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llvm_propeller_cfg.cc
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llvm_propeller_cfg.cc
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#include "llvm_propeller_cfg.h"
#include <algorithm>
#include <memory>
#include <ostream>
#include <string>
#include <utility>
#include <vector>
#include "third_party/abseil/absl/container/flat_hash_map.h"
#include "third_party/abseil/absl/strings/str_cat.h"
#include "third_party/abseil/absl/types/span.h"
#include "base/logging.h"
namespace devtools_crosstool_autofdo {
std::string CFGNode::GetName() const {
std::string bb_name = absl::StrCat(function_index());
if (!is_entry()) absl::StrAppend(&bb_name, ".", bb_index(), ".id", bb_id());
if (clone_number() != 0) absl::StrAppend(&bb_name, ".c", clone_number());
return bb_name;
}
CFGEdge *CFGNode::GetEdgeTo(const CFGNode &node, CFGEdge::Kind kind) const {
for (const std::vector<CFGEdge *> *edges : {&intra_outs_, &inter_outs_})
for (CFGEdge *edge : *edges) {
if (edge->kind() != kind) continue;
if (edge->sink() == &node) return edge;
}
return nullptr;
}
CFGEdge *ControlFlowGraph::CreateOrUpdateEdge(CFGNode *from, CFGNode *to,
int weight, CFGEdge::Kind kind,
bool inter_section) {
CFGEdge *edge = from->GetEdgeTo(*to, kind);
if (edge == nullptr) return CreateEdge(from, to, weight, kind, inter_section);
edge->IncrementWeight(weight);
return edge;
}
CFGEdge *ControlFlowGraph::CreateEdge(CFGNode *from, CFGNode *to, int weight,
CFGEdge::Kind kind, bool inter_section) {
if (inter_section)
CHECK_NE(from->function_index(), to->function_index())
<< " intra-function edges cannot be inter-section.";
auto edge = std::make_unique<CFGEdge>(from, to, weight, kind, inter_section);
auto *ret = edge.get();
auto has_duplicates = [from,
to](absl::Span<const std::unique_ptr<CFGEdge>> edges) {
for (auto &e : edges)
if (e->src() == from && e->sink() == to) return true;
return false;
};
(void)(has_duplicates); // For release build warning.
if (from->function_index() == to->function_index()) {
CHECK(!has_duplicates(intra_edges_))
<< " " << from->inter_cfg_id() << " to " << to->inter_cfg_id();
from->intra_outs_.push_back(edge.get());
to->intra_ins_.push_back(edge.get());
intra_edges_.push_back(std::move(edge));
} else {
DCHECK(!has_duplicates(inter_edges_));
from->inter_outs_.push_back(edge.get());
to->inter_ins_.push_back(edge.get());
inter_edges_.push_back(std::move(edge));
}
return ret;
}
void ControlFlowGraph::WriteDotFormat(
std::ostream &os,
const absl::flat_hash_map<CFGNode::IntraCfgId, int> &layout_index_map)
const {
os << "digraph {\n";
os << "label=\"" << GetPrimaryName().str() << "#" << function_index_
<< "\"\n";
os << "forcelabels=true;\n";
for (const auto &node : nodes_) {
os << node->GetDotFormatLabel() << " [xlabel=\"" << node->freq_ << "#"
<< node->size_ << "#" << node->bb_index() << "\", color = \""
<< (node->clone_number() ? "red" : "black") << "\" ];\n";
}
for (const auto &edge : intra_edges_) {
bool is_layout_edge =
layout_index_map.contains(edge->sink()->intra_cfg_id()) &&
layout_index_map.contains(edge->src()->intra_cfg_id()) &&
layout_index_map.at(edge->sink()->intra_cfg_id()) -
layout_index_map.at(edge->src()->intra_cfg_id()) ==
1;
os << edge->src()->GetDotFormatLabel() << " -> "
<< edge->sink()->GetDotFormatLabel() << "[ label=\""
<< edge->GetDotFormatLabel() << "\", color =\""
<< (is_layout_edge ? "red" : "black") << "\"];\n";
}
os << "}\n";
}
std::vector<int> ControlFlowGraph::GetHotJoinNodes(
int hot_node_frequency_threshold, int hot_edge_frequency_threshold) const {
std::vector<int> ret;
for (const std::unique_ptr<CFGNode> &node : nodes_) {
if (node->is_entry()) continue;
if (node->CalculateFrequency() < hot_node_frequency_threshold) continue;
auto num_hot_branches_to =
std::count_if(node->intra_ins().begin(), node->intra_ins().end(),
[&](const CFGEdge *edge) {
return edge->src() != edge->sink() && !edge->IsCall() &&
!edge->IsReturn() &&
edge->weight() >= hot_edge_frequency_threshold;
});
if (num_hot_branches_to <= 1) continue;
ret.push_back(node->bb_index());
}
return ret;
}
int CFGNode::CalculateFrequency() const {
// A node (basic block) may have multiple outgoing calls to different
// functions. In that case, a single execution of that node counts toward
// the weight of each of its calls as wells as returns back to the
// callsites. To avoid double counting, we only consider the heaviest
// call-out and return-in towards calculating the node's frequency. This
// mitigates some cases at the expense of possible
// underestimation. The underestimation may happen when these calls and
// returns occur in separate LBR stacks. Another source of underestimation
// is indirect calls. A node may only have one indirect call instruction,
// but if different functions are called by that indirect call, the node's
// frequency is equal to the aggregation of call-outs rather than their max.
int max_call_out = 0;
int max_ret_in = 0;
// Total incoming edge frequency to the node's entry (first instruction).
int sum_in = 0;
// Total outgoing edge frequency from the node's exit (last instruction).
int sum_out = 0;
for (auto *out_edges : {&inter_outs_, &intra_outs_}) {
for (auto &edge : *out_edges) {
if (edge->IsCall()) {
max_call_out = std::max(max_call_out, edge->weight());
} else {
sum_out += edge->weight();
}
}
}
for (auto *in_edges : {&inter_ins_, &intra_ins_}) {
for (auto &edge : *in_edges) {
if (edge->IsReturn()) {
max_ret_in = std::max(max_ret_in, edge->weight());
} else {
sum_in += edge->weight();
}
}
}
return std::max({max_call_out, max_ret_in, sum_out, sum_in});
}
std::string CFGEdge::GetCfgEdgeKindString(Kind kind) {
switch (kind) {
case CFGEdge::Kind::kBranchOrFallthough:
return "BranchOrFallthrough";
case CFGEdge::Kind::kCall:
return "Call";
case CFGEdge::Kind::kRet:
return "Return";
}
LOG(FATAL) << "Invalid edge kind.";
}
std::string CFGEdge::GetDotFormatLabelForEdgeKind(Kind kind) {
return CFGEdge::GetCfgEdgeKindString(kind).substr(0, 1);
}
std::ostream &operator<<(std::ostream &os, const CFGEdge::Kind &kind) {
return os << CFGEdge::GetCfgEdgeKindString(kind);
}
std::unique_ptr<ControlFlowGraph> CloneCfg(const ControlFlowGraph &cfg) {
// Create a clone of `cfg` with all the nodes copied.
std::vector<std::unique_ptr<CFGNode>> nodes;
for (const std::unique_ptr<CFGNode> &node : cfg.nodes())
nodes.push_back(node->Clone(node->clone_number(), nodes.size()));
auto cfg_clone = std::make_unique<ControlFlowGraph>(
cfg.section_name(), cfg.function_index(), cfg.module_name(), cfg.names(),
std::move(nodes));
// Now copy the intra-function edges.
for (const std::unique_ptr<CFGEdge> &edge : cfg.intra_edges()) {
CHECK_EQ(edge->src()->function_index(), edge->sink()->function_index());
cfg_clone->CreateEdge(&cfg_clone->GetNodeById(edge->src()->intra_cfg_id()),
&cfg_clone->GetNodeById(edge->sink()->intra_cfg_id()),
edge->weight(), edge->kind(), edge->inter_section());
}
return cfg_clone;
}
ControlFlowGraph::NodeFrequencyStats ControlFlowGraph::GetNodeFrequencyStats()
const {
ControlFlowGraph::NodeFrequencyStats stats;
for (const auto &node : nodes_) {
if (node->CalculateFrequency() == 0) continue;
++stats.n_hot_blocks;
if (node->size() == 0) ++stats.n_hot_empty_blocks;
if (node->is_landing_pad()) ++stats.n_hot_landing_pads;
}
return stats;
}
} // namespace devtools_crosstool_autofdo