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frozen_concat_linear.cpp
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frozen_concat_linear.cpp
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#include <c10/util/irange.h>
#include <torch/csrc/jit/ir/alias_analysis.h>
#include <torch/csrc/jit/ir/ir.h>
#include <torch/csrc/jit/ir/ir_views.h>
#include <torch/csrc/jit/jit_log.h>
#include <torch/csrc/jit/passes/frozen_concat_linear.h>
#include <torch/csrc/jit/passes/frozen_conv_folding.h>
#include <torch/csrc/jit/passes/frozen_graph_optimizations.h>
#include <torch/csrc/jit/passes/remove_dropout.h>
#include <torch/csrc/jit/passes/utils/optimization_utils.h>
#include <torch/csrc/jit/runtime/graph_executor.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#else
#include <ATen/ops/cat.h>
#endif
#include <unordered_set>
#include <utility>
#include <vector>
namespace torch {
namespace jit {
namespace {
using Tensor = at::Tensor;
class ConcatLinearLayers {
public:
explicit ConcatLinearLayers(std::shared_ptr<Graph> graph)
: graph_(std::move(graph)) {}
bool run() {
handleBlockAndSubblocks(graph_->block());
return graph_modified;
}
AliasDb* getAliasDb() {
if (!aliasDb_) {
aliasDb_ = std::make_unique<AliasDb>(graph_);
}
return aliasDb_.get();
}
void collectConstantLinearLayers(
Block* b,
std::unordered_map<Value*, std::vector<Node*>>& grouped_linear_layers,
std::vector<Value*>& ordered_tensor_inputs) {
// We are using an ordered list so that we only have to
// check if moving items forward is a valid move, not
// backwards. Otherwise we need to rebuild the aliasDb when we add values.
for (Node* n : b->nodes()) {
// Grouping together all linear layers that use the same Tensor for input
if (n->kind() != aten::linear) {
continue;
}
auto weight = n->namedInput("weight");
auto bias = n->namedInput("bias");
if (weight->type() == NoneType::get() ||
bias->type() == NoneType::get()) {
continue;
}
if (nonConstantParameters(n)) {
continue;
}
auto weight_tensor = constant_as<Tensor>(weight).value();
if (!weight_tensor.device().is_cuda()) {
continue;
}
Value* linear_input = n->inputs().at(0);
if (grouped_linear_layers.find(linear_input) ==
grouped_linear_layers.cend()) {
grouped_linear_layers.insert({linear_input, std::vector<Node*>()});
ordered_tensor_inputs.push_back(linear_input);
}
grouped_linear_layers.find(linear_input)->second.push_back(n);
}
}
void mergeLinearLayers(std::vector<Node*>& compatible_layers) {
graph_modified = true;
assert(!compatible_layers.empty());
Node* base_node = compatible_layers[0];
// Scope needed to make sure we free the WithInsertPoint guard
// and reset the insert point before we delete `base_node`
Node* linear_node = nullptr;
{
WithInsertPoint guard(base_node);
auto weight_list = c10::fmap(compatible_layers, [](Node* n) {
return constant_as<Tensor>(n->namedInput("weight")).value();
});
Tensor cat_weight = at::cat(weight_list, /*dim=*/0);
Value* cat_weight_value = graph_->insertConstant(std::move(cat_weight));
auto bias_list = c10::fmap(compatible_layers, [](Node* n) {
return constant_as<Tensor>(n->namedInput("bias")).value();
});
Tensor cat_bias = at::cat(bias_list, /*dim=*/0);
Value* cat_bias_value = graph_->insertConstant(std::move(cat_bias));
auto tensor_input = base_node->inputs().at(0);
std::vector<Value*> linear_in = {
tensor_input, cat_weight_value, cat_bias_value};
linear_node = graph_->create(aten::linear, linear_in);
linear_node->insertBefore(base_node);
}
// Update the outputs of the nodes
WithInsertPoint guard2(linear_node);
Value* neg1 = graph_->insertConstant(-1);
Value* one = graph_->insertConstant(1);
int64_t slice_start = 0;
Value* slice_start_val = graph_->insertConstant(0);
for (Node* orig_node : compatible_layers) {
// for each node in the compatible_layers list,
// slide the output of the combined linear layer
// and use it instead of the output of the original node
Tensor weight_tensor =
constant_as<Tensor>(orig_node->namedInput("weight")).value();
int64_t slice_end = slice_start + weight_tensor.size(0);
Value* slice_end_val = graph_->insertConstant(slice_end);
Node* slice = graph_->create(
aten::slice,
{linear_node->output(), neg1, slice_start_val, slice_end_val, one});
slice->insertAfter(linear_node);
orig_node->replaceAllUsesWith(slice);
orig_node->destroy();
slice_start = slice_end;
slice_start_val = slice_end_val;
}
}
bool isNonZeroDimEqual(Tensor& tensor_a, Tensor& tensor_b) {
if (tensor_a.dim() != tensor_b.dim()) {
return false;
}
for (int64_t i = 1; i < tensor_a.dim(); i++) {
if (tensor_a.size(i) != tensor_b.size(i)) {
return false;
}
}
return true;
}
// Check the linear_layer_group of a tensor to find ones that can be
// combined
void collectAndMergeLinearLayers(std::vector<Node*>& linear_layer_group) {
std::unordered_set<Node*> checked_nodes;
for (size_t i = 0; i < linear_layer_group.size(); i++) {
Node* base_node = linear_layer_group[i];
if (checked_nodes.count(base_node) != 0) {
continue;
}
std::vector<Node*> compatible_layers;
compatible_layers.push_back(base_node);
auto base_weight =
constant_as<Tensor>(base_node->namedInput("weight")).value();
auto base_bias =
constant_as<Tensor>(base_node->namedInput("bias")).value();
// Now iterate over the rest of the users of the set to
// see if there is anything that we can coalesce `base_node` with.
for (size_t j = i + 1; j < linear_layer_group.size(); j++) {
auto node = linear_layer_group[j];
if (checked_nodes.count(node) != 0) {
continue;
}
auto weight = constant_as<Tensor>(node->namedInput("weight")).value();
auto bias = constant_as<Tensor>(node->namedInput("bias")).value();
// For now we will just keep it simple and require matching types
// Type promotion might cause performance to actually decrease.
if (base_weight.dtype() != weight.dtype() ||
base_weight.device() != weight.device() ||
base_bias.dtype() != bias.dtype() ||
base_bias.device() != bias.device()) {
continue;
}
if (!isNonZeroDimEqual(base_weight, weight) ||
!isNonZeroDimEqual(base_bias, bias)) {
continue;
}
bool can_move_before_all = true;
for (auto n : compatible_layers) {
can_move_before_all &=
getAliasDb()->couldMoveBeforeTopologically(node, n);
}
if (!can_move_before_all) {
continue;
}
// Found a node that is eligible for combination
compatible_layers.push_back(node);
checked_nodes.insert(node);
}
if (compatible_layers.size() == 1) {
continue; // No other layers to merge
}
mergeLinearLayers(compatible_layers);
}
}
void handleBlockAndSubblocks(Block* block) {
for (auto node : block->nodes()) {
for (Block* subblock : node->blocks()) {
handleBlockAndSubblocks(subblock);
}
}
// Processing for the block itself
std::unordered_map<Value*, std::vector<Node*>> grouped_linear_layers;
std::vector<Value*> ordered_tensor_inputs;
collectConstantLinearLayers(
block, grouped_linear_layers, ordered_tensor_inputs);
// Reverse topological ordering is used to prevent the need to
// update the aliasDB
for (auto tensor_it = ordered_tensor_inputs.rbegin();
tensor_it != ordered_tensor_inputs.rend();
++tensor_it) {
collectAndMergeLinearLayers(grouped_linear_layers.at(*tensor_it));
}
}
private:
std::shared_ptr<Graph> graph_;
bool graph_modified = false;
std::unique_ptr<AliasDb> aliasDb_ = nullptr;
};
} // namespace
TORCH_API bool FrozenConcatLinear(std::shared_ptr<Graph>& graph) {
ConcatLinearLayers concatLayers(graph);
GRAPH_DUMP("Before FrozenConcatLinear", graph);
bool changed = concatLayers.run();
if (changed) {
GRAPH_DUMP("After FrozenConcatLinear", graph);
}
return changed;
}
} // namespace jit
} // namespace torch