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module_grouper.cc
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module_grouper.cc
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// Copyright 2014 Google Inc. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "module_grouper.h"
#include "gflags/gflags.h"
#include "base/common.h"
#include "symbolize/bytereader-inl.h"
#include "symbolize/elf_reader.h"
#include "symbol_map.h"
DEFINE_int32(cutoff_percent, 85,
"The module group will stop when total number of integrated call "
"edge counts sums to more than this percentage of total call edge "
"count");
DEFINE_int32(max_ggc_memory, 3 << 20,
"The maximum ggc memory (in KB) of each module. This indicates "
"how much memory GCC can be used to build each module. The "
"default value is 3GB because hip-forge cluster enforce memory "
"consumption to be less than 3GB");
namespace autofdo {
// in_func is not a const pointer, but it's not modified in the function.
void Function::AddInEdgeCount(int64 count, Function *in_func) {
pair<EdgeCount::iterator, bool> ret = in_edge_count.insert(
EdgeCount::value_type(in_func, 0));
ret.first->second += count;
total_in_count += count;
}
// out_func is not a const pointer, but it's not modified in the function.
void Function::AddOutEdgeCount(int64 count, Function *out_func) {
pair<EdgeCount::iterator, bool> ret = out_edge_count.insert(
EdgeCount::value_type(out_func, 0));
ret.first->second += count;
total_out_count += count;
}
ModuleGrouper *ModuleGrouper::GroupModule(
const string &binary,
const string §ion_prefix,
const SymbolMap *symbol_map) {
ModuleGrouper *grouper = new ModuleGrouper(symbol_map);
grouper->ReadModuleOptions(binary, section_prefix);
if (grouper->module_map().size() == 0) {
LOG(WARNING) << "Cannot read compilation info from binary. "
<< "Please use -frecord-compilation-info-in-elf when "
<< "building the binary";
} else {
grouper->Group();
}
return grouper;
}
void ModuleGrouper::Group() {
BuildGraph();
CallEdge max_edge;
int64 target_accumulate_count = total_count_ * FLAGS_cutoff_percent / 100;
map<string, set<string> > legacy_group;
// Reads the legacy group from inline stacks (symbol_map.map())
for (const auto &name_symbol : symbol_map_->map()) {
const Symbol *symbol = name_symbol.second;
if (symbol->IsFromHeader()) {
continue;
}
const string base_module_name = symbol->ModuleName();
vector<const Symbol *> queue;
queue.push_back(symbol);
while (!queue.empty()) {
const Symbol *s = queue.back();
queue.pop_back();
for (const auto &pos_symbol : s->callsites) {
queue.push_back(pos_symbol.second);
}
if (s->IsFromHeader() || s->ModuleName() == base_module_name ||
s->total_count == 0) {
continue;
}
legacy_group[base_module_name].insert(s->ModuleName());
}
}
// Updates the legacy group to the new module group
for (const auto &name_modules : legacy_group) {
if (module_map_.find(name_modules.first) == module_map_.end()) {
LOG(ERROR) << "Primary module " << name_modules.first
<< " is not found in the profile binary";
continue;
}
for (const auto &name : name_modules.second) {
if (module_map_.find(name) == module_map_.end()) {
LOG(ERROR) << "Module " << name.c_str()
<< " is not found in the profile binary";
continue;
}
module_map_[name].is_exported = true;
}
module_map_[name_modules.first].aux_modules.insert(
name_modules.second.begin(), name_modules.second.end());
}
for (int64 accumulate_count = GetMaxEdge(&max_edge);
accumulate_count < target_accumulate_count;
accumulate_count += GetMaxEdge(&max_edge)) {
if (edge_map_[max_edge] == 0) {
break;
}
// Check if module should be integrated as aux-module.
if (ShouldIntegrate(max_edge.from->module, max_edge.to->module)) {
IntegrateEdge(max_edge);
} else {
// The edge has been processed and edge count should been decreased so
// that it will not be processed any more.
AddEdgeCount(max_edge, edge_map_[max_edge] * -1);
}
}
}
string ModuleGrouper::ReplaceHeaderToCC(string header_name) const {
// Header file name is something like: ./mustang/hit-iterator.h
// We change it to: mustang/hit-iterator.cc
if (header_name.size() < 5 || header_name.substr(0, 2) != "./"
|| header_name.substr(header_name.size() - 2) != ".h") {
return header_name;
}
return header_name.substr(2, header_name.size() - 3) + "cc";
}
string ModuleGrouper::UpdateModuleMap(string name) {
if (module_map_.find(name) == module_map_.end()) {
string new_name = ReplaceHeaderToCC(name);
if (module_map_.find(new_name) != module_map_.end()) {
return new_name;
} else {
module_map_.insert(ModuleMap::value_type(name, Module(true)));
}
}
return name;
}
void ModuleGrouper::RecursiveBuildGraph(const string &caller_name,
const Symbol *symbol) {
const Symbol *caller = symbol_map_->GetSymbolByName(caller_name);
CHECK(caller != NULL);
for (const auto &pos_count : symbol->pos_counts) {
for (const auto &target_count : pos_count.second.target_map) {
const string &callee_name = target_count.first;
const Symbol *callee = symbol_map_->GetSymbolByName(callee_name);
if (callee == NULL || caller == callee) {
continue;
}
total_count_ += target_count.second;
string caller_module_name = UpdateModuleMap(caller->ModuleName());
string callee_module_name = UpdateModuleMap(callee->ModuleName());
pair<FunctionMap::iterator, bool> caller_ret =
function_map_.insert(FunctionMap::value_type(
caller_name, Function(caller_name, caller_module_name)));
pair<FunctionMap::iterator, bool> callee_ret =
function_map_.insert(FunctionMap::value_type(
callee_name, Function(callee_name, callee_module_name)));
AddEdgeCount(
CallEdge(&(caller_ret.first->second), &(callee_ret.first->second)),
target_count.second);
}
}
for (const auto &callsite_symbol : symbol->callsites) {
// For the inlined functions, the call will be attributed to the outermost
// symbol, i.e. the symbol that is emitted in the profiled binary.
RecursiveBuildGraph(caller_name, callsite_symbol.second);
}
}
void ModuleGrouper::BuildGraph() {
for (const auto &name_symbol : symbol_map_->map()) {
RecursiveBuildGraph(name_symbol.first, name_symbol.second);
}
}
void ModuleGrouper::AddEdgeCount(const CallEdge &edge, int64 count) {
edge.from->AddOutEdgeCount(count, edge.to);
edge.to->AddInEdgeCount(count, edge.from);
pair<EdgeMap::iterator, bool> ret = edge_map_.insert(
EdgeMap::value_type(edge, 0));
ret.first->second += count;
}
// Integrates edge.to into edge.from.
// The integration has two steps:
// 1. Integrates the node (function) in the call graph.
// Clones the the callees of edge.to to edge.from (with scaled count),
// and decreases the counts in for edge.to's callee accordingly.
// 2. Integrates the module.
// 2.1 Adds edge.to.module.aux_modules to edge.from.module
// 2.2 Sets the is_exported field of edge.to.module
void ModuleGrouper::IntegrateEdge(const CallEdge &edge) {
int64 count = edge_map_[edge];
int64 total = edge.to->total_in_count;
AddEdgeCount(edge, count * -1);
for (auto &callee_count : edge.to->out_edge_count) {
int64 scaled_count = callee_count.second * count / total;
if (scaled_count > 0) {
// Only add the scaled_count for non-recursive functions.
if (callee_count.first != edge.from) {
AddEdgeCount(CallEdge(edge.from, callee_count.first),
scaled_count);
}
// Decrease the scaled_count from the original callee.
AddEdgeCount(CallEdge(edge.to, callee_count.first), scaled_count * -1);
}
}
// Add the callee's module as the caller's module's aux-module.
ModuleMap::iterator from_module_iter = module_map_.find(edge.from->module);
ModuleMap::iterator to_module_iter = module_map_.find(edge.to->module);
if (from_module_iter->first != to_module_iter->first) {
if (!to_module_iter->second.is_fake) {
from_module_iter->second.aux_modules.insert(to_module_iter->first);
}
from_module_iter->second.aux_modules.insert(
to_module_iter->second.aux_modules.begin(),
to_module_iter->second.aux_modules.end());
to_module_iter->second.is_exported = true;
}
}
uint32 ModuleGrouper::GetTotalMemory(const set<string> &modules) {
uint32 ret = 0;
for (const auto &module : modules) {
ret += module_map_[module].ggc_memory_in_kb;
}
return ret;
}
// Data structure and content copied from gcc.
struct opt_desc {
const char *opt_str;
const char *opt_neg_str;
bool default_val;
};
static struct opt_desc force_match_opts[] = {
{ "-fexceptions", "-fno-exceptions", true },
{ "-fsized-delete", "-fno-sized-delete", false },
{ "-frtti", "-fno-rtti", true },
{ "-fstrict-aliasing", "-fno-strict-aliasing", true },
{ "-fsigned-char", "-funsigned-char", true},
};
static bool HasIncompatibleArg(const Module &m1, const Module &m2) {
for (int i = 0; i < sizeof(force_match_opts)/sizeof(opt_desc); i++) {
if (m1.flag_values.find(force_match_opts[i].opt_str)->second !=
m2.flag_values.find(force_match_opts[i].opt_str)->second) {
return false;
}
}
return true;
}
bool ModuleGrouper::ShouldIntegrate(const string &from_module,
const string &to_module) {
if (!module_map_[from_module].is_valid
|| !module_map_[to_module].is_valid) {
return false;
}
if (from_module == to_module) {
return true;
}
// Never integrate tcmalloc as auxilary module.
if (to_module == "tcmalloc/tcmalloc_or_debug.cc"
|| to_module == "tcmalloc/tcmalloc.cc") {
return false;
}
// We preprocess faked module first because it does not have lang field and
// flag_values fields.
if (!module_map_[to_module].is_fake && !module_map_[from_module].is_fake) {
if ((module_map_[from_module].lang & 0xffff) !=
(module_map_[to_module].lang & 0xffff)) {
return false;
}
if (!HasIncompatibleArg(module_map_[from_module], module_map_[to_module])) {
return false;
}
}
set<string> modules;
modules.insert(from_module);
modules.insert(to_module);
modules.insert(module_map_[from_module].aux_modules.begin(),
module_map_[from_module].aux_modules.end());
modules.insert(module_map_[to_module].aux_modules.begin(),
module_map_[to_module].aux_modules.end());
return GetTotalMemory(modules) < FLAGS_max_ggc_memory;
}
int64 ModuleGrouper::GetMaxEdge(CallEdge *edge) {
// TODO(dehao): use more effective approach to search.
int64 max_count = 0;
for (const auto &edge_count : edge_map_) {
if (edge_count.second > max_count ||
(edge_count.second == max_count && edge_count.first < *edge)) {
max_count = edge_count.second;
*edge = edge_count.first;
}
}
return max_count;
}
// Function that read in the options from the elf section.
void ModuleGrouper::ReadModuleOptions(const string &binary,
const string §ion_prefix) {
ReadOptionsByType(binary, section_prefix, QUOTE_PATHS);
ReadOptionsByType(binary, section_prefix, BRACKET_PATHS);
ReadOptionsByType(binary, section_prefix, SYSTEM_PATHS);
ReadOptionsByType(binary, section_prefix, CPP_DEFINES);
ReadOptionsByType(binary, section_prefix, CPP_INCLUDES);
ReadOptionsByType(binary, section_prefix, CL_ARGS);
ReadOptionsByType(binary, section_prefix, LIPO_INFO);
}
// Reads in command-line options from the elf section by a specific type.
void ModuleGrouper::ReadOptionsByType(const string &binary,
const string §ion_prefix,
OptionType type) {
// Reads from the elf .note sections to get the option info
// stored by the compiler.
ElfReader elf(binary);
const char *sect_data = NULL;
size_t section_size;
switch (type) {
case QUOTE_PATHS:
sect_data = elf.GetSectionByName(
section_prefix + ".quote_paths", §ion_size);
break;
case BRACKET_PATHS:
sect_data = elf.GetSectionByName(
section_prefix + ".bracket_paths", §ion_size);
break;
case SYSTEM_PATHS:
sect_data = elf.GetSectionByName(
section_prefix + ".system_paths", §ion_size);
break;
case CPP_DEFINES:
sect_data = elf.GetSectionByName(
section_prefix + ".cpp_defines", §ion_size);
break;
case CPP_INCLUDES:
sect_data = elf.GetSectionByName(
section_prefix + ".cpp_includes", §ion_size);
break;
case CL_ARGS:
sect_data = elf.GetSectionByName(
section_prefix + ".cl_args", §ion_size);
break;
case LIPO_INFO:
sect_data = elf.GetSectionByName(
section_prefix + ".lipo_info", §ion_size);
break;
}
if (!sect_data || section_size == 0)
return;
// Iterates all sections to read in compilation info stored by compiler.
for (const char *curr = sect_data; curr < sect_data + section_size;) {
const char *module_name = curr;
const char *num_ptr = curr + strlen(module_name) + 1;
ByteReader reader(ENDIANNESS_LITTLE);
size_t len;
uint64 option_num =
(type == LIPO_INFO) ? 0 : reader.ReadUnsignedLEB128(num_ptr, &len);
std::pair<ModuleMap::iterator, bool> status = module_map_.insert(
ModuleMap::value_type(module_name, Module()));
Module *module = &status.first->second;
bool is_duplicated = false;
switch (type) {
case QUOTE_PATHS:
if (module->num_quote_paths > 0) {
is_duplicated = true;
} else {
module->num_quote_paths = option_num;
}
break;
case SYSTEM_PATHS:
module->has_system_paths_field = true;
if (!sect_data || section_size == 0)
return;
if (module->num_system_paths > 0) {
is_duplicated = true;
} else {
module->num_system_paths = option_num;
}
break;
case BRACKET_PATHS:
if (module->num_bracket_paths > 0) {
is_duplicated = true;
} else {
module->num_bracket_paths = option_num;
}
break;
case CPP_DEFINES:
if (module->num_cpp_defines > 0) {
is_duplicated = true;
} else {
module->num_cpp_defines = option_num;
}
break;
case CPP_INCLUDES:
if (module->num_cpp_includes > 0) {
is_duplicated = true;
} else {
module->num_cpp_includes = option_num;
}
break;
case CL_ARGS:
if (module->num_cl_args > 0) {
is_duplicated = true;
} else {
module->num_cl_args = option_num;
}
break;
case LIPO_INFO:
size_t len1, len2;
module->lang = reader.ReadUnsignedLEB128(num_ptr, &len1);
module->ggc_memory_in_kb = reader.ReadUnsignedLEB128(num_ptr + len1,
&len2);
len = len1 + len2;
break;
}
for (int j = 0; j < sizeof(force_match_opts) / sizeof(opt_desc); j++) {
module->flag_values[force_match_opts[j].opt_str] =
force_match_opts[j].default_val;
}
curr = curr + strlen(curr) + 1 + len;
for (int j = 0; j < option_num; j++) {
if (!is_duplicated) {
module->options.push_back(Option(type, curr));
if (type == CL_ARGS) {
for (int k = 0; k < sizeof(force_match_opts) / sizeof(opt_desc);
k++) {
// Checks if flag matches with the force_match_opts, if none is
// matching, this flag does not need to be checked.
if (!strcmp(force_match_opts[k].opt_str, curr)) {
module->flag_values[force_match_opts[k].opt_str] = true;
} else if (!strcmp(force_match_opts[k].opt_neg_str, curr)) {
module->flag_values[force_match_opts[k].opt_str] = false;
}
}
}
} else if (module->options[module->options.size() - option_num + j].second
!= curr) {
module->is_valid = false;
LOG(ERROR) << "Duplicated module entry for " << module_name;
break;
}
curr += strlen(curr) + 1;
}
}
}
} // namespace autofdo