#include <array>
#include <map>
#include <unordered_map>
-#include <functional>
#include "aco_ir.h"
#include "sid.h"
namespace aco {
namespace {
+unsigned get_subdword_operand_stride(chip_class chip, const aco_ptr<Instruction>& instr, unsigned idx, RegClass rc);
+void add_subdword_operand(chip_class chip, aco_ptr<Instruction>& instr, unsigned idx, unsigned byte, RegClass rc);
+std::pair<unsigned, unsigned> get_subdword_definition_info(Program *program, const aco_ptr<Instruction>& instr, RegClass rc);
+void add_subdword_definition(Program *program, aco_ptr<Instruction>& instr, unsigned idx, PhysReg reg, bool is_partial);
+
struct assignment {
PhysReg reg;
RegClass rc;
std::unordered_map<unsigned, Temp> orig_names;
std::unordered_map<unsigned, phi_info> phi_map;
std::unordered_map<unsigned, unsigned> affinities;
+ std::unordered_map<unsigned, Instruction*> vectors;
+ std::unordered_map<unsigned, Instruction*> split_vectors;
+ aco_ptr<Instruction> pseudo_dummy;
unsigned max_used_sgpr = 0;
unsigned max_used_vgpr = 0;
std::bitset<64> defs_done; /* see MAX_ARGS in aco_instruction_selection_setup.cpp */
renames(program->blocks.size()),
incomplete_phis(program->blocks.size()),
filled(program->blocks.size()),
- sealed(program->blocks.size()) {}
+ sealed(program->blocks.size())
+ {
+ pseudo_dummy.reset(create_instruction<Instruction>(aco_opcode::p_parallelcopy, Format::PSEUDO, 0, 0));
+ }
+};
+
+struct DefInfo {
+ uint16_t lb;
+ uint16_t ub;
+ uint8_t size;
+ uint8_t stride;
+ RegClass rc;
+
+ DefInfo(ra_ctx& ctx, aco_ptr<Instruction>& instr, RegClass rc_, int operand) : rc(rc_) {
+ size = rc.size();
+ stride = 1;
+
+ if (rc.type() == RegType::vgpr) {
+ lb = 256;
+ ub = 256 + ctx.program->max_reg_demand.vgpr;
+ } else {
+ lb = 0;
+ ub = ctx.program->max_reg_demand.sgpr;
+ if (size == 2)
+ stride = 2;
+ else if (size >= 4)
+ stride = 4;
+ }
+
+ if (rc.is_subdword() && operand >= 0) {
+ /* stride in bytes */
+ stride = get_subdword_operand_stride(ctx.program->chip_class, instr, operand, rc);
+ } else if (rc.is_subdword()) {
+ std::pair<unsigned, unsigned> info = get_subdword_definition_info(ctx.program, instr, rc);
+ stride = info.first;
+ if (info.second > rc.bytes()) {
+ rc = RegClass::get(rc.type(), info.second);
+ size = rc.size();
+ /* we might still be able to put the definition in the high half,
+ * but that's only useful for affinities and this information isn't
+ * used for them */
+ stride = align(stride, info.second);
+ if (!rc.is_subdword())
+ stride = DIV_ROUND_UP(stride, 4);
+ }
+ assert(stride > 0);
+ }
+ }
};
class RegisterFile {
return false;
}
- void fill(PhysReg start, unsigned size, uint32_t val) {
- for (unsigned i = 0; i < size; i++)
- regs[start + i] = val;
- }
-
- void fill_subdword(PhysReg start, unsigned num_bytes, uint32_t val) {
- fill(start, DIV_ROUND_UP(num_bytes, 4), 0xF0000000);
- for (PhysReg i = start; i.reg_b < start.reg_b + num_bytes; i = PhysReg(i + 1)) {
- /* emplace or get */
- std::array<uint32_t, 4>& sub = subdword_regs.emplace(i, std::array<uint32_t, 4>{0, 0, 0, 0}).first->second;
- for (unsigned j = i.byte(); i * 4 + j < start.reg_b + num_bytes && j < 4; j++)
- sub[j] = val;
-
- if (sub == std::array<uint32_t, 4>{0, 0, 0, 0}) {
- subdword_regs.erase(i);
- regs[i] = 0;
- }
- }
- }
-
- void block(PhysReg start, unsigned num_bytes) {
- if (start.byte() || num_bytes % 4)
- fill_subdword(start, num_bytes, 0xFFFFFFFF);
+ void block(PhysReg start, RegClass rc) {
+ if (rc.is_subdword())
+ fill_subdword(start, rc.bytes(), 0xFFFFFFFF);
else
- fill(start, num_bytes / 4, 0xFFFFFFFF);
+ fill(start, rc.size(), 0xFFFFFFFF);
}
bool is_blocked(PhysReg start) {
void clear(Definition def) {
clear(def.physReg(), def.regClass());
}
+
+ unsigned get_id(PhysReg reg) {
+ return regs[reg] == 0xF0000000 ? subdword_regs[reg][reg.byte()] : regs[reg];
+ }
+
+private:
+ void fill(PhysReg start, unsigned size, uint32_t val) {
+ for (unsigned i = 0; i < size; i++)
+ regs[start + i] = val;
+ }
+
+ void fill_subdword(PhysReg start, unsigned num_bytes, uint32_t val) {
+ fill(start, DIV_ROUND_UP(num_bytes, 4), 0xF0000000);
+ for (PhysReg i = start; i.reg_b < start.reg_b + num_bytes; i = PhysReg(i + 1)) {
+ /* emplace or get */
+ std::array<uint32_t, 4>& sub = subdword_regs.emplace(i, std::array<uint32_t, 4>{0, 0, 0, 0}).first->second;
+ for (unsigned j = i.byte(); i * 4 + j < start.reg_b + num_bytes && j < 4; j++)
+ sub[j] = val;
+
+ if (sub == std::array<uint32_t, 4>{0, 0, 0, 0}) {
+ subdword_regs.erase(i);
+ regs[i] = 0;
+ }
+ }
+ }
};
#endif
+unsigned get_subdword_operand_stride(chip_class chip, const aco_ptr<Instruction>& instr, unsigned idx, RegClass rc)
+{
+ if (instr->format == Format::PSEUDO && chip >= GFX8)
+ return rc.bytes() % 2 == 0 ? 2 : 1;
+
+ if (instr->opcode == aco_opcode::v_cvt_f32_ubyte0) {
+ return 1;
+ } else if (can_use_SDWA(chip, instr)) {
+ return rc.bytes() % 2 == 0 ? 2 : 1;
+ } else if (rc.bytes() == 2 && can_use_opsel(chip, instr->opcode, idx, 1)) {
+ return 2;
+ }
+
+ switch (instr->opcode) {
+ case aco_opcode::ds_write_b8:
+ case aco_opcode::ds_write_b16:
+ return chip >= GFX8 ? 2 : 4;
+ case aco_opcode::buffer_store_byte:
+ case aco_opcode::buffer_store_short:
+ case aco_opcode::flat_store_byte:
+ case aco_opcode::flat_store_short:
+ case aco_opcode::scratch_store_byte:
+ case aco_opcode::scratch_store_short:
+ case aco_opcode::global_store_byte:
+ case aco_opcode::global_store_short:
+ return chip >= GFX9 ? 2 : 4;
+ default:
+ break;
+ }
+
+ return 4;
+}
+
+void add_subdword_operand(chip_class chip, aco_ptr<Instruction>& instr, unsigned idx, unsigned byte, RegClass rc)
+{
+ if (instr->format == Format::PSEUDO || byte == 0)
+ return;
+
+ assert(rc.bytes() <= 2);
+
+ if (!instr->usesModifiers() && instr->opcode == aco_opcode::v_cvt_f32_ubyte0) {
+ switch (byte) {
+ case 0:
+ instr->opcode = aco_opcode::v_cvt_f32_ubyte0;
+ break;
+ case 1:
+ instr->opcode = aco_opcode::v_cvt_f32_ubyte1;
+ break;
+ case 2:
+ instr->opcode = aco_opcode::v_cvt_f32_ubyte2;
+ break;
+ case 3:
+ instr->opcode = aco_opcode::v_cvt_f32_ubyte3;
+ break;
+ }
+ return;
+ } else if (can_use_SDWA(chip, instr)) {
+ convert_to_SDWA(chip, instr);
+ return;
+ } else if (rc.bytes() == 2 && can_use_opsel(chip, instr->opcode, idx, byte / 2)) {
+ VOP3A_instruction *vop3 = static_cast<VOP3A_instruction *>(instr.get());
+ vop3->opsel |= (byte / 2) << idx;
+ return;
+ }
+
+ if (chip >= GFX8 && instr->opcode == aco_opcode::ds_write_b8 && byte == 2) {
+ instr->opcode = aco_opcode::ds_write_b8_d16_hi;
+ return;
+ }
+ if (chip >= GFX8 && instr->opcode == aco_opcode::ds_write_b16 && byte == 2) {
+ instr->opcode = aco_opcode::ds_write_b16_d16_hi;
+ return;
+ }
+
+ if (chip >= GFX9 && byte == 2) {
+ if (instr->opcode == aco_opcode::buffer_store_byte)
+ instr->opcode = aco_opcode::buffer_store_byte_d16_hi;
+ else if (instr->opcode == aco_opcode::buffer_store_short)
+ instr->opcode = aco_opcode::buffer_store_short_d16_hi;
+ else if (instr->opcode == aco_opcode::flat_store_byte)
+ instr->opcode = aco_opcode::flat_store_byte_d16_hi;
+ else if (instr->opcode == aco_opcode::flat_store_short)
+ instr->opcode = aco_opcode::flat_store_short_d16_hi;
+ else if (instr->opcode == aco_opcode::scratch_store_byte)
+ instr->opcode = aco_opcode::scratch_store_byte_d16_hi;
+ else if (instr->opcode == aco_opcode::scratch_store_short)
+ instr->opcode = aco_opcode::scratch_store_short_d16_hi;
+ else if (instr->opcode == aco_opcode::global_store_byte)
+ instr->opcode = aco_opcode::global_store_byte_d16_hi;
+ else if (instr->opcode == aco_opcode::global_store_short)
+ instr->opcode = aco_opcode::global_store_short_d16_hi;
+ else
+ unreachable("Something went wrong: Impossible register assignment.");
+ }
+}
+
+/* minimum_stride, bytes_written */
+std::pair<unsigned, unsigned> get_subdword_definition_info(Program *program, const aco_ptr<Instruction>& instr, RegClass rc)
+{
+ chip_class chip = program->chip_class;
+
+ if (instr->format == Format::PSEUDO && chip >= GFX8)
+ return std::make_pair(rc.bytes() % 2 == 0 ? 2 : 1, rc.bytes());
+ else if (instr->format == Format::PSEUDO)
+ return std::make_pair(4, rc.size() * 4u);
+
+ unsigned bytes_written = chip >= GFX10 ? rc.bytes() : 4u;
+ switch (instr->opcode) {
+ case aco_opcode::v_mad_f16:
+ case aco_opcode::v_mad_u16:
+ case aco_opcode::v_mad_i16:
+ case aco_opcode::v_fma_f16:
+ case aco_opcode::v_div_fixup_f16:
+ case aco_opcode::v_interp_p2_f16:
+ bytes_written = chip >= GFX9 ? rc.bytes() : 4u;
+ break;
+ default:
+ break;
+ }
+ bytes_written = MAX2(bytes_written, instr_info.definition_size[(int)instr->opcode] / 8u);
+
+ if (can_use_SDWA(chip, instr)) {
+ return std::make_pair(rc.bytes(), rc.bytes());
+ } else if (rc.bytes() == 2 && can_use_opsel(chip, instr->opcode, -1, 1)) {
+ return std::make_pair(2u, bytes_written);
+ }
+
+ switch (instr->opcode) {
+ case aco_opcode::buffer_load_ubyte_d16:
+ case aco_opcode::buffer_load_short_d16:
+ case aco_opcode::flat_load_ubyte_d16:
+ case aco_opcode::flat_load_short_d16:
+ case aco_opcode::scratch_load_ubyte_d16:
+ case aco_opcode::scratch_load_short_d16:
+ case aco_opcode::global_load_ubyte_d16:
+ case aco_opcode::global_load_short_d16:
+ case aco_opcode::ds_read_u8_d16:
+ case aco_opcode::ds_read_u16_d16:
+ if (chip >= GFX9 && !program->sram_ecc_enabled)
+ return std::make_pair(2u, 2u);
+ else
+ return std::make_pair(2u, 4u);
+ default:
+ break;
+ }
+
+ return std::make_pair(4u, bytes_written);
+}
+
+void add_subdword_definition(Program *program, aco_ptr<Instruction>& instr, unsigned idx, PhysReg reg, bool is_partial)
+{
+ RegClass rc = instr->definitions[idx].regClass();
+ chip_class chip = program->chip_class;
+
+ instr->definitions[idx].setFixed(reg);
+
+ if (instr->format == Format::PSEUDO) {
+ return;
+ } else if (can_use_SDWA(chip, instr)) {
+ if (reg.byte() || (is_partial && chip < GFX10))
+ convert_to_SDWA(chip, instr);
+ return;
+ } else if (reg.byte() && rc.bytes() == 2 && can_use_opsel(chip, instr->opcode, -1, reg.byte() / 2)) {
+ VOP3A_instruction *vop3 = static_cast<VOP3A_instruction *>(instr.get());
+ if (reg.byte() == 2)
+ vop3->opsel |= (1 << 3); /* dst in high half */
+ return;
+ }
+
+ if (reg.byte() == 2) {
+ if (instr->opcode == aco_opcode::buffer_load_ubyte_d16)
+ instr->opcode = aco_opcode::buffer_load_ubyte_d16_hi;
+ else if (instr->opcode == aco_opcode::buffer_load_short_d16)
+ instr->opcode = aco_opcode::buffer_load_short_d16_hi;
+ else if (instr->opcode == aco_opcode::flat_load_ubyte_d16)
+ instr->opcode = aco_opcode::flat_load_ubyte_d16_hi;
+ else if (instr->opcode == aco_opcode::flat_load_short_d16)
+ instr->opcode = aco_opcode::flat_load_short_d16_hi;
+ else if (instr->opcode == aco_opcode::scratch_load_ubyte_d16)
+ instr->opcode = aco_opcode::scratch_load_ubyte_d16_hi;
+ else if (instr->opcode == aco_opcode::scratch_load_short_d16)
+ instr->opcode = aco_opcode::scratch_load_short_d16_hi;
+ else if (instr->opcode == aco_opcode::global_load_ubyte_d16)
+ instr->opcode = aco_opcode::global_load_ubyte_d16_hi;
+ else if (instr->opcode == aco_opcode::global_load_short_d16)
+ instr->opcode = aco_opcode::global_load_short_d16_hi;
+ else if (instr->opcode == aco_opcode::ds_read_u8_d16)
+ instr->opcode = aco_opcode::ds_read_u8_d16_hi;
+ else if (instr->opcode == aco_opcode::ds_read_u16_d16)
+ instr->opcode = aco_opcode::ds_read_u16_d16_hi;
+ else
+ unreachable("Something went wrong: Impossible register assignment.");
+ }
+}
+
void adjust_max_used_regs(ra_ctx& ctx, RegClass rc, unsigned reg)
{
unsigned max_addressible_sgpr = ctx.program->sgpr_limit;
void update_renames(ra_ctx& ctx, RegisterFile& reg_file,
std::vector<std::pair<Operand, Definition>>& parallelcopies,
- aco_ptr<Instruction>& instr)
+ aco_ptr<Instruction>& instr, bool rename_not_killed_ops)
{
/* allocate id's and rename operands: this is done transparently here */
for (std::pair<Operand, Definition>& copy : parallelcopies) {
reg_file.fill(copy.second);
/* check if we moved an operand */
- for (Operand& op : instr->operands) {
+ bool first = true;
+ for (unsigned i = 0; i < instr->operands.size(); i++) {
+ Operand& op = instr->operands[i];
if (!op.isTemp())
continue;
if (op.tempId() == copy.first.tempId()) {
- bool omit_renaming = instr->opcode == aco_opcode::p_create_vector && !op.isKillBeforeDef();
+ bool omit_renaming = !rename_not_killed_ops && !op.isKillBeforeDef();
for (std::pair<Operand, Definition>& pc : parallelcopies) {
PhysReg def_reg = pc.second.physReg();
omit_renaming &= def_reg > copy.first.physReg() ?
(copy.first.physReg() + copy.first.size() <= def_reg.reg()) :
(def_reg + pc.second.size() <= copy.first.physReg().reg());
}
- if (omit_renaming)
+ if (omit_renaming) {
+ if (first)
+ op.setFirstKill(true);
+ else
+ op.setKill(true);
+ first = false;
continue;
+ }
op.setTemp(copy.second.getTemp());
op.setFixed(copy.second.physReg());
}
}
}
-bool instr_can_access_subdword(aco_ptr<Instruction>& instr)
-{
- return instr->isSDWA() || instr->format == Format::PSEUDO;
-}
-
std::pair<PhysReg, bool> get_reg_simple(ra_ctx& ctx,
RegisterFile& reg_file,
- uint32_t lb, uint32_t ub,
- uint32_t size, uint32_t stride,
- RegClass rc)
+ DefInfo info)
{
- if (rc.is_subdword()) {
- for (std::pair<uint32_t, std::array<uint32_t, 4>> entry : reg_file.subdword_regs) {
- assert(reg_file[entry.first] == 0xF0000000);
- if (lb > entry.first || entry.first >= ub)
- continue;
-
- for (unsigned i = 0; i < 4; i+= stride) {
- if (entry.second[i] != 0)
- continue;
+ uint32_t lb = info.lb;
+ uint32_t ub = info.ub;
+ uint32_t size = info.size;
+ uint32_t stride = info.rc.is_subdword() ? DIV_ROUND_UP(info.stride, 4) : info.stride;
+ RegClass rc = info.rc;
- bool reg_found = true;
- for (unsigned j = 1; reg_found && i + j < 4 && j < rc.bytes(); j++)
- reg_found &= entry.second[i + j] == 0;
+ if (stride == 1) {
- /* check neighboring reg if needed */
- reg_found &= (i <= 4 - rc.bytes() || reg_file[entry.first + 1] == 0);
- if (reg_found) {
- PhysReg res{entry.first};
- res.reg_b += i;
- return {res, true};
- }
- }
+ for (unsigned stride = 8; stride > 1; stride /= 2) {
+ if (size % stride)
+ continue;
+ info.stride = stride;
+ std::pair<PhysReg, bool> res = get_reg_simple(ctx, reg_file, info);
+ if (res.second)
+ return res;
}
- stride = 1; /* stride in full registers */
- }
-
- /* best fit algorithm: find the smallest gap to fit in the variable */
- if (stride == 1) {
+ /* best fit algorithm: find the smallest gap to fit in the variable */
unsigned best_pos = 0xFFFF;
unsigned gap_size = 0xFFFF;
- unsigned next_pos = 0xFFFF;
+ unsigned last_pos = 0xFFFF;
for (unsigned current_reg = lb; current_reg < ub; current_reg++) {
- if (reg_file[current_reg] != 0 || ctx.war_hint[current_reg]) {
- if (next_pos == 0xFFFF)
- continue;
- /* check if the variable fits */
- if (next_pos + size > current_reg) {
- next_pos = 0xFFFF;
+ if (reg_file[current_reg] == 0 && !ctx.war_hint[current_reg]) {
+ if (last_pos == 0xFFFF)
+ last_pos = current_reg;
+
+ /* stop searching after max_used_gpr */
+ if (current_reg == ctx.max_used_sgpr + 1 || current_reg == 256 + ctx.max_used_vgpr + 1)
+ break;
+ else
continue;
- }
+ }
- /* check if the tested gap is smaller */
- if (current_reg - next_pos < gap_size) {
- best_pos = next_pos;
- gap_size = current_reg - next_pos;
- }
- next_pos = 0xFFFF;
+ if (last_pos == 0xFFFF)
continue;
+
+ /* early return on exact matches */
+ if (last_pos + size == current_reg) {
+ adjust_max_used_regs(ctx, rc, last_pos);
+ return {PhysReg{last_pos}, true};
}
- if (next_pos == 0xFFFF)
- next_pos = current_reg;
+ /* check if it fits and the gap size is smaller */
+ if (last_pos + size < current_reg && current_reg - last_pos < gap_size) {
+ best_pos = last_pos;
+ gap_size = current_reg - last_pos;
+ }
+ last_pos = 0xFFFF;
}
/* final check */
- if (next_pos != 0xFFFF &&
- next_pos + size <= ub &&
- ub - next_pos < gap_size) {
- best_pos = next_pos;
- gap_size = ub - next_pos;
+ if (last_pos + size <= ub && ub - last_pos < gap_size) {
+ best_pos = last_pos;
+ gap_size = ub - last_pos;
}
- if (best_pos != 0xFFFF) {
- adjust_max_used_regs(ctx, rc, best_pos);
- return {PhysReg{best_pos}, true};
+
+ if (best_pos == 0xFFFF)
+ return {{}, false};
+
+ /* find best position within gap by leaving a good stride for other variables*/
+ unsigned buffer = gap_size - size;
+ if (buffer > 1) {
+ if (((best_pos + size) % 8 != 0 && (best_pos + buffer) % 8 == 0) ||
+ ((best_pos + size) % 4 != 0 && (best_pos + buffer) % 4 == 0) ||
+ ((best_pos + size) % 2 != 0 && (best_pos + buffer) % 2 == 0))
+ best_pos = best_pos + buffer;
}
- return {{}, false};
+
+ adjust_max_used_regs(ctx, rc, best_pos);
+ return {PhysReg{best_pos}, true};
}
bool found = false;
reg_lo += stride;
}
+ /* do this late because using the upper bytes of a register can require
+ * larger instruction encodings or copies
+ * TODO: don't do this in situations where it doesn't benefit */
+ if (rc.is_subdword()) {
+ for (std::pair<uint32_t, std::array<uint32_t, 4>> entry : reg_file.subdword_regs) {
+ assert(reg_file[entry.first] == 0xF0000000);
+ if (lb > entry.first || entry.first >= ub)
+ continue;
+
+ for (unsigned i = 0; i < 4; i+= info.stride) {
+ if (entry.second[i] != 0)
+ continue;
+
+ bool reg_found = true;
+ for (unsigned j = 1; reg_found && i + j < 4 && j < rc.bytes(); j++)
+ reg_found &= entry.second[i + j] == 0;
+
+ /* check neighboring reg if needed */
+ reg_found &= ((int)i <= 4 - (int)rc.bytes() || reg_file[entry.first + 1] == 0);
+ if (reg_found) {
+ PhysReg res{entry.first};
+ res.reg_b += i;
+ adjust_max_used_regs(ctx, rc, entry.first);
+ return {res, true};
+ }
+ }
+ }
+ }
+
return {{}, false};
}
for (std::set<std::pair<unsigned, unsigned>>::const_reverse_iterator it = vars.rbegin(); it != vars.rend(); ++it) {
unsigned id = it->second;
assignment& var = ctx.assignments[id];
- uint32_t size = var.rc.size();
- uint32_t stride = 1;
- if (var.rc.type() == RegType::sgpr) {
- if (size == 2)
- stride = 2;
- if (size > 3)
- stride = 4;
- }
+ DefInfo info = DefInfo(ctx, ctx.pseudo_dummy, var.rc, -1);
+ uint32_t size = info.size;
- /* check if this is a dead operand, then we can re-use the space from the definition */
+ /* check if this is a dead operand, then we can re-use the space from the definition
+ * also use the correct stride for sub-dword operands */
bool is_dead_operand = false;
- for (unsigned i = 0; !is_phi(instr) && !is_dead_operand && (i < instr->operands.size()); i++) {
- if (instr->operands[i].isTemp() && instr->operands[i].isKillBeforeDef() && instr->operands[i].tempId() == id)
- is_dead_operand = true;
+ for (unsigned i = 0; !is_phi(instr) && i < instr->operands.size(); i++) {
+ if (instr->operands[i].isTemp() && instr->operands[i].tempId() == id) {
+ if (instr->operands[i].isKillBeforeDef())
+ is_dead_operand = true;
+ info = DefInfo(ctx, instr, var.rc, i);
+ break;
+ }
}
std::pair<PhysReg, bool> res;
if (is_dead_operand) {
if (instr->opcode == aco_opcode::p_create_vector) {
- for (unsigned i = 0, offset = 0; i < instr->operands.size(); offset += instr->operands[i].size(), i++) {
+ PhysReg reg(def_reg_lo);
+ for (unsigned i = 0; i < instr->operands.size(); i++) {
if (instr->operands[i].isTemp() && instr->operands[i].tempId() == id) {
- for (unsigned j = 0; j < size; j++)
- assert(reg_file[def_reg_lo + offset + j] == 0);
- res = {PhysReg{def_reg_lo + offset}, true};
+ assert(!reg_file.test(reg, var.rc.bytes()));
+ res = {reg, !var.rc.is_subdword() || (reg.byte() % info.stride == 0)};
break;
}
+ reg.reg_b += instr->operands[i].bytes();
}
} else {
- res = get_reg_simple(ctx, reg_file, def_reg_lo, def_reg_hi + 1, size, stride, var.rc);
+ info.lb = def_reg_lo;
+ info.ub = def_reg_hi + 1;
+ res = get_reg_simple(ctx, reg_file, info);
}
} else {
- res = get_reg_simple(ctx, reg_file, lb, def_reg_lo, size, stride, var.rc);
- if (!res.second) {
- unsigned lb = (def_reg_hi + stride) & ~(stride - 1);
- res = get_reg_simple(ctx, reg_file, lb, ub, size, stride, var.rc);
+ info.lb = lb;
+ info.ub = MIN2(def_reg_lo, ub);
+ res = get_reg_simple(ctx, reg_file, info);
+ if (!res.second && def_reg_hi < ub) {
+ info.lb = (def_reg_hi + info.stride) & ~(info.stride - 1);
+ info.ub = ub;
+ res = get_reg_simple(ctx, reg_file, info);
}
}
if (res.second) {
/* mark the area as blocked */
- reg_file.block(res.first, var.rc.bytes());
+ reg_file.block(res.first, var.rc);
/* create parallelcopy pair (without definition id) */
Temp tmp = Temp(id, var.rc);
/* we use a sliding window to find potential positions */
unsigned reg_lo = lb;
unsigned reg_hi = lb + size - 1;
+ unsigned stride = var.rc.is_subdword() ? 1 : info.stride;
for (reg_lo = lb, reg_hi = lb + size - 1; reg_hi < ub; reg_lo += stride, reg_hi += stride) {
if (!is_dead_operand && ((reg_lo >= def_reg_lo && reg_lo <= def_reg_hi) ||
(reg_hi >= def_reg_lo && reg_hi <= def_reg_hi)))
std::set<std::pair<unsigned, unsigned>> new_vars = collect_vars(ctx, reg_file, PhysReg{reg_lo}, size);
/* mark the area as blocked */
- reg_file.block(PhysReg{reg_lo}, size * 4);
+ reg_file.block(PhysReg{reg_lo}, var.rc);
if (!get_regs_for_copies(ctx, reg_file, parallelcopies, new_vars, lb, ub, instr, def_reg_lo, def_reg_hi))
return false;
std::pair<PhysReg, bool> get_reg_impl(ra_ctx& ctx,
RegisterFile& reg_file,
std::vector<std::pair<Operand, Definition>>& parallelcopies,
- uint32_t lb, uint32_t ub,
- uint32_t size, uint32_t stride,
- RegClass rc,
+ DefInfo info,
aco_ptr<Instruction>& instr)
{
+ uint32_t lb = info.lb;
+ uint32_t ub = info.ub;
+ uint32_t size = info.size;
+ uint32_t stride = info.stride;
+ RegClass rc = info.rc;
+
/* check how many free regs we have */
unsigned regs_free = reg_file.count_zero(PhysReg{lb}, ub-lb);
if (instr->operands[j].isTemp() &&
instr->operands[j].isFirstKillBeforeDef() &&
instr->operands[j].physReg() >= lb &&
- instr->operands[j].physReg() < ub) {
+ instr->operands[j].physReg() < ub &&
+ !reg_file.test(instr->operands[j].physReg(), instr->operands[j].bytes())) {
assert(instr->operands[j].isFixed());
- assert(!reg_file.test(instr->operands[j].physReg(), instr->operands[j].bytes()));
- reg_file.block(instr->operands[j].physReg(), instr->operands[j].bytes());
+ reg_file.block(instr->operands[j].physReg(), instr->operands[j].regClass());
killed_ops += instr->operands[j].getTemp().size();
}
}
unsigned reg_hi = lb + size - 1;
for (reg_lo = lb, reg_hi = lb + size - 1; reg_hi < ub; reg_lo += stride, reg_hi += stride) {
/* first check the edges: this is what we have to fix to allow for num_moves > size */
- if (reg_lo > lb && reg_file[reg_lo] != 0 && reg_file[reg_lo] == reg_file[reg_lo - 1])
+ if (reg_lo > lb && reg_file[reg_lo] != 0 && reg_file.get_id(PhysReg(reg_lo)) == reg_file.get_id(PhysReg(reg_lo).advance(-1)))
continue;
- if (reg_hi < ub - 1 && reg_file[reg_hi] != 0 && reg_file[reg_hi] == reg_file[reg_hi + 1])
+ if (reg_hi < ub - 1 && reg_file[reg_hi] != 0 && reg_file.get_id(PhysReg(reg_hi).advance(3)) == reg_file.get_id(PhysReg(reg_hi).advance(4)))
continue;
/* second, check that we have at most k=num_moves elements in the window
std::set<std::pair<unsigned, unsigned>> vars = collect_vars(ctx, reg_file, PhysReg{best_pos}, size);
if (instr->opcode == aco_opcode::p_create_vector) {
- /* move killed operands which aren't yet at the correct position */
- for (unsigned i = 0, offset = 0; i < instr->operands.size(); offset += instr->operands[i].size(), i++) {
- if (instr->operands[i].isTemp() && instr->operands[i].isFirstKillBeforeDef() &&
- instr->operands[i].getTemp().type() == rc.type()) {
-
- if (instr->operands[i].physReg() != best_pos + offset) {
- vars.emplace(instr->operands[i].bytes(), instr->operands[i].tempId());
- reg_file.clear(instr->operands[i]);
+ /* move killed operands which aren't yet at the correct position (GFX9+)
+ * or which are in the definition space */
+ PhysReg reg = PhysReg{best_pos};
+ for (Operand& op : instr->operands) {
+ if (op.isTemp() && op.isFirstKillBeforeDef() &&
+ op.getTemp().type() == rc.type()) {
+ if (op.physReg() != reg &&
+ (ctx.program->chip_class >= GFX9 ||
+ (op.physReg().advance(op.bytes()) > PhysReg{best_pos} &&
+ op.physReg() < PhysReg{best_pos + size}))) {
+ vars.emplace(op.bytes(), op.tempId());
+ reg_file.clear(op);
} else {
- reg_file.fill(instr->operands[i]);
+ reg_file.fill(op);
}
}
+ reg.reg_b += op.bytes();
}
- } else {
- /* re-enable the killed operands */
- for (unsigned j = 0; !is_phi(instr) && j < instr->operands.size(); j++) {
- if (instr->operands[j].isTemp() && instr->operands[j].isFirstKill())
- reg_file.fill(instr->operands[j]);
+ } else if (!is_phi(instr)) {
+ /* re-enable killed operands */
+ for (Operand& op : instr->operands) {
+ if (op.isTemp() && op.isFirstKillBeforeDef())
+ reg_file.fill(op);
}
}
/* we set the definition regs == 0. the actual caller is responsible for correct setting */
reg_file.clear(PhysReg{best_pos}, rc);
- update_renames(ctx, reg_file, parallelcopies, instr);
+ update_renames(ctx, reg_file, parallelcopies, instr, instr->opcode != aco_opcode::p_create_vector);
/* remove killed operands from reg_file once again */
for (unsigned i = 0; !is_phi(instr) && i < instr->operands.size(); i++) {
return {PhysReg{best_pos}, true};
}
-PhysReg get_reg(ra_ctx& ctx,
- RegisterFile& reg_file,
- RegClass rc,
- std::vector<std::pair<Operand, Definition>>& parallelcopies,
- aco_ptr<Instruction>& instr)
+bool get_reg_specified(ra_ctx& ctx,
+ RegisterFile& reg_file,
+ RegClass rc,
+ std::vector<std::pair<Operand, Definition>>& parallelcopies,
+ aco_ptr<Instruction>& instr,
+ PhysReg reg)
{
+ std::pair<unsigned, unsigned> sdw_def_info;
+ if (rc.is_subdword())
+ sdw_def_info = get_subdword_definition_info(ctx.program, instr, rc);
+
+ if (rc.is_subdword() && reg.byte() % sdw_def_info.first)
+ return false;
+ if (!rc.is_subdword() && reg.byte())
+ return false;
+
uint32_t size = rc.size();
uint32_t stride = 1;
uint32_t lb, ub;
+
if (rc.type() == RegType::vgpr) {
lb = 256;
ub = 256 + ctx.program->max_reg_demand.vgpr;
} else {
- lb = 0;
- ub = ctx.program->max_reg_demand.sgpr;
if (size == 2)
stride = 2;
else if (size >= 4)
stride = 4;
+ if (reg % stride != 0)
+ return false;
+ lb = 0;
+ ub = ctx.program->max_reg_demand.sgpr;
}
+ uint32_t reg_lo = reg.reg();
+ uint32_t reg_hi = reg + (size - 1);
+
+ if (reg_lo < lb || reg_hi >= ub || reg_lo > reg_hi)
+ return false;
+
if (rc.is_subdword()) {
- /* stride in bytes */
- if(!instr_can_access_subdword(instr))
- stride = 4;
- else if (rc.bytes() % 4 == 0)
- stride = 4;
- else if (rc.bytes() % 2 == 0)
- stride = 2;
+ PhysReg test_reg;
+ test_reg.reg_b = reg.reg_b & ~(sdw_def_info.second - 1);
+ if (reg_file.test(test_reg, sdw_def_info.second))
+ return false;
+ } else {
+ if (reg_file.test(reg, rc.bytes()))
+ return false;
}
- std::pair<PhysReg, bool> res = {{}, false};
+ adjust_max_used_regs(ctx, rc, reg_lo);
+ return true;
+}
+
+PhysReg get_reg(ra_ctx& ctx,
+ RegisterFile& reg_file,
+ Temp temp,
+ std::vector<std::pair<Operand, Definition>>& parallelcopies,
+ aco_ptr<Instruction>& instr,
+ int operand_index=-1)
+{
+ auto split_vec = ctx.split_vectors.find(temp.id());
+ if (split_vec != ctx.split_vectors.end()) {
+ unsigned offset = 0;
+ for (Definition def : split_vec->second->definitions) {
+ auto affinity_it = ctx.affinities.find(def.tempId());
+ if (affinity_it != ctx.affinities.end() && ctx.assignments[affinity_it->second].assigned) {
+ PhysReg reg = ctx.assignments[affinity_it->second].reg;
+ reg.reg_b -= offset;
+ if (get_reg_specified(ctx, reg_file, temp.regClass(), parallelcopies, instr, reg))
+ return reg;
+ }
+ offset += def.bytes();
+ }
+ }
+
+ if (ctx.affinities.find(temp.id()) != ctx.affinities.end() &&
+ ctx.assignments[ctx.affinities[temp.id()]].assigned) {
+ PhysReg reg = ctx.assignments[ctx.affinities[temp.id()]].reg;
+ if (get_reg_specified(ctx, reg_file, temp.regClass(), parallelcopies, instr, reg))
+ return reg;
+ }
+
+ if (ctx.vectors.find(temp.id()) != ctx.vectors.end()) {
+ Instruction* vec = ctx.vectors[temp.id()];
+ unsigned byte_offset = 0;
+ for (const Operand& op : vec->operands) {
+ if (op.isTemp() && op.tempId() == temp.id())
+ break;
+ else
+ byte_offset += op.bytes();
+ }
+ unsigned k = 0;
+ for (const Operand& op : vec->operands) {
+ if (op.isTemp() &&
+ op.tempId() != temp.id() &&
+ op.getTemp().type() == temp.type() &&
+ ctx.assignments[op.tempId()].assigned) {
+ PhysReg reg = ctx.assignments[op.tempId()].reg;
+ reg.reg_b += (byte_offset - k);
+ if (get_reg_specified(ctx, reg_file, temp.regClass(), parallelcopies, instr, reg))
+ return reg;
+ }
+ k += op.bytes();
+ }
+
+ DefInfo info(ctx, ctx.pseudo_dummy, vec->definitions[0].regClass(), -1);
+ std::pair<PhysReg, bool> res = get_reg_simple(ctx, reg_file, info);
+ PhysReg reg = res.first;
+ if (res.second) {
+ reg.reg_b += byte_offset;
+ /* make sure to only use byte offset if the instruction supports it */
+ if (get_reg_specified(ctx, reg_file, temp.regClass(), parallelcopies, instr, reg))
+ return reg;
+ }
+ }
+
+ DefInfo info(ctx, instr, temp.regClass(), operand_index);
+
/* try to find space without live-range splits */
- if (rc.type() == RegType::vgpr && (size == 4 || size == 8))
- res = get_reg_simple(ctx, reg_file, lb, ub, size, 4, rc);
- if (!res.second)
- res = get_reg_simple(ctx, reg_file, lb, ub, size, stride, rc);
+ std::pair<PhysReg, bool> res = get_reg_simple(ctx, reg_file, info);
+
if (res.second)
return res.first;
/* try to find space with live-range splits */
- res = get_reg_impl(ctx, reg_file, parallelcopies, lb, ub, size, stride, rc, instr);
+ res = get_reg_impl(ctx, reg_file, parallelcopies, info, instr);
if (res.second)
return res.first;
/* We should only fail here because keeping under the limit would require
* too many moves. */
- assert(reg_file.count_zero(PhysReg{lb}, ub-lb) >= size);
+ assert(reg_file.count_zero(PhysReg{info.lb}, info.ub-info.lb) >= info.size);
uint16_t max_addressible_sgpr = ctx.program->sgpr_limit;
uint16_t max_addressible_vgpr = ctx.program->vgpr_limit;
- if (rc.type() == RegType::vgpr && ctx.program->max_reg_demand.vgpr < max_addressible_vgpr) {
+ if (info.rc.type() == RegType::vgpr && ctx.program->max_reg_demand.vgpr < max_addressible_vgpr) {
update_vgpr_sgpr_demand(ctx.program, RegisterDemand(ctx.program->max_reg_demand.vgpr + 1, ctx.program->max_reg_demand.sgpr));
- return get_reg(ctx, reg_file, rc, parallelcopies, instr);
- } else if (rc.type() == RegType::sgpr && ctx.program->max_reg_demand.sgpr < max_addressible_sgpr) {
+ return get_reg(ctx, reg_file, temp, parallelcopies, instr, operand_index);
+ } else if (info.rc.type() == RegType::sgpr && ctx.program->max_reg_demand.sgpr < max_addressible_sgpr) {
update_vgpr_sgpr_demand(ctx.program, RegisterDemand(ctx.program->max_reg_demand.vgpr, ctx.program->max_reg_demand.sgpr + 1));
- return get_reg(ctx, reg_file, rc, parallelcopies, instr);
+ return get_reg(ctx, reg_file, temp, parallelcopies, instr, operand_index);
}
//FIXME: if nothing helps, shift-rotate the registers to make space
- unreachable("did not find a register");
+ fprintf(stderr, "ACO: failed to allocate registers during shader compilation\n");
+ abort();
}
-
-std::pair<PhysReg, bool> get_reg_vec(ra_ctx& ctx,
- RegisterFile& reg_file,
- RegClass rc)
-{
- uint32_t size = rc.size();
- uint32_t stride = 1;
- uint32_t lb, ub;
- if (rc.type() == RegType::vgpr) {
- lb = 256;
- ub = 256 + ctx.program->max_reg_demand.vgpr;
- } else {
- lb = 0;
- ub = ctx.program->max_reg_demand.sgpr;
- if (size == 2)
- stride = 2;
- else if (size >= 4)
- stride = 4;
- }
- return get_reg_simple(ctx, reg_file, lb, ub, size, stride, rc);
-}
-
-
PhysReg get_reg_create_vector(ra_ctx& ctx,
RegisterFile& reg_file,
- RegClass rc,
+ Temp temp,
std::vector<std::pair<Operand, Definition>>& parallelcopies,
aco_ptr<Instruction>& instr)
{
+ RegClass rc = temp.regClass();
/* create_vector instructions have different costs w.r.t. register coalescing */
uint32_t size = rc.size();
+ uint32_t bytes = rc.bytes();
uint32_t stride = 1;
uint32_t lb, ub;
if (rc.type() == RegType::vgpr) {
stride = 4;
}
+ //TODO: improve p_create_vector for sub-dword vectors
+
unsigned best_pos = -1;
unsigned num_moves = 0xFF;
bool best_war_hint = true;
/* test for each operand which definition placement causes the least shuffle instructions */
- for (unsigned i = 0, offset = 0; i < instr->operands.size(); offset += instr->operands[i].size(), i++) {
+ for (unsigned i = 0, offset = 0; i < instr->operands.size(); offset += instr->operands[i].bytes(), i++) {
// TODO: think about, if we can alias live operands on the same register
if (!instr->operands[i].isTemp() || !instr->operands[i].isKillBeforeDef() || instr->operands[i].getTemp().type() != rc.type())
continue;
- if (offset > instr->operands[i].physReg())
+ if (offset > instr->operands[i].physReg().reg_b)
continue;
- unsigned reg_lo = instr->operands[i].physReg() - offset;
+ unsigned reg_lo = instr->operands[i].physReg().reg_b - offset;
+ if (reg_lo % 4)
+ continue;
+ reg_lo /= 4;
unsigned reg_hi = reg_lo + size - 1;
unsigned k = 0;
// TODO: this can be improved */
if (reg_lo < lb || reg_hi >= ub || reg_lo % stride != 0)
continue;
- if (reg_lo > lb && reg_file[reg_lo] != 0 && reg_file[reg_lo] == reg_file[reg_lo - 1])
+ if (reg_lo > lb && reg_file[reg_lo] != 0 && reg_file.get_id(PhysReg(reg_lo)) == reg_file.get_id(PhysReg(reg_lo).advance(-1)))
continue;
- if (reg_hi < ub - 1 && reg_file[reg_hi] != 0 && reg_file[reg_hi] == reg_file[reg_hi + 1])
+ if (reg_hi < ub - 1 && reg_file[reg_hi] != 0 && reg_file.get_id(PhysReg(reg_hi).advance(3)) == reg_file.get_id(PhysReg(reg_hi).advance(4)))
continue;
/* count variables to be moved and check war_hint */
bool linear_vgpr = false;
for (unsigned j = reg_lo; j <= reg_hi && !linear_vgpr; j++) {
if (reg_file[j] != 0) {
- k++;
- /* we cannot split live ranges of linear vgprs */
- if (ctx.assignments[reg_file[j]].rc & (1 << 6))
- linear_vgpr = true;
+ if (reg_file[j] == 0xF0000000) {
+ PhysReg reg;
+ reg.reg_b = j * 4;
+ unsigned bytes_left = bytes - (j - reg_lo) * 4;
+ for (unsigned k = 0; k < MIN2(bytes_left, 4); k++, reg.reg_b++)
+ k += reg_file.test(reg, 1);
+ } else {
+ k += 4;
+ /* we cannot split live ranges of linear vgprs */
+ if (ctx.assignments[reg_file[j]].rc & (1 << 6))
+ linear_vgpr = true;
+ }
}
war_hint |= ctx.war_hint[j];
}
continue;
/* count operands in wrong positions */
- for (unsigned j = 0, offset = 0; j < instr->operands.size(); offset += instr->operands[j].size(), j++) {
+ for (unsigned j = 0, offset = 0; j < instr->operands.size(); offset += instr->operands[j].bytes(), j++) {
if (j == i ||
!instr->operands[j].isTemp() ||
instr->operands[j].getTemp().type() != rc.type())
continue;
- if (instr->operands[j].physReg() != reg_lo + offset)
- k += instr->operands[j].size();
+ if (instr->operands[j].physReg().reg_b != reg_lo * 4 + offset)
+ k += instr->operands[j].bytes();
}
bool aligned = rc == RegClass::v4 && reg_lo % 4 == 0;
if (k > num_moves || (!aligned && k == num_moves))
best_war_hint = war_hint;
}
- if (num_moves >= size)
- return get_reg(ctx, reg_file, rc, parallelcopies, instr);
-
- /* collect variables to be moved */
- std::set<std::pair<unsigned, unsigned>> vars = collect_vars(ctx, reg_file, PhysReg{best_pos}, size);
+ if (num_moves >= bytes)
+ return get_reg(ctx, reg_file, temp, parallelcopies, instr);
- /* move killed operands which aren't yet at the correct position */
- for (unsigned i = 0, offset = 0; i < instr->operands.size(); offset += instr->operands[i].size(), i++) {
+ /* re-enable killed operands which are in the wrong position */
+ for (unsigned i = 0, offset = 0; i < instr->operands.size(); offset += instr->operands[i].bytes(), i++) {
if (instr->operands[i].isTemp() &&
instr->operands[i].isFirstKillBeforeDef() &&
- instr->operands[i].getTemp().type() == rc.type() &&
- instr->operands[i].physReg() != best_pos + offset)
- vars.emplace(instr->operands[i].bytes(), instr->operands[i].tempId());
+ instr->operands[i].physReg().reg_b != best_pos * 4 + offset)
+ reg_file.fill(instr->operands[i]);
}
+ /* collect variables to be moved */
+ std::set<std::pair<unsigned, unsigned>> vars = collect_vars(ctx, reg_file, PhysReg{best_pos}, size);
+
+ /* GFX9+: move killed operands which aren't yet at the correct position
+ * Moving all killed operands generally leads to more register swaps.
+ * This is only done on GFX9+ because of the cheap v_swap instruction.
+ */
+ if (ctx.program->chip_class >= GFX9) {
+ for (unsigned i = 0, offset = 0; i < instr->operands.size(); offset += instr->operands[i].bytes(), i++) {
+ if (instr->operands[i].isTemp() &&
+ instr->operands[i].isFirstKillBeforeDef() &&
+ instr->operands[i].getTemp().type() == rc.type() &&
+ instr->operands[i].physReg().reg_b != best_pos * 4 + offset) {
+ vars.emplace(instr->operands[i].bytes(), instr->operands[i].tempId());
+ reg_file.clear(instr->operands[i]);
+ }
+ }
+ }
ASSERTED bool success = false;
success = get_regs_for_copies(ctx, reg_file, parallelcopies, vars, lb, ub, instr, best_pos, best_pos + size - 1);
assert(success);
- update_renames(ctx, reg_file, parallelcopies, instr);
+ update_renames(ctx, reg_file, parallelcopies, instr, false);
adjust_max_used_regs(ctx, rc, best_pos);
- return PhysReg{best_pos};
-}
-bool get_reg_specified(ra_ctx& ctx,
- RegisterFile& reg_file,
- RegClass rc,
- std::vector<std::pair<Operand, Definition>>& parallelcopies,
- aco_ptr<Instruction>& instr,
- PhysReg reg)
-{
- uint32_t size = rc.size();
- uint32_t stride = 1;
- uint32_t lb, ub;
-
- if (rc.type() == RegType::vgpr) {
- lb = 256;
- ub = 256 + ctx.program->max_reg_demand.vgpr;
- } else {
- if (size == 2)
- stride = 2;
- else if (size >= 4)
- stride = 4;
- if (reg % stride != 0)
- return false;
- lb = 0;
- ub = ctx.program->max_reg_demand.sgpr;
+ /* remove killed operands from reg_file once again */
+ for (unsigned i = 0; i < instr->operands.size(); i++) {
+ if (!instr->operands[i].isTemp() || !instr->operands[i].isFixed())
+ continue;
+ assert(!instr->operands[i].isUndefined());
+ if (instr->operands[i].isFirstKillBeforeDef())
+ reg_file.clear(instr->operands[i]);
}
- if (rc.is_subdword() && reg.byte() && !instr_can_access_subdword(instr))
- return false;
-
- uint32_t reg_lo = reg.reg();
- uint32_t reg_hi = reg + (size - 1);
-
- if (reg_lo < lb || reg_hi >= ub || reg_lo > reg_hi)
- return false;
-
- if (reg_file.test(reg, rc.bytes()))
- return false;
-
- adjust_max_used_regs(ctx, rc, reg_lo);
- return true;
+ return PhysReg{best_pos};
}
void handle_pseudo(ra_ctx& ctx,
}
/* if all operands are constant, no need to care either */
bool reads_sgpr = false;
+ bool reads_subdword = false;
for (Operand& op : instr->operands) {
if (op.isTemp() && op.getTemp().type() == RegType::sgpr) {
reads_sgpr = true;
break;
}
+ if (op.isTemp() && op.regClass().is_subdword())
+ reads_subdword = true;
}
- if (!(writes_sgpr && reads_sgpr))
+ bool needs_scratch_reg = (writes_sgpr && reads_sgpr) ||
+ (ctx.program->chip_class <= GFX7 && reads_subdword);
+ if (!needs_scratch_reg)
return;
Pseudo_instruction *pi = (Pseudo_instruction *)instr;
reg = ctx.max_used_sgpr + 1;
for (; reg < ctx.program->max_reg_demand.sgpr && reg_file[reg]; reg++)
;
- assert(reg < ctx.program->max_reg_demand.sgpr);
+ if (reg == ctx.program->max_reg_demand.sgpr) {
+ assert(reads_subdword && reg_file[m0] == 0);
+ reg = m0;
+ }
}
adjust_max_used_regs(ctx, s1, reg);
}
}
-bool operand_can_use_reg(aco_ptr<Instruction>& instr, unsigned idx, PhysReg reg)
+bool operand_can_use_reg(chip_class chip, aco_ptr<Instruction>& instr, unsigned idx, PhysReg reg, RegClass rc)
{
- if (!instr_can_access_subdword(instr) && reg.byte())
- return false;
+ if (instr->operands[idx].isFixed())
+ return instr->operands[idx].physReg() == reg;
+
+ if (reg.byte()) {
+ unsigned stride = get_subdword_operand_stride(chip, instr, idx, rc);
+ if (reg.byte() % stride)
+ return false;
+ }
switch (instr->format) {
case Format::SMEM:
}
}
-} /* end namespace */
-
-
-void register_allocation(Program *program, std::vector<TempSet>& live_out_per_block)
+void get_reg_for_operand(ra_ctx& ctx, RegisterFile& register_file,
+ std::vector<std::pair<Operand, Definition>>& parallelcopy,
+ aco_ptr<Instruction>& instr, Operand& operand, unsigned operand_index)
{
- ra_ctx ctx(program);
-
- std::function<Temp(Temp,unsigned)> read_variable;
- std::function<Temp(Temp,Block*)> handle_live_in;
- std::function<void(Temp)> try_remove_trivial_phi;
+ /* check if the operand is fixed */
+ PhysReg dst;
+ if (operand.isFixed()) {
+ assert(operand.physReg() != ctx.assignments[operand.tempId()].reg);
+
+ /* check if target reg is blocked, and move away the blocking var */
+ if (register_file[operand.physReg().reg()]) {
+ assert(register_file[operand.physReg()] != 0xF0000000);
+ uint32_t blocking_id = register_file[operand.physReg().reg()];
+ RegClass rc = ctx.assignments[blocking_id].rc;
+ Operand pc_op = Operand(Temp{blocking_id, rc});
+ pc_op.setFixed(operand.physReg());
+
+ /* find free reg */
+ PhysReg reg = get_reg(ctx, register_file, pc_op.getTemp(), parallelcopy, ctx.pseudo_dummy);
+ Definition pc_def = Definition(PhysReg{reg}, pc_op.regClass());
+ register_file.clear(pc_op);
+ parallelcopy.emplace_back(pc_op, pc_def);
+ }
+ dst = operand.physReg();
- read_variable = [&](Temp val, unsigned block_idx) -> Temp {
- std::unordered_map<unsigned, Temp>::iterator it = ctx.renames[block_idx].find(val.id());
- if (it == ctx.renames[block_idx].end())
- return val;
- else
- return it->second;
- };
+ } else {
+ dst = get_reg(ctx, register_file, operand.getTemp(), parallelcopy, instr, operand_index);
+ }
- handle_live_in = [&](Temp val, Block *block) -> Temp {
- std::vector<unsigned>& preds = val.is_linear() ? block->linear_preds : block->logical_preds;
- if (preds.size() == 0 || val.regClass() == val.regClass().as_linear())
- return val;
+ Operand pc_op = operand;
+ pc_op.setFixed(ctx.assignments[operand.tempId()].reg);
+ Definition pc_def = Definition(dst, pc_op.regClass());
+ register_file.clear(pc_op);
+ parallelcopy.emplace_back(pc_op, pc_def);
+ update_renames(ctx, register_file, parallelcopy, instr, true);
+}
- assert(preds.size() > 0);
+Temp read_variable(ra_ctx& ctx, Temp val, unsigned block_idx)
+{
+ std::unordered_map<unsigned, Temp>::iterator it = ctx.renames[block_idx].find(val.id());
+ if (it == ctx.renames[block_idx].end())
+ return val;
+ else
+ return it->second;
+}
- Temp new_val;
- if (!ctx.sealed[block->index]) {
- /* consider rename from already processed predecessor */
- Temp tmp = read_variable(val, preds[0]);
+Temp handle_live_in(ra_ctx& ctx, Temp val, Block* block)
+{
+ std::vector<unsigned>& preds = val.is_linear() ? block->linear_preds : block->logical_preds;
+ if (preds.size() == 0 || val.regClass() == val.regClass().as_linear())
+ return val;
+
+ assert(preds.size() > 0);
+
+ Temp new_val;
+ if (!ctx.sealed[block->index]) {
+ /* consider rename from already processed predecessor */
+ Temp tmp = read_variable(ctx, val, preds[0]);
+
+ /* if the block is not sealed yet, we create an incomplete phi (which might later get removed again) */
+ new_val = Temp{ctx.program->allocateId(), val.regClass()};
+ ctx.assignments.emplace_back();
+ aco_opcode opcode = val.is_linear() ? aco_opcode::p_linear_phi : aco_opcode::p_phi;
+ aco_ptr<Instruction> phi{create_instruction<Pseudo_instruction>(opcode, Format::PSEUDO, preds.size(), 1)};
+ phi->definitions[0] = Definition(new_val);
+ for (unsigned i = 0; i < preds.size(); i++)
+ phi->operands[i] = Operand(val);
+ if (tmp.regClass() == new_val.regClass())
+ ctx.affinities[new_val.id()] = tmp.id();
+
+ ctx.phi_map.emplace(new_val.id(), phi_info{phi.get(), block->index});
+ ctx.incomplete_phis[block->index].emplace_back(phi.get());
+ block->instructions.insert(block->instructions.begin(), std::move(phi));
+
+ } else if (preds.size() == 1) {
+ /* if the block has only one predecessor, just look there for the name */
+ new_val = read_variable(ctx, val, preds[0]);
+ } else {
+ /* there are multiple predecessors and the block is sealed */
+ Temp ops[preds.size()];
+
+ /* get the rename from each predecessor and check if they are the same */
+ bool needs_phi = false;
+ for (unsigned i = 0; i < preds.size(); i++) {
+ ops[i] = read_variable(ctx, val, preds[i]);
+ if (i == 0)
+ new_val = ops[i];
+ else
+ needs_phi |= !(new_val == ops[i]);
+ }
- /* if the block is not sealed yet, we create an incomplete phi (which might later get removed again) */
- new_val = Temp{program->allocateId(), val.regClass()};
- ctx.assignments.emplace_back();
+ if (needs_phi) {
+ /* the variable has been renamed differently in the predecessors: we need to insert a phi */
aco_opcode opcode = val.is_linear() ? aco_opcode::p_linear_phi : aco_opcode::p_phi;
aco_ptr<Instruction> phi{create_instruction<Pseudo_instruction>(opcode, Format::PSEUDO, preds.size(), 1)};
+ new_val = Temp{ctx.program->allocateId(), val.regClass()};
phi->definitions[0] = Definition(new_val);
- for (unsigned i = 0; i < preds.size(); i++)
- phi->operands[i] = Operand(val);
- if (tmp.regClass() == new_val.regClass())
- ctx.affinities[new_val.id()] = tmp.id();
-
+ for (unsigned i = 0; i < preds.size(); i++) {
+ phi->operands[i] = Operand(ops[i]);
+ phi->operands[i].setFixed(ctx.assignments[ops[i].id()].reg);
+ if (ops[i].regClass() == new_val.regClass())
+ ctx.affinities[new_val.id()] = ops[i].id();
+ }
+ ctx.assignments.emplace_back();
+ assert(ctx.assignments.size() == ctx.program->peekAllocationId());
ctx.phi_map.emplace(new_val.id(), phi_info{phi.get(), block->index});
- ctx.incomplete_phis[block->index].emplace_back(phi.get());
block->instructions.insert(block->instructions.begin(), std::move(phi));
+ }
+ }
- } else if (preds.size() == 1) {
- /* if the block has only one predecessor, just look there for the name */
- new_val = read_variable(val, preds[0]);
- } else {
- /* there are multiple predecessors and the block is sealed */
- Temp ops[preds.size()];
-
- /* get the rename from each predecessor and check if they are the same */
- bool needs_phi = false;
- for (unsigned i = 0; i < preds.size(); i++) {
- ops[i] = read_variable(val, preds[i]);
- if (i == 0)
- new_val = ops[i];
- else
- needs_phi |= !(new_val == ops[i]);
- }
+ if (new_val != val) {
+ ctx.renames[block->index][val.id()] = new_val;
+ ctx.orig_names[new_val.id()] = val;
+ }
+ return new_val;
+}
- if (needs_phi) {
- /* the variable has been renamed differently in the predecessors: we need to insert a phi */
- aco_opcode opcode = val.is_linear() ? aco_opcode::p_linear_phi : aco_opcode::p_phi;
- aco_ptr<Instruction> phi{create_instruction<Pseudo_instruction>(opcode, Format::PSEUDO, preds.size(), 1)};
- new_val = Temp{program->allocateId(), val.regClass()};
- phi->definitions[0] = Definition(new_val);
- for (unsigned i = 0; i < preds.size(); i++) {
- phi->operands[i] = Operand(ops[i]);
- phi->operands[i].setFixed(ctx.assignments[ops[i].id()].reg);
- if (ops[i].regClass() == new_val.regClass())
- ctx.affinities[new_val.id()] = ops[i].id();
- }
- ctx.assignments.emplace_back();
- assert(ctx.assignments.size() == ctx.program->peekAllocationId());
- ctx.phi_map.emplace(new_val.id(), phi_info{phi.get(), block->index});
- block->instructions.insert(block->instructions.begin(), std::move(phi));
- }
- }
+void try_remove_trivial_phi(ra_ctx& ctx, Temp temp)
+{
+ std::unordered_map<unsigned, phi_info>::iterator info = ctx.phi_map.find(temp.id());
- if (new_val != val) {
- ctx.renames[block->index][val.id()] = new_val;
- ctx.orig_names[new_val.id()] = val;
- }
- return new_val;
- };
+ if (info == ctx.phi_map.end() || !ctx.sealed[info->second.block_idx])
+ return;
- try_remove_trivial_phi = [&] (Temp temp) -> void {
- std::unordered_map<unsigned, phi_info>::iterator info = ctx.phi_map.find(temp.id());
+ assert(info->second.block_idx != 0);
+ Instruction* phi = info->second.phi;
+ Temp same = Temp();
+ Definition def = phi->definitions[0];
- if (info == ctx.phi_map.end() || !ctx.sealed[info->second.block_idx])
+ /* a phi node is trivial if all operands are the same as the definition of the phi */
+ for (const Operand& op : phi->operands) {
+ const Temp t = op.getTemp();
+ if (t == same || t == def.getTemp()) {
+ assert(t == same || op.physReg() == def.physReg());
+ continue;
+ }
+ if (same != Temp())
return;
- assert(info->second.block_idx != 0);
- Instruction* phi = info->second.phi;
- Temp same = Temp();
- Definition def = phi->definitions[0];
-
- /* a phi node is trivial if all operands are the same as the definition of the phi */
- for (const Operand& op : phi->operands) {
- const Temp t = op.getTemp();
- if (t == same || t == def.getTemp()) {
- assert(t == same || op.physReg() == def.physReg());
+ same = t;
+ }
+ assert(same != Temp() || same == def.getTemp());
+
+ /* reroute all uses to same and remove phi */
+ std::vector<Temp> phi_users;
+ std::unordered_map<unsigned, phi_info>::iterator same_phi_info = ctx.phi_map.find(same.id());
+ for (Instruction* instr : info->second.uses) {
+ assert(phi != instr);
+ /* recursively try to remove trivial phis */
+ if (is_phi(instr)) {
+ /* ignore if the phi was already flagged trivial */
+ if (instr->definitions.empty())
continue;
- }
- if (same != Temp())
- return;
- same = t;
+ if (instr->definitions[0].getTemp() != temp)
+ phi_users.emplace_back(instr->definitions[0].getTemp());
}
- assert(same != Temp() || same == def.getTemp());
-
- /* reroute all uses to same and remove phi */
- std::vector<Temp> phi_users;
- std::unordered_map<unsigned, phi_info>::iterator same_phi_info = ctx.phi_map.find(same.id());
- for (Instruction* instr : info->second.uses) {
- assert(phi != instr);
- /* recursively try to remove trivial phis */
- if (is_phi(instr)) {
- /* ignore if the phi was already flagged trivial */
- if (instr->definitions.empty())
- continue;
-
- if (instr->definitions[0].getTemp() != temp)
- phi_users.emplace_back(instr->definitions[0].getTemp());
- }
- for (Operand& op : instr->operands) {
- if (op.isTemp() && op.tempId() == def.tempId()) {
- op.setTemp(same);
- if (same_phi_info != ctx.phi_map.end())
- same_phi_info->second.uses.emplace(instr);
- }
+ for (Operand& op : instr->operands) {
+ if (op.isTemp() && op.tempId() == def.tempId()) {
+ op.setTemp(same);
+ if (same_phi_info != ctx.phi_map.end())
+ same_phi_info->second.uses.emplace(instr);
}
}
+ }
- auto it = ctx.orig_names.find(same.id());
- unsigned orig_var = it != ctx.orig_names.end() ? it->second.id() : same.id();
- for (unsigned i = 0; i < program->blocks.size(); i++) {
- auto it = ctx.renames[i].find(orig_var);
- if (it != ctx.renames[i].end() && it->second == def.getTemp())
- ctx.renames[i][orig_var] = same;
- }
+ auto it = ctx.orig_names.find(same.id());
+ unsigned orig_var = it != ctx.orig_names.end() ? it->second.id() : same.id();
+ for (unsigned i = 0; i < ctx.program->blocks.size(); i++) {
+ auto it = ctx.renames[i].find(orig_var);
+ if (it != ctx.renames[i].end() && it->second == def.getTemp())
+ ctx.renames[i][orig_var] = same;
+ }
- phi->definitions.clear(); /* this indicates that the phi can be removed */
- ctx.phi_map.erase(info);
- for (Temp t : phi_users)
- try_remove_trivial_phi(t);
+ phi->definitions.clear(); /* this indicates that the phi can be removed */
+ ctx.phi_map.erase(info);
+ for (Temp t : phi_users)
+ try_remove_trivial_phi(ctx, t);
- return;
- };
+ return;
+}
- std::unordered_map<unsigned, Instruction*> vectors;
+} /* end namespace */
+
+
+void register_allocation(Program *program, std::vector<TempSet>& live_out_per_block)
+{
+ ra_ctx ctx(program);
std::vector<std::vector<Temp>> phi_ressources;
std::unordered_map<unsigned, unsigned> temp_to_phi_ressources;
for (rit = block.instructions.rbegin(); rit != block.instructions.rend(); ++rit) {
aco_ptr<Instruction>& instr = *rit;
if (is_phi(instr)) {
- live.erase(instr->definitions[0].getTemp());
- if (instr->definitions[0].isKill() || instr->definitions[0].isFixed())
+ if (instr->definitions[0].isKill() || instr->definitions[0].isFixed()) {
+ live.erase(instr->definitions[0].getTemp());
continue;
+ }
/* collect information about affinity-related temporaries */
std::vector<Temp> affinity_related;
/* affinity_related[0] is the last seen affinity-related temp */
}
}
phi_ressources.emplace_back(std::move(affinity_related));
- continue;
- }
+ } else {
+ /* add vector affinities */
+ if (instr->opcode == aco_opcode::p_create_vector) {
+ for (const Operand& op : instr->operands) {
+ if (op.isTemp() && op.isFirstKill() && op.getTemp().type() == instr->definitions[0].getTemp().type())
+ ctx.vectors[op.tempId()] = instr.get();
+ }
+ }
- /* add vector affinities */
- if (instr->opcode == aco_opcode::p_create_vector) {
+ if (instr->opcode == aco_opcode::p_split_vector && instr->operands[0].isFirstKillBeforeDef())
+ ctx.split_vectors[instr->operands[0].tempId()] = instr.get();
+
+ /* add operands to live variables */
for (const Operand& op : instr->operands) {
- if (op.isTemp() && op.getTemp().type() == instr->definitions[0].getTemp().type())
- vectors[op.tempId()] = instr.get();
+ if (op.isTemp())
+ live.emplace(op.getTemp());
}
}
- /* add operands to live variables */
- for (const Operand& op : instr->operands) {
- if (op.isTemp())
- live.emplace(op.getTemp());
- }
-
/* erase definitions from live */
for (unsigned i = 0; i < instr->definitions.size(); i++) {
const Definition& def = instr->definitions[i];
if (it != temp_to_phi_ressources.end() && def.regClass() == phi_ressources[it->second][0].regClass()) {
phi_ressources[it->second][0] = def.getTemp();
/* try to coalesce phi affinities with parallelcopies */
- if (!def.isFixed() && instr->opcode == aco_opcode::p_parallelcopy) {
- Operand op = instr->operands[i];
- if (op.isTemp() && op.isFirstKillBeforeDef() && def.regClass() == op.regClass()) {
- phi_ressources[it->second].emplace_back(op.getTemp());
- temp_to_phi_ressources[op.tempId()] = it->second;
- }
+ Operand op = Operand();
+ if (!def.isFixed() && instr->opcode == aco_opcode::p_parallelcopy)
+ op = instr->operands[i];
+ else if ((instr->opcode == aco_opcode::v_mad_f32 ||
+ (instr->opcode == aco_opcode::v_fma_f32 && program->chip_class >= GFX10) ||
+ instr->opcode == aco_opcode::v_mad_f16 ||
+ instr->opcode == aco_opcode::v_mad_legacy_f16 ||
+ (instr->opcode == aco_opcode::v_fma_f16 && program->chip_class >= GFX10)) && !instr->usesModifiers())
+ op = instr->operands[2];
+
+ if (op.isTemp() && op.isFirstKillBeforeDef() && def.regClass() == op.regClass()) {
+ phi_ressources[it->second].emplace_back(op.getTemp());
+ temp_to_phi_ressources[op.tempId()] = it->second;
}
}
}
ctx.war_hint.reset();
for (Temp t : live) {
- Temp renamed = handle_live_in(t, &block);
- if (ctx.assignments[renamed.id()].assigned)
- register_file.fill(ctx.assignments[renamed.id()].reg, t.size(), renamed.id());
+ Temp renamed = handle_live_in(ctx, t, &block);
+ assignment& var = ctx.assignments[renamed.id()];
+ /* due to live-range splits, the live-in might be a phi, now */
+ if (var.assigned)
+ register_file.fill(Definition(renamed.id(), var.reg, var.rc));
}
std::vector<aco_ptr<Instruction>> instructions;
}
}
if (!definition.isFixed())
- definition.setFixed(get_reg(ctx, register_file, definition.regClass(), parallelcopy, phi));
+ definition.setFixed(get_reg(ctx, register_file, definition.getTemp(), parallelcopy, phi));
/* process parallelcopy */
for (std::pair<Operand, Definition> pc : parallelcopy) {
}
if (prev_phi) {
/* if so, just update that phi's register */
+ register_file.clear(prev_phi->definitions[0]);
prev_phi->definitions[0].setFixed(pc.second.physReg());
ctx.assignments[prev_phi->definitions[0].tempId()] = {pc.second.physReg(), pc.second.regClass()};
- register_file.fill(pc.second.physReg(), pc.second.size(), prev_phi->definitions[0].tempId());
+ register_file.fill(prev_phi->definitions[0]);
continue;
}
if (phi->operands[idx].isTemp() &&
phi->operands[idx].getTemp().type() == RegType::sgpr &&
phi->operands[idx].isFirstKillBeforeDef()) {
- Temp phi_op = read_variable(phi->operands[idx].getTemp(), block.index);
+ Temp phi_op = read_variable(ctx, phi->operands[idx].getTemp(), block.index);
PhysReg reg = ctx.assignments[phi_op.id()].reg;
assert(register_file[reg] == phi_op.id());
register_file[reg] = 0;
continue;
/* rename operands */
- operand.setTemp(read_variable(operand.getTemp(), block.index));
-
- /* check if the operand is fixed */
- if (operand.isFixed()) {
+ operand.setTemp(read_variable(ctx, operand.getTemp(), block.index));
+ assert(ctx.assignments[operand.tempId()].assigned);
- if (operand.physReg() == ctx.assignments[operand.tempId()].reg) {
- /* we are fine: the operand is already assigned the correct reg */
-
- } else {
- /* check if target reg is blocked, and move away the blocking var */
- if (register_file[operand.physReg().reg()]) {
- uint32_t blocking_id = register_file[operand.physReg().reg()];
- RegClass rc = ctx.assignments[blocking_id].rc;
- Operand pc_op = Operand(Temp{blocking_id, rc});
- pc_op.setFixed(operand.physReg());
- Definition pc_def = Definition(Temp{program->allocateId(), pc_op.regClass()});
- /* find free reg */
- PhysReg reg = get_reg(ctx, register_file, pc_op.regClass(), parallelcopy, instr);
- pc_def.setFixed(reg);
- ctx.assignments.emplace_back(reg, pc_def.regClass());
- assert(ctx.assignments.size() == ctx.program->peekAllocationId());
- register_file.clear(pc_op);
- register_file.fill(pc_def);
- parallelcopy.emplace_back(pc_op, pc_def);
-
- /* handle renames of previous operands */
- for (unsigned j = 0; j < i; j++) {
- Operand& op = instr->operands[j];
- if (op.isTemp() && op.tempId() == blocking_id) {
- op.setTemp(pc_def.getTemp());
- op.setFixed(reg);
- }
- }
- }
- /* move operand to fixed reg and create parallelcopy pair */
- Operand pc_op = operand;
- Temp tmp = Temp{program->allocateId(), operand.regClass()};
- Definition pc_def = Definition(tmp);
- pc_def.setFixed(operand.physReg());
- pc_op.setFixed(ctx.assignments[operand.tempId()].reg);
- operand.setTemp(tmp);
- ctx.assignments.emplace_back(pc_def.physReg(), pc_def.regClass());
- assert(ctx.assignments.size() == ctx.program->peekAllocationId());
- operand.setFixed(pc_def.physReg());
- register_file.clear(pc_op);
- register_file.fill(pc_def);
- parallelcopy.emplace_back(pc_op, pc_def);
- }
- } else {
- assert(ctx.assignments[operand.tempId()].assigned);
- PhysReg reg = ctx.assignments[operand.tempId()].reg;
-
- if (operand_can_use_reg(instr, i, reg)) {
- operand.setFixed(ctx.assignments[operand.tempId()].reg);
- } else {
- Operand pc_op = operand;
- pc_op.setFixed(reg);
- PhysReg new_reg = get_reg(ctx, register_file, operand.regClass(), parallelcopy, instr);
- Definition pc_def = Definition(program->allocateId(), new_reg, pc_op.regClass());
- ctx.assignments.emplace_back(new_reg, pc_def.regClass());
- assert(ctx.assignments.size() == ctx.program->peekAllocationId());
- register_file.clear(pc_op);
- register_file.fill(pc_def);
- parallelcopy.emplace_back(pc_op, pc_def);
- operand.setTemp(pc_def.getTemp());
- operand.setFixed(new_reg);
- }
+ PhysReg reg = ctx.assignments[operand.tempId()].reg;
+ if (operand_can_use_reg(program->chip_class, instr, i, reg, operand.regClass()))
+ operand.setFixed(reg);
+ else
+ get_reg_for_operand(ctx, register_file, parallelcopy, instr, operand, i);
- if (instr->format == Format::EXP ||
- (instr->isVMEM() && i == 3 && program->chip_class == GFX6) ||
- (instr->format == Format::DS && static_cast<DS_instruction*>(instr.get())->gds)) {
- for (unsigned j = 0; j < operand.size(); j++)
- ctx.war_hint.set(operand.physReg().reg() + j);
- }
+ if (instr->format == Format::EXP ||
+ (instr->isVMEM() && i == 3 && ctx.program->chip_class == GFX6) ||
+ (instr->format == Format::DS && static_cast<DS_instruction*>(instr.get())->gds)) {
+ for (unsigned j = 0; j < operand.size(); j++)
+ ctx.war_hint.set(operand.physReg().reg() + j);
}
+
std::unordered_map<unsigned, phi_info>::iterator phi = ctx.phi_map.find(operand.getTemp().id());
if (phi != ctx.phi_map.end())
phi->second.uses.emplace(instr.get());
-
}
+
/* remove dead vars from register file */
for (const Operand& op : instr->operands) {
if (op.isTemp() && op.isFirstKillBeforeDef())
}
/* try to optimize v_mad_f32 -> v_mac_f32 */
- if (instr->opcode == aco_opcode::v_mad_f32 &&
+ if ((instr->opcode == aco_opcode::v_mad_f32 ||
+ (instr->opcode == aco_opcode::v_fma_f32 && program->chip_class >= GFX10) ||
+ instr->opcode == aco_opcode::v_mad_f16 ||
+ instr->opcode == aco_opcode::v_mad_legacy_f16 ||
+ (instr->opcode == aco_opcode::v_fma_f16 && program->chip_class >= GFX10)) &&
instr->operands[2].isTemp() &&
instr->operands[2].isKillBeforeDef() &&
instr->operands[2].getTemp().type() == RegType::vgpr &&
instr->operands[1].isTemp() &&
- instr->operands[1].getTemp().type() == RegType::vgpr) { /* TODO: swap src0 and src1 in this case */
- VOP3A_instruction* vop3 = static_cast<VOP3A_instruction*>(instr.get());
- bool can_use_mac = !(vop3->abs[0] || vop3->abs[1] || vop3->abs[2] ||
- vop3->neg[0] || vop3->neg[1] || vop3->neg[2] ||
- vop3->clamp || vop3->omod || vop3->opsel);
- if (can_use_mac) {
+ instr->operands[1].getTemp().type() == RegType::vgpr &&
+ !instr->usesModifiers() &&
+ instr->operands[0].physReg().byte() == 0 &&
+ instr->operands[1].physReg().byte() == 0 &&
+ instr->operands[2].physReg().byte() == 0) {
+ unsigned def_id = instr->definitions[0].tempId();
+ auto it = ctx.affinities.find(def_id);
+ if (it == ctx.affinities.end() || !ctx.assignments[it->second].assigned ||
+ instr->operands[2].physReg() == ctx.assignments[it->second].reg ||
+ register_file.test(ctx.assignments[it->second].reg, instr->operands[2].bytes())) {
instr->format = Format::VOP2;
- instr->opcode = aco_opcode::v_mac_f32;
+ switch (instr->opcode) {
+ case aco_opcode::v_mad_f32:
+ instr->opcode = aco_opcode::v_mac_f32;
+ break;
+ case aco_opcode::v_fma_f32:
+ instr->opcode = aco_opcode::v_fmac_f32;
+ break;
+ case aco_opcode::v_mad_f16:
+ case aco_opcode::v_mad_legacy_f16:
+ instr->opcode = aco_opcode::v_mac_f16;
+ break;
+ case aco_opcode::v_fma_f16:
+ instr->opcode = aco_opcode::v_fmac_f16;
+ break;
+ default:
+ break;
+ }
}
}
/* handle definitions which must have the same register as an operand */
if (instr->opcode == aco_opcode::v_interp_p2_f32 ||
instr->opcode == aco_opcode::v_mac_f32 ||
+ instr->opcode == aco_opcode::v_fmac_f32 ||
+ instr->opcode == aco_opcode::v_mac_f16 ||
+ instr->opcode == aco_opcode::v_fmac_f16 ||
instr->opcode == aco_opcode::v_writelane_b32 ||
instr->opcode == aco_opcode::v_writelane_b32_e64) {
instr->definitions[0].setFixed(instr->operands[2].physReg());
adjust_max_used_regs(ctx, definition.regClass(), definition.physReg());
/* check if the target register is blocked */
- if (register_file[definition.physReg().reg()] != 0) {
- /* create parallelcopy pair to move blocking var */
- Temp tmp = {register_file[definition.physReg()], ctx.assignments[register_file[definition.physReg()]].rc};
- Operand pc_op = Operand(tmp);
- pc_op.setFixed(ctx.assignments[register_file[definition.physReg().reg()]].reg);
- RegClass rc = pc_op.regClass();
- tmp = Temp{program->allocateId(), rc};
- Definition pc_def = Definition(tmp);
-
- /* re-enable the killed operands, so that we don't move the blocking var there */
+ if (register_file.test(definition.physReg(), definition.bytes())) {
+ /* create parallelcopy pair to move blocking vars */
+ std::set<std::pair<unsigned, unsigned>> vars = collect_vars(ctx, register_file, definition.physReg(), definition.size());
+
+ /* re-enable the killed operands, so that we don't move the blocking vars there */
for (const Operand& op : instr->operands) {
if (op.isTemp() && op.isFirstKillBeforeDef())
register_file.fill(op);
}
- /* find a new register for the blocking variable */
- PhysReg reg = get_reg(ctx, register_file, rc, parallelcopy, instr);
+ ASSERTED bool success = false;
+ DefInfo info(ctx, instr, definition.regClass(), -1);
+ success = get_regs_for_copies(ctx, register_file, parallelcopy,
+ vars, info.lb, info.ub, instr,
+ definition.physReg(),
+ definition.physReg() + definition.size() - 1);
+ assert(success);
+
+ update_renames(ctx, register_file, parallelcopy, instr, false);
+
/* once again, disable killed operands */
for (const Operand& op : instr->operands) {
if (op.isTemp() && op.isFirstKillBeforeDef())
if (instr->definitions[k].isTemp() && ctx.defs_done.test(k) && !instr->definitions[k].isKill())
register_file.fill(instr->definitions[k]);
}
- pc_def.setFixed(reg);
-
- /* finish assignment of parallelcopy */
- ctx.assignments.emplace_back(reg, pc_def.regClass());
- assert(ctx.assignments.size() == ctx.program->peekAllocationId());
- parallelcopy.emplace_back(pc_op, pc_def);
-
- /* add changes to reg_file */
- register_file.clear(pc_op);
- register_file.fill(pc_def);
}
ctx.defs_done.set(i);
/* handle all other definitions */
for (unsigned i = 0; i < instr->definitions.size(); ++i) {
- auto& definition = instr->definitions[i];
+ Definition *definition = &instr->definitions[i];
- if (definition.isFixed() || !definition.isTemp())
+ if (definition->isFixed() || !definition->isTemp())
continue;
/* find free reg */
- if (definition.hasHint() && register_file[definition.physReg().reg()] == 0)
- definition.setFixed(definition.physReg());
+ if (definition->hasHint() && register_file[definition->physReg().reg()] == 0)
+ definition->setFixed(definition->physReg());
else if (instr->opcode == aco_opcode::p_split_vector) {
PhysReg reg = instr->operands[0].physReg();
- reg.reg_b += i * definition.bytes();
- if (!get_reg_specified(ctx, register_file, definition.regClass(), parallelcopy, instr, reg))
- reg = get_reg(ctx, register_file, definition.regClass(), parallelcopy, instr);
- definition.setFixed(reg);
- } else if (instr->opcode == aco_opcode::p_wqm) {
- PhysReg reg;
- if (instr->operands[0].isKillBeforeDef() && instr->operands[0].getTemp().type() == definition.getTemp().type()) {
- reg = instr->operands[0].physReg();
- assert(register_file[reg.reg()] == 0);
- } else {
- reg = get_reg(ctx, register_file, definition.regClass(), parallelcopy, instr);
- }
- definition.setFixed(reg);
+ for (unsigned j = 0; j < i; j++)
+ reg.reg_b += instr->definitions[j].bytes();
+ if (get_reg_specified(ctx, register_file, definition->regClass(), parallelcopy, instr, reg))
+ definition->setFixed(reg);
+ } else if (instr->opcode == aco_opcode::p_wqm || instr->opcode == aco_opcode::p_parallelcopy) {
+ PhysReg reg = instr->operands[i].physReg();
+ if (instr->operands[i].isTemp() &&
+ instr->operands[i].getTemp().type() == definition->getTemp().type() &&
+ !register_file.test(reg, definition->bytes()))
+ definition->setFixed(reg);
} else if (instr->opcode == aco_opcode::p_extract_vector) {
PhysReg reg;
if (instr->operands[0].isKillBeforeDef() &&
- instr->operands[0].getTemp().type() == definition.getTemp().type()) {
+ instr->operands[0].getTemp().type() == definition->getTemp().type()) {
reg = instr->operands[0].physReg();
- reg.reg_b += definition.bytes() * instr->operands[1].constantValue();
- assert(!register_file.test(reg, definition.bytes()));
- } else {
- reg = get_reg(ctx, register_file, definition.regClass(), parallelcopy, instr);
+ reg.reg_b += definition->bytes() * instr->operands[1].constantValue();
+ assert(!register_file.test(reg, definition->bytes()));
+ definition->setFixed(reg);
}
- definition.setFixed(reg);
} else if (instr->opcode == aco_opcode::p_create_vector) {
- PhysReg reg = get_reg_create_vector(ctx, register_file, definition.regClass(),
+ PhysReg reg = get_reg_create_vector(ctx, register_file, definition->getTemp(),
parallelcopy, instr);
- definition.setFixed(reg);
- } else if (ctx.affinities.find(definition.tempId()) != ctx.affinities.end() &&
- ctx.assignments[ctx.affinities[definition.tempId()]].assigned) {
- PhysReg reg = ctx.assignments[ctx.affinities[definition.tempId()]].reg;
- if (get_reg_specified(ctx, register_file, definition.regClass(), parallelcopy, instr, reg))
- definition.setFixed(reg);
- else
- definition.setFixed(get_reg(ctx, register_file, definition.regClass(), parallelcopy, instr));
+ definition->setFixed(reg);
+ }
- } else if (vectors.find(definition.tempId()) != vectors.end()) {
- Instruction* vec = vectors[definition.tempId()];
- unsigned byte_offset = 0;
- for (const Operand& op : vec->operands) {
- if (op.isTemp() && op.tempId() == definition.tempId())
- break;
- else
- byte_offset += op.bytes();
- }
- unsigned k = 0;
- for (const Operand& op : vec->operands) {
- if (op.isTemp() &&
- op.tempId() != definition.tempId() &&
- op.getTemp().type() == definition.getTemp().type() &&
- ctx.assignments[op.tempId()].assigned) {
- PhysReg reg = ctx.assignments[op.tempId()].reg;
- reg.reg_b += (byte_offset - k);
- if (get_reg_specified(ctx, register_file, definition.regClass(), parallelcopy, instr, reg)) {
- definition.setFixed(reg);
- break;
- }
- }
- k += op.bytes();
- }
- if (!definition.isFixed()) {
- std::pair<PhysReg, bool> res = get_reg_vec(ctx, register_file, vec->definitions[0].regClass());
- PhysReg reg = res.first;
- if (res.second) {
- reg.reg_b += byte_offset;
- /* make sure to only use byte offset if the instruction supports it */
- if (vec->definitions[0].regClass().is_subdword() && reg.byte() && !instr_can_access_subdword(instr))
- reg = get_reg(ctx, register_file, definition.regClass(), parallelcopy, instr);
- } else {
- reg = get_reg(ctx, register_file, definition.regClass(), parallelcopy, instr);
- }
- definition.setFixed(reg);
+ if (!definition->isFixed()) {
+ Temp tmp = definition->getTemp();
+ if (definition->regClass().is_subdword() && definition->bytes() < 4) {
+ PhysReg reg = get_reg(ctx, register_file, tmp, parallelcopy, instr);
+ bool partial = !(tmp.bytes() <= 4 && reg.byte() == 0 && !register_file.test(reg, 4));
+ add_subdword_definition(program, instr, i, reg, partial);
+ definition = &instr->definitions[i]; /* add_subdword_definition can invalidate the reference */
+ } else {
+ definition->setFixed(get_reg(ctx, register_file, tmp, parallelcopy, instr));
}
- } else
- definition.setFixed(get_reg(ctx, register_file, definition.regClass(), parallelcopy, instr));
+ }
- assert(definition.isFixed() && ((definition.getTemp().type() == RegType::vgpr && definition.physReg() >= 256) ||
- (definition.getTemp().type() != RegType::vgpr && definition.physReg() < 256)));
+ assert(definition->isFixed() && ((definition->getTemp().type() == RegType::vgpr && definition->physReg() >= 256) ||
+ (definition->getTemp().type() != RegType::vgpr && definition->physReg() < 256)));
ctx.defs_done.set(i);
/* set live if it has a kill point */
- if (!definition.isKill())
- live.emplace(definition.getTemp());
+ if (!definition->isKill())
+ live.emplace(definition->getTemp());
- ctx.assignments[definition.tempId()] = {definition.physReg(), definition.regClass()};
- register_file.fill(definition);
+ ctx.assignments[definition->tempId()] = {definition->physReg(), definition->regClass()};
+ register_file.fill(*definition);
}
handle_pseudo(ctx, register_file, instr.get());
- /* kill definitions and late-kill operands */
+ /* kill definitions and late-kill operands and ensure that sub-dword operands can actually be read */
for (const Definition& def : instr->definitions) {
if (def.isTemp() && def.isKill())
register_file.clear(def);
}
- for (const Operand& op : instr->operands) {
+ for (unsigned i = 0; i < instr->operands.size(); i++) {
+ const Operand& op = instr->operands[i];
if (op.isTemp() && op.isFirstKill() && op.isLateKill())
register_file.clear(op);
+ if (op.isTemp() && op.physReg().byte() != 0)
+ add_subdword_operand(program->chip_class, instr, i, op.physReg().byte(), op.regClass());
}
/* emit parallelcopy */
}
for (const Operand& op : instr->operands) {
if (op.isTemp() && op.isFirstKill())
- register_file.fill(op.physReg(), op.size(), 0xFFFF);
+ register_file.block(op.physReg(), op.regClass());
}
handle_pseudo(ctx, register_file, pc.get());
register_file.clear(def);
for (const Operand& op : instr->operands) {
if (op.isTemp() && op.isFirstKill())
- register_file.fill(op.physReg(), op.size(), 0xFFFF);
+ register_file.block(op.physReg(), op.regClass());
}
- RegClass rc = can_sgpr ? s1 : v1;
- PhysReg reg = get_reg(ctx, register_file, rc, parallelcopy, instr);
- Temp tmp = {program->allocateId(), rc};
- ctx.assignments.emplace_back(reg, rc);
+ Temp tmp = {program->allocateId(), can_sgpr ? s1 : v1};
+ ctx.assignments.emplace_back();
+ PhysReg reg = get_reg(ctx, register_file, tmp, parallelcopy, instr);
aco_ptr<Instruction> mov;
if (can_sgpr)
}
std::copy(tmp->definitions.begin(), tmp->definitions.end(), instr->definitions.begin());
}
+
instructions.emplace_back(std::move(*it));
} /* end for Instr */
for (Instruction* phi : ctx.incomplete_phis[succ_idx]) {
std::vector<unsigned> preds = phi->definitions[0].getTemp().is_linear() ? succ.linear_preds : succ.logical_preds;
for (unsigned i = 0; i < phi->operands.size(); i++) {
- phi->operands[i].setTemp(read_variable(phi->operands[i].getTemp(), preds[i]));
+ phi->operands[i].setTemp(read_variable(ctx, phi->operands[i].getTemp(), preds[i]));
phi->operands[i].setFixed(ctx.assignments[phi->operands[i].tempId()].reg);
}
- try_remove_trivial_phi(phi->definitions[0].getTemp());
+ try_remove_trivial_phi(ctx, phi->definitions[0].getTemp());
}
/* complete the original phi nodes, but no need to check triviality */
for (aco_ptr<Instruction>& instr : succ.instructions) {
auto& operand = instr->operands[i];
if (!operand.isTemp())
continue;
- operand.setTemp(read_variable(operand.getTemp(), preds[i]));
+ operand.setTemp(read_variable(ctx, operand.getTemp(), preds[i]));
operand.setFixed(ctx.assignments[operand.tempId()].reg);
std::unordered_map<unsigned, phi_info>::iterator phi = ctx.phi_map.find(operand.getTemp().id());
if (phi != ctx.phi_map.end())