/* * Copyright (C) 2017 The Android Open Source Project * * 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 "CallChainJoiner.h" #include #include "environment.h" #include "utils.h" namespace simpleperf { namespace call_chain_joiner_impl { LRUCache::LRUCache(size_t cache_size, size_t matched_node_count_to_extend_callchain) : node_set_(1024 * 16, CacheNodeHash, CacheNodeEqual) { cache_stat_.cache_size = cache_size; cache_stat_.max_node_count = cache_size / sizeof(CacheNode); CHECK_GE(cache_stat_.max_node_count, 2u); CHECK_GE(matched_node_count_to_extend_callchain, 1u); cache_stat_.matched_node_count_to_extend_callchain = matched_node_count_to_extend_callchain; nodes_ = new CacheNode[cache_stat_.max_node_count + 1]; // with 1 sentinel node // nodes_[0] is the sentinel node of the LRU linked list. nodes_[0].is_leaf = 1; nodes_[0].parent_index = 0; nodes_[0].leaf_link_prev = nodes_[0].leaf_link_next = 0; } LRUCache::~LRUCache() { delete[] nodes_; } void LRUCache::AddCallChain(pid_t tid, std::vector& ips, std::vector& sps) { // 1. Build current call chain. std::vector chain; for (size_t i = 0; i < ips.size(); ++i) { CacheNode* node = GetNode(tid, ips[i], sps[i]); chain.push_back(node); } // 2. Check if the (tid, ip, sp) tuples of the top [matched_node_count_to_extend_callchain] // nodes of current call chain exist in the cache and have the same relation as in current // call chain. If true, we can extend current call chain. bool can_extend = true; if (chain.size() < cache_stat_.matched_node_count_to_extend_callchain) { can_extend = false; } else { size_t chain_pos = chain.size() - 2; for (size_t i = 1; i < cache_stat_.matched_node_count_to_extend_callchain; ++i) { if (GetParent(chain[chain_pos]) != chain[chain_pos + 1]) { can_extend = false; break; } } } std::vector origin_ip = ips; // 3. Add current call chain to the cache. for (size_t i = 0; i + 1 < chain.size(); ++i) { LinkParent(chain[i], chain[i + 1]); } // 4. Optionally extend current call chain. if (can_extend) { CacheNode* top = chain.back(); while ((top = GetParent(top)) != nullptr) { if (top->sp == chain.back()->sp) { // This is to prevent a loop case as below, which is unlikely to happen. // The cache has node A.parent = B, while current call chain has node B.parent = A. // This makes a loop of A -> B -> A -> B... bool has_loop = false; for (auto it = chain.rbegin(); it != chain.rend() && (*it)->sp == top->sp; ++it) { if ((*it)->ip == top->ip) { has_loop = true; break; } } if (has_loop) { UnlinkParent(chain.back()); ips.resize(chain.size()); sps.resize(chain.size()); break; } } ips.push_back(top->ip); sps.push_back(top->sp); } } else { UnlinkParent(chain.back()); } } bool LRUCache::CacheNodeEqual(const CacheNode* n1, const CacheNode* n2) { return n1->tid == n2->tid && n1->ip == n2->ip && n1->sp == n2->sp; } size_t LRUCache::CacheNodeHash(const CacheNode* n) { return static_cast(n->tid ^ n->ip ^ n->sp); } CacheNode* LRUCache::GetNode(uint32_t tid, uint64_t ip, uint64_t sp) { CacheNode* node = FindNode(tid, ip, sp); if (node != nullptr) { if (node->is_leaf) { // Update the node's position in the LRU linked list. RemoveNodeFromLRUList(node); AppendNodeToLRUList(node); } return node; } node = AllocNode(); node->tid = tid; node->ip = ip; node->sp = sp; node->is_leaf = 1; node->parent_index = 0; node->leaf_link_prev = node->leaf_link_next = GetNodeIndex(node); node_set_.insert(node); AppendNodeToLRUList(node); return node; } CacheNode* LRUCache::AllocNode() { if (cache_stat_.used_node_count < cache_stat_.max_node_count) { return &nodes_[++cache_stat_.used_node_count]; } // Recycle the node at the front of the LRU linked list. CacheNode* node = &nodes_[nodes_->leaf_link_next]; RemoveNodeFromLRUList(node); node_set_.erase(node); CacheNode* parent = GetParent(node); if (parent != nullptr) { DecreaseChildCountOfNode(parent); } cache_stat_.recycled_node_count++; return node; } void LRUCache::LinkParent(CacheNode* child, CacheNode* new_parent) { CacheNode* old_parent = GetParent(child); if (old_parent != nullptr) { DecreaseChildCountOfNode(old_parent); } child->parent_index = GetNodeIndex(new_parent); if (new_parent->is_leaf) { RemoveNodeFromLRUList(new_parent); new_parent->is_leaf = 0; new_parent->children_count = 1; } else { new_parent->children_count++; } } void LRUCache::UnlinkParent(CacheNode* child) { CacheNode* old_parent = GetParent(child); if (old_parent != nullptr) { DecreaseChildCountOfNode(old_parent); } child->parent_index = 0; } } // namespace call_chain_joiner_impl using namespace call_chain_joiner_impl; static bool WriteCallChain(FILE* fp, pid_t pid, pid_t tid, CallChainJoiner::ChainType type, const std::vector& ips, const std::vector& sps, size_t ip_count) { // Below is the content of a call chain stored in file. // uint32_t pid; // uint32_t tid; // uint32_t chain_type; // uint32_t ip_count; // uint64_t ips[]; // uint64_t sps[]; // uint32_t size; uint32_t size = 4 * sizeof(uint32_t) + sizeof(uint64_t) * ip_count * 2 + sizeof(uint32_t); std::vector data(size); char* p = data.data(); MoveToBinaryFormat(pid, p); MoveToBinaryFormat(tid, p); MoveToBinaryFormat(type, p); MoveToBinaryFormat(static_cast(ip_count), p); MoveToBinaryFormat(ips.data(), ip_count, p); MoveToBinaryFormat(sps.data(), ip_count, p); MoveToBinaryFormat(size, p); if (fwrite(data.data(), size, 1, fp) != 1) { PLOG(ERROR) << "fwrite"; return false; } return true; } static bool ReadCallChain(FILE* fp, pid_t& pid, pid_t& tid, CallChainJoiner::ChainType& type, std::vector& ips, std::vector& sps) { std::vector data(4 * sizeof(uint32_t)); if (fread(data.data(), data.size(), 1, fp) != 1) { PLOG(ERROR) << "fread"; return false; } const char* p = data.data(); MoveFromBinaryFormat(pid, p); MoveFromBinaryFormat(tid, p); MoveFromBinaryFormat(type, p); uint32_t ip_count; MoveFromBinaryFormat(ip_count, p); data.resize(sizeof(uint64_t) * ip_count * 2 + sizeof(uint32_t)); if (fread(data.data(), data.size(), 1, fp) != 1) { PLOG(ERROR) << "fread"; return false; } p = data.data(); ips.resize(ip_count); MoveFromBinaryFormat(ips.data(), ip_count, p); sps.resize(ip_count); MoveFromBinaryFormat(sps.data(), ip_count, p); return true; } static bool ReadCallChainInReverseOrder(FILE* fp, pid_t& pid, pid_t& tid, CallChainJoiner::ChainType& type, std::vector& ips, std::vector& sps) { uint32_t size; if (fseek(fp, -4, SEEK_CUR) != 0 || fread(&size, sizeof(size), 1, fp) != 1) { PLOG(ERROR) << "fread"; return false; } std::vector data(size - 4); if (fseek(fp, -static_cast(size), SEEK_CUR) != 0 || fread(data.data(), data.size(), 1, fp) != 1 || fseek(fp, -static_cast(data.size()), SEEK_CUR) != 0) { PLOG(ERROR) << "fread"; return false; } const char* p = data.data(); MoveFromBinaryFormat(pid, p); MoveFromBinaryFormat(tid, p); MoveFromBinaryFormat(type, p); uint32_t ip_count; MoveFromBinaryFormat(ip_count, p); ips.resize(ip_count); MoveFromBinaryFormat(ips.data(), ip_count, p); sps.resize(ip_count); MoveFromBinaryFormat(sps.data(), ip_count, p); return true; } static FILE* CreateTempFp() { std::unique_ptr tmpfile = ScopedTempFiles::CreateTempFile(); FILE* fp = fdopen(tmpfile->release(), "web+"); if (fp == nullptr) { PLOG(ERROR) << "fdopen"; return nullptr; } return fp; } CallChainJoiner::CallChainJoiner(size_t cache_size, size_t matched_node_count_to_extend_callchain, bool keep_original_callchains) : keep_original_callchains_(keep_original_callchains), original_chains_fp_(nullptr), joined_chains_fp_(nullptr), next_chain_index_(0u) { cache_stat_.cache_size = cache_size; cache_stat_.matched_node_count_to_extend_callchain = matched_node_count_to_extend_callchain; } CallChainJoiner::~CallChainJoiner() { if (original_chains_fp_ != nullptr) { fclose(original_chains_fp_); } if (joined_chains_fp_ != nullptr) { fclose(joined_chains_fp_); } } bool CallChainJoiner::AddCallChain(pid_t pid, pid_t tid, ChainType type, const std::vector& ips, const std::vector& sps) { CHECK_EQ(ips.size(), sps.size()); CHECK_GT(ips.size(), 0u); CHECK(type == ORIGINAL_OFFLINE || type == ORIGINAL_REMOTE); // Make sure sps are in non-decreasing order, and there is no duplicated items. size_t ip_count = ips.size(); for (size_t i = 1; i < ips.size(); ++i) { if (sps[i] < sps[i - 1]) { ip_count = i; break; } else if (sps[i] == sps[i - 1]) { bool has_duplicated_items = false; for (size_t j = i; j > 0 && sps[j - 1] == sps[i]; --j) { if (ips[j - 1] == ips[i]) { has_duplicated_items = true; break; } } if (has_duplicated_items) { ip_count = i; break; } } } if (original_chains_fp_ == nullptr) { original_chains_fp_ = CreateTempFp(); if (original_chains_fp_ == nullptr) { return false; } } stat_.chain_count++; return WriteCallChain(original_chains_fp_, pid, tid, type, ips, sps, ip_count); } bool CallChainJoiner::JoinCallChains() { if (stat_.chain_count == 0u) { return true; } LRUCache cache(cache_stat_.cache_size, cache_stat_.matched_node_count_to_extend_callchain); std::unique_ptr tmp_fp(CreateTempFp(), fclose); if (!tmp_fp) { return false; } joined_chains_fp_ = CreateTempFp(); if (joined_chains_fp_ == nullptr) { return false; } pid_t pid; pid_t tid; ChainType type; std::vector ips; std::vector sps; if (fseek(original_chains_fp_, 0, SEEK_END) != 0) { PLOG(ERROR) << "fseek"; return false; } std::vector> file_pairs = { std::make_pair(original_chains_fp_, tmp_fp.get()), std::make_pair(tmp_fp.get(), joined_chains_fp_)}; for (size_t pass = 0; pass < 2u; ++pass) { auto& pair = file_pairs[pass]; for (size_t i = 0; i < stat_.chain_count; ++i) { if (!ReadCallChainInReverseOrder(pair.first, pid, tid, type, ips, sps)) { return false; } if (pass == 0u) { if (type == ORIGINAL_OFFLINE) { type = JOINED_OFFLINE; } else if (type == ORIGINAL_REMOTE) { type = JOINED_REMOTE; } stat_.before_join_node_count += ips.size(); } cache.AddCallChain(tid, ips, sps); if (pass == 1u) { stat_.after_join_node_count += ips.size(); stat_.after_join_max_chain_length = std::max(stat_.after_join_max_chain_length, ips.size()); } if (!WriteCallChain(pair.second, pid, tid, type, ips, sps, ips.size())) { return false; } } } cache_stat_ = cache.Stat(); return true; } bool CallChainJoiner::GetNextCallChain(pid_t& pid, pid_t& tid, ChainType& type, std::vector& ips, std::vector& sps) { if (next_chain_index_ == stat_.chain_count * 2) { // No more chains. return false; } if (next_chain_index_ == 0u) { if (fseek(original_chains_fp_, 0, SEEK_SET) != 0 || fseek(joined_chains_fp_, 0, SEEK_SET) != 0) { PLOG(ERROR) << "fseek"; return false; } } FILE* fp; if (keep_original_callchains_) { fp = (next_chain_index_ & 1) ? joined_chains_fp_ : original_chains_fp_; next_chain_index_++; } else { fp = joined_chains_fp_; next_chain_index_ += 2; } return ReadCallChain(fp, pid, tid, type, ips, sps); } void CallChainJoiner::DumpStat() { LOG(DEBUG) << "call chain joiner stat:"; LOG(DEBUG) << " cache_size: " << cache_stat_.cache_size; LOG(DEBUG) << " matched_node_count_to_extend_callchain: " << cache_stat_.matched_node_count_to_extend_callchain; LOG(DEBUG) << " max_node_count in cache: " << cache_stat_.max_node_count; LOG(DEBUG) << " used_node_count in cache: " << cache_stat_.used_node_count; LOG(DEBUG) << " recycled_node_count in cache: " << cache_stat_.recycled_node_count; LOG(DEBUG) << " call_chain_count: " << stat_.chain_count; LOG(DEBUG) << " before_join_node_count: " << stat_.before_join_node_count; if (stat_.chain_count > 0u) { LOG(DEBUG) << " before_join_average_chain_length: " << (stat_.before_join_node_count * 1.0 / stat_.chain_count); } LOG(DEBUG) << " after_join_node_count: " << stat_.after_join_node_count; if (stat_.chain_count > 0u) { LOG(DEBUG) << " after_join_average_chain_length: " << (stat_.after_join_node_count * 1.0 / stat_.chain_count); } LOG(DEBUG) << " after_join_max_chain_length: " << stat_.after_join_max_chain_length; } } // namespace simpleperf