// Copyright (c) 2021 PaddlePaddle Authors. 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 "paddle/fluid/distributed/ps/table/common_graph_table.h" #include #include #include #include #include #include "paddle/fluid/distributed/common/utils.h" #include "paddle/fluid/distributed/ps/table/graph/graph_node.h" #include "paddle/fluid/framework/generator.h" #include "paddle/fluid/string/printf.h" #include "paddle/fluid/string/string_helper.h" namespace paddle { namespace distributed { #ifdef PADDLE_WITH_HETERPS int32_t GraphTable::Load_to_ssd(const std::string &path, const std::string ¶m) { bool load_edge = (param[0] == 'e'); bool load_node = (param[0] == 'n'); if (load_edge) { bool reverse_edge = (param[1] == '<'); std::string edge_type = param.substr(2); return this->load_edges_to_ssd(path, reverse_edge, edge_type); } if (load_node) { std::string node_type = param.substr(1); return this->load_nodes(path, node_type); } return 0; } paddle::framework::GpuPsCommGraph GraphTable::make_gpu_ps_graph( int idx, std::vector ids) { std::vector> bags(task_pool_size_); for (auto x : ids) { int location = x % shard_num % task_pool_size_; bags[location].push_back(x); } std::vector> tasks; std::vector edge_array[task_pool_size_]; std::vector node_array[task_pool_size_]; for (size_t i = 0; i < bags.size(); i++) { if (bags[i].size() > 0) { tasks.push_back(_shards_task_pool[i]->enqueue([&, i, this]() -> int { paddle::framework::GpuPsGraphNode x; for (size_t j = 0; j < bags[i].size(); j++) { Node *v = find_node(0, idx, bags[i][j]); x.node_id = bags[i][j]; if (v == NULL) { x.neighbor_size = 0; x.neighbor_offset = 0; node_array[i].push_back(x); } else { x.neighbor_size = v->get_neighbor_size(); x.neighbor_offset = edge_array[i].size(); node_array[i].push_back(x); for (size_t k = 0; k < x.neighbor_size; k++) { edge_array[i].push_back(v->get_neighbor_id(k)); } } } return 0; })); } } for (int i = 0; i < (int)tasks.size(); i++) tasks[i].get(); paddle::framework::GpuPsCommGraph res; unsigned int tot_len = 0; for (int i = 0; i < task_pool_size_; i++) { tot_len += edge_array[i].size(); } // res.neighbor_size = tot_len; // res.node_size = ids.size(); // res.neighbor_list = new int64_t[tot_len]; // res.node_list = new paddle::framework::GpuPsGraphNode[ids.size()]; res.init_on_cpu(tot_len, (unsigned int)ids.size()); unsigned int offset = 0, ind = 0; for (int i = 0; i < task_pool_size_; i++) { for (int j = 0; j < (int)node_array[i].size(); j++) { res.node_list[ind] = node_array[i][j]; res.node_list[ind++].neighbor_offset += offset; } for (size_t j = 0; j < edge_array[i].size(); j++) { res.neighbor_list[offset + j] = edge_array[i][j]; } offset += edge_array[i].size(); } return res; } int32_t GraphTable::add_node_to_ssd(int type_id, int idx, int64_t src_id, char *data, int len) { if (_db != NULL) { char ch[sizeof(int) * 2 + sizeof(int64_t)]; memcpy(ch, &type_id, sizeof(int)); memcpy(ch + sizeof(int), &idx, sizeof(int)); memcpy(ch + sizeof(int) * 2, &src_id, sizeof(int64_t)); std::string str; if (_db->get(src_id % shard_num % task_pool_size_, ch, sizeof(int) * 2 + sizeof(int64_t), str) == 0) { int64_t *stored_data = ((int64_t *)str.c_str()); int n = str.size() / sizeof(int64_t); char *new_data = new char[n * sizeof(int64_t) + len]; memcpy(new_data, stored_data, n * sizeof(int64_t)); memcpy(new_data + n * sizeof(int64_t), data, len); _db->put(src_id % shard_num % task_pool_size_, ch, sizeof(int) * 2 + sizeof(int64_t), (char *)new_data, n * sizeof(int64_t) + len); delete[] new_data; } else { _db->put(src_id % shard_num % task_pool_size_, ch, sizeof(int) * 2 + sizeof(int64_t), (char *)data, len); } _db->flush(src_id % shard_num % task_pool_size_); std::string x; // if (_db->get(src_id % shard_num % task_pool_size_, ch, sizeof(int64_t) + // 2 * sizeof(int), x) ==0){ // VLOG(0)<<"put result"; // for(int i = 0;i < x.size();i+=8){ // VLOG(0)<<"get an id "<<*((int64_t *)(x.c_str() + i)); // } //} } return 0; } char *GraphTable::random_sample_neighbor_from_ssd( int idx, int64_t id, int sample_size, const std::shared_ptr rng, int &actual_size) { if (_db == NULL) { actual_size = 0; return NULL; } std::string str; char ch[sizeof(int) * 2 + sizeof(int64_t)]; memset(ch, 0, sizeof(int)); memcpy(ch + sizeof(int), &idx, sizeof(int)); memcpy(ch + sizeof(int) * 2, &id, sizeof(int64_t)); if (_db->get(id % shard_num % task_pool_size_, ch, sizeof(int) * 2 + sizeof(int64_t), str) == 0) { int64_t *data = ((int64_t *)str.c_str()); int n = str.size() / sizeof(int64_t); std::unordered_map m; // std::vector res; int sm_size = std::min(n, sample_size); actual_size = sm_size * Node::id_size; char *buff = new char[actual_size]; for (int i = 0; i < sm_size; i++) { std::uniform_int_distribution distrib(0, n - i - 1); int t = distrib(*rng); // int t = rand() % (n-i); int pos = 0; auto iter = m.find(t); if (iter != m.end()) { pos = iter->second; } else { pos = t; } auto iter2 = m.find(n - i - 1); int key2 = iter2 == m.end() ? n - i - 1 : iter2->second; m[t] = key2; m.erase(n - i - 1); memcpy(buff + i * Node::id_size, &data[pos], Node::id_size); // res.push_back(data[pos]); } return buff; } actual_size = 0; return NULL; } int64_t GraphTable::load_graph_to_memory_from_ssd(int idx, std::vector &ids) { std::vector> bags(task_pool_size_); for (auto x : ids) { int location = x % shard_num % task_pool_size_; bags[location].push_back(x); } std::vector> tasks; std::vector count(task_pool_size_, 0); for (size_t i = 0; i < bags.size(); i++) { if (bags[i].size() > 0) { tasks.push_back(_shards_task_pool[i]->enqueue([&, i, idx, this]() -> int { char ch[sizeof(int) * 2 + sizeof(int64_t)]; memset(ch, 0, sizeof(int)); memcpy(ch + sizeof(int), &idx, sizeof(int)); for (size_t k = 0; k < bags[i].size(); k++) { auto v = bags[i][k]; memcpy(ch + sizeof(int) * 2, &v, sizeof(int64_t)); std::string str; if (_db->get(i, ch, sizeof(int) * 2 + sizeof(int64_t), str) == 0) { count[i] += (int64_t)str.size(); for (int j = 0; j < str.size(); j += sizeof(int64_t)) { int64_t id = *(int64_t *)(str.c_str() + j); add_comm_edge(idx, v, id); } } } return 0; })); } } for (int i = 0; i < (int)tasks.size(); i++) tasks[i].get(); int64_t tot = 0; for (auto x : count) tot += x; return tot; } void GraphTable::make_partitions(int idx, int64_t byte_size, int device_len) { VLOG(2) << "start to make graph partitions , byte_size = " << byte_size << " total memory cost = " << total_memory_cost; if (total_memory_cost == 0) { VLOG(0) << "no edges are detected,make partitions exits"; return; } const float a = 2.0, y = 1.25; int64_t gb_size_by_discount = byte_size * 0.8 * device_len; if (gb_size_by_discount <= 0) gb_size_by_discount = 1; int part_len = total_memory_cost / gb_size_by_discount; if (part_len == 0) part_len = 1; VLOG(2) << "part_len = " << part_len << " byte size = " << gb_size_by_discount; partitions[idx].clear(); partitions[idx].resize(part_len); std::vector memory_remaining(part_len, gb_size_by_discount); std::vector score(part_len, 0); std::unordered_map id_map; std::vector iters; for (int i = 0; i < task_pool_size_; i++) { iters.push_back(_db->get_iterator(i)); iters[i]->SeekToFirst(); } int next = 0; while (iters.size()) { if (next >= iters.size()) { next = 0; } if (!iters[next]->Valid()) { iters.erase(iters.begin() + next); continue; } std::string key = iters[next]->key().ToString(); int temp_idx = *(int *)(key.c_str() + sizeof(int)); if (temp_idx != idx) { iters[next]->Next(); next++; continue; } std::string value = iters[next]->value().ToString(); std::int64_t i_key = *(int64_t *)(key.c_str() + 8); for (int i = 0; i < part_len; i++) { if (memory_remaining[i] < (int64_t)value.size()) { score[i] = -100000.0; } else { score[i] = 0; } } for (int j = 0; j < value.size(); j += sizeof(int64_t)) { int64_t v = *((int64_t *)(value.c_str() + j)); int index = -1; if (id_map.find(v) != id_map.end()) { index = id_map[v]; score[index]++; } } float base; int index = 0; for (int i = 0; i < part_len; i++) { base = gb_size_by_discount - memory_remaining[i]; score[i] -= a * y * std::pow(1.0 * base, y - 1); if (score[i] > score[index]) index = i; VLOG(2) << "score" << i << " = " << score[i] << " memory left " << memory_remaining[i]; } id_map[i_key] = index; partitions[idx][index].push_back(i_key); memory_remaining[index] -= (int64_t)value.size(); iters[next]->Next(); next++; } for (int i = 0; i < part_len; i++) { if (partitions[idx][i].size() == 0) { partitions[idx].erase(partitions[idx].begin() + i); i--; part_len--; continue; } VLOG(2) << " partition " << i << " size = " << partitions[idx][i].size(); for (auto x : partitions[idx][i]) { VLOG(2) << "find a id " << x; } } next_partition = 0; } void GraphTable::clear_graph(int idx) { for (auto p : edge_shards[idx]) { delete p; } edge_shards[idx].clear(); for (size_t i = 0; i < shard_num_per_server; i++) { edge_shards[idx].push_back(new GraphShard()); } } int32_t GraphTable::load_next_partition(int idx) { if (next_partition >= partitions[idx].size()) { VLOG(0) << "partition iteration is done"; return -1; } clear_graph(idx); load_graph_to_memory_from_ssd(idx, partitions[idx][next_partition]); next_partition++; return 0; } int32_t GraphTable::load_edges_to_ssd(const std::string &path, bool reverse_edge, const std::string &edge_type) { int idx = 0; if (edge_type == "") { VLOG(0) << "edge_type not specified, loading edges to " << id_to_edge[0] << " part"; } else { if (edge_to_id.find(edge_type) == edge_to_id.end()) { VLOG(0) << "edge_type " << edge_type << " is not defined, nothing will be loaded"; return 0; } idx = edge_to_id[edge_type]; } total_memory_cost = 0; auto paths = paddle::string::split_string(path, ";"); int64_t count = 0; std::string sample_type = "random"; bool is_weighted = false; int valid_count = 0; for (auto path : paths) { std::ifstream file(path); std::string line; while (std::getline(file, line)) { VLOG(0) << "get a line from file " << line; auto values = paddle::string::split_string(line, "\t"); count++; if (values.size() < 2) continue; auto src_id = std::stoll(values[0]); auto dist_ids = paddle::string::split_string(values[1], ";"); std::vector dist_data; for (auto x : dist_ids) { dist_data.push_back(std::stoll(x)); total_memory_cost += sizeof(int64_t); } add_node_to_ssd(0, idx, src_id, (char *)dist_data.data(), (int)(dist_data.size() * sizeof(int64_t))); } } VLOG(0) << "total memory cost = " << total_memory_cost << " bytes"; return 0; } int32_t GraphTable::dump_edges_to_ssd(int idx) { VLOG(0) << "calling dump edges to ssd"; const int64_t fixed_size = 10000; // std::vector edge_array[task_pool_size_]; std::vector> count(task_pool_size_); std::vector> tasks; auto &shards = edge_shards[idx]; for (size_t i = 0; i < shards.size(); ++i) { tasks.push_back(_shards_task_pool[i % task_pool_size_]->enqueue( [&, i, this]() -> int64_t { int64_t cost = 0; std::vector &v = shards[i]->get_bucket(); std::vector s; size_t ind = i % this->task_pool_size_; for (size_t j = 0; j < v.size(); j++) { for (int k = 0; k < v[j]->get_neighbor_size(); k++) { s.push_back(v[j]->get_neighbor_id(k)); } cost += v[j]->get_neighbor_size() * sizeof(int64_t); add_node_to_ssd(0, idx, v[j]->get_id(), (char *)s.data(), s.size() * sizeof(int64_t)); } return cost; })); } for (size_t i = 0; i < tasks.size(); i++) total_memory_cost += tasks[i].get(); return 0; } int32_t GraphTable::make_complementary_graph(int idx, int64_t byte_size) { VLOG(0) << "make_complementary_graph"; const int64_t fixed_size = 10000; // std::vector edge_array[task_pool_size_]; std::vector> count(task_pool_size_); std::vector> tasks; auto &shards = edge_shards[idx]; for (size_t i = 0; i < shards.size(); ++i) { tasks.push_back( _shards_task_pool[i % task_pool_size_]->enqueue([&, i, this]() -> int { std::vector &v = shards[i]->get_bucket(); size_t ind = i % this->task_pool_size_; for (size_t j = 0; j < v.size(); j++) { size_t location = v[j]->get_id(); for (int k = 0; k < v[j]->get_neighbor_size(); k++) { count[ind][v[j]->get_neighbor_id(k)]++; } } return 0; })); } std::unordered_map final_count; std::map> count_to_id; std::vector buffer; for (auto p : edge_shards[idx]) { delete p; } edge_shards[idx].clear(); for (size_t i = 0; i < shard_num_per_server; i++) { edge_shards[idx].push_back(new GraphShard()); } for (size_t i = 0; i < tasks.size(); i++) tasks[i].get(); for (int i = 0; i < task_pool_size_; i++) { for (auto &p : count[i]) { final_count[p.first] = final_count[p.first] + p.second; } count[i].clear(); } for (auto &p : final_count) { count_to_id[p.second].push_back(p.first); VLOG(2) << p.first << " appear " << p.second << " times"; } // std::map>::iterator iter= count_to_id.rbegin(); auto iter = count_to_id.rbegin(); while (iter != count_to_id.rend() && byte_size > 0) { for (auto x : iter->second) { buffer.push_back(x); if (buffer.size() >= fixed_size) { int64_t res = load_graph_to_memory_from_ssd(idx, buffer); byte_size -= res; } if (byte_size <= 0) break; } iter++; } if (byte_size > 0 && buffer.size() > 0) { int64_t res = load_graph_to_memory_from_ssd(idx, buffer); byte_size -= res; } std::string sample_type = "random"; for (auto &shard : edge_shards[idx]) { auto bucket = shard->get_bucket(); for (size_t i = 0; i < bucket.size(); i++) { bucket[i]->build_sampler(sample_type); } } return 0; } #endif /* int CompleteGraphSampler::run_graph_sampling() { pthread_rwlock_t *rw_lock = graph_table->rw_lock.get(); pthread_rwlock_rdlock(rw_lock); std::cout << "in graph sampling" << std::endl; sample_nodes.clear(); sample_neighbors.clear(); sample_res.clear(); sample_nodes.resize(gpu_num); sample_neighbors.resize(gpu_num); sample_res.resize(gpu_num); std::vector>> sample_nodes_ex(graph_table->task_pool_size_); std::vector>> sample_neighbors_ex( graph_table->task_pool_size_); for (int i = 0; i < graph_table->task_pool_size_; i++) { sample_nodes_ex[i].resize(gpu_num); sample_neighbors_ex[i].resize(gpu_num); } std::vector> tasks; for (size_t i = 0; i < graph_table->shards.size(); ++i) { tasks.push_back( graph_table->_shards_task_pool[i % graph_table->task_pool_size_] ->enqueue([&, i, this]() -> int { if (this->status == GraphSamplerStatus::terminating) return 0; paddle::framework::GpuPsGraphNode node; std::vector &v = this->graph_table->shards[i]->get_bucket(); size_t ind = i % this->graph_table->task_pool_size_; for (size_t j = 0; j < v.size(); j++) { size_t location = v[j]->get_id() % this->gpu_num; node.node_id = v[j]->get_id(); node.neighbor_size = v[j]->get_neighbor_size(); node.neighbor_offset = (int)sample_neighbors_ex[ind][location].size(); sample_nodes_ex[ind][location].emplace_back(node); for (int k = 0; k < node.neighbor_size; k++) sample_neighbors_ex[ind][location].push_back( v[j]->get_neighbor_id(k)); } return 0; })); } for (size_t i = 0; i < tasks.size(); i++) tasks[i].get(); tasks.clear(); for (int i = 0; i < gpu_num; i++) { tasks.push_back( graph_table->_shards_task_pool[i % graph_table->task_pool_size_] ->enqueue([&, i, this]() -> int { if (this->status == GraphSamplerStatus::terminating) return 0; int total_offset = 0; size_t ind = i % this->graph_table->task_pool_size_; for (int j = 0; j < this->graph_table->task_pool_size_; j++) { for (size_t k = 0; k < sample_nodes_ex[j][ind].size(); k++) { sample_nodes[ind].push_back(sample_nodes_ex[j][ind][k]); sample_nodes[ind].back().neighbor_offset += total_offset; } size_t neighbor_size = sample_neighbors_ex[j][ind].size(); total_offset += neighbor_size; for (size_t k = 0; k < neighbor_size; k++) { sample_neighbors[ind].push_back( sample_neighbors_ex[j][ind][k]); } } return 0; })); } for (size_t i = 0; i < tasks.size(); i++) tasks[i].get(); if (this->status == GraphSamplerStatus::terminating) { pthread_rwlock_unlock(rw_lock); return 0; } for (int i = 0; i < gpu_num; i++) { sample_res[i].node_list = sample_nodes[i].data(); sample_res[i].neighbor_list = sample_neighbors[i].data(); sample_res[i].node_size = sample_nodes[i].size(); sample_res[i].neighbor_size = sample_neighbors[i].size(); } pthread_rwlock_unlock(rw_lock); if (this->status == GraphSamplerStatus::terminating) { return 0; } callback(sample_res); return 0; } void CompleteGraphSampler::init(size_t gpu_num, GraphTable *graph_table, std::vector args) { this->gpu_num = gpu_num; this->graph_table = graph_table; } int BasicBfsGraphSampler::run_graph_sampling() { pthread_rwlock_t *rw_lock = graph_table->rw_lock.get(); pthread_rwlock_rdlock(rw_lock); while (rounds > 0 && status == GraphSamplerStatus::running) { for (size_t i = 0; i < sample_neighbors_map.size(); i++) { sample_neighbors_map[i].clear(); } sample_neighbors_map.clear(); std::vector nodes_left(graph_table->shards.size(), node_num_for_each_shard); std::promise prom; std::future fut = prom.get_future(); sample_neighbors_map.resize(graph_table->task_pool_size_); int task_size = 0; std::vector> tasks; int init_size = 0; //__sync_fetch_and_add std::function bfs = [&, this](int i, int id) -> int { if (this->status == GraphSamplerStatus::terminating) { int task_left = __sync_sub_and_fetch(&task_size, 1); if (task_left == 0) { prom.set_value(0); } return 0; } size_t ind = i % this->graph_table->task_pool_size_; if (nodes_left[i] > 0) { auto iter = sample_neighbors_map[ind].find(id); if (iter == sample_neighbors_map[ind].end()) { Node *node = graph_table->shards[i]->find_node(id); if (node != NULL) { nodes_left[i]--; sample_neighbors_map[ind][id] = std::vector(); iter = sample_neighbors_map[ind].find(id); size_t edge_fetch_size = std::min((size_t) this->edge_num_for_each_node, node->get_neighbor_size()); for (size_t k = 0; k < edge_fetch_size; k++) { int64_t neighbor_id = node->get_neighbor_id(k); int node_location = neighbor_id % this->graph_table->shard_num % this->graph_table->task_pool_size_; __sync_add_and_fetch(&task_size, 1); graph_table->_shards_task_pool[node_location]->enqueue( bfs, neighbor_id % this->graph_table->shard_num, neighbor_id); iter->second.push_back(neighbor_id); } } } } int task_left = __sync_sub_and_fetch(&task_size, 1); if (task_left == 0) { prom.set_value(0); } return 0; }; for (size_t i = 0; i < graph_table->shards.size(); ++i) { std::vector &v = graph_table->shards[i]->get_bucket(); if (v.size() > 0) { int search_size = std::min(init_search_size, (int)v.size()); for (int k = 0; k < search_size; k++) { init_size++; __sync_add_and_fetch(&task_size, 1); int64_t id = v[k]->get_id(); graph_table->_shards_task_pool[i % graph_table->task_pool_size_] ->enqueue(bfs, i, id); } } // if } if (init_size == 0) { prom.set_value(0); } fut.get(); if (this->status == GraphSamplerStatus::terminating) { pthread_rwlock_unlock(rw_lock); return 0; } VLOG(0) << "BasicBfsGraphSampler finishes the graph searching task"; sample_nodes.clear(); sample_neighbors.clear(); sample_res.clear(); sample_nodes.resize(gpu_num); sample_neighbors.resize(gpu_num); sample_res.resize(gpu_num); std::vector>> sample_nodes_ex(graph_table->task_pool_size_); std::vector>> sample_neighbors_ex( graph_table->task_pool_size_); for (int i = 0; i < graph_table->task_pool_size_; i++) { sample_nodes_ex[i].resize(gpu_num); sample_neighbors_ex[i].resize(gpu_num); } tasks.clear(); for (size_t i = 0; i < (size_t)graph_table->task_pool_size_; ++i) { tasks.push_back( graph_table->_shards_task_pool[i]->enqueue([&, i, this]() -> int { if (this->status == GraphSamplerStatus::terminating) { return 0; } paddle::framework::GpuPsGraphNode node; auto iter = sample_neighbors_map[i].begin(); size_t ind = i; for (; iter != sample_neighbors_map[i].end(); iter++) { size_t location = iter->first % this->gpu_num; node.node_id = iter->first; node.neighbor_size = iter->second.size(); node.neighbor_offset = (int)sample_neighbors_ex[ind][location].size(); sample_nodes_ex[ind][location].emplace_back(node); for (auto k : iter->second) sample_neighbors_ex[ind][location].push_back(k); } return 0; })); } for (size_t i = 0; i < tasks.size(); i++) { tasks[i].get(); sample_neighbors_map[i].clear(); } tasks.clear(); if (this->status == GraphSamplerStatus::terminating) { pthread_rwlock_unlock(rw_lock); return 0; } for (size_t i = 0; i < (size_t)gpu_num; i++) { tasks.push_back( graph_table->_shards_task_pool[i % graph_table->task_pool_size_] ->enqueue([&, i, this]() -> int { if (this->status == GraphSamplerStatus::terminating) { pthread_rwlock_unlock(rw_lock); return 0; } int total_offset = 0; for (int j = 0; j < this->graph_table->task_pool_size_; j++) { for (size_t k = 0; k < sample_nodes_ex[j][i].size(); k++) { sample_nodes[i].push_back(sample_nodes_ex[j][i][k]); sample_nodes[i].back().neighbor_offset += total_offset; } size_t neighbor_size = sample_neighbors_ex[j][i].size(); total_offset += neighbor_size; for (size_t k = 0; k < neighbor_size; k++) { sample_neighbors[i].push_back(sample_neighbors_ex[j][i][k]); } } return 0; })); } for (size_t i = 0; i < tasks.size(); i++) tasks[i].get(); if (this->status == GraphSamplerStatus::terminating) { pthread_rwlock_unlock(rw_lock); return 0; } for (int i = 0; i < gpu_num; i++) { sample_res[i].node_list = sample_nodes[i].data(); sample_res[i].neighbor_list = sample_neighbors[i].data(); sample_res[i].node_size = sample_nodes[i].size(); sample_res[i].neighbor_size = sample_neighbors[i].size(); } pthread_rwlock_unlock(rw_lock); if (this->status == GraphSamplerStatus::terminating) { return 0; } callback(sample_res); rounds--; if (rounds > 0) { for (int i = 0; i < interval && this->status == GraphSamplerStatus::running; i++) { std::this_thread::sleep_for(std::chrono::seconds(1)); } } VLOG(0)<<"bfs returning"; } return 0; } void BasicBfsGraphSampler::init(size_t gpu_num, GraphTable *graph_table, std::vector args) { this->gpu_num = gpu_num; this->graph_table = graph_table; init_search_size = args.size() > 0 ? std::stoi(args[0]) : 10; node_num_for_each_shard = args.size() > 1 ? std::stoi(args[1]) : 10; edge_num_for_each_node = args.size() > 2 ? std::stoi(args[2]) : 10; rounds = args.size() > 3 ? std::stoi(args[3]) : 1; interval = args.size() > 4 ? std::stoi(args[4]) : 60; } #endif */ std::vector GraphShard::get_batch(int start, int end, int step) { if (start < 0) start = 0; std::vector res; for (int pos = start; pos < std::min(end, (int)bucket.size()); pos += step) { res.push_back(bucket[pos]); } return res; } size_t GraphShard::get_size() { return bucket.size(); } int32_t GraphTable::add_comm_edge(int idx, int64_t src_id, int64_t dst_id) { size_t src_shard_id = src_id % shard_num; if (src_shard_id >= shard_end || src_shard_id < shard_start) { return -1; } size_t index = src_shard_id - shard_start; edge_shards[idx][index]->add_graph_node(src_id)->build_edges(false); edge_shards[idx][index]->add_neighbor(src_id, dst_id, 1.0); return 0; } int32_t GraphTable::add_graph_node(int idx, std::vector &id_list, std::vector &is_weight_list) { auto &shards = edge_shards[idx]; size_t node_size = id_list.size(); std::vector>> batch(task_pool_size_); for (size_t i = 0; i < node_size; i++) { size_t shard_id = id_list[i] % shard_num; if (shard_id >= shard_end || shard_id < shard_start) { continue; } batch[get_thread_pool_index(id_list[i])].push_back( {id_list[i], i < is_weight_list.size() ? is_weight_list[i] : false}); } std::vector> tasks; for (size_t i = 0; i < batch.size(); ++i) { if (!batch[i].size()) continue; tasks.push_back( _shards_task_pool[i]->enqueue([&shards, &batch, i, this]() -> int { for (auto &p : batch[i]) { size_t index = p.first % this->shard_num - this->shard_start; shards[index]->add_graph_node(p.first)->build_edges(p.second); } return 0; })); } for (size_t i = 0; i < tasks.size(); i++) tasks[i].get(); return 0; } int32_t GraphTable::remove_graph_node(int idx, std::vector &id_list) { size_t node_size = id_list.size(); std::vector> batch(task_pool_size_); for (size_t i = 0; i < node_size; i++) { size_t shard_id = id_list[i] % shard_num; if (shard_id >= shard_end || shard_id < shard_start) continue; batch[get_thread_pool_index(id_list[i])].push_back(id_list[i]); } auto &shards = edge_shards[idx]; std::vector> tasks; for (size_t i = 0; i < batch.size(); ++i) { if (!batch[i].size()) continue; tasks.push_back( _shards_task_pool[i]->enqueue([&shards, &batch, i, this]() -> int { for (auto &p : batch[i]) { size_t index = p % this->shard_num - this->shard_start; shards[index]->delete_node(p); } return 0; })); } for (size_t i = 0; i < tasks.size(); i++) tasks[i].get(); return 0; } void GraphShard::clear() { for (size_t i = 0; i < bucket.size(); i++) { delete bucket[i]; } bucket.clear(); node_location.clear(); } GraphShard::~GraphShard() { clear(); } void GraphShard::delete_node(int64_t id) { auto iter = node_location.find(id); if (iter == node_location.end()) return; int pos = iter->second; delete bucket[pos]; if (pos != (int)bucket.size() - 1) { bucket[pos] = bucket.back(); node_location[bucket.back()->get_id()] = pos; } node_location.erase(id); bucket.pop_back(); } GraphNode *GraphShard::add_graph_node(int64_t id) { if (node_location.find(id) == node_location.end()) { node_location[id] = bucket.size(); bucket.push_back(new GraphNode(id)); } return (GraphNode *)bucket[node_location[id]]; } GraphNode *GraphShard::add_graph_node(Node *node) { auto id = node->get_id(); if (node_location.find(id) == node_location.end()) { node_location[id] = bucket.size(); bucket.push_back(node); } return (GraphNode *)bucket[node_location[id]]; } FeatureNode *GraphShard::add_feature_node(int64_t id) { if (node_location.find(id) == node_location.end()) { node_location[id] = bucket.size(); bucket.push_back(new FeatureNode(id)); } return (FeatureNode *)bucket[node_location[id]]; } void GraphShard::add_neighbor(int64_t id, int64_t dst_id, float weight) { find_node(id)->add_edge(dst_id, weight); } Node *GraphShard::find_node(int64_t id) { auto iter = node_location.find(id); return iter == node_location.end() ? nullptr : bucket[iter->second]; } GraphTable::~GraphTable() { for (int i = 0; i < (int)edge_shards.size(); i++) { for (auto p : edge_shards[i]) { delete p; } edge_shards[i].clear(); } for (int i = 0; i < (int)feature_shards.size(); i++) { for (auto p : feature_shards[i]) { delete p; } feature_shards[i].clear(); } } int32_t GraphTable::Load(const std::string &path, const std::string ¶m) { bool load_edge = (param[0] == 'e'); bool load_node = (param[0] == 'n'); if (load_edge) { bool reverse_edge = (param[1] == '<'); std::string edge_type = param.substr(2); return this->load_edges(path, reverse_edge, edge_type); } if (load_node) { std::string node_type = param.substr(1); return this->load_nodes(path, node_type); } return 0; } int32_t GraphTable::get_nodes_ids_by_ranges( int type_id, int idx, std::vector> ranges, std::vector &res) { int start = 0, end, index = 0, total_size = 0; res.clear(); auto &shards = type_id == 0 ? edge_shards[idx] : feature_shards[idx]; std::vector>> tasks; for (size_t i = 0; i < shards.size() && index < (int)ranges.size(); i++) { end = total_size + shards[i]->get_size(); start = total_size; while (start < end && index < (int)ranges.size()) { if (ranges[index].second <= start) index++; else if (ranges[index].first >= end) { break; } else { int first = std::max(ranges[index].first, start); int second = std::min(ranges[index].second, end); start = second; first -= total_size; second -= total_size; tasks.push_back(_shards_task_pool[i % task_pool_size_]->enqueue( [&shards, this, first, second, i]() -> std::vector { return shards[i]->get_ids_by_range(first, second); })); } } total_size += shards[i]->get_size(); } for (size_t i = 0; i < tasks.size(); i++) { auto vec = tasks[i].get(); for (auto &id : vec) { res.push_back(id); std::swap(res[rand() % res.size()], res[(int)res.size() - 1]); } } return 0; } int32_t GraphTable::load_nodes(const std::string &path, std::string node_type) { auto paths = paddle::string::split_string(path, ";"); int64_t count = 0; int64_t valid_count = 0; int idx = 0; if (node_type == "") { VLOG(0) << "node_type not specified, loading edges to " << id_to_feature[0] << " part"; } else { if (feature_to_id.find(node_type) == feature_to_id.end()) { VLOG(0) << "node_type " << node_type << " is not defined, nothing will be loaded"; return 0; } idx = feature_to_id[node_type]; } for (auto path : paths) { std::ifstream file(path); std::string line; while (std::getline(file, line)) { auto values = paddle::string::split_string(line, "\t"); if (values.size() < 2) continue; auto id = std::stoull(values[1]); size_t shard_id = id % shard_num; if (shard_id >= shard_end || shard_id < shard_start) { VLOG(4) << "will not load " << id << " from " << path << ", please check id distribution"; continue; } if (count % 1000000 == 0) { VLOG(0) << count << " nodes are loaded from filepath"; VLOG(0) << line; } count++; std::string nt = values[0]; if (nt != node_type) { continue; } size_t index = shard_id - shard_start; // auto node = shards[index]->add_feature_node(id); auto node = feature_shards[idx][index]->add_feature_node(id); node->set_feature_size(feat_name[idx].size()); for (size_t slice = 2; slice < values.size(); slice++) { auto feat = this->parse_feature(idx, values[slice]); if (feat.first >= 0) { node->set_feature(feat.first, feat.second); } else { VLOG(4) << "Node feature: " << values[slice] << " not in feature_map."; } } valid_count++; } } VLOG(0) << valid_count << "/" << count << " nodes in type " << node_type << " are loaded successfully in " << path; return 0; } int32_t GraphTable::build_sampler(int idx, std::string sample_type) { for (auto &shard : edge_shards[idx]) { auto bucket = shard->get_bucket(); for (size_t i = 0; i < bucket.size(); i++) { bucket[i]->build_sampler(sample_type); } } return 0; } int32_t GraphTable::load_edges(const std::string &path, bool reverse_edge, const std::string &edge_type) { #ifdef PADDLE_WITH_HETERPS // if (gpups_mode) pthread_rwlock_rdlock(rw_lock.get()); if (search_level == 2) total_memory_cost = 0; const int64_t fixed_load_edges = 1000000; #endif int idx = 0; if (edge_type == "") { VLOG(0) << "edge_type not specified, loading edges to " << id_to_edge[0] << " part"; } else { if (edge_to_id.find(edge_type) == edge_to_id.end()) { VLOG(0) << "edge_type " << edge_type << " is not defined, nothing will be loaded"; return 0; } idx = edge_to_id[edge_type]; } auto paths = paddle::string::split_string(path, ";"); int64_t count = 0; std::string sample_type = "random"; bool is_weighted = false; int valid_count = 0; for (auto path : paths) { std::ifstream file(path); std::string line; while (std::getline(file, line)) { auto values = paddle::string::split_string(line, "\t"); count++; if (values.size() < 2) continue; auto src_id = std::stoull(values[0]); auto dst_id = std::stoull(values[1]); if (reverse_edge) { std::swap(src_id, dst_id); } float weight = 1; if (values.size() == 3) { weight = std::stof(values[2]); sample_type = "weighted"; is_weighted = true; } size_t src_shard_id = src_id % shard_num; if (src_shard_id >= shard_end || src_shard_id < shard_start) { VLOG(4) << "will not load " << src_id << " from " << path << ", please check id distribution"; continue; } if (count % 1000000 == 0) { VLOG(0) << count << " edges are loaded from filepath"; VLOG(0) << line; } size_t index = src_shard_id - shard_start; edge_shards[idx][index]->add_graph_node(src_id)->build_edges(is_weighted); edge_shards[idx][index]->add_neighbor(src_id, dst_id, weight); valid_count++; #ifdef PADDLE_WITH_HETERPS // if (gpups_mode) pthread_rwlock_rdlock(rw_lock.get()); if (count > fixed_load_edges && search_level == 2) { dump_edges_to_ssd(idx); VLOG(0) << "dumping edges to ssd, edge count is reset to 0"; clear_graph(idx); count = 0; } #endif } } VLOG(0) << valid_count << "/" << count << " edges are loaded successfully in " << path; // Build Sampler j #ifdef PADDLE_WITH_HETERPS // if (gpups_mode) pthread_rwlock_rdlock(rw_lock.get()); if (search_level == 2) { if (count > 0) { dump_edges_to_ssd(idx); VLOG(0) << "dumping edges to ssd, edge count is reset to 0"; clear_graph(idx); count = 0; } return 0; } #endif for (auto &shard : edge_shards[idx]) { auto bucket = shard->get_bucket(); for (size_t i = 0; i < bucket.size(); i++) { bucket[i]->build_sampler(sample_type); } } return 0; } Node *GraphTable::find_node(int type_id, int idx, int64_t id) { size_t shard_id = id % shard_num; if (shard_id >= shard_end || shard_id < shard_start) { return nullptr; } size_t index = shard_id - shard_start; auto &search_shards = type_id == 0 ? edge_shards[idx] : feature_shards[idx]; Node *node = search_shards[index]->find_node(id); return node; } uint32_t GraphTable::get_thread_pool_index(int64_t node_id) { return node_id % shard_num % shard_num_per_server % task_pool_size_; } uint32_t GraphTable::get_thread_pool_index_by_shard_index(int64_t shard_index) { return shard_index % shard_num_per_server % task_pool_size_; } int32_t GraphTable::clear_nodes(int type_id, int idx) { auto &search_shards = type_id == 0 ? edge_shards[idx] : feature_shards[idx]; for (int i = 0; i < search_shards.size(); i++) { search_shards[i]->clear(); } return 0; } int32_t GraphTable::random_sample_nodes(int type_id, int idx, int sample_size, std::unique_ptr &buffer, int &actual_size) { int total_size = 0; auto &shards = type_id == 0 ? edge_shards[idx] : feature_shards[idx]; for (int i = 0; i < (int)shards.size(); i++) { total_size += shards[i]->get_size(); } if (sample_size > total_size) sample_size = total_size; int range_num = random_sample_nodes_ranges; if (range_num > sample_size) range_num = sample_size; if (sample_size == 0 || range_num == 0) return 0; std::vector ranges_len, ranges_pos; int remain = sample_size, last_pos = -1, num; std::set separator_set; for (int i = 0; i < range_num - 1; i++) { while (separator_set.find(num = rand() % (sample_size - 1)) != separator_set.end()) ; separator_set.insert(num); } for (auto p : separator_set) { ranges_len.push_back(p - last_pos); last_pos = p; } ranges_len.push_back(sample_size - 1 - last_pos); remain = total_size - sample_size + range_num; separator_set.clear(); for (int i = 0; i < range_num; i++) { while (separator_set.find(num = rand() % remain) != separator_set.end()) ; separator_set.insert(num); } int used = 0, index = 0; last_pos = -1; for (auto p : separator_set) { used += p - last_pos - 1; last_pos = p; ranges_pos.push_back(used); used += ranges_len[index++]; } std::vector> first_half, second_half; int start_index = rand() % total_size; for (size_t i = 0; i < ranges_len.size() && i < ranges_pos.size(); i++) { if (ranges_pos[i] + ranges_len[i] - 1 + start_index < total_size) first_half.push_back({ranges_pos[i] + start_index, ranges_pos[i] + ranges_len[i] + start_index}); else if (ranges_pos[i] + start_index >= total_size) { second_half.push_back( {ranges_pos[i] + start_index - total_size, ranges_pos[i] + ranges_len[i] + start_index - total_size}); } else { first_half.push_back({ranges_pos[i] + start_index, total_size}); second_half.push_back( {0, ranges_pos[i] + ranges_len[i] + start_index - total_size}); } } for (auto &pair : first_half) second_half.push_back(pair); std::vector res; get_nodes_ids_by_ranges(type_id, idx, second_half, res); actual_size = res.size() * sizeof(int64_t); buffer.reset(new char[actual_size]); char *pointer = buffer.get(); memcpy(pointer, res.data(), actual_size); return 0; } int32_t GraphTable::random_sample_neighbors( int idx, int64_t *node_ids, int sample_size, std::vector> &buffers, std::vector &actual_sizes, bool need_weight) { size_t node_num = buffers.size(); std::function char_del = [](char *c) { delete[] c; }; std::vector> tasks; std::vector> seq_id(task_pool_size_); std::vector> id_list(task_pool_size_); size_t index; for (size_t idy = 0; idy < node_num; ++idy) { index = get_thread_pool_index(node_ids[idy]); seq_id[index].emplace_back(idy); id_list[index].emplace_back(idx, node_ids[idy], sample_size, need_weight); } for (int i = 0; i < (int)seq_id.size(); i++) { if (seq_id[i].size() == 0) continue; tasks.push_back(_shards_task_pool[i]->enqueue([&, i, this]() -> int { int64_t node_id; std::vector> r; LRUResponse response = LRUResponse::blocked; if (use_cache) { response = scaled_lru->query(i, id_list[i].data(), id_list[i].size(), r); } int index = 0; std::vector sample_res; std::vector sample_keys; auto &rng = _shards_task_rng_pool[i]; for (size_t k = 0; k < id_list[i].size(); k++) { if (index < (int)r.size() && r[index].first.node_key == id_list[i][k].node_key) { int idy = seq_id[i][k]; actual_sizes[idy] = r[index].second.actual_size; buffers[idy] = r[index].second.buffer; index++; } else { node_id = id_list[i][k].node_key; Node *node = find_node(0, idx, node_id); int idy = seq_id[i][k]; int &actual_size = actual_sizes[idy]; if (node == nullptr) { #ifdef PADDLE_WITH_HETERPS if (search_level == 2) { VLOG(2) << "enter sample from ssd"; char *buffer_addr = random_sample_neighbor_from_ssd( idx, node_id, sample_size, rng, actual_size); if (actual_size != 0) { std::shared_ptr &buffer = buffers[idx]; buffer.reset(buffer_addr, char_del); } continue; } #endif actual_size = 0; continue; } std::shared_ptr &buffer = buffers[idy]; std::vector res = node->sample_k(sample_size, rng); actual_size = res.size() * (need_weight ? (Node::id_size + Node::weight_size) : Node::id_size); int offset = 0; int64_t id; float weight; char *buffer_addr = new char[actual_size]; if (response == LRUResponse::ok) { sample_keys.emplace_back(idx, node_id, sample_size, need_weight); sample_res.emplace_back(actual_size, buffer_addr); buffer = sample_res.back().buffer; } else { buffer.reset(buffer_addr, char_del); } for (int &x : res) { id = node->get_neighbor_id(x); memcpy(buffer_addr + offset, &id, Node::id_size); offset += Node::id_size; if (need_weight) { weight = node->get_neighbor_weight(x); memcpy(buffer_addr + offset, &weight, Node::weight_size); offset += Node::weight_size; } } } } if (sample_res.size()) { scaled_lru->insert(i, sample_keys.data(), sample_res.data(), sample_keys.size()); } return 0; })); } for (auto &t : tasks) { t.get(); } return 0; } int32_t GraphTable::get_node_feat(int idx, const std::vector &node_ids, const std::vector &feature_names, std::vector> &res) { size_t node_num = node_ids.size(); std::vector> tasks; for (size_t idy = 0; idy < node_num; ++idy) { int64_t node_id = node_ids[idy]; tasks.push_back(_shards_task_pool[get_thread_pool_index(node_id)]->enqueue( [&, idx, idy, node_id]() -> int { Node *node = find_node(1, idx, node_id); if (node == nullptr) { return 0; } for (int feat_idx = 0; feat_idx < (int)feature_names.size(); ++feat_idx) { const std::string &feature_name = feature_names[feat_idx]; if (feat_id_map[idx].find(feature_name) != feat_id_map[idx].end()) { // res[feat_idx][idx] = // node->get_feature(feat_id_map[feature_name]); auto feat = node->get_feature(feat_id_map[idx][feature_name]); res[feat_idx][idy] = feat; } } return 0; })); } for (size_t idy = 0; idy < node_num; ++idy) { tasks[idy].get(); } return 0; } int32_t GraphTable::set_node_feat( int idx, const std::vector &node_ids, const std::vector &feature_names, const std::vector> &res) { size_t node_num = node_ids.size(); std::vector> tasks; for (size_t idy = 0; idy < node_num; ++idy) { int64_t node_id = node_ids[idy]; tasks.push_back(_shards_task_pool[get_thread_pool_index(node_id)]->enqueue( [&, idx, idy, node_id]() -> int { size_t index = node_id % this->shard_num - this->shard_start; auto node = feature_shards[idx][index]->add_feature_node(node_id); node->set_feature_size(this->feat_name[idx].size()); for (int feat_idx = 0; feat_idx < (int)feature_names.size(); ++feat_idx) { const std::string &feature_name = feature_names[feat_idx]; if (feat_id_map[idx].find(feature_name) != feat_id_map[idx].end()) { node->set_feature(feat_id_map[idx][feature_name], res[feat_idx][idy]); } } return 0; })); } for (size_t idy = 0; idy < node_num; ++idy) { tasks[idy].get(); } return 0; } std::pair GraphTable::parse_feature( int idx, std::string feat_str) { // Return (feat_id, btyes) if name are in this->feat_name, else return (-1, // "") auto fields = paddle::string::split_string(feat_str, " "); if (feat_id_map[idx].count(fields[0])) { // if (this->feat_id_map.count(fields[0])) { int32_t id = this->feat_id_map[idx][fields[0]]; std::string dtype = this->feat_dtype[idx][id]; std::vector values(fields.begin() + 1, fields.end()); if (dtype == "feasign") { return std::make_pair( int32_t(id), paddle::string::join_strings(values, ' ')); } else if (dtype == "string") { return std::make_pair( int32_t(id), paddle::string::join_strings(values, ' ')); } else if (dtype == "float32") { return std::make_pair( int32_t(id), FeatureNode::parse_value_to_bytes(values)); } else if (dtype == "float64") { return std::make_pair( int32_t(id), FeatureNode::parse_value_to_bytes(values)); } else if (dtype == "int32") { return std::make_pair( int32_t(id), FeatureNode::parse_value_to_bytes(values)); } else if (dtype == "int64") { return std::make_pair( int32_t(id), FeatureNode::parse_value_to_bytes(values)); } } return std::make_pair(-1, ""); } std::vector> GraphTable::get_all_id(int type_id, int idx, int slice_num) { std::vector> res(slice_num); auto &search_shards = type_id == 0 ? edge_shards[idx] : feature_shards[idx]; std::vector>> tasks; for (int i = 0; i < search_shards.size(); i++) { tasks.push_back(_shards_task_pool[i % task_pool_size_]->enqueue( [&search_shards, i]() -> std::vector { return search_shards[i]->get_all_id(); })); } for (size_t i = 0; i < tasks.size(); ++i) { tasks[i].wait(); } for (size_t i = 0; i < tasks.size(); i++) { auto ids = tasks[i].get(); for (auto &id : ids) res[id % slice_num].push_back(id); } return res; } int32_t GraphTable::pull_graph_list(int type_id, int idx, int start, int total_size, std::unique_ptr &buffer, int &actual_size, bool need_feature, int step) { if (start < 0) start = 0; int size = 0, cur_size; auto &search_shards = type_id == 0 ? edge_shards[idx] : feature_shards[idx]; std::vector>> tasks; for (size_t i = 0; i < search_shards.size() && total_size > 0; i++) { cur_size = search_shards[i]->get_size(); if (size + cur_size <= start) { size += cur_size; continue; } int count = std::min(1 + (size + cur_size - start - 1) / step, total_size); int end = start + (count - 1) * step + 1; tasks.push_back(_shards_task_pool[i % task_pool_size_]->enqueue( [&search_shards, this, i, start, end, step, size]() -> std::vector { return search_shards[i]->get_batch(start - size, end - size, step); })); start += count * step; total_size -= count; size += cur_size; } for (size_t i = 0; i < tasks.size(); ++i) { tasks[i].wait(); } size = 0; std::vector> res; for (size_t i = 0; i < tasks.size(); i++) { res.push_back(tasks[i].get()); for (size_t j = 0; j < res.back().size(); j++) { size += res.back()[j]->get_size(need_feature); } } char *buffer_addr = new char[size]; buffer.reset(buffer_addr); int index = 0; for (size_t i = 0; i < res.size(); i++) { for (size_t j = 0; j < res[i].size(); j++) { res[i][j]->to_buffer(buffer_addr + index, need_feature); index += res[i][j]->get_size(need_feature); } } actual_size = size; return 0; } int32_t GraphTable::get_server_index_by_id(int64_t id) { return id % shard_num / shard_num_per_server; } int32_t GraphTable::Initialize(const TableParameter &config, const FsClientParameter &fs_config) { LOG(INFO) << "in graphTable initialize"; _config = config; if (InitializeAccessor() != 0) { LOG(WARNING) << "Table accessor initialize failed"; return -1; } if (_afs_client.initialize(fs_config) != 0) { LOG(WARNING) << "Table fs_client initialize failed"; // return -1; } auto graph = config.graph_parameter(); shard_num = _config.shard_num(); LOG(INFO) << "in graphTable initialize over"; return Initialize(graph); } int32_t GraphTable::Initialize(const GraphParameter &graph) { task_pool_size_ = graph.task_pool_size(); #ifdef PADDLE_WITH_HETERPS _db = NULL; search_level = graph.search_level(); if (search_level >= 2) { _db = paddle::distributed::RocksDBHandler::GetInstance(); _db->initialize("./temp_gpups_db", task_pool_size_); } // gpups_mode = true; // auto *sampler = // CREATE_PSCORE_CLASS(GraphSampler, graph.gpups_graph_sample_class()); // auto slices = // string::split_string(graph.gpups_graph_sample_args(), ","); // std::cout << "slices" << std::endl; // for (auto x : slices) std::cout << x << std::endl; // sampler->init(graph.gpu_num(), this, slices); // graph_sampler.reset(sampler); #endif if (shard_num == 0) { server_num = 1; _shard_idx = 0; shard_num = graph.shard_num(); } use_cache = graph.use_cache(); if (use_cache) { cache_size_limit = graph.cache_size_limit(); cache_ttl = graph.cache_ttl(); make_neighbor_sample_cache((size_t)cache_size_limit, (size_t)cache_ttl); } _shards_task_pool.resize(task_pool_size_); for (size_t i = 0; i < _shards_task_pool.size(); ++i) { _shards_task_pool[i].reset(new ::ThreadPool(1)); _shards_task_rng_pool.push_back(paddle::framework::GetCPURandomEngine(0)); } auto graph_feature = graph.graph_feature(); auto node_types = graph.node_types(); auto edge_types = graph.edge_types(); VLOG(0) << "got " << edge_types.size() << "edge types in total"; feat_id_map.resize(node_types.size()); for (int k = 0; k < edge_types.size(); k++) { VLOG(0) << "in initialize: get a edge_type " << edge_types[k]; edge_to_id[edge_types[k]] = k; id_to_edge.push_back(edge_types[k]); } feat_name.resize(node_types.size()); feat_shape.resize(node_types.size()); feat_dtype.resize(node_types.size()); VLOG(0) << "got " << node_types.size() << "node types in total"; for (int k = 0; k < node_types.size(); k++) { feature_to_id[node_types[k]] = k; auto node_type = node_types[k]; auto feature = graph_feature[k]; id_to_feature.push_back(node_type); int feat_conf_size = static_cast(feature.name().size()); for (int i = 0; i < feat_conf_size; i++) { // auto &f_name = common.attributes()[i]; // auto &f_shape = common.dims()[i]; // auto &f_dtype = common.params()[i]; auto &f_name = feature.name()[i]; auto &f_shape = feature.shape()[i]; auto &f_dtype = feature.dtype()[i]; feat_name[k].push_back(f_name); feat_shape[k].push_back(f_shape); feat_dtype[k].push_back(f_dtype); feat_id_map[k][f_name] = i; VLOG(0) << "init graph table feat conf name:" << f_name << " shape:" << f_shape << " dtype:" << f_dtype; } } // this->table_name = common.table_name(); // this->table_type = common.name(); this->table_name = graph.table_name(); this->table_type = graph.table_type(); VLOG(0) << " init graph table type " << this->table_type << " table name " << this->table_name; // int feat_conf_size = static_cast(common.attributes().size()); // int feat_conf_size = static_cast(graph_feature.name().size()); VLOG(0) << "in init graph table shard num = " << shard_num << " shard_idx" << _shard_idx; shard_num_per_server = sparse_local_shard_num(shard_num, server_num); shard_start = _shard_idx * shard_num_per_server; shard_end = shard_start + shard_num_per_server; VLOG(0) << "in init graph table shard idx = " << _shard_idx << " shard_start " << shard_start << " shard_end " << shard_end; edge_shards.resize(id_to_edge.size()); #ifdef PADDLE_WITH_HETERPS partitions.resize(id_to_edge.size()); #endif for (int k = 0; k < (int)edge_shards.size(); k++) { for (size_t i = 0; i < shard_num_per_server; i++) { edge_shards[k].push_back(new GraphShard()); } } feature_shards.resize(id_to_feature.size()); for (int k = 0; k < (int)feature_shards.size(); k++) { for (size_t i = 0; i < shard_num_per_server; i++) { feature_shards[k].push_back(new GraphShard()); } } return 0; } } // namespace distributed }; // namespace paddle