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memonger.cc
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#include "caffe2/core/memonger.h"
#include <set>
#include <unordered_set>
#include "caffe2/utils/proto_utils.h"
namespace caffe2 {
void run_schema_check(const NetDef& net) {
for (auto& op : net.op()) {
auto* schema = OpSchemaRegistry::Schema(op.type());
if (schema) {
CAFFE_ENFORCE(
schema->Verify(op),
"Operator def did not pass schema checking: ",
ProtoDebugString(op));
}
}
}
namespace memonger {
NetDef optimize_inference_net(
const NetDef& net,
const std::set<string>& static_blobs) {
if (net.type() != "" && net.type() != "simple") {
LOG(INFO) << "Cannot optimize memory for nets of type: " << net.type();
return net;
}
// Memonger modifies the graph. Do an early schema check here to make sure
// the operators are valid
run_schema_check(net);
std::vector<OperatorDef> ops;
for (auto& op : net.op()) {
if (op.type() == "RecurrentNetwork") {
// NOTE: for subtleties of RNN op memonger, see memonger.py on how
// to deal with the forward/backward links etc.
LOG(INFO) << "Memonger does not support RecurrentNetwork yet";
return net;
}
ops.push_back(op);
}
// Step 1: count first and last operator for each blob
std::unordered_set<std::string> all_blobs;
std::unordered_map<std::string, std::pair<int, int>> ranges;
for (size_t i = 0; i < ops.size(); i++) {
for (auto& inp : ops[i].input()) {
if (ranges.find(inp) != ranges.end()) {
ranges[inp].second = i;
}
all_blobs.insert(inp);
}
for (auto& outp : ops[i].output()) {
all_blobs.insert(outp);
if (static_blobs.find(outp) != static_blobs.end()) {
continue;
}
if (ranges.find(outp) == ranges.end()) {
ranges[outp] = std::make_pair(i, i);
}
}
}
// Step 2: pass over ops and recycle
std::vector<std::string> free_blobs;
std::unordered_map<std::string, std::string> renaming;
std::unordered_map<std::string, std::string> mapping;
for (int i = 0; i < (int)ops.size(); i++) {
auto& op = ops[i];
std::unordered_set<std::string> new_free_blobs;
// Check if some input is used the last time, and release it
for (auto& inp : op.input()) {
auto rit = ranges.find(inp);
if (rit != ranges.end() && rit->second.second == i) {
if (mapping.find(inp) == mapping.end()) {
new_free_blobs.insert(inp);
mapping[inp] = inp;
// Safety check to prevent double-memongering nets.
string shared_blob =
"__m" + c10::to_string(renaming.size()) + "_shared";
if (all_blobs.find(shared_blob) != all_blobs.end()) {
LOG(INFO) << "Net was already memongered!";
return net;
}
renaming[inp] = shared_blob;
} else {
new_free_blobs.insert(mapping[inp]);
}
}
}
// Check if some output appears the first time, and see if we can replace it
// with a recycled blob.
for (auto& outp : op.output()) {
if (!free_blobs.empty()) {
// first use?
auto rit = ranges.find(outp);
if (rit != ranges.end() && rit->second.first == i) {
std::string recycled = free_blobs.back();
free_blobs.pop_back();
mapping[outp] = recycled;
}
}
}
// Add blobs released from this op to the pool.
for (auto& b : new_free_blobs) {
free_blobs.push_back(b);
}
}
// Step 3: rename inputs and outputs and create new net
NetDef optim_net = net;
optim_net.mutable_op()->Clear();
for (auto op : ops) {
for (int i = 0; i < op.input_size(); i++) {
auto& inp = op.input(i);
if (mapping.find(inp) != mapping.end()) {
op.set_input(i, renaming[mapping[inp]]);
}
}
for (int i = 0; i < op.output_size(); i++) {
auto& outp = op.output(i);
if (mapping.find(outp) != mapping.end()) {
op.set_output(i, renaming[mapping[outp]]);
}
}
auto* ao = optim_net.add_op();
ao->CopyFrom(op);
}
VLOG(1) << "optimized net using " << renaming.size() << " shared blobs";
return optim_net;
}
class ComputeBlobRecyclingForDag {
public:
explicit ComputeBlobRecyclingForDag(const int size)
: op_inputs_(size),
op_visited_count_(size),
op_token_deposit_(size),
op_visited_(size, false) {}
NetDef OptimizeNet(
const NetDef& net,
const std::vector<string>& heads,
const std::vector<int>& op_indices,
const std::unordered_set<string>& shareable_blob_names,
const string& namescope,
const std::unordered_set<string>& dont_share_blob_names,
const std::unordered_map<string, vector<int>>& blob_shapes) {
// Construct the set of input blobs.
std::unordered_set<string> heads_blobs_set(heads.begin(), heads.end());
// Construct the set of output blobs we want to optimize.
for (const int op_index : op_indices) {
for (const auto& output : net.op(op_index).output()) {
optim_op_outputs_.insert(output);
}
}
// Compute operators in degree (op_inputs_) and initialize how many ops are
// sharing input blobs (share_counts_).
// Note: We have to handle the cases where output blobs are shared.
std::unordered_map<string, int> blob_seen;
for (const int op_index : op_indices) {
for (const auto& input : net.op(op_index).input()) {
if (has_key(shareable_blob_names, input) ||
has_key(heads_blobs_set, input)) {
if (has_key(optim_op_outputs_, input)) {
CAFFE_ENFORCE(
blob_seen.find(input) != blob_seen.end(),
"Input ",
input,
" was not output by an op before");
op_inputs_[op_index] += blob_seen[input];
} else {
share_counts_[input] = 1;
}
blob_to_ops_[input].push_back(op_index);
}
}
for (const auto& output : net.op(op_index).output()) {
blob_seen[output] += 1;
blob_device_[output] = net.op(op_index).device_option();
// Exception for CopyGPUToCPU that has
// cuda device option but whose inputs/outputs are on CPU
if (net.op(op_index).type() == "CopyGPUToCPU") {
blob_device_[output].set_device_type(0);
blob_device_[output].set_device_id(0);
}
}
}
// The main recursive call. Here we do start DFS in the operator graph
// from the input blobs.
for (const auto& input_blob : heads) {
for (const int op_index : blob_to_ops_[input_blob]) {
if (!op_visited_[op_index]) {
vector<std::pair<int, string>> free_blobs;
std::unordered_set<int> tokens{tokens_counter_++};
process_op(
net,
shareable_blob_names,
namescope,
dont_share_blob_names,
blob_shapes,
op_index,
&free_blobs,
&tokens);
}
}
}
// Rename mapped blobs.
std::unordered_map<string, string> renamed;
int name_idx = 0;
std::unordered_set<string> mapped_blobs_set;
for (const auto& mapped_blob : mapping_) {
mapped_blobs_set.insert(mapped_blob.second);
if (has_key(optim_op_outputs_, mapped_blob.second)) {
if (renamed.find(mapped_blob.second) == renamed.end()) {
renamed.insert(
{mapped_blob.second,
namescope + "__m" + c10::to_string(name_idx++) + "_shared"});
}
} else {
renamed.insert({mapped_blob.second, mapped_blob.second});
}
}
// Recursively rename mapped_blobs.
mapping_.insert(renamed.begin(), renamed.end());
bool had_changes = true;
while (had_changes) {
had_changes = false;
for (const auto mapped_blob : mapping_) {
if (has_key(renamed, mapped_blob.second) &&
renamed[mapped_blob.second] != mapped_blob.second) {
renamed[mapped_blob.first] = renamed[mapped_blob.second];
mapping_[mapped_blob.first] = renamed[mapped_blob.first];
}
}
}
NetDef optimized_net = apply_assignments(net);
LOG(INFO) << "Remapping " << mapping_.size() << " using "
<< mapped_blobs_set.size() << " shared blobs.";
if (floats_saved_ > 0) {
LOG(INFO) << "Memonger saved approximately : "
<< (floats_saved_ * 4.0 / 1024.0 / 1024.0) << " MB.";
}
return optimized_net;
}
private:
NetDef apply_assignments(const NetDef& net) {
NetDef optimized_net = net;
// Rename optimized_net blobs.
for (int i = 0; i < optimized_net.op_size(); ++i) {
// Special handling for RNNs, which have internal nets that
// can refer to memongered blobs
if (optimized_net.op(i).type().find("RecurrentNetwork") == 0) {
apply_recurrent_blob_assignments(optimized_net.mutable_op(i));
}
for (int j = 0; j < optimized_net.op(i).input_size(); ++j) {
const string& input_name =
get_blob_or_mapped_blob(optimized_net.op(i).input(j));
optimized_net.mutable_op(i)->set_input(j, input_name);
}
for (int j = 0; j < optimized_net.op(i).output_size(); ++j) {
auto output_name =
get_blob_or_mapped_blob(optimized_net.op(i).output(j));
optimized_net.mutable_op(i)->set_output(j, output_name);
}
}
return optimized_net;
}
void apply_recurrent_blob_assignments(OperatorDef* op) {
// Recursively map stepnets in RecurrentNetworks, and
// attach a mapping table
for (int i = 0; i < op->arg_size(); i++) {
Argument* arg = op->mutable_arg(i);
const string& name = arg->name();
if (name == "step_net" || name == "backward_step_net") {
if (arg->has_n()) {
NetDef* step_net_ref = arg->mutable_n();
CAFFE_ENFORCE(
!arg->has_s(),
"Invalid definition for ",
name,
". Only one of NetDef and string should be present");
NetDef optimized_net = apply_assignments(*step_net_ref);
step_net_ref->CopyFrom(optimized_net);
} else {
NetDef step_net;
CAFFE_ENFORCE(
TextFormat::ParseFromString(
arg->s(), &step_net),
"Could not parse step net:",
name);
step_net = apply_assignments(step_net);
arg->set_s(ProtoDebugString(step_net));
}
}
}
// Store renamings
vector<string> inputs_outputs(op->input().begin(), op->input().end());
inputs_outputs.insert(
inputs_outputs.end(), op->output().begin(), op->output().end());
for (auto& b : inputs_outputs) {
string mapped = get_blob_or_mapped_blob(b);
if (b != mapped) {
Argument* map_arg = op->add_arg();
map_arg->set_name(b + ".rename");
map_arg->set_s(mapped);
}
}
}
template <typename K, typename V>
inline bool has_key(const std::unordered_map<K, V>& in_map, const K& key) {
return in_map.find(key) != in_map.end();
}
template <typename K>
inline bool has_key(const std::unordered_set<K>& in_set, const K& key) {
return in_set.find(key) != in_set.end();
}
void process_op(
const NetDef& net,
const std::unordered_set<string>& shareable_blob_names,
const string& namescope,
const std::unordered_set<string>& dont_share_blob_names,
const std::unordered_map<string, vector<int>>& blob_shapes,
int op_index,
std::vector<std::pair<int, string>>* free_blobs,
std::unordered_set<int>* tokens) {
// The tokens we have now is the union of current tokens operator is holding
// and tokens pushed from parents.
tokens->insert(
op_token_deposit_[op_index].begin(), op_token_deposit_[op_index].end());
op_token_deposit_[op_index].clear();
CAFFE_ENFORCE(!op_visited_[op_index]);
op_visited_[op_index] = true;
const OperatorDef& current_op = net.op(op_index);
// The set of freed input blobs by processing current op.
std::vector<std::pair<int, string>> new_free_blobs;
std::unordered_set<string> new_free_blobs_set;
// Now update blob tokens.
for (const auto& input : current_op.input()) {
const auto& actual_blob = get_blob_or_mapped_blob(input);
req_tokens_[actual_blob].insert(tokens->begin(), tokens->end());
if (actual_blob != input) {
req_tokens_[input].insert(tokens->begin(), tokens->end());
}
}
for (const auto& output : current_op.output()) {
const auto& actual_blob = get_blob_or_mapped_blob(output);
req_tokens_[actual_blob].insert(tokens->begin(), tokens->end());
if (actual_blob != output) {
req_tokens_[output].insert(tokens->begin(), tokens->end());
}
}
// Increment blob count and check if we can free input blobs.
for (const auto& input : current_op.input()) {
if (has_key(shareable_blob_names, input)) {
blob_input_count_[input]++;
if (blob_input_count_[input] == (int)blob_to_ops_[input].size()) {
const string& actual_blob = get_blob_or_mapped_blob(input);
if (!has_key(dont_share_blob_names, actual_blob)) {
new_free_blobs.emplace_back(
-share_counts_[actual_blob], actual_blob);
new_free_blobs_set.insert(actual_blob);
}
}
}
}
// Check if we can recycle free blobs and use it as output blob.
for (const auto& output : current_op.output()) {
if (has_key(shareable_blob_names, output) &&
!has_key(processed_output_blobs_, output) &&
!has_key(new_free_blobs_set, output)) {
const string freed_blob = get_free_blob(
output, blob_shapes, tokens, free_blobs, blob_device_[output]);
if (freed_blob != "") {
req_tokens_[freed_blob].insert(tokens->begin(), tokens->end());
share_counts_[freed_blob]++;
mapping_[output] = freed_blob;
}
processed_output_blobs_.insert(output);
}
}
// Insert new freed blobs.
std::unordered_set<string> free_blob_set;
for (const auto& free_blob : *free_blobs) {
free_blob_set.insert(free_blob.second);
}
for (const auto& new_free_blob : new_free_blobs) {
if (!has_key(free_blob_set, new_free_blob.second)) {
free_blobs->push_back(new_free_blob);
if (blob_shapes.size() > 0) {
if (!has_key(blob_sizes_, new_free_blob.second)) {
blob_sizes_.insert(
{new_free_blob.second,
infer_blob_size(new_free_blob.second, blob_shapes)});
}
}
std::push_heap(
free_blobs->begin(),
free_blobs->end(),
std::greater<std::pair<int, string>>());
}
}
int num_branches = 0;
for (const auto& output : current_op.output()) {
num_branches += blob_to_ops_[output].size();
}
for (const auto& output : current_op.output()) {
for (const auto& input_op_index : blob_to_ops_[output]) {
op_visited_count_[input_op_index]++;
if (op_visited_count_[input_op_index] == op_inputs_[input_op_index]) {
std::unordered_set<int> new_tokens;
new_tokens.insert(tokens->begin(), tokens->end());
if (num_branches > 1) {
new_tokens.insert(tokens_counter_++);
}
process_op(
net,
shareable_blob_names,
namescope,
dont_share_blob_names,
blob_shapes,
input_op_index,
free_blobs,
&new_tokens);
} else {
if (!op_visited_[input_op_index]) {
op_token_deposit_[input_op_index].insert(
tokens->begin(), tokens->end());
}
}
}
}
}
inline int infer_blob_size(
const string& blob_name,
const std::unordered_map<string, vector<int>>& blob_shapes) {
const auto& blob_shapes_iter = blob_shapes.find(blob_name);
if (blob_shapes_iter == blob_shapes.end()) {
return 0;
}
int size = 1;
for (size_t i = 0; i < blob_shapes_iter->second.size(); ++i) {
size *= blob_shapes_iter->second[i];
}
return size;
}
inline string get_blob_or_mapped_blob(const string& blob_name) {
auto mapped_blob = mapping_.find(blob_name);
if (mapped_blob == mapping_.end()) {
return blob_name;
} else {
return mapped_blob->second;
}
}
// Returns true if the op that generates that blob acquires all tokens.
inline bool can_use_blob(
const string& blob_name,
std::unordered_set<int>* tokens,
const DeviceOption& device_option) {
const DeviceOption& blob_device = blob_device_[blob_name];
if (device_option.device_type() != blob_device.device_type() ||
device_option.device_id() != blob_device.device_id()) {
return false;
}
for (const int token : req_tokens_[blob_name]) {
if (tokens->find(token) == tokens->end()) {
return false;
}
}
return true;
};
// Returns the name of the blob that we are going to map blob_name into.
inline string get_free_blob(
const string& blob_name,
const std::unordered_map<string, vector<int>>& blob_shapes,
std::unordered_set<int>* tokens,
std::vector<std::pair<int, string>>* free_blobs,
const DeviceOption& device) {
string freed_blob = "";
if (blob_shapes.size() == 0) {
std::vector<std::pair<int, string>> cant_use_blobs;
while (free_blobs->size() > 0) {
std::pop_heap(
free_blobs->begin(),
free_blobs->end(),
std::greater<std::pair<int, string>>());
const auto cand_free_blob = free_blobs->back();
free_blobs->pop_back();
if (can_use_blob(cand_free_blob.second, tokens, device)) {
freed_blob = cand_free_blob.second;
break;
} else {
cant_use_blobs.push_back(cand_free_blob);
}
}
for (const auto& cant_use_blob : cant_use_blobs) {
free_blobs->push_back(cant_use_blob);
std::push_heap(
free_blobs->begin(),
free_blobs->end(),
std::greater<std::pair<int, string>>());
}
} else {
// Heuristic to choose the largest blob to fit output thats
// slightly less than blob_size.
const int blob_size = infer_blob_size(blob_name, blob_shapes);
int best_size = -1;
int free_blob_index = -1;
for (size_t i = 0; i < free_blobs->size(); ++i) {
const string& cb_name = (*free_blobs)[i].second;
if (can_use_blob(cb_name, tokens, device)) {
const int cand_bz = blob_sizes_[cb_name];
CAFFE_ENFORCE(blob_sizes_.find(cb_name) != blob_sizes_.end());
if (cand_bz >= best_size) {
if (best_size < blob_size || best_size >= cand_bz) {
best_size = cand_bz;
free_blob_index = i;
}
}
}
}
if (free_blob_index != -1) {
floats_saved_ += best_size;
freed_blob = (*free_blobs)[free_blob_index].second;
free_blobs->erase(free_blobs->begin() + free_blob_index);
}
}
return freed_blob;
};
int tokens_counter_ = 1;
int floats_saved_ = 0;
// blob_name -> Op edges.
std::unordered_map<string, std::vector<int>> blob_to_ops_;
// Current Op in degree.
std::unordered_map<string, int> blob_input_count_;
// Op in degree.
std::vector<int> op_inputs_;
// Current Op visit counts.
std::vector<int> op_visited_count_;
std::unordered_map<string, int> share_counts_;
std::unordered_map<string, int> blob_sizes_;
std::unordered_map<string, std::unordered_set<int>> req_tokens_;
std::vector<std::unordered_set<int>> op_token_deposit_;
std::unordered_set<string> optim_op_outputs_;
std::unordered_map<string, string> mapping_;
std::unordered_map<string, DeviceOption> blob_device_;
// The set of output blobs we already processed.
std::unordered_set<string> processed_output_blobs_;
std::vector<bool> op_visited_;
};
NetDef compute_blob_recycling_for_dag(
const NetDef& net,
const std::vector<string>& heads,
const std::vector<int>& op_indices,
const std::unordered_set<string>& shareable_blob_names,
const string& namescope,
const std::unordered_set<string>& dont_share_blob_names,
const std::unordered_map<string, vector<int>>& blob_shapes) {
ComputeBlobRecyclingForDag memonger(net.op_size());
return memonger.OptimizeNet(
net,
heads,
op_indices,
shareable_blob_names,
namescope,
dont_share_blob_names,
blob_shapes);
}
} // memonger
} // caffe2