(lval->reg.file, lval->reg.size); f = lval->reg.file; reg = -1; if (lval->reg.data.id >= 0) reg = regs.idToUnits(lval); weight = std::numeric_limits<float>::infinity(); degree = 0; int size = regs.getFileSize(f, lval->reg.size); // On nv50, we lose a bit of gpr encoding when there's an embedded // immediate. if (regs.restrictedGPR16Range && f == FILE_GPR && isShortRegVal(lval)) size /= 2; degreeLimit = size; degreeLimit -= relDegree[1][colors] - 1; livei.insert(lval->livei); } bool GCRA::coalesceValues(Value *dst, Value *src, bool force) { LValue *rep = dst->join->asLValue(); LValue *val = src->join->asLValue(); if (!force && val->reg.data.id >= 0) { rep = src->join->asLValue(); val = dst->join->asLValue(); } RIG_Node *nRep = &nodes[rep->id]; RIG_Node *nVal = &nodes[val->id]; if (src->reg.file != dst->reg.file) { if (!force) return false; WARN("forced coalescing of values in different files !\n"); } if (!force && dst->reg.size != src->reg.size) return false; if ((rep->reg.data.id >= 0) && (rep->reg.data.id != val->reg.data.id)) { if (force) { if (val->reg.data.id >= 0) WARN("forced coalescing of values in different fixed regs !\n"); } else { if (val->reg.data.id >= 0) return false; // make sure that there is no overlap with the fixed register of rep for (ArrayList::Iterator it = func->allLValues.iterator(); !it.end(); it.next()) { Value *reg = reinterpret_cast<Value *>(it.get())->asLValue(); assert(reg); if (reg->interfers(rep) && reg->livei.overlaps(nVal->livei)) return false; } } } if (!force && nRep->livei.overlaps(nVal->livei)) return false; INFO_DBG(prog->dbgFlags, REG_ALLOC, "joining %%%i($%i) <- %%%i\n", rep->id, rep->reg.data.id, val->id); // set join pointer of all values joined with val for (Value::DefIterator def = val->defs.begin(); def != val->defs.end(); ++def) (*def)->get()->join = rep; assert(rep->join == rep && val->join == rep); // add val's definitions to rep and extend the live interval of its RIG node rep->defs.insert(rep->defs.end(), val->defs.begin(), val->defs.end()); nRep->livei.unify(nVal->livei); return true; } bool GCRA::coalesce(ArrayList& insns) { bool ret = doCoalesce(insns, JOIN_MASK_PHI); if (!ret) return false; switch (func->getProgram()->getTarget()->getChipset() & ~0xf) { case 0x50: case 0x80: case 0x90: case 0xa0: ret = doCoalesce(insns, JOIN_MASK_UNION | JOIN_MASK_TEX); break; case 0xc0: case 0xd0: case 0xe0: case 0xf0: case 0x100: case 0x110: case 0x120: case 0x130: ret = doCoalesce(insns, JOIN_MASK_UNION); break; default: break; } if (!ret) return false; return doCoalesce(insns, JOIN_MASK_MOV); } static inline uint8_t makeCompMask(int compSize, int base, int size) { uint8_t m = ((1 << size) - 1) << base; switch (compSize) { case 1: return 0xff; case 2: m |= (m << 2); return (m << 4) | m; case 3: case 4: return (m << 4) | m; default: assert(compSize <= 8); return m; } } // Used when coalescing moves. The non-compound value will become one, e.g.: // mov b32 $r0 $r2 / merge b64 $r0d { $r0 $r1 } // split b64 { $r0 $r1 } $r0d / mov b64 $r0d f64 $r2d static inline void copyCompound(Value *dst, Value *src) { LValue *ldst = dst->asLValue(); LValue *lsrc = src->asLValue(); if (ldst->compound && !lsrc->compound) { LValue *swap = lsrc; lsrc = ldst; ldst = swap; } ldst->compound = lsrc->compound; ldst->compMask = lsrc->compMask; } void GCRA::makeCompound(Instruction *insn, bool split) { LValue *rep = (split ? insn->getSrc(0) : insn->getDef(0))->asLValue(); if (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) { INFO("makeCompound(split = %i): ", split); insn->print(); } const unsigned int size = getNode(rep)->colors; unsigned int base = 0; if (!rep->compound) rep->compMask = 0xff; rep->compound = 1; for (int c = 0; split ? insn->defExists(c) : insn->srcExists(c); ++c) { LValue *val = (split ? insn->getDef(c) : insn->getSrc(c))->asLValue(); val->compound = 1; if (!val->compMask) val->compMask = 0xff; val->compMask &= makeCompMask(size, base, getNode(val)->colors); assert(val->compMask); INFO_DBG(prog->dbgFlags, REG_ALLOC, "compound: %%%i:%02x <- %%%i:%02x\n", rep->id, rep->compMask, val->id, val->compMask); base += getNode(val)->colors; } assert(base == size); } bool GCRA::doCoalesce(ArrayList& insns, unsigned int mask) { int c, n; for (n = 0; n < insns.getSize(); ++n) { Instruction *i; Instruction *insn = reinterpret_cast<Instruction *>(insns.get(n)); switch (insn->op) { case OP_PHI: if (!(mask & JOIN_MASK_PHI)) break; for (c = 0; insn->srcExists(c); ++c) if (!coalesceValues(insn->getDef(0), insn->getSrc(c), false)) { // this is bad ERROR("failed to coalesce phi operands\n"); return false; } break; case OP_UNION: case OP_MERGE: if (!(mask & JOIN_MASK_UNION)) break; for (c = 0; insn->srcExists(c); ++c) coalesceValues(insn->getDef(0), insn->getSrc(c), true); if (insn->op == OP_MERGE) { merges.push_back(insn); if (insn->srcExists(1)) makeCompound(insn, false); } break; case OP_SPLIT: if (!(mask & JOIN_MASK_UNION)) break; splits.push_back(insn); for (c = 0; insn->defExists(c); ++c) coalesceValues(insn->getSrc(0), insn->getDef(c), true); makeCompound(insn, true); break; case OP_MOV: if (!(mask & JOIN_MASK_MOV)) break; i = NULL; if (!insn->getDef(0)->uses.empty()) i = (*insn->getDef(0)->uses.begin())->getInsn(); // if this is a contraint-move there will only be a single use if (i && i->op == OP_MERGE) // do we really still need this ? break; i = insn->getSrc(0)->getUniqueInsn(); if (i && !i->constrainedDefs()) { if (coalesceValues(insn->getDef(0), insn->getSrc(0), false)) copyCompound(insn->getSrc(0), insn->getDef(0)); } break; case OP_TEX: case OP_TXB: case OP_TXL: case OP_TXF: case OP_TXQ: case OP_TXD: case OP_TXG: case OP_TXLQ: case OP_TEXCSAA: case OP_TEXPREP: if (!(mask & JOIN_MASK_TEX)) break; for (c = 0; insn->srcExists(c) && c != insn->predSrc; ++c) coalesceValues(insn->getDef(c), insn->getSrc(c), true); break; default: break; } } return true; } void GCRA::RIG_Node::addInterference(RIG_Node *node) { this->degree += relDegree[node->colors][colors]; node->degree += relDegree[colors][node->colors]; this->attach(node, Graph::Edge::CROSS); } void GCRA::RIG_Node::addRegPreference(RIG_Node *node) { prefRegs.push_back(node); } GCRA::GCRA(Function *fn, SpillCodeInserter& spill) : func(fn), regs(fn->getProgram()->getTarget()), spill(spill) { prog = func->getProgram(); // initialize relative degrees array - i takes away from j for (int i = 1; i <= 16; ++i) for (int j = 1; j <= 16; ++j) relDegree[i][j] = j * ((i + j - 1) / j); } GCRA::~GCRA() { if (nodes) delete[] nodes; } void GCRA::checkList(std::list<RIG_Node *>& lst) { GCRA::RIG_Node *prev = NULL; for (std::list<RIG_Node *>::iterator it = lst.begin(); it != lst.end(); ++it) { assert((*it)->getValue()->join == (*it)->getValue()); if (prev) assert(prev->livei.begin() <= (*it)->livei.begin()); prev = *it; } } void GCRA::insertOrderedTail(std::list<RIG_Node *>& list, RIG_Node *node) { if (node->livei.isEmpty()) return; // only the intervals of joined values don't necessarily arrive in order std::list<RIG_Node *>::iterator prev, it; for (it = list.end(); it != list.begin(); it = prev) { prev = it; --prev; if ((*prev)->livei.begin() <= node->livei.begin()) break; } list.insert(it, node); } void GCRA::buildRIG(ArrayList& insns) { std::list<RIG_Node *> values, active; for (std::deque<ValueDef>::iterator it = func->ins.begin(); it != func->ins.end(); ++it) insertOrderedTail(values, getNode(it->get()->asLValue())); for (int i = 0; i < insns.getSize(); ++i) { Instruction *insn = reinterpret_cast<Instruction *>(insns.get(i)); for (int d = 0; insn->defExists(d); ++d) if (insn->getDef(d)->rep() == insn->getDef(d)) insertOrderedTail(values, getNode(insn->getDef(d)->asLValue())); } checkList(values); while (!values.empty()) { RIG_Node *cur = values.front(); for (std::list<RIG_Node *>::iterator it = active.begin(); it != active.end();) { RIG_Node *node = *it; if (node->livei.end() <= cur->livei.begin()) { it = active.erase(it); } else { if (node->f == cur->f && node->livei.overlaps(cur->livei)) cur->addInterference(node); ++it; } } values.pop_front(); active.push_back(cur); } } void GCRA::calculateSpillWeights() { for (unsigned int i = 0; i < nodeCount; ++i) { RIG_Node *const n = &nodes[i]; if (!nodes[i].colors || nodes[i].livei.isEmpty()) continue; if (nodes[i].reg >= 0) { // update max reg regs.occupy(n->f, n->reg, n->colors); continue; } LValue *val = nodes[i].getValue(); if (!val->noSpill) { int rc = 0; for (Value::DefIterator it = val->defs.begin(); it != val->defs.end(); ++it) rc += (*it)->get()->refCount(); nodes[i].weight = (float)rc * (float)rc / (float)nodes[i].livei.extent(); } if (nodes[i].degree < nodes[i].degreeLimit) { int l = 0; if (val->reg.size > 4) l = 1; DLLIST_ADDHEAD(&lo[l], &nodes[i]); } else { DLLIST_ADDHEAD(&hi, &nodes[i]); } } if (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) printNodeInfo(); } void GCRA::simplifyEdge(RIG_Node *a, RIG_Node *b) { bool move = b->degree >= b->degreeLimit; INFO_DBG(prog->dbgFlags, REG_ALLOC, "edge: (%%%i, deg %u/%u) >-< (%%%i, deg %u/%u)\n", a->getValue()->id, a->degree, a->degreeLimit, b->getValue()->id, b->degree, b->degreeLimit); b->degree -= relDegree[a->colors][b->colors]; move = move && b->degree < b->degreeLimit; if (move && !DLLIST_EMPTY(b)) { int l = (b->getValue()->reg.size > 4) ? 1 : 0; DLLIST_DEL(b); DLLIST_ADDTAIL(&lo[l], b); } } void GCRA::simplifyNode(RIG_Node *node) { for (Graph::EdgeIterator ei = node->outgoing(); !ei.end(); ei.next()) simplifyEdge(node, RIG_Node::get(ei)); for (Graph::EdgeIterator ei = node->incident(); !ei.end(); ei.next()) simplifyEdge(node, RIG_Node::get(ei)); DLLIST_DEL(node); stack.push(node->getValue()->id); INFO_DBG(prog->dbgFlags, REG_ALLOC, "SIMPLIFY: pushed %%%i%s\n", node->getValue()->id, (node->degree < node->degreeLimit) ? "" : "(spill)"); } bool GCRA::simplify() { for (;;) { if (!DLLIST_EMPTY(&lo[0])) { do { simplifyNode(lo[0].next); } while (!DLLIST_EMPTY(&lo[0])); } else if (!DLLIST_EMPTY(&lo[1])) { simplifyNode(lo[1].next); } else if (!DLLIST_EMPTY(&hi)) { RIG_Node *best = hi.next; float bestScore = best->weight / (float)best->degree; // spill candidate for (RIG_Node *it = best->next; it != &hi; it = it->next) { float score = it->weight / (float)it->degree; if (score < bestScore) { best = it; bestScore = score; } } if (isinf(bestScore)) { ERROR("no viable spill candidates left\n"); return false; } simplifyNode(best); } else { return true; } } } void GCRA::checkInterference(const RIG_Node *node, Graph::EdgeIterator& ei) { const RIG_Node *intf = RIG_Node::get(ei); if (intf->reg < 0) return; const LValue *vA = node->getValue(); const LValue *vB = intf->getValue(); const uint8_t intfMask = ((1 << intf->colors) - 1) << (intf->reg & 7); if (vA->compound | vB->compound) { // NOTE: this only works for >aligned< register tuples ! for (Value::DefCIterator D = vA->defs.begin(); D != vA->defs.end(); ++D) { for (Value::DefCIterator d = vB->defs.begin(); d != vB->defs.end(); ++d) { const LValue *vD = (*D)->get()->asLValue(); const LValue *vd = (*d)->get()->asLValue(); if (!vD->livei.overlaps(vd->livei)) { INFO_DBG(prog->dbgFlags, REG_ALLOC, "(%%%i) X (%%%i): no overlap\n", vD->id, vd->id); continue; } uint8_t mask = vD->compound ? vD->compMask : ~0; if (vd->compound) { assert(vB->compound); mask &= vd->compMask & vB->compMask; } else { mask &= intfMask; } INFO_DBG(prog->dbgFlags, REG_ALLOC, "(%%%i)%02x X (%%%i)%02x & %02x: $r%i.%02x\n", vD->id, vD->compound ? vD->compMask : 0xff, vd->id, vd->compound ? vd->compMask : intfMask, vB->compMask, intf->reg & ~7, mask); if (mask) regs.occupyMask(node->f, intf->reg & ~7, mask); } } } else { INFO_DBG(prog->dbgFlags, REG_ALLOC, "(%%%i) X (%%%i): $r%i + %u\n", vA->id, vB->id, intf->reg, intf->colors); regs.occupy(node->f, intf->reg, intf->colors); } } bool GCRA::selectRegisters() { INFO_DBG(prog->dbgFlags, REG_ALLOC, "\nSELECT phase\n"); while (!stack.empty()) { RIG_Node *node = &nodes[stack.top()]; stack.pop(); regs.reset(node->f); INFO_DBG(prog->dbgFlags, REG_ALLOC, "\nNODE[%%%i, %u colors]\n", node->getValue()->id, node->colors); for (Graph::EdgeIterator ei = node->outgoing(); !ei.end(); ei.next()) checkInterference(node, ei); for (Graph::EdgeIterator ei = node->incident(); !ei.end(); ei.next()) checkInterference(node, ei); if (!node->prefRegs.empty()) { for (std::list<RIG_Node *>::const_iterator it = node->prefRegs.begin(); it != node->prefRegs.end(); ++it) { if ((*it)->reg >= 0 && regs.testOccupy(node->f, (*it)->reg, node->colors)) { node->reg = (*it)->reg; break; } } } if (node->reg >= 0) continue; LValue *lval = node->getValue(); if (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) regs.print(node->f); bool ret = regs.assign(node->reg, node->f, node->colors); if (ret) { INFO_DBG(prog->dbgFlags, REG_ALLOC, "assigned reg %i\n", node->reg); lval->compMask = node->getCompMask(); } else { INFO_DBG(prog->dbgFlags, REG_ALLOC, "must spill: %%%i (size %u)\n", lval->id, lval->reg.size); Symbol *slot = NULL; if (lval->reg.file == FILE_GPR) slot = spill.assignSlot(node->livei, lval->reg.size); mustSpill.push_back(ValuePair(lval, slot)); } } if (!mustSpill.empty()) return false; for (unsigned int i = 0; i < nodeCount; ++i) { LValue *lval = nodes[i].getValue(); if (nodes[i].reg >= 0 && nodes[i].colors > 0) lval->reg.data.id = regs.unitsToId(nodes[i].f, nodes[i].reg, lval->reg.size); } return true; } bool GCRA::allocateRegisters(ArrayList& insns) { bool ret; INFO_DBG(prog->dbgFlags, REG_ALLOC, "allocateRegisters to %u instructions\n", insns.getSize()); nodeCount = func->allLValues.getSize(); nodes = new RIG_Node[nodeCount]; if (!nodes) return false; for (unsigned int i = 0; i < nodeCount; ++i) { LValue *lval = reinterpret_cast<LValue *>(func->allLValues.get(i)); if (lval) { nodes[i].init(regs, lval); RIG.insert(&nodes[i]); if (lval->inFile(FILE_GPR) && lval->getInsn() != NULL && prog->getTarget()->getChipset() < 0xc0) { Instruction *insn = lval->getInsn(); if (insn->op == OP_MAD || insn->op == OP_FMA || insn->op == OP_SAD) // Short encoding only possible if they're all GPRs, no need to // affect them otherwise. if (insn->flagsDef < 0 && insn->src(0).getFile() == FILE_GPR && insn->src(1).getFile() == FILE_GPR && insn->src(2).getFile() == FILE_GPR) nodes[i].addRegPreference(getNode(insn->getSrc(2)->asLValue())); } } } // coalesce first, we use only 1 RIG node for a group of joined values ret = coalesce(insns); if (!ret) goto out; if (func->getProgram()->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) func->printLiveIntervals(); buildRIG(insns); calculateSpillWeights(); ret = simplify(); if (!ret) goto out; ret = selectRegisters(); if (!ret) { INFO_DBG(prog->dbgFlags, REG_ALLOC, "selectRegisters failed, inserting spill code ...\n"); regs.reset(FILE_GPR, true); spill.run(mustSpill); if (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) func->print(); } else { prog->maxGPR = std::max(prog->maxGPR, regs.getMaxAssigned(FILE_GPR)); } out: cleanup(ret); return ret; } void GCRA::cleanup(const bool success) { mustSpill.clear(); for (ArrayList::Iterator it = func->allLValues.iterator(); !it.end(); it.next()) { LValue *lval = reinterpret_cast<LValue *>(it.get()); lval->livei.clear(); lval->compound = 0; lval->compMask = 0; if (lval->join == lval) continue; if (success) { lval->reg.data.id = lval->join->reg.data.id; } else { for (Value::DefIterator d = lval->defs.begin(); d != lval->defs.end(); ++d) lval->join->defs.remove(*d); lval->join = lval; } } if (success) resolveSplitsAndMerges(); splits.clear(); // avoid duplicate entries on next coalesce pass merges.clear(); delete[] nodes; nodes = NULL; hi.next = hi.prev = &hi; lo[0].next = lo[0].prev = &lo[0]; lo[1].next = lo[1].prev = &lo[1]; } Symbol * SpillCodeInserter::assignSlot(const Interval &livei, const unsigned int size) { SpillSlot slot; int32_t offsetBase = stackSize; int32_t offset; std::list<SpillSlot>::iterator pos = slots.end(), it = slots.begin(); if (offsetBase % size) offsetBase += size - (offsetBase % size); slot.sym = NULL; for (offset = offsetBase; offset < stackSize; offset += size) { const int32_t entryEnd = offset + size; while (it != slots.end() && it->offset < offset) ++it; if (it == slots.end()) // no slots left break; std::list<SpillSlot>::iterator bgn = it; while (it != slots.end() && it->offset < entryEnd) { it->occup.print(); if (it->occup.overlaps(livei)) break; ++it; } if (it == slots.end() || it->offset >= entryEnd) { // fits for (; bgn != slots.end() && bgn->offset < entryEnd; ++bgn) { bgn->occup.insert(livei); if (bgn->size() == size) slot.sym = bgn->sym; } break; } } if (!slot.sym) { stackSize = offset + size; slot.offset = offset; slot.sym = new_Symbol(func->getProgram(), FILE_MEMORY_LOCAL); if (!func->stackPtr) offset += func->tlsBase; slot.sym->setAddress(NULL, offset); slot.sym->reg.size = size; slots.insert(pos, slot)->occup.insert(livei); } return slot.sym; } Value * SpillCodeInserter::offsetSlot(Value *base, const LValue *lval) { if (!lval->compound || (lval->compMask & 0x1)) return base; Value *slot = cloneShallow(func, base); slot->reg.data.offset += (ffs(lval->compMask) - 1) * lval->reg.size; slot->reg.size = lval->reg.size; return slot; } void SpillCodeInserter::spill(Instruction *defi, Value *slot, LValue *lval) { const DataType ty = typeOfSize(lval->reg.size); slot = offsetSlot(slot, lval); Instruction *st; if (slot->reg.file == FILE_MEMORY_LOCAL) { lval->noSpill = 1; if (ty != TYPE_B96) { st = new_Instruction(func, OP_STORE, ty); st->setSrc(0, slot); st->setSrc(1, lval); } else { st = new_Instruction(func, OP_SPLIT, ty); st->setSrc(0, lval); for (int d = 0; d < lval->reg.size / 4; ++d) st->setDef(d, new_LValue(func, FILE_GPR)); for (int d = lval->reg.size / 4 - 1; d >= 0; --d) { Value *tmp = cloneShallow(func, slot); tmp->reg.size = 4; tmp->reg.data.offset += 4 * d; Instruction *s = new_Instruction(func, OP_STORE, TYPE_U32); s->setSrc(0, tmp); s->setSrc(1, st->getDef(d)); defi->bb->insertAfter(defi, s); } } } else { st = new_Instruction(func, OP_CVT, ty); st->setDef(0, slot); st->setSrc(0, lval); if (lval->reg.file == FILE_FLAGS) st->flagsSrc = 0; } defi->bb->insertAfter(defi, st); } LValue * SpillCodeInserter::unspill(Instruction *usei, LValue *lval, Value *slot) { const DataType ty = typeOfSize(lval->reg.size); slot = offsetSlot(slot, lval); lval = cloneShallow(func, lval); Instruction *ld; if (slot->reg.file == FILE_MEMORY_LOCAL) { lval->noSpill = 1; if (ty != TYPE_B96) { ld = new_Instruction(func, OP_LOAD, ty); } else { ld = new_Instruction(func, OP_MERGE, ty); for (int d = 0; d < lval->reg.size / 4; ++d) { Value *tmp = cloneShallow(func, slot); LValue *val; tmp->reg.size = 4; tmp->reg.data.offset += 4 * d; Instruction *l = new_Instruction(func, OP_LOAD, TYPE_U32); l->setDef(0, (val = new_LValue(func, FILE_GPR))); l->setSrc(0, tmp); usei->bb->insertBefore(usei, l); ld->setSrc(d, val); val->noSpill = 1; } ld->setDef(0, lval); usei->bb->insertBefore(usei, ld); return lval; } } else { ld = new_Instruction(func, OP_CVT, ty); } ld->setDef(0, lval); ld->setSrc(0, slot); if (lval->reg.file == FILE_FLAGS) ld->flagsDef = 0; usei->bb->insertBefore(usei, ld); return lval; } static bool value_cmp(ValueRef *a, ValueRef *b) { Instruction *ai = a->getInsn(), *bi = b->getInsn(); if (ai->bb != bi->bb) return ai->bb->getId() < bi->bb->getId(); return ai->serial < bi->serial; } // For each value that is to be spilled, go through all its definitions. // A value can have multiple definitions if it has been coalesced before. // For each definition, first go through all its uses and insert an unspill // instruction before it, then replace the use with the temporary register. // Unspill can be either a load from memory or simply a move to another // register file. // For "Pseudo" instructions (like PHI, SPLIT, MERGE) we can erase the use // if we have spilled to a memory location, or simply with the new register. // No load or conversion instruction should be needed. bool SpillCodeInserter::run(const std::list<ValuePair>& lst) { for (std::list<ValuePair>::const_iterator it = lst.begin(); it != lst.end(); ++it) { LValue *lval = it->first->asLValue(); Symbol *mem = it->second ? it->second->asSym() : NULL; // Keep track of which instructions to delete later. Deleting them // inside the loop is unsafe since a single instruction may have // multiple destinations that all need to be spilled (like OP_SPLIT). unordered_set<Instruction *> to_del; for (Value::DefIterator d = lval->defs.begin(); d != lval->defs.end(); ++d) { Value *slot = mem ? static_cast<Value *>(mem) : new_LValue(func, FILE_GPR); Value *tmp = NULL; Instruction *last = NULL; LValue *dval = (*d)->get()->asLValue(); Instruction *defi = (*d)->getInsn(); // Sort all the uses by BB/instruction so that we don't unspill // multiple times in a row, and also remove a source of // non-determinism. std::vector<ValueRef *> refs(dval->uses.begin(), dval->uses.end()); std::sort(refs.begin(), refs.end(), value_cmp); // Unspill at each use *before* inserting spill instructions, // we don't want to have the spill instructions in the use list here. for (std::vector<ValueRef*>::const_iterator it = refs.begin(); it != refs.end(); ++it) { ValueRef *u = *it; Instruction *usei = u->getInsn(); assert(usei); if (usei->isPseudo()) { tmp = (slot->reg.file == FILE_MEMORY_LOCAL) ? NULL : slot; last = NULL; } else { if (!last || (usei != last->next && usei != last)) tmp = unspill(usei, dval, slot); last = usei; } u->set(tmp); } assert(defi); if (defi->isPseudo()) { d = lval->defs.erase(d); --d; if (slot->reg.file == FILE_MEMORY_LOCAL) to_del.insert(defi); else defi->setDef(0, slot); } else { spill(defi, slot, dval); } } for (unordered_set<Instruction *>::const_iterator it = to_del.begin(); it != to_del.end(); ++it) delete_Instruction(func->getProgram(), *it); } // TODO: We're not trying to reuse old slots in a potential next iteration. // We have to update the slots' livei intervals to be able to do that. stackBase = stackSize; slots.clear(); return true; } bool RegAlloc::exec() { for (IteratorRef it = prog->calls.iteratorDFS(false); !it->end(); it->next()) { func = Function::get(reinterpret_cast<Graph::Node *>(it->get())); func->tlsBase = prog->tlsSize; if (!execFunc()) return false; prog->tlsSize += func->tlsSize; } return true; } bool RegAlloc::execFunc() { InsertConstraintsPass insertConstr; PhiMovesPass insertPhiMoves; ArgumentMovesPass insertArgMoves; BuildIntervalsPass buildIntervals; SpillCodeInserter insertSpills(func); GCRA gcra(func, insertSpills); unsigned int i, retries; bool ret; if (!func->ins.empty()) { // Insert a nop at the entry so inputs only used by the first instruction // don't count as having an empty live range. Instruction *nop = new_Instruction(func, OP_NOP, TYPE_NONE); BasicBlock::get(func->cfg.getRoot())->insertHead(nop); } ret = insertConstr.exec(func); if (!ret) goto out; ret = insertPhiMoves.run(func); if (!ret) goto out; ret = insertArgMoves.run(func); if (!ret) goto out; // TODO: need to fix up spill slot usage ranges to support > 1 retry for (retries = 0; retries < 3; ++retries) { if (retries && (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC)) INFO("Retry: %i\n", retries); if (prog->dbgFlags & NV50_IR_DEBUG_REG_ALLOC) func->print(); // spilling to registers may add live ranges, need to rebuild everything ret = true; for (sequence = func->cfg.nextSequence(), i = 0; ret && i <= func->loopNestingBound; sequence = func->cfg.nextSequence(), ++i) ret = buildLiveSets(BasicBlock::get(func->cfg.getRoot())); // reset marker for (ArrayList::Iterator bi = func->allBBlocks.iterator(); !bi.end(); bi.next()) BasicBlock::get(bi)->liveSet.marker = false; if (!ret) break; func->orderInstructions(this->insns); ret = buildIntervals.run(func); if (!ret) break; ret = gcra.allocateRegisters(insns); if (ret) break; // success } INFO_DBG(prog->dbgFlags, REG_ALLOC, "RegAlloc done: %i\n", ret); func->tlsSize = insertSpills.getStackSize(); out: return ret; } // TODO: check if modifying Instruction::join here breaks anything void GCRA::resolveSplitsAndMerges() { for (std::list<Instruction *>::iterator it = splits.begin(); it != splits.end(); ++it) { Instruction *split = *it; unsigned int reg = regs.idToBytes(split->getSrc(0)); for (int d = 0; split->defExists(d); ++d) { Value *v = split->getDef(d); v->reg.data.id = regs.bytesToId(v, reg); v->join = v; reg += v->reg.size; } } splits.clear(); for (std::list<Instruction *>::iterator it = merges.begin(); it != merges.end(); ++it) { Instruction *merge = *it; unsigned int reg = regs.idToBytes(merge->getDef(0)); for (int s = 0; merge->srcExists(s); ++s) { Value *v = merge->getSrc(s); v->reg.data.id = regs.bytesToId(v, reg); v->join = v; // If the value is defined by a phi/union node, we also need to // perform the same fixup on that node's sources, since after RA // their registers should be identical. if (v->getInsn()->op == OP_PHI || v->getInsn()->op == OP_UNION) { Instruction *phi = v->getInsn(); for (int phis = 0; phi->srcExists(phis); ++phis) { phi->getSrc(phis)->join = v; phi->getSrc(phis)->reg.data.id = v->reg.data.id; } } reg += v->reg.size; } } merges.clear(); } bool Program::registerAllocation() { RegAlloc ra(this); return ra.exec(); } bool RegAlloc::InsertConstraintsPass::exec(Function *ir) { constrList.clear(); bool ret = run(ir, true, true); if (ret) ret = insertConstraintMoves(); return ret; } // TODO: make part of texture insn void RegAlloc::InsertConstraintsPass::textureMask(TexInstruction *tex) { Value *def[4]; int c, k, d; uint8_t mask = 0; for (d = 0, k = 0, c = 0; c < 4; ++c) { if (!(tex->tex.mask & (1 << c))) continue; if (tex->getDef(k)->refCount()) { mask |= 1 << c; def[d++] = tex->getDef(k); } ++k; } tex->tex.mask = mask; for (c = 0; c < d; ++c) tex->setDef(c, def[c]); for (; c < 4; ++c) tex->setDef(c, NULL); } bool RegAlloc::InsertConstraintsPass::detectConflict(Instruction *cst, int s) { Value *v = cst->getSrc(s); // current register allocation can't handle it if a value participates in // multiple constraints for (Value::UseIterator it = v->uses.begin(); it != v->uses.end(); ++it) { if (cst != (*it)->getInsn()) return true; } // can start at s + 1 because detectConflict is called on all sources for (int c = s + 1; cst->srcExists(c); ++c) if (v == cst->getSrc(c)) return true; Instruction *defi = v->getInsn(); return (!defi || defi->constrainedDefs()); } void RegAlloc::InsertConstraintsPass::addConstraint(Instruction *i, int s, int n) { Instruction *cst; int d; // first, look for an existing identical constraint op for (std::list<Instruction *>::iterator it = constrList.begin(); it != constrList.end(); ++it) { cst = (*it); if (!i->bb->dominatedBy(cst->bb)) break; for (d = 0; d < n; ++d) if (cst->getSrc(d) != i->getSrc(d + s)) break; if (d >= n) { for (d = 0; d < n; ++d, ++s) i->setSrc(s, cst->getDef(d)); return; } } cst = new_Instruction(func, OP_CONSTRAINT, i->dType); for (d = 0; d < n; ++s, ++d) { cst->setDef(d, new_LValue(func, FILE_GPR)); cst->setSrc(d, i->getSrc(s)); i->setSrc(s, cst->getDef(d)); } i->bb->insertBefore(i, cst); constrList.push_back(cst); } // Add a dummy use of the pointer source of >= 8 byte loads after the load // to prevent it from being assigned a register which overlapping the load's // destination, which would produce random corruptions. void RegAlloc::InsertConstraintsPass::addHazard(Instruction *i, const ValueRef *src) { Instruction *hzd = new_Instruction(func, OP_NOP, TYPE_NONE); hzd->setSrc(0, src->get()); i->bb->insertAfter(i, hzd); } // b32 { %r0 %r1 %r2 %r3 } -> b128 %r0q void RegAlloc::InsertConstraintsPass::condenseDefs(Instruction *insn) { uint8_t size = 0; int n; for (n = 0; insn->defExists(n) && insn->def(n).getFile() == FILE_GPR; ++n) size += insn->getDef(n)->reg.size; if (n < 2) return; LValue *lval = new_LValue(func, FILE_GPR); lval->reg.size = size; Instruction *split = new_Instruction(func, OP_SPLIT, typeOfSize(size)); split->setSrc(0, lval); for (int d = 0; d < n; ++d) { split->setDef(d, insn->getDef(d)); insn->setDef(d, NULL); } insn->setDef(0, lval); for (int k = 1, d = n; insn->defExists(d); ++d, ++k) { insn->setDef(k, insn->getDef(d)); insn->setDef(d, NULL); } // carry over predicate if any (mainly for OP_UNION uses) split->setPredicate(insn->cc, insn->getPredicate()); insn->bb->insertAfter(insn, split); constrList.push_back(split); } void RegAlloc::InsertConstraintsPass::condenseSrcs(Instruction *insn, const int a, const int b) { uint8_t size = 0; if (a >= b) return; for (int s = a; s <= b; ++s) size += insn->getSrc(s)->reg.size; if (!size) return; LValue *lval = new_LValue(func, FILE_GPR); lval->reg.size = size; Value *save[3]; insn->takeExtraSources(0, save); Instruction *merge = new_Instruction(func, OP_MERGE, typeOfSize(size)); merge->setDef(0, lval); for (int s = a, i = 0; s <= b; ++s, ++i) { merge->setSrc(i, insn->getSrc(s)); } insn->moveSources(b + 1, a - b); insn->setSrc(a, lval); insn->bb->insertBefore(insn, merge); insn->putExtraSources(0, save); constrList.push_back(merge); } void RegAlloc::InsertConstraintsPass::texConstraintGM107(TexInstruction *tex) { int n, s; if (isTextureOp(tex->op)) textureMask(tex); condenseDefs(tex); if (isSurfaceOp(tex->op)) { int s = tex->tex.target.getDim() + (tex->tex.target.isArray() || tex->tex.target.isCube()); int n = 0; switch (tex->op) { case OP_SUSTB: case OP_SUSTP: n = 4; break; case OP_SUREDB: case OP_SUREDP: if (tex->subOp == NV50_IR_SUBOP_ATOM_CAS) n = 2; break; default: break; } if (s > 1) condenseSrcs(tex, 0, s - 1); if (n > 1) condenseSrcs(tex, 1, n); // do not condense the tex handle } else if (isTextureOp(tex->op)) { if (tex->op != OP_TXQ) { s = tex->tex.target.getArgCount() - tex->tex.target.isMS(); if (tex->op == OP_TXD) { // Indirect handle belongs in the first arg if (tex->tex.rIndirectSrc >= 0) s++; if (!tex->tex.target.isArray() && tex->tex.useOffsets) s++; } n = tex->srcCount(0xff) - s; } else { s = tex->srcCount(0xff); n = 0; } if (s > 1) condenseSrcs(tex, 0, s - 1); if (n > 1) // NOTE: first call modified positions already condenseSrcs(tex, 1, n); } } void RegAlloc::InsertConstraintsPass::texConstraintNVE0(TexInstruction *tex) { if (isTextureOp(tex->op)) textureMask(tex); condenseDefs(tex); if (tex->op == OP_SUSTB || tex->op == OP_SUSTP) { condenseSrcs(tex, 3, 6); } else if (isTextureOp(tex->op)) { int n = tex->srcCount(0xff, true); if (n > 4) { condenseSrcs(tex, 0, 3); if (n > 5) // NOTE: first call modified positions already condenseSrcs(tex, 4 - (4 - 1), n - 1 - (4 - 1)); } else if (n > 1) { condenseSrcs(tex, 0, n - 1); } } } void RegAlloc::InsertConstraintsPass::texConstraintNVC0(TexInstruction *tex) { int n, s; if (isTextureOp(tex->op)) textureMask(tex); if (tex->op == OP_TXQ) { s = tex->srcCount(0xff); n = 0; } else if (isSurfaceOp(tex->op)) { s = tex->tex.target.getDim() + (tex->tex.target.isArray() || tex->tex.target.isCube()); if (tex->op == OP_SUSTB || tex->op == OP_SUSTP) n = 4; else n = 0; } else { s = tex->tex.target.getArgCount() - tex->tex.target.isMS(); if (!tex->tex.target.isArray() && (tex->tex.rIndirectSrc >= 0 || tex->tex.sIndirectSrc >= 0)) ++s; if (tex->op == OP_TXD && tex->tex.useOffsets) ++s; n = tex->srcCount(0xff) - s; assert(n <= 4); } if (s > 1) condenseSrcs(tex, 0, s - 1); if (n > 1) // NOTE: first call modified positions already condenseSrcs(tex, 1, n); condenseDefs(tex); } void RegAlloc::InsertConstraintsPass::texConstraintNV50(TexInstruction *tex) { Value *pred = tex->getPredicate(); if (pred) tex->setPredicate(tex->cc, NULL); textureMask(tex); assert(tex->defExists(0) && tex->srcExists(0)); // make src and def count match int c; for (c = 0; tex->srcExists(c) || tex->defExists(c); ++c) { if (!tex->srcExists(c)) tex->setSrc(c, new_LValue(func, tex->getSrc(0)->asLValue())); if (!tex->defExists(c)) tex->setDef(c, new_LValue(func, tex->getDef(0)->asLValue())); } if (pred) tex->setPredicate(tex->cc, pred); condenseDefs(tex); condenseSrcs(tex, 0, c - 1); } // Insert constraint markers for instructions whose multiple sources must be // located in consecutive registers. bool RegAlloc::InsertConstraintsPass::visit(BasicBlock *bb) { TexInstruction *tex; Instruction *next; int s, size; targ = bb->getProgram()->getTarget(); for (Instruction *i = bb->getEntry(); i; i = next) { next = i->next; if ((tex = i->asTex())) { switch (targ->getChipset() & ~0xf) { case 0x50: case 0x80: case 0x90: case 0xa0: texConstraintNV50(tex); break; case 0xc0: case 0xd0: texConstraintNVC0(tex); break; case 0xe0: case 0xf0: case 0x100: texConstraintNVE0(tex); break; case 0x110: case 0x120: case 0x130: texConstraintGM107(tex); break; default: break; } } else if (i->op == OP_EXPORT || i->op == OP_STORE) { for (size = typeSizeof(i->dType), s = 1; size > 0; ++s) { assert(i->srcExists(s)); size -= i->getSrc(s)->reg.size; } condenseSrcs(i, 1, s - 1); } else if (i->op == OP_LOAD || i->op == OP_VFETCH) { condenseDefs(i); if (i->src(0).isIndirect(0) && typeSizeof(i->dType) >= 8) addHazard(i, i->src(0).getIndirect(0)); if (i->src(0).isIndirect(1) && typeSizeof(i->dType) >= 8) addHazard(i, i->src(0).getIndirect(1)); } else if (i->op == OP_UNION || i->op == OP_MERGE || i->op == OP_SPLIT) { constrList.push_back(i); } } return true; } // Insert extra moves so that, if multiple register constraints on a value are // in conflict, these conflicts can be resolved. bool RegAlloc::InsertConstraintsPass::insertConstraintMoves() { for (std::list<Instruction *>::iterator it = constrList.begin(); it != constrList.end(); ++it) { Instruction *cst = *it; Instruction *mov; if (cst->op == OP_SPLIT && 0) { // spilling splits is annoying, just make sure they're separate for (int d = 0; cst->defExists(d); ++d) { if (!cst->getDef(d)->refCount()) continue; LValue *lval = new_LValue(func, cst->def(d).getFile()); const uint8_t size = cst->def(d).getSize(); lval->reg.size = size; mov = new_Instruction(func, OP_MOV, typeOfSize(size)); mov->setSrc(0, lval); mov->setDef(0, cst->getDef(d)); cst->setDef(d, mov->getSrc(0)); cst->bb->insertAfter(cst, mov); cst->getSrc(0)->asLValue()->noSpill = 1; mov->getSrc(0)->asLValue()->noSpill = 1; } } else if (cst->op == OP_MERGE || cst->op == OP_UNION) { for (int s = 0; cst->srcExists(s); ++s) { const uint8_t size = cst->src(s).getSize(); if (!cst->getSrc(s)->defs.size()) { mov = new_Instruction(func, OP_NOP, typeOfSize(size)); mov->setDef(0, cst->getSrc(s)); cst->bb->insertBefore(cst, mov); continue; } assert(cst->getSrc(s)->defs.size() == 1); // still SSA Instruction *defi = cst->getSrc(s)->defs.front()->getInsn(); bool imm = defi->op == OP_MOV && defi->src(0).getFile() == FILE_IMMEDIATE; bool load = defi->op == OP_LOAD && defi->src(0).getFile() == FILE_MEMORY_CONST && !defi->src(0).isIndirect(0); // catch some cases where don't really need MOVs if (cst->getSrc(s)->refCount() == 1 && !defi->constrainedDefs()) { if (imm || load) { // Move the defi right before the cst. No point in expanding // the range. defi->bb->remove(defi); cst->bb->insertBefore(cst, defi); } continue; } LValue *lval = new_LValue(func, cst->src(s).getFile()); lval->reg.size = size; mov = new_Instruction(func, OP_MOV, typeOfSize(size)); mov->setDef(0, lval); mov->setSrc(0, cst->getSrc(s)); if (load) { mov->op = OP_LOAD; mov->setSrc(0, defi->getSrc(0)); } else if (imm) { mov->setSrc(0, defi->getSrc(0)); } cst->setSrc(s, mov->getDef(0)); cst->bb->insertBefore(cst, mov); cst->getDef(0)->asLValue()->noSpill = 1; // doesn't help if (cst->op == OP_UNION) mov->setPredicate(defi->cc, defi->getPredicate()); } } } return true; } } // namespace nv50_ir