/*
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you 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.
*/
/*!
* \file tvm/relay/pass.h
* \brief The set of Relay passes written in C++.
*
* This file also implements a pass manager. The pass manager manages a sequence
* of Relay-to-Relay transformation passes over a particlar unit of AST. The
* design is largely inspired from LLVM's pass manager and modern deep learning
* frameworks that perform tensor->tensor transformations.
*
* The responsibilities of a traditional compiler pass manager usually involves:
* - Organizing the execution order of optimization passes though not
* necessarily in the optimal sequence.
* - Collecting required analysis information and keep them up-to-date.
* - Reducing the effort required to implement new passes for compiler
* developers, etc.
*
* Similar to LLVM's pass manager, we designed the Relay pass manager to work
* different granularity, i.e. module level, function level, and even sequential
* passe that contains a host of passes.
*
* However, we also extend the functionality of the traditional pass manager
* with the consideration of requirements/convention from deep learning
* frameworks, such as Pytorch and Gluon, etc. Each pass in the Relay pass
* manager performs the Relay.Module -> Relay.Module transformation. All
* different types of passes, including the sequential-level pass object, are
* essentially pass objects. This design, therefore, effectively provides users
* a consistent and convenient interface, i.e. Pass, to play with. It offers a
* means to ease the development and testing of Relay passes. For example, with
* the pass manager, external users will be able to have custom passes correctly
* scheduled without having to modify a single handcrafted pass order.
*
* In the future we need to describe constraints between passes. For example,
* we may want to preserve dependencies between different passes and validate
* them on the completion of a certain pass.
*
* We also need to store side information and import the error reporting system.
*/
#ifndef TVM_RELAY_PASS_H_
#define TVM_RELAY_PASS_H_
#include <tvm/ir.h>
#include <tvm/packed_func_ext.h>
#include <tvm/relay/error.h>
#include <tvm/relay/expr.h>
#include <tvm/relay/module.h>
#include <tvm/relay/op_attr_types.h>
#include <tvm/relay/type.h>
#include <tvm/relay/adt.h>
#include <string>
#include <vector>
namespace tvm {
namespace relay {
namespace pass {
/*
* \brief The context of pass.
*/
class PassContext;
/*!
* \brief PassContextNode contains the information that a pass can rely on, such as
* analysis results.
*/
class PassContextNode : public RelayNode {
public:
/*!
* \brief The error reporter used to notify users why an optimization fails.
*/
ErrorReporter err_reporter;
PassContextNode() = default;
void VisitAttrs(tvm::AttrVisitor* v) final {
}
TVM_DLL static PassContext make();
static constexpr const char* _type_key = "relay.PassContext";
TVM_DECLARE_NODE_TYPE_INFO(PassContextNode, RelayNode);
};
TVM_DEFINE_NODE_REF(PassContext, PassContextNode)
/*
* \brief The meta data of a pass.
*
* PassInfo can be extended conveniently in the future if more meta information
* is needed.
*/
class PassInfo;
/*!
* \brief PassInfoNode contains meta data that will be used to help optimization
* and analysis.
*/
class PassInfoNode : public RelayNode {
public:
/*! \brief The minimal optimization level that this pass will be enabled. */
int opt_level;
/*! \brief The name of an optimization/analysis pass. */
std::string name;
/*! \brief The passes that are required to perform the current pass. */
tvm::Array<tvm::Expr> required;
PassInfoNode() = default;
void VisitAttrs(tvm::AttrVisitor* v) final {
v->Visit("opt_level", &opt_level);
v->Visit("name", &name);
v->Visit("required", &required);
}
TVM_DLL static PassInfo make(int opt_level, std::string name,
tvm::Array<tvm::Expr> required);
static constexpr const char* _type_key = "relay.PassInfo";
TVM_DECLARE_NODE_TYPE_INFO(PassInfoNode, RelayNode);
};
TVM_DEFINE_NODE_REF(PassInfo, PassInfoNode)
class Pass;
/*!
* \brief PassNode is the base type of differnt types of optimization passes.
* It is designed as a pure class and implemented by different pass subclasses
* at different granularity of Relay nodes.
*/
class PassNode : public RelayNode {
public:
/*
* \brief Get the pass information/meta data. */
virtual PassInfo Info() const = 0;
/*!
* \brief Set the context information for a pass.
*
* \param pass_ctx The context information for a certain pass.
*/
virtual void SetContext(const PassContext& pass_ctx) = 0;
/*!
* \brief Execute the optimization pass using a functor.
*
* \param mod The module that an optimization pass runs on.
*
* \return The updated module.
*/
virtual Module operator()(const Module& mod) const = 0;
void VisitAttrs(tvm::AttrVisitor* v) override {}
static constexpr const char* _type_key = "relay.Pass";
TVM_DECLARE_BASE_NODE_INFO(PassNode, RelayNode);
};
class Pass : public NodeRef {
public:
Pass() = default;
explicit Pass(NodePtr<tvm::Node> p) : NodeRef(p) {}
PassNode* operator->() const {
return static_cast<PassNode*>(this->node_.get());
}
using ContainerType = PassNode;
};
/*
* \brief Create a module pass.
*
* \param pass_func The packed function that contains the optimization.
* \param opt_level The optimization level of the module pass.
* \param name The name of the module pass.
* \param required The list of the passes that the module pass is dependent on.
*
* \return The created module pass.
*/
Pass CreateModulePass(
const runtime::TypedPackedFunc<Module(Module, PassContext)>& pass_func,
int opt_level,
const std::string& name,
const tvm::Array<tvm::Expr>& required);
/*
* \brief Create a function pass.
*
* \param pass_func The packed function that contains the optimization.
* \param opt_level The optimization level of the function pass.
* \param name The name of the function pass.
* \param required The list of the passes that the function pass is dependent on.
*
* \return The created function pass.
*/
Pass CreateFunctionPass(
const runtime::TypedPackedFunc<Function(Function, PassContext)>& pass_func,
int opt_level,
const std::string& name,
const tvm::Array<tvm::Expr>& required);
/*
* \brief Create a sequential pass.
*
* \param passes The optimization passes will be performed.
* \param opt_level The optimization level of the sequential pass.
* \param name The name of the sequential pass.
* \param required The list of the passes that the sequential pass is dependent on.
* \param disabled The disabled passes.
*
* \return The created sequential pass.
*/
Pass CreateSequentialPass(const tvm::Array<Pass>& passes,
int opt_level,
const std::string& name,
const tvm::Array<tvm::Expr>& required,
const tvm::Array<tvm::Expr>& disabled);
} // namespace pass
/*!
* \brief Infer the type of an expression.
*
* The result of type checking is a new expression with unambigous
* type information filled in, as well as it's checked type field
* populated with the result type.
*
* \param expr The expression to type check.
* \param mod The module used for referencing global functions, can be
* None.
*
* \return A type checked expression with its checked_type field populated.
*/
TVM_DLL Expr InferType(const Expr& expr, const Module& mod);
/*!
* \brief Infer the type of a function as if it is mapped to var in the mod.
*
* \param f the function.
* \param mod The module used for referencing global functions.
* \param var The global variable corresponding to the function.
*
* \return A type checked Function with its checked_type field populated.
* \note this function mutates mod and is not thread-safe.
*/
TVM_DLL Function InferType(const Function& f, const Module& mod,
const GlobalVar& var);
/*!
* \brief Check that types are well kinded by applying "kinding rules".
*
* This pass ensures we do not do things that violate the design of the
* type system when writing down types.
*
* For example tensors are not allowed to contain functions in Relay.
*
* We check this by ensuring the `dtype` field of a Tensor always contains
* a data type such as `int`, `float`, `uint`.
*
* \param t The type to check.
* \param mod The global module.
*
* \return The kind of the passed type.
*/
TVM_DLL Kind KindCheck(const Type& t, const Module& mod);
/*! \brief Compare two expressions for structural equivalence.
*
* This comparison operator respects scoping and compares
* expressions without regard to variable choice.
*
* For example: `let x = 1 in x` is equal to `let y = 1 in y`.
*
* See https://en.wikipedia.org/wiki/Lambda_calculus#Alpha_equivalence
* for more details.
*
* \param e1 The left hand expression.
* \param e2 The right hand expression.
*
* \return true if equal, otherwise false
*/
TVM_DLL bool AlphaEqual(const Expr& e1, const Expr& e2);
/*! \brief Compare two types for structural equivalence.
*
* This comparison operator respects scoping and compares
* expressions without regard to variable choice.
*
* For example: `forall s, Tensor[f32, s]` is equal to
* `forall w, Tensor[f32, w]`.
*
* See https://en.wikipedia.org/wiki/Lambda_calculus#Alpha_equivalence
* for more details.
*
* \param t1 The left hand type.
* \param t2 The right hand type.
*
* \return true if equal, otherwise false
*/
TVM_DLL bool AlphaEqual(const Type& t1, const Type& t2);
/*! \brief Check that each Var is only bound once.
*
* For example, the expression `let x = 1 in let x = 2 in 3` bound x twice.
*
* `let f = (\x -> x) in let g = (\x -> x + 1) in f(g(2))` also bound x twice,
* although x is not shadowed.
*
* \param expr the expression to check.
*
* \return true iff all Var in expr is bound at most once.
*/
TVM_DLL bool WellFormed(const Expr& expr);
/*! \brief Get all bound variables from expression expr.
*
* Bound variables are all variables that are declared in the expr.
* They only have meaning inside that expr, and can only be used in it.
*
* \param expr the expression.
*
* \return List of bound vars, in the PostDFS order in the expression.
*/
TVM_DLL tvm::Array<Var> BoundVars(const Expr& expr);
/*! \brief Get all bound variables from pattern pat.
*
* Bound variables are all variables that got bound by the pat.
* They only have meaning inside that expr, and can only be used in it.
*
* \param pat the Pattern.
*
* \return List of bound vars, in the PostDFS order in the expression.
*/
TVM_DLL tvm::Array<Var> BoundVars(const Pattern& pat);
/*! \brief Get free type parameters from expression expr.
*
* Free variables are variables that are not bound by a
* let or a function parameter in the context.
*
* \param expr the expression.
*
* \return List of free vars, in the PostDFS order in the expression.
*/
TVM_DLL tvm::Array<Var> FreeVars(const Expr& expr);
/*! \brief Get all variables from expression expr.
*
* \param expr the expression.
*
* \return List of all vars, in the PostDFS order in the expression.
*/
TVM_DLL tvm::Array<Var> AllVars(const Expr& expr);
/*! \brief Get free TypeVars from expression expr.
*
* Free type parameters are type parameters that are not bound by a function
* type in the context.
*
* \param expr the expression.
* \param mod the module.
*
* \return List of free vars, in the PostDFS order visited by expr.
*/
TVM_DLL tvm::Array<TypeVar> FreeTypeVars(const Expr& expr, const Module& mod);
/*! \brief Get free TypeVars from type t.
*
* Free type parameters are type parameters that are not bound by a function
* type in the context.
*
* \param t the type.
* \param mod the module.
*
* \return List of free type vars, in the PostDFS order visited by type.
*/
TVM_DLL tvm::Array<TypeVar> FreeTypeVars(const Type& t, const Module& mod);
/*! \brief Get all bound type variables from expression expr.
*
* Bound variables are all type variables that are declared in the expr.
* They only have meaning inside that expr, and can only be used in it.
*
* \param expr the expression.
* \param mod the module.
*
* \return List of bound type vars, in the PostDFS order in the expression.
*/
TVM_DLL tvm::Array<TypeVar> BoundTypeVars(const Expr& expr, const Module& mod);
/*! \brief Get all bound type variables from type t.
*
* Bound variables are all type variables that are declared in the type.
* They only have meaning inside that type, and can only be used in it.
*
* \param t the type
* \param mod the module.
*
* \return List of bound type vars, in the PostDFS order visited by type.
*/
TVM_DLL tvm::Array<TypeVar> BoundTypeVars(const Type& t, const Module& mod);
/*! \brief Get all type variables in expression expr.
*
* \param expr the expression.
* \param mod the module.
*
* \return List of type vars, in the PostDFS order in the expression.
*/
TVM_DLL tvm::Array<TypeVar> AllTypeVars(const Expr& expr, const Module& mod);
/*! \brief Get all type variables in type t.
*
* \param t the type.
* \param mod the module.
*
* \return List of type vars, in the PostDFS order visited by type.
*/
TVM_DLL tvm::Array<TypeVar> AllTypeVars(const Type& t, const Module& mod);
/*! \brief Remove expressions which does not effect the program result.
*
* It will remove let bindings which are not referenced,
* and inline let bindings that are only used once.
*
* For example, this pass should turn `let a = 1 in 2` into `2`,
* as the value of the expression does not depend on a.
*
* As another example, `let a = 1 in a` will be optimized into 1.
*
* \param e the expression to optimize.
*
* \return the optimized expression.
*/
TVM_DLL Expr DeadCodeElimination(const Expr& e);
/*!
* \brief Fold constant expressions.
* \param expr the expression to be optimized.
* \return The optimized expression.
*/
TVM_DLL Expr FoldConstant(const Expr& expr);
/*!
* \brief Fuse operations into expr into seperate functions.
* \param expr The expression.
* \param fuse_opt_level Optimization level.
* \return The optimized expression.
*/
TVM_DLL Expr FuseOps(const Expr& expr, int fuse_opt_level);
/*!
* \brief Apply rewrite rules to rewrite the expr in post DFS order.
* \param expr The expression.
* \param rewrite_map_attr_name The Op's attr name which corresponds to the rewrite
* rule function.
* \param fcontext Additional callback to provide context argument for each call node.
* \param fmulti_ref_trigger Transformation function to be called when
* an Expr consumed by multiple callers.
* \return The rewritten expression.
*/
TVM_DLL Expr ForwardRewrite(const Expr& expr,
const std::string& rewrite_map_attr_name,
std::function<NodeRef(const Call&)> fcontext = nullptr,
std::function<Expr(const Expr&)> fmulti_ref_trigger = nullptr);
/*!
* \brief Apply rewrite rules to rewrite the expr in post DFS order.
* \param expr The expression.
* \param rewrite_func The rewrite func that will apply to all operators.
* \param fcontext Additional callback to provide context argument for each call node.
* \param fmulti_ref_trigger Transformation function to be called when
* an Expr consumed by multiple callers.
* \return The rewritten expression.
*/
TVM_DLL Expr ForwardRewrite(const Expr& expr,
const FForwardRewrite& rewrite_func,
std::function<NodeRef(const Call&)> fcontext = nullptr,
std::function<Expr(const Expr&)> fmulti_ref_trigger = nullptr);
/*!
* \brief Rewrite the annotated program.
* \param expr The expression.
* \param fallback_device The fallback device which is the default device for
* operators without annotation.
* \return The updated program.
*/
TVM_DLL Expr RewriteAnnotatedOps(const Expr& expr, int fallback_device);
/*!
* \brief Collect the device mapping information of each expression.
* \param expr The expression.
* \return The device mapping.
*/
TVM_DLL Map<Expr, Integer> CollectDeviceInfo(const Expr& expr);
/*! \brief A hashing structure in the style of std::hash. */
struct StructuralHash {
/*! \brief Hash a Relay type.
*
* Implements structural hashing of a Relay type.
*
* \param type the type to hash.
*
* \return the hash value.
*/
size_t operator()(const Type& type) const;
/*! \brief Hash a Relay expression.
*
* Implements structural hashing of a Relay expression.
*
* \param expr the expression to hash.
*
* \return the hash value.
*/
size_t operator()(const Expr& expr) const;
};
/*! \brief turn a dataflow graph into Administrative Normal Form, or A-Normal Form (ANF).
*
* It will turn an expression that is in a graph form (with sharing implicit),
* to an expression with explicit sharing (A-Normal Form).
*
* The scope of the root expression is the global scope.
* The scope of any non root expression is the least common ancestor of all it's scope.
*
* Values are ordered by post-DFS order in each scope.
*
* \param e the expression to observably share
*
* \param mod The module used for referencing global functions, can be
* None.
*
* \return expression in A-Normal Form
*/
TVM_DLL Expr ToANormalForm(const Expr& e, const Module& mod);
/*! \brief Remove let binding and directly share via pointer instead.
*
* It will remove all let binding,
* and turn all of the variable bound by let into direct pointer reference.
*
* \param e the expression.
*
* \return the expression in graph normal form.
*/
TVM_DLL Expr ToGraphNormalForm(const Expr& e);
/*! \brief Aggressive constant propagation/constant folding/inlining.
* It will do as much computation in compile time as possible.
* It has two benefit: remove runtime overhead, and allow more optimization (typically fusion).
* As a side effect, code size will explode.
*/
Expr PartialEval(const Expr& e);
} // namespace relay
} // namespace tvm
#endif // TVM_RELAY_PASS_H_