169 lines
5.6 KiB
C++
169 lines
5.6 KiB
C++
#include <vector>
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#include <set>
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#include <algorithm>
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#include "triton/codegen/analysis/layout.h"
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#include "triton/codegen/analysis/allocation.h"
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#include "triton/codegen/transform/membar.h"
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#include "triton/ir/module.h"
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#include "triton/ir/function.h"
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#include "triton/ir/basic_block.h"
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#include "triton/ir/instructions.h"
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#include "triton/ir/utils.h"
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namespace triton {
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namespace codegen{
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namespace transform{
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bool membar::intersect(const interval_vec_t &X, interval_t x) {
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return std::any_of(X.begin(), X.end(), [&](const interval_t &y){
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bool left_intersect = y.first <= x.first && x.first < y.second;
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bool right_intersect = y.first <= x.second && x.second < y.second;
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return left_intersect || right_intersect;
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});
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}
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bool membar::intersect(const interval_vec_t &X, const interval_vec_t &Y) {
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return std::any_of(Y.begin(), Y.end(), [&](const interval_t &y){
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return intersect(X, y);
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});
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}
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void membar::add_reference(ir::value *v, interval_vec_t &res){
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auto *i = dynamic_cast<ir::instruction*>(v);
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if(!i)
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return;
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if(!i->get_type()->is_tile_ty())
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return;
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analysis::shared_layout* layout = layouts_->get(v)->to_shared();
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if(!layout)
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return;
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if(alloc_->has_offset(layout)){
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unsigned offset = alloc_->offset(layout);
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res.push_back(interval_t(offset, offset + layout->get_size()));
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}
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}
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void membar::get_read_intervals(ir::instruction *i, interval_vec_t &res){
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for(ir::value *op: i->ops())
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add_reference(op, res);
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}
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void membar::get_written_intervals(ir::instruction *i, interval_vec_t &res){
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if(!dynamic_cast<ir::phi_node*>(i) && !dynamic_cast<ir::trans_inst*>(i))
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add_reference(i, res);
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}
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void membar::insert_barrier(ir::instruction *instr, ir::builder &builder) {
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if(auto *phi = dynamic_cast<ir::phi_node*>(instr)) {
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std::set<ir::value*> incoming;
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for(unsigned n = 0; n < phi->get_num_incoming(); n++){
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ir::instruction *inc_val = dynamic_cast<ir::instruction*>(phi->get_incoming_value(n));
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assert(inc_val);
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if(incoming.insert(inc_val).second){
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ir::basic_block *block = inc_val->get_parent();
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builder.set_insert_point(block->get_inst_list().back());
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builder.create_barrier();
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}
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}
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}
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else {
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builder.set_insert_point(instr);
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builder.create_barrier();
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}
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}
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membar::interval_vec_t membar::join(const std::vector<interval_vec_t>& intervals) {
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membar::interval_vec_t result;
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for(auto x: intervals)
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for(interval_t i: x)
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result.push_back(i);
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return result;
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}
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std::pair<membar::interval_vec_t,
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membar::interval_vec_t> membar::transfer(ir::basic_block *block,
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const interval_vec_t &written_to,
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const interval_vec_t &read_from,
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std::set<ir::instruction*>& insert_loc,
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std::set<ir::value*>& safe_war) {
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ir::basic_block::inst_list_t instructions = block->get_inst_list();
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interval_vec_t new_written_to = written_to;
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interval_vec_t new_read_from = read_from;
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for(ir::instruction *i: instructions){
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interval_vec_t read, written;
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get_read_intervals(i, read);
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get_written_intervals(i, written);
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bool read_after_write = intersect(new_written_to, read);
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bool write_after_read = intersect(new_read_from, written);
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// double buffering
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if(safe_war.find(i) != safe_war.end()){
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write_after_read = false;
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read_after_write = false;
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}
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// record hazards
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if(read_after_write || write_after_read) {
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insert_loc.insert(i);
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new_written_to.clear();
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new_read_from.clear();
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}
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std::copy(written.begin(), written.end(), std::back_inserter(new_written_to));
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std::copy(read.begin(), read.end(), std::back_inserter(new_read_from));
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}
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return std::make_pair(new_written_to, new_read_from);
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}
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void membar::run(ir::module &mod) {
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ir::builder &builder = mod.get_builder();
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// extract phi-node associates with double-buffered
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// shared-memory copies. These can be read from and written to
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// without needing synchronization
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std::set<ir::value*> safe_war;
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for(const auto& x: layouts_->get_all()){
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analysis::shared_layout* layout = x.second->to_shared();
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if(!layout || !layout->get_double_buffer())
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continue;
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for(ir::value *v: layout->get_values())
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if(v != layout->get_double_buffer()->phi)
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safe_war.insert(v);
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}
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for(ir::function *fn: mod.get_function_list()){
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std::vector<ir::basic_block*> rpo = ir::cfg::reverse_post_order(fn);
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std::map<ir::basic_block*, interval_vec_t> written_to;
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std::map<ir::basic_block*, interval_vec_t> read_from;
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std::set<ir::instruction*> insert_locs;
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size_t n_inserted_im1 = 0;
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bool done = false;
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do{
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// find barrier location
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for(ir::basic_block *block: rpo){
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// written to
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std::vector<interval_vec_t> pred_written_to;
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for(ir::basic_block* pred: block->get_predecessors())
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pred_written_to.push_back(written_to[pred]);
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// read from
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std::vector<interval_vec_t> pred_read_from;
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for(ir::basic_block* pred: block->get_predecessors())
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pred_read_from.push_back(read_from[pred]);
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// apply transfer function
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auto result = transfer(block, join(pred_written_to), join(pred_read_from), insert_locs, safe_war);
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written_to[block] = result.first;
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read_from[block] = result.second;
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}
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size_t n_inserted_i = insert_locs.size();
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done = (n_inserted_im1 == n_inserted_i);
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n_inserted_im1 = n_inserted_i;
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}while(!done);
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for(ir::instruction* i: insert_locs)
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insert_barrier(i, builder);
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}
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}
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}
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}
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}
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