/* * 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 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" #include "nv50_ir_target.h" #include "nv50_ir_driver.h" extern "C" { #include "nv50/nv50_program.h" #include "nv50/nv50_debug.h" } namespace nv50_ir { Modifier::Modifier(operation op) { switch (op) { case OP_NEG: bits = NV50_IR_MOD_NEG; break; case OP_ABS: bits = NV50_IR_MOD_ABS; break; case OP_SAT: bits = NV50_IR_MOD_SAT; break; case OP_NOT: bits = NV50_IR_MOD_NOT; break; default: bits = 0; break; } } Modifier Modifier::operator*(const Modifier m) const { unsigned int a, b, c; b = m.bits; if (this->bits & NV50_IR_MOD_ABS) b &= ~NV50_IR_MOD_NEG; a = (this->bits ^ b) & (NV50_IR_MOD_NOT | NV50_IR_MOD_NEG); c = (this->bits | m.bits) & (NV50_IR_MOD_ABS | NV50_IR_MOD_SAT); return Modifier(a | c); } ValueRef::ValueRef(Value *v) : value(NULL), insn(NULL) { indirect[0] = -1; indirect[1] = -1; usedAsPtr = false; set(v); } ValueRef::ValueRef(const ValueRef& ref) : value(NULL), insn(ref.insn) { set(ref); usedAsPtr = ref.usedAsPtr; } ValueRef::~ValueRef() { this->set(NULL); } bool ValueRef::getImmediate(ImmediateValue &imm) const { const ValueRef *src = this; Modifier m; DataType type = src->insn->sType; while (src) { if (src->mod) { if (src->insn->sType != type) break; m *= src->mod; } if (src->getFile() == FILE_IMMEDIATE) { imm = *(src->value->asImm()); // The immediate's type isn't required to match its use, it's // more of a hint; applying a modifier makes use of that hint. imm.reg.type = type; m.applyTo(imm); return true; } Instruction *insn = src->value->getUniqueInsn(); if (insn && insn->op == OP_MOV) { src = &insn->src(0); if (src->mod) WARN("OP_MOV with modifier encountered !\n"); } else { src = NULL; } } return false; } ValueDef::ValueDef(Value *v) : value(NULL), insn(NULL) { set(v); } ValueDef::ValueDef(const ValueDef& def) : value(NULL), insn(NULL) { set(def.get()); } ValueDef::~ValueDef() { this->set(NULL); } void ValueRef::set(const ValueRef &ref) { this->set(ref.get()); mod = ref.mod; indirect[0] = ref.indirect[0]; indirect[1] = ref.indirect[1]; } void ValueRef::set(Value *refVal) { if (value == refVal) return; if (value) value->uses.remove(this); if (refVal) refVal->uses.push_back(this); value = refVal; } void ValueDef::set(Value *defVal) { if (value == defVal) return; if (value) value->defs.remove(this); if (defVal) defVal->defs.push_back(this); value = defVal; } // Check if we can replace this definition's value by the value in @rep, // including the source modifiers, i.e. make sure that all uses support // @rep.mod. bool ValueDef::mayReplace(const ValueRef &rep) { if (!rep.mod) return true; if (!insn || !insn->bb) // Unbound instruction ? return false; const Target *target = insn->bb->getProgram()->getTarget(); for (Value::UseIterator it = value->uses.begin(); it != value->uses.end(); ++it) { Instruction *insn = (*it)->getInsn(); int s = -1; for (int i = 0; insn->srcExists(i); ++i) { if (insn->src(i).get() == value) { // If there are multiple references to us we'd have to check if the // combination of mods is still supported, but just bail for now. if (&insn->src(i) != (*it)) return false; s = i; } } assert(s >= 0); // integrity of uses list if (!target->isModSupported(insn, s, rep.mod)) return false; } return true; } void ValueDef::replace(const ValueRef &repVal, bool doSet) { assert(mayReplace(repVal)); if (value == repVal.get()) return; while (!value->uses.empty()) { ValueRef *ref = value->uses.front(); ref->set(repVal.get()); ref->mod *= repVal.mod; } if (doSet) set(repVal.get()); } Value::Value() { join = this; memset(®, 0, sizeof(reg)); reg.size = 4; } LValue::LValue(Function *fn, DataFile file) { reg.file = file; reg.size = (file != FILE_PREDICATE) ? 4 : 1; reg.data.id = -1; compMask = 0; compound = 0; ssa = 0; fixedReg = 0; noSpill = 0; fn->add(this, this->id); } LValue::LValue(Function *fn, LValue *lval) { assert(lval); reg.file = lval->reg.file; reg.size = lval->reg.size; reg.data.id = -1; compMask = 0; compound = 0; ssa = 0; fixedReg = 0; noSpill = 0; fn->add(this, this->id); } LValue * LValue::clone(ClonePolicy& pol) const { LValue *that = new_LValue(pol.context(), reg.file); pol.set(this, that); that->reg.size = this->reg.size; that->reg.type = this->reg.type; that->reg.data = this->reg.data; return that; } bool LValue::isUniform() const { if (defs.size() > 1) return false; Instruction *insn = getInsn(); // let's not try too hard here for now ... return !insn->srcExists(1) && insn->getSrc(0)->isUniform(); } Symbol::Symbol(Program *prog, DataFile f, ubyte fidx) { baseSym = NULL; reg.file = f; reg.fileIndex = fidx; reg.data.offset = 0; prog->add(this, this->id); } Symbol * Symbol::clone(ClonePolicy& pol) const { Program *prog = pol.context()->getProgram(); Symbol *that = new_Symbol(prog, reg.file, reg.fileIndex); pol.set(this, that); that->reg.size = this->reg.size; that->reg.type = this->reg.type; that->reg.data = this->reg.data; that->baseSym = this->baseSym; return that; } bool Symbol::isUniform() const { return reg.file != FILE_SYSTEM_VALUE && reg.file != FILE_MEMORY_LOCAL && reg.file != FILE_SHADER_INPUT; } ImmediateValue::ImmediateValue(Program *prog, uint32_t uval) { memset(®, 0, sizeof(reg)); reg.file = FILE_IMMEDIATE; reg.size = 4; reg.type = TYPE_U32; reg.data.u32 = uval; prog->add(this, this->id); } ImmediateValue::ImmediateValue(Program *prog, float fval) { memset(®, 0, sizeof(reg)); reg.file = FILE_IMMEDIATE; reg.size = 4; reg.type = TYPE_F32; reg.data.f32 = fval; prog->add(this, this->id); } ImmediateValue::ImmediateValue(Program *prog, double dval) { memset(®, 0, sizeof(reg)); reg.file = FILE_IMMEDIATE; reg.size = 8; reg.type = TYPE_F64; reg.data.f64 = dval; prog->add(this, this->id); } ImmediateValue::ImmediateValue(const ImmediateValue *proto, DataType ty) { reg = proto->reg; reg.type = ty; reg.size = typeSizeof(ty); } ImmediateValue * ImmediateValue::clone(ClonePolicy& pol) const { Program *prog = pol.context()->getProgram(); ImmediateValue *that = new_ImmediateValue(prog, 0u); pol.set(this, that); that->reg.size = this->reg.size; that->reg.type = this->reg.type; that->reg.data = this->reg.data; return that; } bool ImmediateValue::isInteger(const int i) const { switch (reg.type) { case TYPE_S8: return reg.data.s8 == i; case TYPE_U8: return reg.data.u8 == i; case TYPE_S16: return reg.data.s16 == i; case TYPE_U16: return reg.data.u16 == i; case TYPE_S32: case TYPE_U32: return reg.data.s32 == i; // as if ... case TYPE_F32: return reg.data.f32 == static_cast(i); case TYPE_F64: return reg.data.f64 == static_cast(i); default: return false; } } bool ImmediateValue::isNegative() const { switch (reg.type) { case TYPE_S8: return reg.data.s8 < 0; case TYPE_S16: return reg.data.s16 < 0; case TYPE_S32: case TYPE_U32: return reg.data.s32 < 0; case TYPE_F32: return reg.data.u32 & (1 << 31); case TYPE_F64: return reg.data.u64 & (1ULL << 63); default: return false; } } bool ImmediateValue::isPow2() const { switch (reg.type) { case TYPE_U8: case TYPE_U16: case TYPE_U32: return util_is_power_of_two(reg.data.u32); default: return false; } } void ImmediateValue::applyLog2() { switch (reg.type) { case TYPE_S8: case TYPE_S16: case TYPE_S32: assert(!this->isNegative()); // fall through case TYPE_U8: case TYPE_U16: case TYPE_U32: reg.data.u32 = util_logbase2(reg.data.u32); break; case TYPE_F32: reg.data.f32 = log2f(reg.data.f32); break; case TYPE_F64: reg.data.f64 = log2(reg.data.f64); break; default: assert(0); break; } } bool ImmediateValue::compare(CondCode cc, float fval) const { if (reg.type != TYPE_F32) ERROR("immediate value is not of type f32"); switch (static_cast(cc & 7)) { case CC_TR: return true; case CC_FL: return false; case CC_LT: return reg.data.f32 < fval; case CC_LE: return reg.data.f32 <= fval; case CC_GT: return reg.data.f32 > fval; case CC_GE: return reg.data.f32 >= fval; case CC_EQ: return reg.data.f32 == fval; case CC_NE: return reg.data.f32 != fval; default: assert(0); return false; } } ImmediateValue& ImmediateValue::operator=(const ImmediateValue &that) { this->reg = that.reg; return (*this); } bool Value::interfers(const Value *that) const { uint32_t idA, idB; if (that->reg.file != reg.file || that->reg.fileIndex != reg.fileIndex) return false; if (this->asImm()) return false; if (this->asSym()) { idA = this->join->reg.data.offset; idB = that->join->reg.data.offset; } else { idA = this->join->reg.data.id * MIN2(this->reg.size, 4); idB = that->join->reg.data.id * MIN2(that->reg.size, 4); } if (idA < idB) return (idA + this->reg.size > idB); else if (idA > idB) return (idB + that->reg.size > idA); else return (idA == idB); } bool Value::equals(const Value *that, bool strict) const { if (strict) return this == that; if (that->reg.file != reg.file || that->reg.fileIndex != reg.fileIndex) return false; if (that->reg.size != this->reg.size) return false; if (that->reg.data.id != this->reg.data.id) return false; return true; } bool ImmediateValue::equals(const Value *that, bool strict) const { const ImmediateValue *imm = that->asImm(); if (!imm) return false; return reg.data.u64 == imm->reg.data.u64; } bool Symbol::equals(const Value *that, bool strict) const { if (reg.file != that->reg.file || reg.fileIndex != that->reg.fileIndex) return false; assert(that->asSym()); if (this->baseSym != that->asSym()->baseSym) return false; return this->reg.data.offset == that->reg.data.offset; } void Instruction::init() { next = prev = 0; cc = CC_ALWAYS; rnd = ROUND_N; cache = CACHE_CA; subOp = 0; saturate = 0; join = 0; exit = 0; terminator = 0; ftz = 0; dnz = 0; atomic = 0; perPatch = 0; fixed = 0; encSize = 0; ipa = 0; lanes = 0xf; postFactor = 0; predSrc = -1; flagsDef = -1; flagsSrc = -1; } Instruction::Instruction() { init(); op = OP_NOP; dType = sType = TYPE_F32; id = -1; bb = 0; } Instruction::Instruction(Function *fn, operation opr, DataType ty) { init(); op = opr; dType = sType = ty; fn->add(this, id); } Instruction::~Instruction() { if (bb) { Function *fn = bb->getFunction(); bb->remove(this); fn->allInsns.remove(id); } for (int s = 0; srcExists(s); ++s) setSrc(s, NULL); // must unlink defs too since the list pointers will get deallocated for (int d = 0; defExists(d); ++d) setDef(d, NULL); } void Instruction::setDef(int i, Value *val) { int size = defs.size(); if (i >= size) { defs.resize(i + 1); while (size <= i) defs[size++].setInsn(this); } defs[i].set(val); } void Instruction::setSrc(int s, Value *val) { int size = srcs.size(); if (s >= size) { srcs.resize(s + 1); while (size <= s) srcs[size++].setInsn(this); } srcs[s].set(val); } void Instruction::setSrc(int s, const ValueRef& ref) { setSrc(s, ref.get()); srcs[s].mod = ref.mod; } void Instruction::swapSources(int a, int b) { Value *value = srcs[a].get(); Modifier m = srcs[a].mod; setSrc(a, srcs[b]); srcs[b].set(value); srcs[b].mod = m; } void Instruction::takeExtraSources(int s, Value *values[3]) { values[0] = getIndirect(s, 0); if (values[0]) setIndirect(s, 0, NULL); values[1] = getIndirect(s, 1); if (values[1]) setIndirect(s, 1, NULL); values[2] = getPredicate(); if (values[2]) setPredicate(cc, NULL); } void Instruction::putExtraSources(int s, Value *values[3]) { if (values[0]) setIndirect(s, 0, values[0]); if (values[1]) setIndirect(s, 1, values[1]); if (values[2]) setPredicate(cc, values[2]); } Instruction * Instruction::clone(ClonePolicy& pol, Instruction *i) const { if (!i) i = new_Instruction(pol.context(), op, dType); assert(typeid(*i) == typeid(*this)); pol.set(this, i); i->sType = sType; i->rnd = rnd; i->cache = cache; i->subOp = subOp; i->saturate = saturate; i->join = join; i->exit = exit; i->atomic = atomic; i->ftz = ftz; i->dnz = dnz; i->ipa = ipa; i->lanes = lanes; i->perPatch = perPatch; i->postFactor = postFactor; for (int d = 0; defExists(d); ++d) i->setDef(d, pol.get(getDef(d))); for (int s = 0; srcExists(s); ++s) { i->setSrc(s, pol.get(getSrc(s))); i->src(s).mod = src(s).mod; } i->cc = cc; i->predSrc = predSrc; i->flagsDef = flagsDef; i->flagsSrc = flagsSrc; return i; } unsigned int Instruction::defCount(unsigned int mask, bool singleFile) const { unsigned int i, n; if (singleFile) { unsigned int d = ffs(mask); if (!d) return 0; for (i = d--; defExists(i); ++i) if (getDef(i)->reg.file != getDef(d)->reg.file) mask &= ~(1 << i); } for (n = 0, i = 0; this->defExists(i); ++i, mask >>= 1) n += mask & 1; return n; } unsigned int Instruction::srcCount(unsigned int mask, bool singleFile) const { unsigned int i, n; if (singleFile) { unsigned int s = ffs(mask); if (!s) return 0; for (i = s--; srcExists(i); ++i) if (getSrc(i)->reg.file != getSrc(s)->reg.file) mask &= ~(1 << i); } for (n = 0, i = 0; this->srcExists(i); ++i, mask >>= 1) n += mask & 1; return n; } bool Instruction::setIndirect(int s, int dim, Value *value) { assert(this->srcExists(s)); int p = srcs[s].indirect[dim]; if (p < 0) { if (!value) return true; p = srcs.size(); while (p > 0 && !srcExists(p - 1)) --p; } setSrc(p, value); srcs[p].usedAsPtr = (value != 0); srcs[s].indirect[dim] = value ? p : -1; return true; } bool Instruction::setPredicate(CondCode ccode, Value *value) { cc = ccode; if (!value) { if (predSrc >= 0) { srcs[predSrc].set(NULL); predSrc = -1; } return true; } if (predSrc < 0) { predSrc = srcs.size(); while (predSrc > 0 && !srcExists(predSrc - 1)) --predSrc; } setSrc(predSrc, value); return true; } bool Instruction::writesPredicate() const { for (int d = 0; defExists(d); ++d) if (getDef(d)->inFile(FILE_PREDICATE) || getDef(d)->inFile(FILE_FLAGS)) return true; return false; } static bool insnCheckCommutationDefSrc(const Instruction *a, const Instruction *b) { for (int d = 0; a->defExists(d); ++d) for (int s = 0; b->srcExists(s); ++s) if (a->getDef(d)->interfers(b->getSrc(s))) return false; return true; } static bool insnCheckCommutationDefDef(const Instruction *a, const Instruction *b) { for (int d = 0; a->defExists(d); ++d) for (int c = 0; b->defExists(c); ++c) if (a->getDef(d)->interfers(b->getDef(c))) return false; return true; } bool Instruction::isCommutationLegal(const Instruction *i) const { bool ret = insnCheckCommutationDefDef(this, i); ret = ret && insnCheckCommutationDefSrc(this, i); ret = ret && insnCheckCommutationDefSrc(i, this); return ret; } TexInstruction::TexInstruction(Function *fn, operation op) : Instruction(fn, op, TYPE_F32) { memset(&tex, 0, sizeof(tex)); tex.rIndirectSrc = -1; tex.sIndirectSrc = -1; } TexInstruction::~TexInstruction() { for (int c = 0; c < 3; ++c) { dPdx[c].set(NULL); dPdy[c].set(NULL); } } TexInstruction * TexInstruction::clone(ClonePolicy& pol, Instruction *i) const { TexInstruction *tex = (i ? static_cast(i) : new_TexInstruction(pol.context(), op)); Instruction::clone(pol, tex); tex->tex = this->tex; if (op == OP_TXD) { for (unsigned int c = 0; c < tex->tex.target.getDim(); ++c) { tex->dPdx[c].set(dPdx[c]); tex->dPdy[c].set(dPdy[c]); } } return tex; } const struct TexInstruction::Target::Desc TexInstruction::Target::descTable[] = { { "1D", 1, 1, false, false, false }, { "2D", 2, 2, false, false, false }, { "2D_MS", 2, 2, false, false, false }, { "3D", 3, 3, false, false, false }, { "CUBE", 2, 3, false, true, false }, { "1D_SHADOW", 1, 1, false, false, true }, { "2D_SHADOW", 2, 2, false, false, true }, { "CUBE_SHADOW", 2, 3, false, true, true }, { "1D_ARRAY", 1, 2, true, false, false }, { "2D_ARRAY", 2, 3, true, false, false }, { "2D_MS_ARRAY", 2, 3, true, false, false }, { "CUBE_ARRAY", 2, 4, true, true, false }, { "1D_ARRAY_SHADOW", 1, 2, true, false, true }, { "2D_ARRAY_SHADOW", 2, 3, true, false, true }, { "RECT", 2, 2, false, false, false }, { "RECT_SHADOW", 2, 2, false, false, true }, { "CUBE_ARRAY_SHADOW", 2, 4, true, true, true }, { "BUFFER", 1, 1, false, false, false }, }; CmpInstruction::CmpInstruction(Function *fn, operation op) : Instruction(fn, op, TYPE_F32) { setCond = CC_ALWAYS; } CmpInstruction * CmpInstruction::clone(ClonePolicy& pol, Instruction *i) const { CmpInstruction *cmp = (i ? static_cast(i) : new_CmpInstruction(pol.context(), op)); cmp->dType = dType; Instruction::clone(pol, cmp); cmp->setCond = setCond; return cmp; } FlowInstruction::FlowInstruction(Function *fn, operation op, void *targ) : Instruction(fn, op, TYPE_NONE) { if (op == OP_CALL) target.fn = reinterpret_cast(targ); else target.bb = reinterpret_cast(targ); if (op == OP_BRA || op == OP_CONT || op == OP_BREAK || op == OP_RET || op == OP_EXIT) terminator = 1; else if (op == OP_JOIN) terminator = targ ? 1 : 0; allWarp = absolute = limit = builtin = 0; } FlowInstruction * FlowInstruction::clone(ClonePolicy& pol, Instruction *i) const { FlowInstruction *flow = (i ? static_cast(i) : new_FlowInstruction(pol.context(), op, NULL)); Instruction::clone(pol, flow); flow->allWarp = allWarp; flow->absolute = absolute; flow->limit = limit; flow->builtin = builtin; if (builtin) flow->target.builtin = target.builtin; else if (op == OP_CALL) flow->target.fn = target.fn; else if (target.bb) flow->target.bb = pol.get(target.bb); return flow; } Program::Program(Type type, Target *arch) : progType(type), target(arch), mem_Instruction(sizeof(Instruction), 6), mem_CmpInstruction(sizeof(CmpInstruction), 4), mem_TexInstruction(sizeof(TexInstruction), 4), mem_FlowInstruction(sizeof(FlowInstruction), 4), mem_LValue(sizeof(LValue), 8), mem_Symbol(sizeof(Symbol), 7), mem_ImmediateValue(sizeof(ImmediateValue), 7) { code = NULL; binSize = 0; maxGPR = -1; main = new Function(this, "MAIN", ~0); calls.insert(&main->call); dbgFlags = 0; optLevel = 0; targetPriv = NULL; } Program::~Program() { for (ArrayList::Iterator it = allFuncs.iterator(); !it.end(); it.next()) delete reinterpret_cast(it.get()); for (ArrayList::Iterator it = allRValues.iterator(); !it.end(); it.next()) releaseValue(reinterpret_cast(it.get())); } void Program::releaseInstruction(Instruction *insn) { // TODO: make this not suck so much insn->~Instruction(); if (insn->asCmp()) mem_CmpInstruction.release(insn); else if (insn->asTex()) mem_TexInstruction.release(insn); else if (insn->asFlow()) mem_FlowInstruction.release(insn); else mem_Instruction.release(insn); } void Program::releaseValue(Value *value) { value->~Value(); if (value->asLValue()) mem_LValue.release(value); else if (value->asImm()) mem_ImmediateValue.release(value); else if (value->asSym()) mem_Symbol.release(value); } } // namespace nv50_ir extern "C" { static void nv50_ir_init_prog_info(struct nv50_ir_prog_info *info) { #if defined(PIPE_SHADER_HULL) && defined(PIPE_SHADER_DOMAIN) if (info->type == PIPE_SHADER_HULL || info->type == PIPE_SHADER_DOMAIN) { info->prop.tp.domain = PIPE_PRIM_MAX; info->prop.tp.outputPrim = PIPE_PRIM_MAX; } #endif if (info->type == PIPE_SHADER_GEOMETRY) { info->prop.gp.instanceCount = 1; info->prop.gp.maxVertices = 1; } info->io.clipDistance = 0xff; info->io.pointSize = 0xff; info->io.instanceId = 0xff; info->io.vertexId = 0xff; info->io.edgeFlagIn = 0xff; info->io.edgeFlagOut = 0xff; info->io.fragDepth = 0xff; info->io.sampleMask = 0xff; info->io.backFaceColor[0] = info->io.backFaceColor[1] = 0xff; } int nv50_ir_generate_code(struct nv50_ir_prog_info *info) { int ret = 0; nv50_ir::Program::Type type; nv50_ir_init_prog_info(info); #define PROG_TYPE_CASE(a, b) \ case PIPE_SHADER_##a: type = nv50_ir::Program::TYPE_##b; break switch (info->type) { PROG_TYPE_CASE(VERTEX, VERTEX); // PROG_TYPE_CASE(HULL, TESSELLATION_CONTROL); // PROG_TYPE_CASE(DOMAIN, TESSELLATION_EVAL); PROG_TYPE_CASE(GEOMETRY, GEOMETRY); PROG_TYPE_CASE(FRAGMENT, FRAGMENT); default: type = nv50_ir::Program::TYPE_COMPUTE; break; } INFO_DBG(info->dbgFlags, VERBOSE, "translating program of type %u\n", type); nv50_ir::Target *targ = nv50_ir::Target::create(info->target); if (!targ) return -1; nv50_ir::Program *prog = new nv50_ir::Program(type, targ); if (!prog) return -1; prog->dbgFlags = info->dbgFlags; prog->optLevel = info->optLevel; switch (info->bin.sourceRep) { #if 0 case PIPE_IR_LLVM: case PIPE_IR_GLSL: return -1; case PIPE_IR_SM4: ret = prog->makeFromSM4(info) ? 0 : -2; break; case PIPE_IR_TGSI: #endif default: ret = prog->makeFromTGSI(info) ? 0 : -2; break; } if (ret < 0) goto out; if (prog->dbgFlags & NV50_IR_DEBUG_VERBOSE) prog->print(); targ->parseDriverInfo(info); prog->getTarget()->runLegalizePass(prog, nv50_ir::CG_STAGE_PRE_SSA); prog->convertToSSA(); if (prog->dbgFlags & NV50_IR_DEBUG_VERBOSE) prog->print(); prog->optimizeSSA(info->optLevel); prog->getTarget()->runLegalizePass(prog, nv50_ir::CG_STAGE_SSA); if (prog->dbgFlags & NV50_IR_DEBUG_BASIC) prog->print(); if (!prog->registerAllocation()) { ret = -4; goto out; } prog->getTarget()->runLegalizePass(prog, nv50_ir::CG_STAGE_POST_RA); prog->optimizePostRA(info->optLevel); if (!prog->emitBinary(info)) { ret = -5; goto out; } out: INFO_DBG(prog->dbgFlags, VERBOSE, "nv50_ir_generate_code: ret = %i\n", ret); info->bin.maxGPR = prog->maxGPR; info->bin.code = prog->code; info->bin.codeSize = prog->binSize; info->bin.tlsSpace = prog->tlsSize; delete prog; nv50_ir::Target::destroy(targ); return ret; } } // extern "C"