graph_pattern_detector.h

// Copyright (c) 2018 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.

#pragma once

#ifdef PADDLE_WITH_TESTING
#include <gtest/gtest_prod.h>
#endif

#include <memory>
#include <numeric>
#include <string>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>
#include "paddle/fluid/framework/ir/graph.h"
#include "paddle/fluid/framework/ir/node.h"
#include "paddle/fluid/inference/analysis/dot.h"

namespace paddle {
namespace framework {
namespace ir {
class PDPattern;

// Some basic terminologies:
//   - PDPattern: a pattern defined as a data flow graph.
//   - PDNode: the node in the pattern, each PDNode represents an `ir::Node`
//     that meets some conditions defined in `PDNode.teller`.
//   - A pattern is defined with PDNodes with edges.

// Pattern detector node. This node helps to build a pattern.
struct PDNode {
  // tell whether an ir::Node* is a candidation for a PDNode.
  using teller_t = std::function<bool(Node*)>;
  enum class Type { kOp, kVar };
  enum class Role {
    kUnknown,      // No role,
    kInput,        // an input and will be retained,
    kOutput,       // an output and will be retained,
    kIntermediate  // will be removed after handler.
  };

  // this link to others
  PDNode& LinksTo(const std::vector<PDNode*>& others);
  PDNode& LinksFrom(const std::vector<PDNode*>& others);

  bool Tell(Node* node) const {
    if (teller_) return teller_(node);

    for (auto& asrt : asserts_) {
      if (!asrt(node)) return false;
    }
    return true;
  }

  bool IsOp() const { return type_ == Type::kOp; }
  bool IsVar() const { return type_ == Type::kVar; }

  const std::string& name() const { return name_; }

  PDNode& operator=(const PDNode&) = delete;
  PDNode(const PDNode&) = delete;

  // Mark this node is an Input of a subgraph and will be retained.
  PDNode* AsInput() {
    role_ = Role::kInput;
    return this;
  }
  // Mark this node is an Output of a subgraph and will be retained.
  PDNode* AsOutput() {
    role_ = Role::kOutput;
    return this;
  }
  // Mark this node will be removed, so all the links should be inside a matched
  // sub-graph.
  PDNode* AsIntermediate() {
    role_ = Role::kIntermediate;
    return this;
  }

  bool IsIntermediate() const { return role_ == Role::kIntermediate; }
  bool IsInput() const { return role_ == Role::kInput; }
  bool IsOutput() const { return role_ == Role::kOutput; }

  // Assertions, helper functions to simplify the pattern definition.
  PDNode* assert_is_op();
  PDNode* assert_is_op(const std::string& op_type);
  PDNode* assert_is_var();
  PDNode* assert_is_not_ctrl_var();
  PDNode* assert_var_not_persistable();
  PDNode* assert_is_persistable_var();
  PDNode* assert_is_op_output(const std::string& op_type);
  PDNode* assert_is_op_output(const std::string& op_type,
                              const std::string& argument);
  PDNode* assert_is_op_input(const std::string& op_type);
  PDNode* assert_is_op_input(const std::string& op_type,
                             const std::string& argument);
  PDNode* assert_is_op_nth_input(const std::string& op_type,
                                 const std::string& argument, int nth);
  PDNode* assert_is_op_nth_output(const std::string& op_type,
                                  const std::string& argument, int nth);
  PDNode* assert_is_only_input_of_op(const std::string& op_type);
  PDNode* assert_is_only_output_of_op(const std::string& op_type);
  PDNode* assert_op_has_n_inputs(const std::string& op_type, size_t n);
  PDNode* assert_op_has_n_outputs(const std::string& op_type, size_t n);
  PDNode* assert_more(teller_t&& teller);

  PDNode* assert_is_ops_output(const std::unordered_set<std::string>& op_types);
  PDNode* assert_is_ops(const std::unordered_set<std::string>& op_types);
  PDNode* assert_is_ops_output(const std::unordered_set<std::string>& op_types,
                               const std::string& argument);
  PDNode* assert_is_ops_nth_input(
      const std::unordered_set<std::string>& op_types,
      const std::string& argument, int nth);
  PDNode* assert_is_ops_input(const std::unordered_set<std::string>& op_types);
  PDNode* assert_is_ops_input(const std::unordered_set<std::string>& op_types,
                              const std::string& argument);
  PDNode* assert_is_ops_nth_output(
      const std::unordered_set<std::string>& op_types,
      const std::string& argument, int nth);

  template <typename T>
  PDNode* assert_op_attr(const std::string& attr_name, const T& attr) {
    asserts_.emplace_back([=](Node* x) {
      return x && x->IsOp() && x->Op()->HasAttr(attr_name) &&
             boost::get<T>(x->Op()->GetAttr(attr_name)) == attr;
    });
    return this;
  }

 private:
  PDNode(PDPattern* pattern, const std::string& name = "",
         Type type = Type::kVar)
      : pattern_(pattern), name_(name), type_(type) {}
  PDNode(teller_t&& teller, PDPattern* pattern, const std::string& name = "",
         Type type = Type::kVar)
      : teller_(std::move(teller)),
        pattern_(pattern),
        name_(name),
        type_(type) {
    PADDLE_ENFORCE(teller_ != nullptr, "invalid teller functer is set.");
  }

  PDNode(PDNode&& other) = default;

  friend class PDPattern;

  // Will removed latter.
  teller_t teller_;
  std::vector<teller_t> asserts_;
  PDPattern* pattern_;
  std::string name_;
  Type type_;
  Role role_{Role::kUnknown};
};

/*
 * A pattern in a graph, which defined with PDNode and edges. Most graph
 * patterns can be divided into PDNodes and link relations between them.
 *
 * For example, the FC fusion need to filter the MUL and ELEMENTWISE_ADD
 * operators from the computation graph, the MUL's output should have only one
 * consumer which is the ELEMENTWISE_ADD.
 * This pattern can be defined as with the following pseudo codes
 *
 *     // Create two operator PDNodes.
 *     MUL = PDPattern.NewNode().assert_is_op("mul");
 *     ELE = PDPattern.NewNode().assert_is_op("elementwise_add");
 *     // Create the variable PDNodes.
 *     MUL_out = PDPattern.NewNode().assert_is_op_output("mul") \
 *                                  .assert_is_op_input("elementwise_add") \
 *                                  .AsIntermediate();
 *     // Add relations.
 *     MUL->LinksTo({MUL_out});
 *     MUL_out->LinksTo({ELE});
 *
 * One can add more specific asserts for PDNodes or edges, both the Operator
 * and Variable Nodes can be ruled in PDNode.assert_more(...).
 *
 * PDPattern can record the general patterns, such as the pattern represents
 *   - Op in CPU -> Op in GPU -> Op in CPU, to findout the IO abnormal place.
 *   - Ops whose inputs and outputs share the same variables
 */
class PDPattern {
 public:
  using edge_t = std::pair<PDNode*, PDNode*>;

  void AddEdge(PDNode* a, PDNode* b);

  PDNode* NewNode(PDNode::teller_t&& teller, const std::string& name = NewID());
  PDNode* NewNode(const std::string& name = NewID());
  PDNode* NewNode(const std::string& prefix, const std::string& name) {
    return NewNode(prefix + "/" + name);
  }
  PDNode* RetrieveNode(const std::string& id) const;

  const std::vector<std::unique_ptr<PDNode>>& nodes() const { return nodes_; }
  const std::vector<edge_t>& edges() const { return edges_; }

  std::string DotString() const;

 private:
#ifdef PADDLE_WITH_TESTING
  FRIEND_TEST(PDPattern, AddEdge);
  FRIEND_TEST(PDPattern, NewNode);
#endif

  static std::string NewID() { return "pdnode-" + std::to_string(id_++); }

  std::vector<std::unique_ptr<PDNode>> nodes_;
  std::vector<edge_t> edges_;
  std::unordered_map<std::string, PDNode*> node_map_;
  static size_t id_;
};

/*
 * GraphPatternDetector helps to detect the specific patterns in the graph.
 * Input a pattern, output a list of the matched subgraphs/nodes.
 * This helper can be used to support fuse(conv+batchnorm => batchnorm e.g.).
 *
 * The algorithm has three phases:
 *   1. Mark the nodes that match the defined PDNodes in a PDPattern,
 *   2. Extend a PDNode to subgraphs by deducing the connection relation defined
 *      in PAPattern(the edges),
 *   3. Get the filtered subgraphs and treat them with a pre-defined handler.
 *
 * Usage:
 *    // Create a detector
 *    GraphPatternDetector detector;
 *    // Define the detector's pattern, by adding PDNode and define the edges.
 *    auto* node0 = detector.mutable_pattern().AddNode(...)
 *    auto* node1 = detector.mutable_pattern().AddNode(...)
 *    node0->teller = some lambda.
 *    node1->teller = some lambda.
 *    detector.mutable_pattern().AddEdge(node0, node1);
 *    // Create an handler, to define the behavior of treating the filtered
 *    // subgraphs that comply with the patterns.
 *    GraphPatternDetector::handle_t handler = some labmda
 *    // Execute the detector.
 *    detector(&graph, handler);
 */
class GraphPatternDetector {
 public:
  using subgraph_t = std::unordered_map<PDNode*, Node*>;

  // Operate on the detected pattern.
  using handle_t =
      std::function<void(const subgraph_t& /*hitted pattern*/, Graph*)>;

  void operator()(Graph* graph, handle_t handler);

  const PDPattern& pattern() const { return pattern_; }
  PDPattern* mutable_pattern() { return &pattern_; }

 private:
  // Mark the nodes that fits the pattern.
  bool MarkPDNodesInGraph(const ir::Graph& graph);

  // Detect all the pattern and output the hit records.
  std::vector<subgraph_t> DetectPatterns();

  // Remove duplicate patterns.
  void UniquePatterns(std::vector<subgraph_t>* subgraphs);

  // Remove overlapped match subgraphs, when overlapped, keep the previous one.
  // The intermediate PDNodes will be removed, so can't shared by multiple
  // patterns.
  void RemoveOverlappedMatch(std::vector<subgraph_t>* subgraphs);

  // Validate whether the intermediate nodes are linked by external nodes.
  void ValidateByNodeRole(std::vector<subgraph_t>* subgraphs);

#ifdef PADDLE_WITH_TESTING
  FRIEND_TEST(GraphPatternDetecter, MarkPDNodesInGraph);
  FRIEND_TEST(GraphPatternDetecter, DetectPatterns);
#endif

 private:
  using hit_rcd_t =
      std::pair<Node* /*node in graph*/, PDNode* /*node in pattern*/>;
  PDPattern pattern_;
  std::unordered_map<const PDNode*, std::unordered_set<Node*>> pdnodes2nodes_;
};

// some helper methods.

// Tell if a var links to an Op
bool VarLinksToOp(Node* node, const std::string& op_type);

// Tell if an op links to a var
bool VarLinksFromOp(Node* node, const std::string& op_type);

// Check whether a var node is a op node's nth input.
bool IsNthInput(Node* var, Node* op, const std::string& argument, size_t nth);

// Tell whether a var node is a op node's nth output.
bool IsNthOutput(Node* var, Node* op, const std::string& argument, size_t nth);

// Graph safely remove some nodes, will automatically clean up the edges.
void GraphSafeRemoveNodes(Graph* graph,
                          const std::unordered_set<const Node*>& nodes);

// Some pre-defined patterns those can be reused in multiple passes.
// The related Fluid Layer or Op should be one pattern here for better re-usage
// across different fusion.
namespace patterns {

struct KeyCounter {
  static KeyCounter& Instance() {
    static KeyCounter x;
    return x;
  }

  int IncCounter(const std::string& key) { return dic_[key]++; }

 private:
  std::unordered_map<std::string, size_t> dic_;
};

// Generate a unique PDNode's name with name_scope and id.
// The format is {name_scope}/{repr}/{id}/{name}
static std::string PDNodeName(const std::string& name_scope,
                              const std::string& repr, size_t id,
                              const std::string& name) {
  return string::Sprintf("%s/%s/%d/%s", name_scope, repr, id, name);
}
// Generate a unique PDNode's name.
// The format is {name_scope}/{repr}/{id}
static std::string PDNodeName(const std::string& name_scope,
                              const std::string& repr) {
  return string::Sprintf("%s/%s/%d", name_scope, repr,
                         KeyCounter::Instance().IncCounter(repr));
}
// Generate a unique key. It can be used for a universally unique temporary
// name.
// The format is {repr}/{id}
static std::string UniqueKey(const std::string& repr) {
  return string::Sprintf("%s/%d", repr,
                         KeyCounter::Instance().IncCounter(repr));
}

// Declare a PDNode in a pattern, will create two methods:
// std::string xxx_repr(); return this PDNode's string id.
// PDNode* xxx_n(); return the corresponding PDNode.
#define PATTERN_DECL_NODE(name__)                        \
  std::string name__##_repr() const {                    \
    return PDNodeName(name_scope_, repr_, id_, #name__); \
  }                                                      \
  PDNode* name__##_n() const { return pattern->RetrieveNode(name__##_repr()); }

// Get an ir::Node* from the matched subgraph.
// var: variable.
// arg: the argument declared by PATTERN_DECL_NODE in a pattern definition.
// pat: the pattern object.
#define GET_IR_NODE_FROM_SUBGRAPH(var, arg, pat)                    \
  PADDLE_ENFORCE(subgraph.count(pat.arg##_n()),                     \
                 "Node not found for PDNode %s", pat.arg##_repr()); \
  Node* var = subgraph.at(pat.arg##_n());                           \
  PADDLE_ENFORCE(var, "node %s not exists in the sub-graph", #arg)

// The base class of all the patterns.
struct PatternBase {
  PatternBase(PDPattern* pattern, const std::string& name_scope,
              const std::string& repr)
      : pattern(pattern),
        name_scope_(name_scope),
        repr_(repr),
        id_(KeyCounter::Instance().IncCounter(repr)) {}

  PDPattern* pattern;

 protected:
  std::string name_scope_;
  std::string repr_;
  size_t id_;
};

// Conv with batch norm
// op: conv + (elementwise_add +) batch_norm
// named nodes:
// conv_weight, conv_out, conv,
// bn_x, bn_scale, bn_bias, bn_mean,  bn_variance,
// bn_batch_norm, bn_y, bn_mean_out, bn_variance_out,
// bn_saved_mean, bn_saved_variance
struct ConvBN : public PatternBase {
  ConvBN(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "conv_bn") {}

  PDNode* operator()(PDNode* conv_input, bool with_eltwise_add);

  // declare operator node's name
  PATTERN_DECL_NODE(conv);
  PATTERN_DECL_NODE(batch_norm);
  PATTERN_DECL_NODE(eltwise);  // ELEMENTWISE_ADD
  // CONV inputs
  PATTERN_DECL_NODE(conv_weight);  // Filter
  // CONV outputs
  PATTERN_DECL_NODE(conv_out);  // tmp
  // ELTWISE inputs
  PATTERN_DECL_NODE(eltwise_y_in);
  // ELTWISE outputs
  PATTERN_DECL_NODE(eltwise_out);  // tmp
  // BN inputs
  PATTERN_DECL_NODE(bn_scale);
  PATTERN_DECL_NODE(bn_bias);
  PATTERN_DECL_NODE(bn_mean);
  PATTERN_DECL_NODE(bn_variance);
  // BN outputs
  PATTERN_DECL_NODE(bn_out);  // Out
  PATTERN_DECL_NODE(bn_mean_out);
  PATTERN_DECL_NODE(bn_variance_out);
  PATTERN_DECL_NODE(bn_saved_mean);
  PATTERN_DECL_NODE(bn_saved_variance);
};

// CONV with ReLU
// op: conv + relu
// named nodes:
// conv_input, conv_weight,
// conv_out, conv,
// relu_out, relu
struct ConvReLU : public PatternBase {
  ConvReLU(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "conv_relu") {}

  PDNode* operator()(PDNode* conv_input);

  // declare operator node's name
  PATTERN_DECL_NODE(conv);
  PATTERN_DECL_NODE(relu);
  // declare variable node's name
  PATTERN_DECL_NODE(conv_weight);
  PATTERN_DECL_NODE(conv_out);
  PATTERN_DECL_NODE(relu_out);
};

// SEQCONV with Elementwise_Add ReLU
// op: seqconv + elementwise_add + relu
// named nodes:
// seqconv_input, seqconv_weight,
// seqconv_out, seqconv,
// elementwise_add_bias, elementwise_add_out, elementwise_add
// relu_out, relu
struct SeqConvEltAddRelu : public PatternBase {
  SeqConvEltAddRelu(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "seqconv_eltadd_relu") {}

  PDNode* operator()(PDNode* seqconv_input);

  // declare operator node's name
  PATTERN_DECL_NODE(seqconv);
  PATTERN_DECL_NODE(eltadd);
  PATTERN_DECL_NODE(relu);
  // declare variable node's name
  PATTERN_DECL_NODE(seqconv_weight);
  PATTERN_DECL_NODE(seqconv_out);
  PATTERN_DECL_NODE(eltadd_bias);
  PATTERN_DECL_NODE(eltadd_out);
  PATTERN_DECL_NODE(relu_out);
};

// FC with bias
// op: mul + elementwise_add
// named nodes:
// mul, elementwise_add
// w, mul_out, bias, fc_out
struct FC : public PatternBase {
  FC(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "fc") {}

  PDNode* operator()(PDNode* x, bool with_bias);

  // declare operator node's name
  PATTERN_DECL_NODE(fc);
  PATTERN_DECL_NODE(mul);
  PATTERN_DECL_NODE(elementwise_add);
  // declare variable node's name
  PATTERN_DECL_NODE(w);
  PATTERN_DECL_NODE(mul_out);  // (x,w) -> mul_out
  PATTERN_DECL_NODE(bias);
  PATTERN_DECL_NODE(Out);
};

// Embedding
struct Embedding : public PatternBase {
  Embedding(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "embedding") {}

  PDNode* operator()(PDNode* x);

  // declare operator node's name
  PATTERN_DECL_NODE(lookup_table);
  // Inputs
  //
  PATTERN_DECL_NODE(Ids);
  PATTERN_DECL_NODE(W);  // embeddings
  // Outputs
  PATTERN_DECL_NODE(Out);
};

struct LSTM : public PatternBase {
  LSTM(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "lstm") {}

  PDNode* operator()(PDNode* x);

  // Operators
  PATTERN_DECL_NODE(lstm);

  // Inputs
  PATTERN_DECL_NODE(Input);
  PATTERN_DECL_NODE(H0);
  PATTERN_DECL_NODE(C0);
  PATTERN_DECL_NODE(Weight);
  PATTERN_DECL_NODE(Bias);

  // Outputs
  PATTERN_DECL_NODE(Hidden);
  PATTERN_DECL_NODE(Cell);
  PATTERN_DECL_NODE(BatchGate);
  PATTERN_DECL_NODE(BatchCellPreAct);
};

struct GRU : public PatternBase {
  GRU(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "gru") {}

  PDNode* operator()(PDNode* x);

  // Operators
  PATTERN_DECL_NODE(gru);

  // Inputs
  PATTERN_DECL_NODE(Bias);
  PATTERN_DECL_NODE(Weight);

  // Outputs
  PATTERN_DECL_NODE(BatchGate);
  PATTERN_DECL_NODE(BatchResetHiddenPrev);
  PATTERN_DECL_NODE(BatchHidden);
  PATTERN_DECL_NODE(Hidden);
};

// The following patterns are used to fuse elewise_add and act
// formula: act(ele_add(x, y))
// op: elementwise_add + act
// named nodes: elementwise_add, act
//              ele_x, ele_y, elewise_add_out, act_out
struct ElewiseAddAct : public PatternBase {
  ElewiseAddAct(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "elewise_add_act") {}

  PDNode* operator()(PDNode* x, std::unordered_set<std::string> acts);

  // declare operator node's name
  PATTERN_DECL_NODE(ele_add);
  PATTERN_DECL_NODE(act);
  // declare variable node's name
  PATTERN_DECL_NODE(elewise_add_out);
  PATTERN_DECL_NODE(ele_y);
  PATTERN_DECL_NODE(act_out);
};

// formula: ele_add(x, act(y))
// op: elementwise_add + act
// named nodes: elementwise_add, act
//              act_in, act_out, ele_x, elewise_add_out
struct ActElewiseAdd : public PatternBase {
  ActElewiseAdd(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "act_elewise_add") {}

  PDNode* operator()(PDNode* x, std::unordered_set<std::string> acts);

  // declare operator node's name
  PATTERN_DECL_NODE(act);
  PATTERN_DECL_NODE(ele_add);
  // declare variable node's name
  PATTERN_DECL_NODE(act_out);
  PATTERN_DECL_NODE(ele_x);
  PATTERN_DECL_NODE(elewise_add_out);
};

// the backward of act(ele_add(x, y))
// the act is inplace.
// op: elementwise_add_grad + act_grad
// named nodes: elementwise_add_grad, act_grad
//              act_out, act_out_g, ele_y, d_itermediate_out, d_ele_x, d_ele_y
struct ElewiseAddActInplaceGrad : public PatternBase {
  ElewiseAddActInplaceGrad(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "elewise_add_act_grad1") {}

  // act_grad: in["Out", "Out@GRAD"], out["X@GRAD"]
  // ele_add_grad: in["Y", "Out@GRAD"], out["X@GRAD", "Y@GRAD"]
  PDNode* operator()(PDNode* x, std::unordered_set<std::string> acts);

  // declare operator node's name
  PATTERN_DECL_NODE(act_grad);
  PATTERN_DECL_NODE(ele_add_grad);
  // declare variable node's name
  PATTERN_DECL_NODE(act_out);
  PATTERN_DECL_NODE(d_itermediate_out);
  PATTERN_DECL_NODE(d_ele_x);
  PATTERN_DECL_NODE(d_ele_y);
  PATTERN_DECL_NODE(ele_y);
};

// Conv with Elementwise_add as bias
// op: conv + elementwise_add
// named nodes:
// conv_input, conv_weight,
// conv_out, conv,
// eltwise_bias, eltwise_out,
// elementwise_add
struct ConvBias : public PatternBase {
  ConvBias(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "conv_bias") {}
  PDNode* operator()(PDNode* conv_input, bool is_conv3d = false);
  // declare operator node's name
  PATTERN_DECL_NODE(conv);
  PATTERN_DECL_NODE(eltwise);
  // declare variable node's name
  PATTERN_DECL_NODE(conv_weight);
  PATTERN_DECL_NODE(conv_out);
  PATTERN_DECL_NODE(eltwise_bias);
  PATTERN_DECL_NODE(eltwise_out);
};

// Convolution op
// Forward pass for convolution.
// conv_input, conv_bias and conv_filter are inputs.
// conv_output is a result of the operator.
// residual_data is data used by skip connection.
// If residual connection fusion is on, the formula is:
// conv_output = conv_op(conv_filter, conv_input, conv_bias)
//             + conv_residual_data
// If the fusion is off, conv_residual_data is not added.
struct Conv : public PatternBase {
  Conv(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "convolution") {}

  PDNode* operator()();

  PATTERN_DECL_NODE(conv_op);
  PATTERN_DECL_NODE(conv_input);
  PATTERN_DECL_NODE(conv_filter);
  PATTERN_DECL_NODE(conv_residual_data);
  PATTERN_DECL_NODE(conv_output);
};

// Convolution op with residual data
struct ConvResidual : public PatternBase {
  ConvResidual(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "conv_residual") {}

  PDNode* operator()(bool with_residual_data);

  PATTERN_DECL_NODE(conv_op);
  PATTERN_DECL_NODE(conv_input);
  PATTERN_DECL_NODE(conv_filter);
  PATTERN_DECL_NODE(conv_residual_data);
  PATTERN_DECL_NODE(conv_output);
};

// Pool op
// Forward pass for pooling.
// pool_input is the input.
// pool_output is a result of the operator.
struct Pool : public PatternBase {
  Pool(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "pooling") {}

  PDNode* operator()();

  PATTERN_DECL_NODE(pool_op);
  PATTERN_DECL_NODE(pool_input);
  PATTERN_DECL_NODE(pool_output);
};

// ElementwiseAdd used in residual connections.
// y_var is used and convolution output.
// The operator is removed, when residual
// connection fusion is on.
struct ElementwiseAdd : public PatternBase {
  ElementwiseAdd(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "elementwise_add") {}

  PDNode* operator()(PDNode* x_var, PDNode* y_var);

  PATTERN_DECL_NODE(elementwise_add_op);
  PATTERN_DECL_NODE(elementwise_add_x);
  PATTERN_DECL_NODE(elementwise_add_y);
  PATTERN_DECL_NODE(elementwise_add_out);
};

// Conv + ElementwiseAdd + an activation
// This pattern can futher fuse the conv related ops after the conv+bn fusion.
struct ConvElementwiseaddAct : public PatternBase {
  ConvElementwiseaddAct(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "conv_elementwiseadd_act") {}

  PDNode* operator()(PDNode* conv_in);

  PATTERN_DECL_NODE(conv_op);
  PATTERN_DECL_NODE(conv_out);
  PATTERN_DECL_NODE(conv_filter);

  PATTERN_DECL_NODE(elementwise_add_op);
  PATTERN_DECL_NODE(elementwise_add_in_y);  // input
  PATTERN_DECL_NODE(elementwise_add_out);

  PATTERN_DECL_NODE(act_op);
  PATTERN_DECL_NODE(act_out);
};

// Conv + ElementwiseAdd + ElementwiseAdd + Activation
struct ConvElementwiseadd2Act : public PatternBase {
  ConvElementwiseadd2Act(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope,
                    "conv_elementwiseadd2_elementwiseadd_act") {}

  PDNode* operator()(PDNode* conv_in);

  PATTERN_DECL_NODE(conv_op);
  PATTERN_DECL_NODE(conv_filter);
  PATTERN_DECL_NODE(conv_out);

  PATTERN_DECL_NODE(elementwise_add_op);
  PATTERN_DECL_NODE(elementwise_add_in_y);  // input
  PATTERN_DECL_NODE(elementwise_add_out);

  PATTERN_DECL_NODE(elementwise_add_op_1);
  PATTERN_DECL_NODE(elementwise_add_in_y_1);  // input
  PATTERN_DECL_NODE(elementwise_add_out_1);

  PATTERN_DECL_NODE(act_op);
  PATTERN_DECL_NODE(act_out);
};

// Conv + ElementwiseAdd
// This pattern should be used after ConvElementwiseadd2Act or
// ConvElementwiseadd pass
struct ConvElementwiseadd : public PatternBase {
  ConvElementwiseadd(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "conv_elementwiseadd") {}

  PDNode* operator()(PDNode* conv_in);

  PATTERN_DECL_NODE(conv_op);
  PATTERN_DECL_NODE(conv_out);
  PATTERN_DECL_NODE(conv_filter);

  PATTERN_DECL_NODE(elementwise_add_op);
  PATTERN_DECL_NODE(elementwise_add_in_y);
  PATTERN_DECL_NODE(elementwise_add_out);
};

// Conv with affine_channel
// op: conv + (elementwise_add +) affine_channel
// named nodes:
// conv_weight, conv_out, conv,
// ac_x, ac_scale, ac_bias
// affine_channel, ac_out
struct ConvAffineChannel : public PatternBase {
  ConvAffineChannel(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "conv_affine_channel") {}

  PDNode* operator()(PDNode* conv_input, bool with_eltwise_add);

  // declare operator node's name
  PATTERN_DECL_NODE(conv);
  PATTERN_DECL_NODE(affine_channel);
  PATTERN_DECL_NODE(eltwise);  // ELEMENTWISE_ADD
  // CONV inputs
  PATTERN_DECL_NODE(conv_weight);  // Filter
  // CONV outputs
  PATTERN_DECL_NODE(conv_out);  // tmp
  // ELTWISE inputs
  PATTERN_DECL_NODE(eltwise_y_in);
  // ELTWISE outputs
  PATTERN_DECL_NODE(eltwise_out);  // tmp

  // AC(Affine_Channel) inputs
  PATTERN_DECL_NODE(ac_scale);
  PATTERN_DECL_NODE(ac_bias);
  // AC outputs
  PATTERN_DECL_NODE(ac_out);  // Out
};

// Dequantize + Quantize + anyOP
// This pattern is used for squashing the dequantize-quantize pairs.
struct DequantQuantAny : public PatternBase {
  DequantQuantAny(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "dequant_quant_any") {}
  PDNode* operator()();

  PATTERN_DECL_NODE(dequant_in);
  PATTERN_DECL_NODE(dequant_op);
  PATTERN_DECL_NODE(dequant_out);
  PATTERN_DECL_NODE(quant_op);
  PATTERN_DECL_NODE(quant_out);
  PATTERN_DECL_NODE(next_op);
};

// Dequantize + anyOP
// This quantize is used for getting number of ops the Dequantize's
// output is an input to.
struct DequantAny : public PatternBase {
  DequantAny(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "dequant_any") {}
  PDNode* operator()();

  PATTERN_DECL_NODE(dequant_op);
  PATTERN_DECL_NODE(dequant_out);
  PATTERN_DECL_NODE(next_op);
};

struct TransposeFlattenConcat : public PatternBase {
  TransposeFlattenConcat(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "transpose_flatten_concat") {}

  PDNode* operator()(std::vector<PDNode*> conv_inputs, int times);

  std::string GetNodeName(const std::string& op_type) {
    return PDNodeName(name_scope_, repr_, id_, op_type);
  }

  PDNode* GetPDNode(const std::string& op_type) {
    return pattern->RetrieveNode(GetNodeName(op_type));
  }
};

struct AnakinDetectionPattern : public PatternBase {
  AnakinDetectionPattern(PDPattern* pattern, const std::string& name_scope)
      : PatternBase(pattern, name_scope, "anakin_detect_pattern") {}

  PDNode* operator()(std::vector<PDNode*> conv_inputs, int times);

  std::string GetNodeName(const std::string& op_type) {
    return PDNodeName(name_scope_, repr_, id_, op_type);
  }

  PDNode* GetPDNode(const std::string& op_type) {
    return pattern->RetrieveNode(GetNodeName(op_type));
  }
};

}  // namespace patterns

// Link two ir::Nodes from each other.
#define IR_NODE_LINK_TO(a, b) \
  a->outputs.push_back(b);    \
  b->inputs.push_back(a);

// Set the out_var as the output of the op
#define IR_OP_VAR_LINK(op, out_var) \
  op->outputs.push_back(out_var);   \
  out_var->inputs.clear();          \
  out_var->inputs.push_back(op);

}  // namespace ir
}  // namespace framework
}  // namespace paddle