/* * Copyright © 2018 Valve Corporation * Copyright © 2018 Google * * SPDX-License-Identifier: MIT */ #include "aco_ir.h" namespace aco { RegisterDemand get_live_changes(aco_ptr& instr) { RegisterDemand changes; for (const Definition& def : instr->definitions) { if (!def.isTemp() || def.isKill()) continue; changes += def.getTemp(); } for (const Operand& op : instr->operands) { if (!op.isTemp() || !op.isFirstKill()) continue; changes -= op.getTemp(); } return changes; } RegisterDemand get_additional_operand_demand(Instruction* instr) { RegisterDemand additional_demand; int op_idx = get_op_fixed_to_def(instr); if (op_idx != -1 && !instr->operands[op_idx].isKill()) additional_demand += instr->definitions[0].getTemp(); return additional_demand; } RegisterDemand get_temp_registers(aco_ptr& instr) { RegisterDemand demand_before; RegisterDemand demand_after; for (Definition def : instr->definitions) { if (def.isKill()) demand_after += def.getTemp(); else if (def.isTemp()) demand_before -= def.getTemp(); } for (Operand op : instr->operands) { if (op.isFirstKill()) { demand_before += op.getTemp(); if (op.isLateKill()) demand_after += op.getTemp(); } } demand_before += get_additional_operand_demand(instr.get()); demand_after.update(demand_before); return demand_after; } namespace { struct live_ctx { monotonic_buffer_resource m; Program* program; int worklist; }; bool instr_needs_vcc(Instruction* instr) { if (instr->isVOPC()) return true; if (instr->isVOP2() && !instr->isVOP3()) { if (instr->operands.size() == 3 && instr->operands[2].isTemp() && instr->operands[2].regClass().type() == RegType::sgpr) return true; if (instr->definitions.size() == 2) return true; } return false; } void process_live_temps_per_block(live_ctx& ctx, Block* block) { RegisterDemand new_demand; block->register_demand = RegisterDemand(); IDSet live(ctx.program->live.live_out[block->index], ctx.m); /* initialize register demand */ for (unsigned t : live) new_demand += Temp(t, ctx.program->temp_rc[t]); /* traverse the instructions backwards */ int idx; for (idx = block->instructions.size() - 1; idx >= 0; idx--) { Instruction* insn = block->instructions[idx].get(); if (is_phi(insn)) break; ctx.program->needs_vcc |= instr_needs_vcc(insn); insn->register_demand = RegisterDemand(new_demand.vgpr, new_demand.sgpr); /* KILL */ for (Definition& definition : insn->definitions) { if (!definition.isTemp()) { continue; } if (definition.isFixed() && definition.physReg() == vcc) ctx.program->needs_vcc = true; const Temp temp = definition.getTemp(); const size_t n = live.erase(temp.id()); if (n) { new_demand -= temp; definition.setKill(false); } else { insn->register_demand += temp; definition.setKill(true); } } /* we need to do this in a separate loop because the next one can * setKill() for several operands at once and we don't want to * overwrite that in a later iteration */ for (Operand& op : insn->operands) op.setKill(false); /* GEN */ for (unsigned i = 0; i < insn->operands.size(); ++i) { Operand& operand = insn->operands[i]; if (!operand.isTemp()) continue; if (operand.isFixed() && operand.physReg() == vcc) ctx.program->needs_vcc = true; const Temp temp = operand.getTemp(); const bool inserted = live.insert(temp.id()).second; if (inserted) { operand.setFirstKill(true); for (unsigned j = i + 1; j < insn->operands.size(); ++j) { if (insn->operands[j].isTemp() && insn->operands[j].tempId() == operand.tempId()) { insn->operands[j].setFirstKill(false); insn->operands[j].setKill(true); } } if (operand.isLateKill()) insn->register_demand += temp; new_demand += temp; } } RegisterDemand before_instr = new_demand + get_additional_operand_demand(insn); insn->register_demand.update(before_instr); block->register_demand.update(insn->register_demand); } /* handle phi definitions */ for (int phi_idx = 0; phi_idx <= idx; phi_idx++) { Instruction* insn = block->instructions[phi_idx].get(); insn->register_demand = new_demand; assert(is_phi(insn) && insn->definitions.size() == 1); if (!insn->definitions[0].isTemp()) { assert(insn->definitions[0].isFixed() && insn->definitions[0].physReg() == exec); continue; } Definition& definition = insn->definitions[0]; if (definition.isFixed() && definition.physReg() == vcc) ctx.program->needs_vcc = true; const Temp temp = definition.getTemp(); const size_t n = live.erase(temp.id()); if (n) { definition.setKill(false); } else { definition.setKill(true); } } /* now, we need to merge the live-ins into the live-out sets */ bool fast_merge = block->logical_preds.size() == 0 || block->logical_preds == block->linear_preds; #ifndef NDEBUG if ((block->linear_preds.empty() && !live.empty()) || (block->logical_preds.empty() && new_demand.vgpr > 0)) fast_merge = false; /* we might have errors */ #endif if (fast_merge) { for (unsigned pred_idx : block->linear_preds) { if (ctx.program->live.live_out[pred_idx].insert(live)) ctx.worklist = std::max(ctx.worklist, pred_idx); } } else { for (unsigned t : live) { RegClass rc = ctx.program->temp_rc[t]; Block::edge_vec& preds = rc.is_linear() ? block->linear_preds : block->logical_preds; #ifndef NDEBUG if (preds.empty()) aco_err(ctx.program, "Temporary never defined or are defined after use: %%%d in BB%d", t, block->index); #endif for (unsigned pred_idx : preds) { auto it = ctx.program->live.live_out[pred_idx].insert(t); if (it.second) ctx.worklist = std::max(ctx.worklist, pred_idx); } } } /* handle phi operands */ for (int phi_idx = 0; phi_idx <= idx; phi_idx++) { Instruction* insn = block->instructions[phi_idx].get(); assert(is_phi(insn)); /* Ignore dead phis. */ if (insn->definitions[0].isKill()) continue; /* directly insert into the predecessors live-out set */ Block::edge_vec& preds = insn->opcode == aco_opcode::p_phi ? block->logical_preds : block->linear_preds; for (unsigned i = 0; i < preds.size(); ++i) { Operand& operand = insn->operands[i]; if (!operand.isTemp()) continue; if (operand.isFixed() && operand.physReg() == vcc) ctx.program->needs_vcc = true; /* check if we changed an already processed block */ const bool inserted = ctx.program->live.live_out[preds[i]].insert(operand.tempId()).second; if (inserted) ctx.worklist = std::max(ctx.worklist, preds[i]); /* set if the operand is killed by this (or another) phi instruction */ operand.setKill(!live.count(operand.tempId())); } } block->live_in_demand = new_demand; block->live_in_demand.sgpr += 2; /* Add 2 SGPRs for potential long-jumps. */ block->register_demand.update(block->live_in_demand); ctx.program->max_reg_demand.update(block->register_demand); assert(!block->linear_preds.empty() || (new_demand == RegisterDemand() && live.empty())); } unsigned calc_waves_per_workgroup(Program* program) { /* When workgroup size is not known, just go with wave_size */ unsigned workgroup_size = program->workgroup_size == UINT_MAX ? program->wave_size : program->workgroup_size; return align(workgroup_size, program->wave_size) / program->wave_size; } } /* end namespace */ bool uses_scratch(Program* program) { /* RT uses scratch but we don't yet know how much. */ return program->config->scratch_bytes_per_wave || program->stage == raytracing_cs; } uint16_t get_extra_sgprs(Program* program) { /* We don't use this register on GFX6-8 and it's removed on GFX10+. */ bool needs_flat_scr = uses_scratch(program) && program->gfx_level == GFX9; if (program->gfx_level >= GFX10) { assert(!program->dev.xnack_enabled); return 0; } else if (program->gfx_level >= GFX8) { if (needs_flat_scr) return 6; else if (program->dev.xnack_enabled) return 4; else if (program->needs_vcc) return 2; else return 0; } else { assert(!program->dev.xnack_enabled); if (needs_flat_scr) return 4; else if (program->needs_vcc) return 2; else return 0; } } uint16_t get_sgpr_alloc(Program* program, uint16_t addressable_sgprs) { uint16_t sgprs = addressable_sgprs + get_extra_sgprs(program); uint16_t granule = program->dev.sgpr_alloc_granule; return ALIGN_NPOT(std::max(sgprs, granule), granule); } uint16_t get_vgpr_alloc(Program* program, uint16_t addressable_vgprs) { assert(addressable_vgprs <= program->dev.vgpr_limit); uint16_t granule = program->dev.vgpr_alloc_granule; return ALIGN_NPOT(std::max(addressable_vgprs, granule), granule); } unsigned round_down(unsigned a, unsigned b) { return a - (a % b); } uint16_t get_addr_sgpr_from_waves(Program* program, uint16_t waves) { /* it's not possible to allocate more than 128 SGPRs */ uint16_t sgprs = std::min(program->dev.physical_sgprs / waves, 128); sgprs = round_down(sgprs, program->dev.sgpr_alloc_granule); sgprs -= get_extra_sgprs(program); return std::min(sgprs, program->dev.sgpr_limit); } uint16_t get_addr_vgpr_from_waves(Program* program, uint16_t waves) { uint16_t vgprs = program->dev.physical_vgprs / waves; vgprs = vgprs / program->dev.vgpr_alloc_granule * program->dev.vgpr_alloc_granule; vgprs -= program->config->num_shared_vgprs / 2; return std::min(vgprs, program->dev.vgpr_limit); } void calc_min_waves(Program* program) { unsigned waves_per_workgroup = calc_waves_per_workgroup(program); unsigned simd_per_cu_wgp = program->dev.simd_per_cu * (program->wgp_mode ? 2 : 1); program->min_waves = DIV_ROUND_UP(waves_per_workgroup, simd_per_cu_wgp); } uint16_t max_suitable_waves(Program* program, uint16_t waves) { unsigned num_simd = program->dev.simd_per_cu * (program->wgp_mode ? 2 : 1); unsigned waves_per_workgroup = calc_waves_per_workgroup(program); unsigned num_workgroups = waves * num_simd / waves_per_workgroup; /* Adjust #workgroups for LDS */ unsigned lds_per_workgroup = align(program->config->lds_size * program->dev.lds_encoding_granule, program->dev.lds_alloc_granule); if (program->stage == fragment_fs) { /* PS inputs are moved from PC (parameter cache) to LDS before PS waves are launched. * Each PS input occupies 3x vec4 of LDS space. See Figure 10.3 in GCN3 ISA manual. * These limit occupancy the same way as other stages' LDS usage does. */ unsigned lds_bytes_per_interp = 3 * 16; unsigned lds_param_bytes = lds_bytes_per_interp * program->info.ps.num_interp; lds_per_workgroup += align(lds_param_bytes, program->dev.lds_alloc_granule); } unsigned lds_limit = program->wgp_mode ? program->dev.lds_limit * 2 : program->dev.lds_limit; if (lds_per_workgroup) num_workgroups = std::min(num_workgroups, lds_limit / lds_per_workgroup); /* Hardware limitation */ if (waves_per_workgroup > 1) num_workgroups = std::min(num_workgroups, program->wgp_mode ? 32u : 16u); /* Adjust #waves for workgroup multiples: * In cases like waves_per_workgroup=3 or lds=65536 and * waves_per_workgroup=1, we want the maximum possible number of waves per * SIMD and not the minimum. so DIV_ROUND_UP is used */ unsigned workgroup_waves = num_workgroups * waves_per_workgroup; return DIV_ROUND_UP(workgroup_waves, num_simd); } void update_vgpr_sgpr_demand(Program* program, const RegisterDemand new_demand) { assert(program->min_waves >= 1); uint16_t sgpr_limit = get_addr_sgpr_from_waves(program, program->min_waves); uint16_t vgpr_limit = get_addr_vgpr_from_waves(program, program->min_waves); /* this won't compile, register pressure reduction necessary */ if (new_demand.vgpr > vgpr_limit || new_demand.sgpr > sgpr_limit) { program->num_waves = 0; program->max_reg_demand = new_demand; } else { program->num_waves = program->dev.physical_sgprs / get_sgpr_alloc(program, new_demand.sgpr); uint16_t vgpr_demand = get_vgpr_alloc(program, new_demand.vgpr) + program->config->num_shared_vgprs / 2; program->num_waves = std::min(program->num_waves, program->dev.physical_vgprs / vgpr_demand); program->num_waves = std::min(program->num_waves, program->dev.max_waves_per_simd); /* Adjust for LDS and workgroup multiples and calculate max_reg_demand */ program->num_waves = max_suitable_waves(program, program->num_waves); program->max_reg_demand.vgpr = get_addr_vgpr_from_waves(program, program->num_waves); program->max_reg_demand.sgpr = get_addr_sgpr_from_waves(program, program->num_waves); } } void live_var_analysis(Program* program) { program->live.live_out.clear(); program->live.memory.release(); program->live.live_out.resize(program->blocks.size(), IDSet(program->live.memory)); program->max_reg_demand = RegisterDemand(); program->needs_vcc = program->gfx_level >= GFX10; live_ctx ctx; ctx.program = program; ctx.worklist = program->blocks.size() - 1; /* this implementation assumes that the block idx corresponds to the block's position in * program->blocks vector */ while (ctx.worklist >= 0) { process_live_temps_per_block(ctx, &program->blocks[ctx.worklist--]); } /* calculate the program's register demand and number of waves */ if (program->progress < CompilationProgress::after_ra) update_vgpr_sgpr_demand(program, program->max_reg_demand); } } // namespace aco